|
469acf6e-c83b-4fd3-9ec8-f3071056700f
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
ipibkpko-4945
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
JAPANESE LONGEVITY DIET
|
JAPANESE LONGEVITY DIET
|
/home/sid/tuning/finetune/backend/output/ipibkpko- /home/sid/tuning/finetune/backend/output/ipibkpko-4945/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a visual infographic-style guide expla This PDF is a visual infographic-style guide explaining the key principles of the Japanese longevity diet, highlighting the foods, nutrients, eating habits, and cultural practices associated with Japan’s famously long life expectancy (84.78 years). It presents a clear overview of the traditional Japanese diet, its health benefits, and how various food groups contribute to longevity through nutrient richness, digestive support, cardiovascular protection, and immune enhancement.
The infographic also includes culturally significant facts, dietary pillars, common dishes, and the role of soy, rice, vegetables, algae, and fermented foods in Japan’s long-lived population.
🍱 1. Pillars of the Japanese Longevity Diet
The document organizes the longevity diet into foundational food groups, each with scientific and nutritional value:
⭐ Rice
Rich in carbohydrates, protein, minerals (especially phosphorus & potassium), vitamin E, B vitamins, and fiber—promotes digestive health and fullness.
infographics-japanese-longgevit…
⭐ Fish & Seafood
High in omega-3 fatty acids, crucial for nervous, immune, and cardiovascular systems; rich in iodine and selenium.
infographics-japanese-longgevit…
⭐ Algae (Wakame, Nori)
Loaded with macro- & micronutrients, vitamin C, beta-carotene, fiber, protein, and omega-3s; noted for anti-cancer, antibacterial, and antiviral effects.
infographics-japanese-longgevit…
⭐ Soy & Beans
Provide protein, lecithin, fiber, vitamins E, K2, and B-group vitamins; recommended for gut health and malabsorption.
infographics-japanese-longgevit…
⭐ Nattō
A fermented soy food containing nattokinase, which helps regulate blood pressure, cholesterol, blood sugar, and coagulation; also has anti-cancer benefits.
infographics-japanese-longgevit…
⭐ Raw or Undercooked Eggs
Source of proteins, lecithin, and fats that support nervous and immune system function.
infographics-japanese-longgevit…
⭐ Tsukemono (Fermented Pickles)
Contain lactic acid bacteria that enhance digestion, immunity, and microbiome health.
infographics-japanese-longgevit…
⭐ Matcha (Powdered Green Tea)
Rich in polyphenols and flavonoids; supports cardiovascular health and reduces cholesterol.
infographics-japanese-longgevit…
⭐ Vegetables & Fresh Spices
Turnip, onions, cabbage, chives—high in fiber, vitamins, and minerals.
infographics-japanese-longgevit…
⭐ Fungi (e.g., Shiitake)
Provide enzymes and beta-D-glucan, a compound that boosts immune defenses, especially against cancer.
infographics-japanese-longgevit…
🍜 2. Japanese Soups and Noodle Dishes
The infographic gives examples of traditional soups:
Miso Ramen – wheat noodles in a meat broth with pork toppings.
Soba – buckwheat noodles in a soy-fish broth with algae.
Mandu-guk – egg noodles and dumplings in soup.
infographics-japanese-longgevit…
These dishes reflect the balance of proteins, fermented foods, and mineral-rich broths in Japanese cuisine.
🫘 3. Soy-Based Foods
The PDF categorizes soy foods by fermentation level:
✔ Natto – fermented, rich in nattokinase
✔ Soy sauce & miso paste – fermented flavoring agents
✔ Tofu – unfermented soy milk product
✔ Edamame – unfermented green soybeans
Each category illustrates soy’s central role in Japanese health and nutrition.
infographics-japanese-longgevit…
🍚 4. Rice-Based Foods
The infographic shows familiar rice dishes:
✔ Sushi – vinegared rice with raw/marinated fish
✔ Onigiri – triangular rice balls wrapped in nori
✔ Boiled rice – a staple side dish
✔ Mochi – rice cakes often filled with beans or tea flavors
infographics-japanese-longgevit…
These highlight rice as the foundation of the Japanese dietary pattern.
💡 5. “Did You Know?” Cultural Longevity Insights
The PDF includes cultural notes explaining why Japanese dietary habits support long life:
Japanese eat little bread or potatoes—they rely on rice.
Genuine wasabi is extremely expensive and potent.
Meals are celebrated (e.g., tea ceremony), and eating while walking is discouraged.
Historically, meat consumption was restricted until the 19th century.
Japanese cooking uses little sugar or salt; flavors come from soy sauce, ginger, and wasabi.
Matcha often replaces coffee and chocolate.
Meals consist of small, colorful seasonal dishes, eaten slowly and mindfully with chopsticks.
infographics-japanese-longgevit…
These cultural behaviors reinforce healthy digestion, slower eating, portion control, and enjoyment of food—all linked to longevity.
⭐ Overall Summary
This infographic presents a complete visual guide to the Japanese longevity diet, highlighting nutrient-dense whole foods such as rice, fish, algae, soy, vegetables, fungi, fermented foods, and matcha. It emphasizes balanced meals, mindful eating, low sugar and low salt intake, and fermented dishes that support gut health. It also connects Japanese cultural customs with remarkable longevity....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/ipibkpko-4945/data/document.pdf", "num_examples": 4, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/ipibkpko- /home/sid/tuning/finetune/backend/output/ipibkpko-4945/data/ipibkpko-4945.json...
|
null
|
completed
|
1764888328
|
1764888925
|
NULL
|
/home/sid/tuning/finetune/backend/output/ipibkpko- /home/sid/tuning/finetune/backend/output/ipibkpko-4945/adapter...
|
False
|
Edit
Delete
|
|
9e398b73-5266-4658-aafe-dfc32f30fd45
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
dbwgstxo-2209
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Increased Longevity in Eu
|
Increased Longevity in Europe
|
/home/sid/tuning/finetune/backend/output/dbwgstxo- /home/sid/tuning/finetune/backend/output/dbwgstxo-2209/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This report examines one of the most pressing demo This report examines one of the most pressing demographic questions in modern Europe: As Europeans live longer, are they gaining more years of healthy life—or simply spending more years in poor health? Using high-quality, internationally comparable data from the Global Burden of Disease (GBD) project for 43 European countries (1990–2019), the authors analyze trends in:
Life expectancy (LE)
Healthy life expectancy (HALE)
Unhealthy life expectancy (UHLE)
The central aim is to determine whether Europe is experiencing compression of morbidity (more healthy years) or expansion of morbidity (more unhealthy years) as longevity rises.
🔍 Key Findings
1. All European regions show rising LE, HALE, and UHLE
Across Central/Eastern, Northern, Southern, and Western Europe, both life expectancy and years lived in poor and good health have increased. But the balance differs sharply by region and over time.
2. Strong regional disparities persist
Southern & Western Europe enjoy the highest HALE levels.
Central & Eastern Europe consistently show lower HALE, strongly affected by the post-Soviet mortality crisis in the early 1990s.
Northern Europe sits between these groups, gradually converging with Western/Southern Europe.
3. Women live longer but spend more years in poor health
Women have higher LE, HALE, and UHLE, but their extra years tend to be more unhealthy years. The expansion of morbidity is more pronounced among women than men.
4. Countries with initially lower longevity gained more healthy years
The study finds a strong pattern:
Countries with low LE in 1990 (e.g., Russia, Latvia) gained longevity mainly through increases in HALE—over 90% of LE gains came from added healthy years.
Countries with high LE in 1990 (e.g., Switzerland, France) gained longevity with a larger share of new years spent in poor health—only around 60% of gains came from healthy years.
This reveals a structural limit: as countries approach high longevity ceilings, further gains tend to add more years with illness, because the remaining room for improvement lies in very old age.
5. Europe is experiencing a partial expansion of morbidity
The results align more closely with Gruenberg’s morbidity expansion hypothesis (1977) than with Fries’ compression of morbidity theory (1980).
Why?
Because at advanced ages—where further mortality reductions must occur—chronic disease and disability are common. Thus, more longevity increasingly means more years with illness, unless major health improvements occur at older ages.
6. Spain stands out as a positive case
Spain shows:
One of the highest life expectancies in Europe
A very high proportion of years lived in good health
A favorable balance between HALE and UHLE increases
Spain is a standout example of adding both years to life and life to years.
🧠 Interpretation & Implications
If longevity continues rising beyond 100 years (as some projections suggest), Europe may face:
More years lived with multiple chronic conditions (co-morbidity)
Increasing pressure on health and long-term care systems
A widening gap between quantity and quality of life
Policy implications
The authors emphasize the need to:
Delay onset of disease and disability through public health and prevention
Promote healthy lifestyles and supportive socioeconomic conditions
Invest in new medical treatments and technologies
Improve the quality of life among people living with chronic illness
Without such interventions, rising longevity may come at the cost of substantially more years lived in poor health.
🏁 Conclusion
Europe has succeeded in adding years to life, but is only partially succeeding in adding life to those years. While life expectancy continues to rise steadily, healthy life expectancy does not always rise at the same pace—especially in already long-lived nations.
For most European countries, the future challenge is clear:
How can we ensure that the extra years gained through rising longevity are healthy ones, not years spent in illness and disability?...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/dbwgstxo-2209/data/document.pdf", "num_examples": 9, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/dbwgstxo- /home/sid/tuning/finetune/backend/output/dbwgstxo-2209/data/dbwgstxo-2209.json...
|
null
|
completed
|
1764888760
|
1764890564
|
NULL
|
/home/sid/tuning/finetune/backend/output/dbwgstxo- /home/sid/tuning/finetune/backend/output/dbwgstxo-2209/adapter...
|
False
|
Edit
Delete
|
|
fe4b6e3c-4f53-4aca-b99c-7a24177192b2
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
bcdylrfz-2817
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Increase of Human Life
|
Increase of Human Longevity
|
/home/sid/tuning/finetune/backend/output/bcdylrfz- /home/sid/tuning/finetune/backend/output/bcdylrfz-2817/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a comprehensive demographic presentati This PDF is a comprehensive demographic presentation that explains how human longevity has increased over the past 250 years, the biological, social, and medical drivers behind those improvements, and whether there is a true limit to human lifespan. Created by John R. Wilmoth, one of the world’s leading demographers and former director of the UN Population Division, the document provides historical data, scientific analysis, and future projections on global life expectancy.
It combines global mortality statistics, historical transitions in causes of death, medical breakthroughs, and theoretical debates to explain how humans moved from a world where average life expectancy was 30 years to a world where it routinely exceeds 80—and may continue rising.
🔶 1. Purpose of the Presentation
The PDF aims to:
Trace the historical rise of life expectancy
Explain age patterns of mortality and how they shifted
Identify medical, social, and historical reasons for increased longevity
Examine the debate about biological limits to lifespan
Forecast future trends in global life expectancy
Increase of Human Longevity Pas…
🔶 2. Historical Increase of Longevity
The document shows dramatic gains in life expectancy from the 18th century to the 21st century.
⭐ Key historical facts:
Prehistoric humans: 20–35 years average life expectancy
Sweden in 1750s: 36 years
USA in 1900: 48 years
France in 1950: 66 years
Japan in 2007: 83 years with <3 infant deaths per 1,000 births
Increase of Human Longevity Pas…
Charts show life expectancy trends for France, India, Japan, Western Europe, and global regions from 1816–2009.
🔶 3. Changing Age Patterns of Mortality
The PDF shows how the distribution of death has shifted across ages:
In 1900, many deaths occurred at young ages.
By 1995, most deaths were concentrated at older ages.
Survival curves show people living longer and dying more uniformly later in life.
Increase of Human Longevity Pas…
The interquartile range of ages at death shrunk dramatically in Sweden from 1751 to 1995, meaning life has become more predictable and deaths occur later and closer together.
🔶 4. Medical Causes of Mortality Decline
The document clearly identifies the medical advances that propelled longevity increases.
⭐ A. Infectious Disease Decline
Driven by:
Sanitation and clean water
Public health reforms
Hygiene
Antibiotics and sulfonamides
Increase of Human Longevity Pas…
⭐ B. Cardiovascular Disease Decline
Due to:
Reduction in smoking
Healthier diets (lower saturated fat and cholesterol)
Hypertension and cholesterol control
Modern cardiology, diagnostics, and emergency care
Increase of Human Longevity Pas…
⭐ C. Cancer Mortality Trends
The report distinguishes between:
Infectious-cause cancers (e.g., stomach, liver, uterus)
Non-infectious cancers (lung, breast, colon, pancreas, etc.)
Increase of Human Longevity Pas…
Declines in cancer mortality result from:
Infection control (H. pylori, HPV, hepatitis)
Declining smoking rates
Better treatment and earlier detection
🔶 5. Epidemiological Transitions in Human History
The PDF provides a timeline of how the major causes of death shifted as societies developed:
Type of Society Major Cause of Death
Hunter-gatherer Injuries
Agricultural Infectious disease
Industrial Cardiovascular disease
High-tech Cancer
Future Senescence (frailty/aging)
Increase of Human Longevity Pas…
This framework shows the progression from external dangers to internal biological aging as the main determinant of mortality.
🔶 6. Social and Historical Causes of Longevity Increase
Beyond medicine, several societal forces drove longevity gains:
Rising incomes → better nutrition & housing
Science and technology advances
Application of scientific knowledge (public health, medical care)
Improved safety (e.g., fewer road accidents)
Increase of Human Longevity Pas…
A chart shows the strong correlation between national GDP per capita and life expectancy, with richer countries achieving much longer lives.
🔶 7. Are There Limits to Human Lifespan?
The PDF examines one of the most famous debates in demographics:
⭐ Maximum Lifespan
Evidence shows:
The oldest age at death (recorded globally and nationally) has increased over time.
Jeanne Calment (122 years) and Christian Mortensen (115 years) exemplify trends.
Sweden’s maximum age at death rose steadily from 1861–2007.
Increase of Human Longevity Pas…
There is no clear evidence of a fixed biological ceiling.
⭐ Average Lifespan
Mortality rates continue to fall in many countries.
Nations like Japan still make significant gains despite already high longevity.
No sign of stagnation or convergence at a limit.
Increase of Human Longevity Pas…
🔶 8. Summary of Longevity Trends
Indicator Before 1960 After 1970
Average lifespan Increased rapidly Increased moderately
Maximum lifespan Increased slowly Increased moderately
Variability Decreased rapidly Stable
Increase of Human Longevity Pas…
Even though gains have slowed, longevity continues to rise in both average and maximal terms.
🔶 9. Future Projections
UN projections (2009) suggest continued global improvements:
World life expectancy: 68 → 72 → 76 (2009–2049)
Developed countries: 77 → 83+
Japan: 83 → 87
Developing countries also show large gains (India, China, Brazil, Nigeria)
Increase of Human Longevity Pas…
🔶 10. Final Lessons of History
The PDF closes with four key insights:
Mortality decline is driven by humanity’s deep desire for longer life.
Past improvements resulted from multiple causes, not a single breakthrough.
Likewise, no single factor will stop future increases.
With economic growth and political stability, there are no obvious limits to further gains in human longevity.
Increase of Human Longevity Pas…
⭐ Perfect One-Sentence Summary
This PDF provides a comprehensive historical and scientific explanation of how human life expectancy has increased over time, why deaths have shifted to older ages, what medical and social forces drove these improvements, and why there is no clear biological limit preventing future gains in human longevity....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/bcdylrfz-2817/data/document.pdf"}...
|
/home/sid/tuning/finetune/backend/output/bcdylrfz- /home/sid/tuning/finetune/backend/output/bcdylrfz-2817/data/bcdylrfz-2817.json...
|
null
|
failed
|
1764888783
|
1764889686
|
NULL
|
/home/sid/tuning/finetune/backend/output/bcdylrfz- /home/sid/tuning/finetune/backend/output/bcdylrfz-2817/adapter...
|
False
|
Edit
Delete
|
|
c8fe3ce3-f7f5-4b17-8201-998127d7cb80
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
dcrzdwhm-3097
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Life expectancy can
|
Life expectancy can increase
|
/home/sid/tuning/finetune/backend/output/dcrzdwhm- /home/sid/tuning/finetune/backend/output/dcrzdwhm-3097/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a clear, visual, infographic-style gui This PDF is a clear, visual, infographic-style guide that explains the most important, evidence-based strategies for increasing human longevity. It presents a simple but comprehensive overview of how lifestyle, diet, physical activity, sleep, mental health, environment, and harmful habits influence lifespan. Each section highlights practical actions that promote healthy aging and protect the body from premature decline.
The document is divided into eight pillars of longevity, summarizing what science has repeatedly confirmed:
Long life is shaped far more by daily habits than by genetics.
Increase Longevity
🧠 1. Healthy Diet
The PDF emphasizes a balanced eating pattern rich in:
Fruits & vegetables
Lean protein
Whole grains
Low-fat dairy
Such diets reduce chronic disease risk, support immune function, and slow aging.
Increase Longevity
🏃 2. Exercise
Regular physical activity—especially aerobic exercise like walking—helps:
Strengthen the heart
Maintain healthy weight
Lower chronic disease risk
Improve overall fitness
Walking is highlighted as the simplest and most effective activity.
Increase Longevity
💧 3. Hydration
The infographic stresses drinking adequate water every day to:
Support metabolic processes
Aid circulation
Maintain cellular function
Improve cognitive health
Proper hydration is essential for longevity.
Increase Longevity
😴 4. Sleep
Good-quality sleep is described as a longevity multiplier, helping:
Repair and restore tissues
Stabilize hormones
Regulate metabolism
Support long-term brain health
Increase Longevity
😌 5. Stress Management
The PDF highlights stress as a major lifespan reducer.
Effective tools include:
Relaxation activities
Mindfulness
Self-care
Social connection
Increase Longevity
Managing stress lowers inflammation and improves resilience.
🚬 6. Avoid Smoking
Smoking is identified as one of the strongest predictors of early death.
Quitting dramatically improves:
Lung health
Heart health
Vascular function
Increase Longevity
🍺 7. Limit Alcohol
Moderation is key.
Excessive alcohol harms multiple organs and accelerates aging, while controlled consumption avoids long-term damage.
Increase Longevity
🩺 8. Regular Health Checkups
Preventive screenings and routine medical check-ups help catch diseases early—especially heart disease, cancer, and diabetes.
Early detection increases lifespan and improves quality of life.
Increase Longevity
⭐ Overall Summary
This PDF provides a clean and accessible overview of the eight essential lifestyle factors that increase longevity: healthy diet, exercise, hydration, sleep, stress management, avoiding smoking, limiting alcohol, and regular health checkups. It reinforces a simple but powerful truth:
Longevity is built through consistent, everyday healthy habits....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/dcrzdwhm-3097/data/document.pdf"}...
|
/home/sid/tuning/finetune/backend/output/dcrzdwhm- /home/sid/tuning/finetune/backend/output/dcrzdwhm-3097/data/dcrzdwhm-3097.json...
|
null
|
failed
|
1764888801
|
1764893917
|
NULL
|
/home/sid/tuning/finetune/backend/output/dcrzdwhm- /home/sid/tuning/finetune/backend/output/dcrzdwhm-3097/adapter...
|
False
|
Edit
Delete
|
|
2fffd40f-60de-41b8-9d19-0b8a7f3ed1c5
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
pgsfrslr-9904
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Implausibility of radical
|
Implausibility of radical life extension
|
/home/sid/tuning/finetune/backend/output/pgsfrslr- /home/sid/tuning/finetune/backend/output/pgsfrslr-9904/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a scholarly article analyzing whether This PDF is a scholarly article analyzing whether humans can achieve radical life extension—such as living far beyond current maximum lifespans—within the 21st century. Using demographic, biological, and scientific evidence, the authors conclude that such extreme increases in human longevity are highly implausible, if not impossible, within this time frame.
The paper evaluates claims from futurists, technologists, and some biomedical researchers who argue that breakthroughs in biotechnology, genetic engineering, regenerative medicine, or anti-aging science will soon allow humans to live 150, 200, or even indefinitely long lives.
The authors compare these claims with historical mortality trends, scientific constraints, and biological limits of human aging.
📌 Main Themes of the Article
1. Historical Evidence Shows Slow and Steady Gains
Over the past 100+ years, human life expectancy has increased gradually.
These gains are due mostly to:
reductions in infectious disease,
improved public health,
better nutrition,
improved medical care.
Maximum human lifespan has barely changed, even though average life expectancy has risen.
The authors argue that radical jumps (e.g., doubling human lifespan) contradict all known demographic patterns.
2. Biological Limits to Human Longevity
The paper reviews scientific constraints such as:
Cellular senescence, which accumulates with age
DNA damage and mutation load
Protein misfolding and aggregation
Mitochondrial dysfunction
Limits of regeneration in human tissues
Immune system decline
Stochastic biological processes that cannot be fully prevented
These fundamental biological processes suggest that pushing lifespan far beyond ~120 years faces severe biological barriers.
3. Implausibility of “Longevity Escape Velocity”
Some futurists claim that if we slow aging slightly each decade, we can eventually reach a point where people live long enough for science to develop the next anti-aging breakthrough, creating “escape velocity.”
The article argues this is not realistic, because:
Rates of scientific discovery are unpredictable, uneven, and slow.
Aging involves thousands of interconnected biological pathways.
Slowing one pathway often accelerates another.
No current therapy has shown the ability to dramatically extend human lifespan.
4. Exaggerated Claims in Biotechnology
The paper critiques overly optimistic expectations from:
stem cell therapies
genetic engineering
nanotechnology
anti-aging drugs
organ regeneration
cryonics
It explains that many of these technologies:
are in early stages,
work in model organisms but not humans,
target only small aspects of aging,
cannot overcome fundamental biological constraints.
5. Reliable Projections Suggest Only Modest Gains
Using demographic models, the paper concludes:
Life expectancy will likely continue to rise slowly, due to improvements in chronic disease treatment.
But the odds of extending maximum lifespan far beyond ~120 years in this century are extremely low.
Even optimistic projections suggest only small increases—not radical extension.
6. Ethical and Social Considerations
Although not the primary focus, the article acknowledges that extreme longevity raises concerns about:
resource distribution
intergenerational equity
social system sustainability
These issues cannot be adequately addressed given the scientific implausibility of radical extension.
🧾 Overall Conclusion
The PDF concludes that radical life extension for humans in the 21st century is scientifically implausible.
The combination of:
✔ biological limits,
✔ slow historical trends,
✔ lack of evidence for transformative therapies, and
✔ unrealistic predictions from futurists
makes extreme longevity an unlikely outcome before 2100.
The most realistic future involves incremental improvements in healthspan, allowing people to live healthier—not massively longer—lives....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/pgsfrslr-9904/data/document.pdf", "num_examples": 53, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/pgsfrslr- /home/sid/tuning/finetune/backend/output/pgsfrslr-9904/data/pgsfrslr-9904.json...
|
null
|
completed
|
1764888922
|
1764894026
|
NULL
|
/home/sid/tuning/finetune/backend/output/pgsfrslr- /home/sid/tuning/finetune/backend/output/pgsfrslr-9904/adapter...
|
False
|
Edit
Delete
|
|
645606ae-9d60-4abb-bb85-83e21e93e323
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
dkenfidx-5180
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Inconvenient Truths
|
Inconvenient Truths About Human Longevity
|
/home/sid/tuning/finetune/backend/output/dkenfidx- /home/sid/tuning/finetune/backend/output/dkenfidx-5180/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This article challenges popular claims about radic This article challenges popular claims about radical life extension and explains why human longevity has biological limits, why further increases in life expectancy are slowing, and why the real goal should be to extend healthspan, not lifespan.
The authors show that many predictions of extreme longevity are based on mathematical extrapolation, not biological reality, and that these predictions ignore fundamental constraints imposed by human physiology, genetics, evolutionary history, and mortality patterns.
🧠 1. The Central Argument
Human lifespan has increased dramatically over the last 120 years, but this increase is slowing.
The authors argue that:
✅ Human longevity has an upper limit, around 85 years of average life expectancy
Inconvenient Truths About Human…
Not because we “stop improving,” but because biology imposes ceilings on mortality improvement at older ages.
❌ Radical life extension is not supported by evidence
Predictions that most people born after 2000 “will live to 100” rest on unrealistic assumptions about future declines in mortality.
⭐ The real opportunity is health extension
Improving how long people live free of disease, disability, and frailty.
📉 2. Why Radical Life Extension Is Unlikely
The paper critiques three groups of claims:
A. Mathematical extrapolations
Some argue that because death rates declined historically, they will continue to decline indefinitely—even reaching zero.
The authors compare this flawed reasoning to Zeno’s Paradox: a mathematical idea that ignores biological reality.
Inconvenient Truths About Human…
B. Claims of actuarial escape velocity
Some predict that near-future technology will reduce mortality so rapidly that people’s remaining lifespan increases every year.
The authors emphasize:
No biological evidence supports this.
Death rates after age 105 are extremely high (≈50%), not near 1%.
Inconvenient Truths About Human…
C. Linear forecasts of rising life expectancy
Predictions that life expectancy will continue to increase at 2 years per decade require huge annual mortality declines.
But real-world U.S. data show:
Only one decade since 1990 approached those gains.
Mortality improvements have dramatically slowed since 2010.
Inconvenient Truths About Human…
🧬 3. Biological, Demographic, and Evolutionary Limits
The authors outline three independent scientific lines of evidence that point to limits:
1. Life table entropy
As life expectancy approaches 80+, mortality becomes heavily concentrated between ages 60–95.
Saving lives at these ages produces diminishing returns.
Inconvenient Truths About Human…
2. Cross-species mortality patterns
When human, mouse, and dog mortality curves are scaled for time, they form parallel patterns, showing that each species has an inherent mortality signature tied to its evolutionary biology.
For humans, these comparisons imply an upper limit near 85 years.
Inconvenient Truths About Human…
3. Species-specific “warranty periods”
Each species has a biological “design life,” tied to reproductive age, development, and evolutionary trade-offs.
Human biology evolved to optimize survival to reproductive success, not extreme longevity.
Inconvenient Truths About Human…
These three independent methods converge on the same conclusion:
Human populations cannot exceed an average life expectancy of ~85 years without altering the biology of aging.
🧩 4. Why Life Expectancy Is Slowing
Life expectancy cannot keep rising linearly because:
Young-age mortality has already fallen to very low levels.
Future gains must come from reducing old-age mortality.
But aging itself is the strongest risk factor for chronic disease.
Diseases of aging (heart disease, stroke, Alzheimer’s, cancer) emerge because we live longer than ever before.
Inconvenient Truths About Human…
In short:
We already harvested the “easy wins” in longevity.
❤️ 5. The Case for Healthspan, Not Lifespan
The authors make a strong argument that focusing on curing individual diseases is inefficient:
If you cure one disease, people survive longer and simply live long enough to develop another.
This increases the “red zone”: a period of frailty and disability at the end of life.
Inconvenient Truths About Human…
⭐ The solution: Target the process of aging itself
This is the basis of Geroscience and the Longevity Dividend:
Slow biological aging
Delay multiple diseases simultaneously
Increase years of healthy life
Inconvenient Truths About Human…
This approach could:
Compress morbidity
Improve quality of life
Extend healthspan
Produce only moderate increases in lifespan (not radical ones)
🔍 6. The Authors’ Final Conclusions
1. Radical life extension lacks biological evidence.
Most claims rely on mathematical mistakes or speculation.
2. Human longevity is biologically constrained.
Current estimates show:
Lifespan limit ≈ 115 for individuals
Life expectancy limit ≈ 85 for populations
Inconvenient Truths About Human…
3. Gains in life expectancy are slowing globally.
Many countries are already leveling off near 83–85.
4. Healthspan extension is the path forward.
Improving biological aging processes could revolutionize medicine—even if lifespan changes are small.
🟢 PERFECT ONE-SENTENCE SUMMARY
Human longevity is nearing its biological limits, radical life extension is unsupported by science, and the true opportunity for the future lies not in making humans live far longer, but in enabling them to live far healthier.
...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/dkenfidx-5180/data/document.pdf", "num_examples": 30, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/dkenfidx- /home/sid/tuning/finetune/backend/output/dkenfidx-5180/data/dkenfidx-5180.json...
|
null
|
completed
|
1764889039
|
1764893231
|
NULL
|
/home/sid/tuning/finetune/backend/output/dkenfidx- /home/sid/tuning/finetune/backend/output/dkenfidx-5180/adapter...
|
False
|
Edit
Delete
|
|
9de7d2a5-252b-4a53-87c1-f7222877ac4c
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
tdijspez-8905
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Impacts of Poverty
|
Impacts of Poverty and Lifestyles on Mortality
|
/home/sid/tuning/finetune/backend/output/tdijspez- /home/sid/tuning/finetune/backend/output/tdijspez-8905/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This study investigates how poverty and unhealthy This study investigates how poverty and unhealthy lifestyles influence the risk of death in the United Kingdom, using three large, nationally representative cohort studies. Its central conclusion is striking and policy-relevant: poverty is the strongest predictor of mortality, more powerful than any individual lifestyle factor such as smoking, inactivity, obesity, or poor diet.
The study examines five key variables:
Housing tenure (proxy for lifetime poverty)
Poverty
Smoking status
Lack of physical exercise
Unhealthy diet
Across every cohort analyzed, poverty emerges as the single most important determinant of death risk. People living in poverty were twice as likely to die early compared to those who were not. Housing tenure — especially renting rather than owning — similarly predicted higher mortality, reflecting deeper socioeconomic deprivation accumulated over the life course.
Lifestyle factors do matter, but far less so. Smoking increased mortality risk by 94%, lack of exercise by 44%, and unhealthy diet by 33%, while obesity raised the risk by 27%. But even combined, these lifestyle risks did not outweigh the impact of poverty.
The study also demonstrates a powerful cumulative effect: individuals exposed to multiple lifestyle risks + poverty experience the highest mortality hazards of all. However, the data show that eliminating poverty alone would produce larger population-level mortality reductions than eliminating any single lifestyle factor — challenging the common assumption that public health should focus primarily on personal behaviors.
🔍 Key Findings
1. Poverty dominates mortality risk
Poverty had the strongest hazard ratio across all models.
Reducing poverty would therefore generate the largest reduction in premature deaths.
2. Lifestyle risks matter but are secondary
Smoking, inactivity, and diet each contribute to mortality —
but their impact is smaller than poverty’s.
3. Housing tenure is a powerful long-term socioeconomic marker
Renters had significantly higher mortality risk than homeowners,
indicating that lifelong deprivation drives long-term health outcomes.
4. Combined risk exposure worsens mortality dramatically
People who were poor and had multiple unhealthy lifestyle behaviors
experienced the highest mortality hazards.
5. Policy implication: Social determinants must take priority
The study argues that public health must not focus solely on individual lifestyles.
Structural socioeconomic inequalities — income, housing, access, opportunity —
shape the distribution of unhealthy behaviors in the first place.
🧭 Overall Conclusion
This research provides compelling evidence that poverty reduction is the most effective mortality-reduction strategy available, outweighing even the combined effect of major lifestyle changes. While promoting healthy behavior remains important, the paper demonstrates that addressing socioeconomic deprivation is essential for improving national life expectancy and reducing health inequalities....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/tdijspez-8905/data/document.pdf", "num_examples": 84, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/tdijspez- /home/sid/tuning/finetune/backend/output/tdijspez-8905/data/tdijspez-8905.json...
|
null
|
completed
|
1764889556
|
1764893752
|
NULL
|
/home/sid/tuning/finetune/backend/output/tdijspez- /home/sid/tuning/finetune/backend/output/tdijspez-8905/adapter...
|
False
|
Edit
Delete
|
|
18e12aca-f2c6-4bed-b809-3e0e1110881e
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
aygvnaxq-2918
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Impact of rapamycin life
|
Impact of rapamycin on longevity
|
/home/sid/tuning/finetune/backend/output/aygvnaxq- /home/sid/tuning/finetune/backend/output/aygvnaxq-2918/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This document is a comprehensive scientific review This document is a comprehensive scientific review exploring how rapamycin influences aging and longevity across biological systems. It explains, in clear mechanistic detail, how rapamycin inhibits the mTOR pathway, a central regulator of growth, metabolism, and cellular aging.
The paper summarizes:
1. Why Aging Happens
It describes aging as the gradual accumulation of cellular and molecular damage, leading to reduced function, increased disease risk, and ultimately death.
2. The Role of mTOR in Aging
mTOR is a nutrient-sensing pathway that controls growth, metabolism, protein synthesis, autophagy, and mitochondrial function.
Overactivation of mTOR accelerates aging.
Rapamycin inhibits mTORC1 and indirectly mTORC2, creating conditions that slow aging at the cellular, tissue, and organ level.
3. Rapamycin as a Longevity Drug
The review highlights extensive evidence from yeast, worms, flies, and mice, showing that rapamycin:
Extends lifespan
Improves healthspan
Reduces age-related diseases
4. Key Anti-Aging Mechanisms of Rapamycin
The document details multiple biological pathways influenced by rapamycin:
Protein Homeostasis
Improves fidelity of protein translation
Reduces toxic misfolded protein accumulation
Suppresses harmful senescence-associated secretory phenotype (SASP)
Autophagy Activation
Encourages the removal of damaged organelles and proteins
Protects against neurodegeneration, heart aging, liver aging, and metabolic decline
Mitochondrial Protection
Enhances function and reduces oxidative stress
Immune Rejuvenation
Balances inflammatory signaling
Reduces age-related immune dysfunction
5. Organ-Specific Benefits
The paper includes a detailed table summarizing preclinical evidence showing rapamycin’s benefits in:
Cardiovascular system
Nervous system
Liver
Kidneys
Muscles
Reproductive organs
Respiratory system
Gastrointestinal tract
These benefits involve improvements in:
Autophagy
Stem cell activity
Inflammation
Oxidative stress
Mitochondrial health
6. Limitations & Challenges
While promising, rapamycin has:
Metabolic side effects
Immune-related risks
Dose-timing challenges
Proper therapeutic regimens are required before safe widespread human use.
In Summary
This document provides an up-to-date, detailed, and scientific overview of how rapamycin may slow aging and extend lifespan by targeting mTOR signaling. It integrates molecular biology, animal research, and clinical considerations to outline rapamycin’s potential as one of the most powerful known geroprotective drugs....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/aygvnaxq-2918/data/document.pdf", "num_examples": 26, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/aygvnaxq- /home/sid/tuning/finetune/backend/output/aygvnaxq-2918/data/aygvnaxq-2918.json...
|
null
|
completed
|
1764889575
|
1764901608
|
NULL
|
/home/sid/tuning/finetune/backend/output/aygvnaxq- /home/sid/tuning/finetune/backend/output/aygvnaxq-2918/adapter...
|
False
|
Edit
Delete
|
|
6de08c55-9bdd-4fd7-a7a6-b038ed7aca76
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
nyqlyyen-2541
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
The Impact of Longevity
|
The Impact of Longevity Improvements on U.S.
|
/home/sid/tuning/finetune/backend/output/nyqlyyen- /home/sid/tuning/finetune/backend/output/nyqlyyen-2541/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a policy-oriented actuarial and econom This PDF is a policy-oriented actuarial and economic analysis that explains how improvements in U.S. longevity—people living longer than previous generations—affect population size, economic productivity, Social Security, Medicare, government budgets, and overall national well-being. The document uses demographic projections, mortality data, and economic modeling to show how even small improvements in life expectancy significantly change the financial and social landscape of the United States.
Its central message is clear:
Longevity improvements generate substantial economic and societal benefits, but also increase long-term public spending, especially through Social Security and Medicare. Both the benefits and costs must be understood together.
📈 1. What the Document Examines
The paper analyzes:
How rising life expectancy will reshape the U.S. population
The economic value created when people live longer
Increased tax revenues from longer working lives
Higher federal spending resulting from extended retirements
Effects on Social Security, Medicare, and fiscal sustainability
Impact of Longevity improvement…
👥 2. Population & Longevity Trends
The analysis highlights:
The U.S. population is aging as mortality declines.
Even modest improvements in longevity generate large changes in the number of older Americans.
The share of adults over age 65 will continue rising for decades.
Impact of Longevity improvement…
These demographic shifts increase both the economic potential of a healthier older population and the fiscal pressure on entitlement programs.
💵 3. Economic Benefits of Longevity Improvements
Living longer and healthier creates major economic gains:
✔ Increased Labor Supply
Many adults work longer if they remain healthy.
✔ Higher Productivity
Longer education, more experience, and healthier aging improve worker output.
✔ Greater Tax Revenues
Extended working years increase income taxes, payroll taxes, and spending.
✔ Larger Consumer Market
An aging but healthy population boosts demand for goods, services, and innovation.
Impact of Longevity improvement…
🏛 4. Fiscal Costs of Longevity Improvements
The report explains that increased longevity also increases federal spending:
✔ Higher Social Security Outlays
More retirees receiving benefits for more years.
✔ Higher Medicare & Medicaid Costs
Longer lifespans mean longer periods of medical care and long-term care use.
✔ Potential Strain on Disability & Pension Systems
If health improvements do not keep pace with lifespan gains, disability costs may rise.
Impact of Longevity improvement…
⚖️ 5. Net Impact: Benefits vs. Costs
A key conclusion:
Longevity improvements produce very large economic benefits, but public program spending rises as well, requiring policy adjustments.
The document quantifies both sides:
Benefits: trillions of dollars in increased economic value
Costs: higher federal program obligations, especially for the elderly
Impact of Longevity improvement…
The net impact depends on policy choices such as retirement age, health system investment, and how healthspan improves relative to lifespan.
🔮 6. Policy Implications
The PDF suggests that policymakers must prepare for an aging America by:
● Strengthening Social Security solvency
● Reforming Medicare to handle long-term cost growth
● Encouraging longer working lives
● Investing in preventive health and chronic disease management
● Focusing on healthspan, not just lifespan
Impact of Longevity improvement…
If reforms are implemented effectively, longevity improvements can become an economic advantage rather than a fiscal burden.
⭐ Overall Summary
This PDF provides a balanced and research-driven examination of how increasing longevity influences the U.S. economy, government programs, and national finances. It shows that longer lives bring enormous economic value—in productivity, workforce participation, and consumer activity—but also increase federal spending on Social Security and Medicare. The report emphasizes that preparing for an aging population requires proactive adjustments in retirement policy, health care, and fiscal planning....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/nyqlyyen-2541/data/document.pdf", "num_examples": 14, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/nyqlyyen- /home/sid/tuning/finetune/backend/output/nyqlyyen-2541/data/nyqlyyen-2541.json...
|
null
|
completed
|
1764889601
|
1764895602
|
NULL
|
/home/sid/tuning/finetune/backend/output/nyqlyyen- /home/sid/tuning/finetune/backend/output/nyqlyyen-2541/adapter...
|
False
|
Edit
Delete
|
|
b596fa0a-4893-4b7a-b744-95f9f068b63b
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
ymoxtdyn-7204
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Impact of Ecological
|
Impact of Ecological Footprint on the Longevity of
|
/home/sid/tuning/finetune/backend/output/ymoxtdyn- /home/sid/tuning/finetune/backend/output/ymoxtdyn-7204/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This study investigates how environmental degradat This study investigates how environmental degradation, ecological footprint, climate factors, and socioeconomic variables influence human life expectancy in major emerging Asian economies including Bangladesh, China, India, Malaysia, South Korea, Singapore, Thailand, and Vietnam.
1. Core Purpose
The research aims to determine whether rising ecological footprint—the pressure placed on natural ecosystems by human use of resources—reduces life expectancy, and how other factors such as globalization, GDP, carbon emissions, temperature, health expenditure, and infant mortality interact with longevity in these countries (2000–2019).
🌍 2. Key Findings
A. Negative Environmental Impacts on Life Expectancy
The study finds that:
Higher ecological footprint ↓ life expectancy
Each 1% rise in ecological footprint reduces life expectancy by 0.021%.
Carbon emissions ↓ life expectancy
A 1% rise in CO₂ emissions reduces life expectancy by 0.0098%.
Rising average temperature ↓ life expectancy
Heatwaves, diseases, respiratory problems, and infectious illnesses are intensified by climate change.
B. Positive Determinants of Longevity
Globalization ↑ life expectancy
Increased trade, technology spread, and global integration improve development and healthcare.
GDP ↑ life expectancy
Economic growth improves living standards, jobs, nutrition, and health services.
Health expenditure ↑ life expectancy
Every 1% rise in public health spending increases life expectancy by 0.089%.
C. Negative Social Determinants
Infant mortality ↓ life expectancy
A 1% rise in infant deaths decreases life expectancy by 0.061%, reflecting poor healthcare quality.
🔍 3. Data & Methods
Panel data (2000–2019) from 8 Asian economies.
Variables include ecological footprint, CO₂ emissions, temperature, GDP, globalization, health expenditure, and infant mortality.
Econometric models used:
Cross-sectional dependence tests
Second-generation unit root tests (Pesaran CADF)
KAO Cointegration
FMOLS (Fully Modified Ordinary Least Squares) for long-run estimations.
The statistical model explains 94% of life expectancy variation (R² = 0.94).
🌱 4. Major Conclusions
Environmental degradation significantly reduces human longevity in emerging Asian countries.
Ecological footprint and temperature rise are major threats to health and human welfare.
Carbon emissions drive respiratory, cardiovascular, and infectious diseases.
Globalization, GDP, and health spending improve life expectancy.
Strong environmental policies are needed to reduce ecological pressure and carbon emissions.
Health systems must be strengthened, especially in developing Asian economies.
🧭 5. Policy Recommendations
Reduce ecological footprint by improving resource efficiency.
Decarbonize industry, transport, and energy sectors.
Invest more in public health systems and medical infrastructure.
Create markets for ecosystem services.
Promote sustainable development, green energy, and trade policies.
Reduce infant mortality through prenatal, maternal, and child healthcare....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/ymoxtdyn-7204/data/document.pdf", "num_examples": 41, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/ymoxtdyn- /home/sid/tuning/finetune/backend/output/ymoxtdyn-7204/data/ymoxtdyn-7204.json...
|
null
|
completed
|
1764889621
|
1764895315
|
NULL
|
/home/sid/tuning/finetune/backend/output/ymoxtdyn- /home/sid/tuning/finetune/backend/output/ymoxtdyn-7204/adapter...
|
False
|
Edit
Delete
|
|
d21f0bb8-3c4e-455c-b7cd-3c01486e8b74
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
dhnwupta-3434
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Human longevity
|
Human longevity
|
/home/sid/tuning/finetune/backend/output/dhnwupta- /home/sid/tuning/finetune/backend/output/dhnwupta-3434/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
The PDF is a historical and medical editorial disc The PDF is a historical and medical editorial discussing human longevity. It compares ancient observations, historical case reports, and modern scientific understanding to explore why some individuals live exceptionally long lives—sometimes beyond 100 or even 150 years (as documented in rare historical cases).
The article emphasizes that the factors linked to long life today—such as healthy habits, clean air, moderate diet, physical activity, and low exposure to harmful substances—were already recognized centuries ago by physicians, philosophers, and early researchers.
The document uses historical records (such as Easton’s 1799 compilation of long-lived individuals) and medical anecdotes to highlight enduring truths about what contributes to human longevity.
📜 Key Themes of the PDF
1. Historical Evidence of Longevity
The article begins by summarizing Easton’s 1799 report documenting 1,712 individuals who lived 100 years or more, spanning periods from 66 A.D. to 1799.
During the 18th century, mortality was extremely high—half of all children died before age 10—yet some people still lived beyond 100, demonstrating that long life is possible even in harsh conditions.
2. Philosophical and Early Medical Insights
The article cites ancient thinkers such as Seneca, who said:
“Life is long if you know how to use it.”
Easton’s writing is also quoted extensively, noting timeless principles:
Lifestyle matters more than wealth or medicine
Simple diets, fresh air, physical work, and exposure to nature foster longevity
Polluted air, overeating, tobacco, alcohol, and inactivity shorten life
These observations match modern public health findings.
3. Example of an Extreme Long-lived Individual
A major part of the article recounts the famous case of Thomas Parr, allegedly aged 152 years when he died in 1635.
The report includes remarkable details:
Married first at age 38, became a father at over 100
Worked in agriculture into his 130s
Lived on simple foods: milk, bread, cheese, small beer
After moving to London and adopting a rich diet, his health rapidly deteriorated
A postmortem by William Harvey, the discoverer of blood circulation, showed his organs were surprisingly healthy for his age
This case is used to highlight how lifestyle disruption can harm longevity.
4. Modern Confirmation of Ancient Wisdom
The editorial argues that risk factors we focus on today were recognized centuries ago, including:
Air pollution
Obesity
Heavy tobacco use
Excessive alcohol consumption
High saturated-fat diets
Lack of physical exercise
The article’s message:
The basic rules for long life have not changed.
5. Scientific Vindication of Traditional Practices
The final section shifts to another medical story showing how traditional or “primitive” remedies were later validated by scientific research.
Example:
Pernicious anemia was once fatal
Observations showed that eating liver improved the condition
Years later, vitamin B12 was discovered in liver and identified as the key therapeutic factor
Minot, Murphy, and Whipple earned the Nobel Prize in 1934 for this discovery
This reinforces the theme that earlier observations often contain truths confirmed later by science.
🧾 Overall Conclusion
The PDF argues that human longevity is governed by simple, well-known principles:
💠 Fresh air
💠 Physical activity
💠 Moderate diet
💠 Low stress
💠 Avoidance of excess (tobacco, alcohol, overeating)
💠 Clean environments
These insights have been recognized for centuries and remain supported by modern research.
The article blends historical records, medical anecdotes, and scientific reflections to illustrate that while medicine has advanced greatly, the foundational lifestyle elements that promote long life remain unchanged.
I...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/dhnwupta-3434/data/document.pdf"}...
|
/home/sid/tuning/finetune/backend/output/dhnwupta- /home/sid/tuning/finetune/backend/output/dhnwupta-3434/data/dhnwupta-3434.json...
|
null
|
failed
|
1764889783
|
1764890686
|
NULL
|
/home/sid/tuning/finetune/backend/output/dhnwupta- /home/sid/tuning/finetune/backend/output/dhnwupta-3434/adapter...
|
False
|
Edit
Delete
|
|
421dcfa5-091c-4a6c-99f0-c02be6e82ccc
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
nplhswyv-5794
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Human longevity: Genetics
|
Human longevity: Genetics or Lifestyle
|
/home/sid/tuning/finetune/backend/output/nplhswyv- /home/sid/tuning/finetune/backend/output/nplhswyv-5794/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This review explains that human longevity is shape This review explains that human longevity is shaped by a dynamic interaction between genetics and lifestyle, where neither factor alone is sufficient. About 25% of lifespan variation is due to genetics, while the remainder is influenced by lifestyle, environment, medical care, and epigenetic changes across life.
The paper traces the scientific journey behind understanding longevity, beginning with early experiments in C. elegans showing that mutations in key genes can dramatically extend lifespan. These findings led to the discovery of conserved genetic pathways — such as IGF-1/insulin signaling, FOXO transcription factors, TOR, DNA repair genes, telomere maintenance, and mitochondrial function — that influence cellular maintenance, metabolism, and aging in humans.
Human studies, including twin studies, family studies, and genome-wide association research, confirm a modest but real genetic influence. Siblings of centenarians consistently show higher survival rates, especially men, indicating inherited resilience. However, no single gene determines longevity; instead, many small-effect variants combine, and their cumulative action shapes aging and survival.
The review shows that while genetics provides a foundational capacity for longer life, lifestyle and environment have historically produced the greatest gains in life expectancy. Improvements in sanitation, nutrition, public health, and medical care significantly lengthened lifespan worldwide. Yet these gains have not equally extended healthy life expectancy, prompting research into interventions that target the biological mechanisms of aging.
One key insight is that calorie restriction and nutrient-sensing pathways (IGF-1, FOXO, TOR) are strongly linked to longer life in animals. These discoveries explain why certain traditional diets — like the Mediterranean diet and the Okinawan low-calorie, nutrient-dense diet — are associated with exceptional human longevity. They also motivate the development of drugs that mimic the effects of dietary restriction without requiring major lifestyle changes.
A major emerging field discussed is epigenetics. Epigenetic modifications, such as DNA methylation, reflect both genetic background and lifestyle exposure. They change predictably with age and have become powerful biomarkers through the “epigenetic clock.” These methylation patterns can predict biological age, disease risk, and even all-cause mortality more accurately than telomere length. Epigenetic aging is accelerated in conditions like Down syndrome and slowed in long-lived individuals.
🔍 Key Takeaways
1. Genetics explains ~25% of lifespan variation
Twin and family studies show strong but limited heritability, more pronounced in men and at older ages.
2. Longevity genes maintain cellular integrity
Genes involved in:
DNA repair
Telomere protection
Stress response
Mitochondrial efficiency
Nutrient sensing (IGF-1, FOXO, TOR)
play essential roles in determining aging pace.
3. Lifestyle and environment have the largest historical impact
Modern sanitation, medical advances, nutrition, and lower infection rates dramatically increased human lifespan in the 20th century.
4. Exceptional longevity comes from a “lucky” combination
Some individuals inherit optimal metabolic and stress-response variants; others can mimic these genetic advantages through diet, exercise, and targeted interventions.
5. Epigenetics links genes and lifestyle
DNA methylation patterns:
reflect biological aging
predict mortality
respond to lifestyle factors
may soon serve as targets for anti-aging interventions
6. The future of longevity research targets interactions
Extending healthspan requires approaches that modulate both genetic pathways and lifestyle behaviors, emphasizing that genetics and lifestyle “dance together.”
🧭 Overall Conclusion
Human longevity is not simply written in DNA nor solely determined by lifestyle. Instead, it emerges from the interplay between inherited biological systems and environmental influences across the life course. Small genetic advantages make some individuals naturally more resilient, but lifestyle — particularly nutrition, activity, and stress exposure — can harness or hinder these genetic potentials. Epigenetic processes act as the bridge between the two, shaping how genes express and how fast the body ages.
Longevity, therefore, “takes two to tango”:
genes set the stage, but lifestyle leads the dance....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/nplhswyv-5794/data/document.pdf", "num_examples": 15, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/nplhswyv- /home/sid/tuning/finetune/backend/output/nplhswyv-5794/data/nplhswyv-5794.json...
|
null
|
completed
|
1764890260
|
1764893850
|
NULL
|
/home/sid/tuning/finetune/backend/output/nplhswyv- /home/sid/tuning/finetune/backend/output/nplhswyv-5794/adapter...
|
False
|
Edit
Delete
|
|
40b7a363-0c7b-4acb-a427-e9527c1b7008
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
aazjwlos-6198
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Human longevity
|
Human longevity at the cost of reproductive
|
/home/sid/tuning/finetune/backend/output/aazjwlos- /home/sid/tuning/finetune/backend/output/aazjwlos-6198/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This scientific paper provides a comprehensive, gl This scientific paper provides a comprehensive, global-scale analysis showing that human longevity and reproductive success are biologically linked through a life-history trade-off: populations where women have more children tend to have shorter average lifespans, even after adjusting for economic, geographic, ethnic, religious, and disease-related factors.
Authored by Thomas, Teriokhin, Renaud, De Meeûs, and Guégan, the study combines evolutionary theory with large-scale demographic data from 153 countries to examine whether humans—like other organisms—experience the classic evolutionary trade-off:
More reproduction → less somatic maintenance → shorter lifespan
🔶 1. Purpose of the Study
The authors aim to determine whether humans display the fundamental evolutionary principle that reproduction is costly—and that allocating energy to childbirth reduces resources for body repair, thereby shortening lifespan.
This principle is widely documented in animals but rarely tested in humans at the global level.
🔶 2. Background Theory
The paper draws on life-history theory, explaining that aging evolves due to:
Accumulation of late-acting mutations (Medawar)
Antagonistic pleiotropy: genes improving early reproduction may harm late survival (Williams)
Allocation of limited energy between reproduction and somatic maintenance (Kirkwood’s Disposable Soma theory)
Evidence from insects, worms, and other species shows that higher reproductive effort often leads to:
Reduced survival
Faster aging
Increased physiological damage
🔶 3. What Makes This Study Unique
Unlike most previous work on humans (e.g., genealogical studies of British aristocracy), this study uses broad international datasets:
153 countries
Measures of:
Female life expectancy
Fecundity (average lifetime births per woman)
Infant mortality
Economic indicators (GNP)
Disease burden (16 infectious diseases)
Geography and population structure
Religion
Ethnic/phylogenetic groupings
This allows the authors to control for confounding factors and test whether the relationship remains after adjustment.
🔶 4. Methods Overview
⭐ Longevity calculation
Life expectancy was reconstructed using:
Infant mortality rates
Gompertz mortality function (for age-related mortality)
Environmental mortality (country-specific)
Only female life expectancy at age 1 (L1) was used in final models.
⭐ Fecundity measurement
Log-transformed average number of children per woman
Only includes women who survived to reproductive age
Not affected by childhood mortality
⭐ Control variables included
Ethnic group (8 categories)
Religion (5 categories)
16 infectious disease categories
GDP per capita (log)
Population density, size, growth
Hemisphere, island vs. continent, latitude, longitude
Country surface area
⭐ Statistical approach
General linear models (GLMs)
Backward stepwise elimination
Inclusion threshold: p < 0.05
Multicollinearity checks
Residual correlations to test trade-off
🔶 5. Key Findings
⭐ 1. A strong negative raw correlation
Across 153 countries:
More children = shorter female lifespan
r = –0.70, p < 0.001
Human longevity at the cost of …
This shows that high-fecundity populations (e.g., developing nations) tend to have lower longevity.
⭐ 2. The trade-off remains after controlling for all confounders
After removing effects of:
Economy
Disease load
Ethnicity
Religion
Geography
The relationship still exists:
Women who have more children live shorter lives on average.
(r = –0.27, p = 0.0012)
Human longevity at the cost of …
⭐ 3. Economic and disease factors matter
Higher GDP → higher longevity & lower fertility
Higher infectious disease burden → lower longevity & higher fertility
⭐ 4. Ethnic and religious groupings have significant predictive power
Human phylogeny and culture influence both fertility patterns and lifespan variability.
🔶 6. Interpretation
The results strongly support the evolutionary trade-off theory:
Investing biological resources in reproduction reduces the energy available for body repair, leading to earlier aging and death.
This parallels findings in:
Fruit flies
Nematodes
Birds
Mammals
The study suggests these trade-offs operate even at the societal and population level, not only within individuals.
🔶 7. Limitations Acknowledged
The authors caution that:
Human reproduction is strongly influenced by socio-cultural factors (e.g., education, contraception), not purely biology
Some cultural factors may confound the relationship
Genetic vs. environmental contributions are not disentangled
Country-level averages do not reflect individual variation
However, despite these limitations, the consistency of the global pattern is compelling.
🔶 8. Conclusion (Perfect Summary)
This study provides robust global evidence that human longevity and reproductive success are linked by a fundamental biological trade-off: populations with higher fertility have shorter female lifespans, even after controlling for economic, geographic, disease-related, ethnic, and cultural factors. The findings extend life-history theory to humans on a worldwide scale and support the idea that allocating energy to childbearing reduces resources for somatic maintenance, accelerating aging....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/aazjwlos-6198/data/document.pdf", "num_examples": 26, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/aazjwlos- /home/sid/tuning/finetune/backend/output/aazjwlos-6198/data/aazjwlos-6198.json...
|
null
|
completed
|
1764890279
|
1764892966
|
NULL
|
/home/sid/tuning/finetune/backend/output/aazjwlos- /home/sid/tuning/finetune/backend/output/aazjwlos-6198/adapter...
|
False
|
Edit
Delete
|
|
37edd981-d0d9-4897-afe1-0c01c137e538
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
ztozpksb-7071
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
HUMAN LONGEVITY
|
HUMAN LONGEVITY AND IMPLICATIONS FOR SOCIAL
|
/home/sid/tuning/finetune/backend/output/ztozpksb- /home/sid/tuning/finetune/backend/output/ztozpksb-7071/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Title: Human Longevity and Implications for Social Title: Human Longevity and Implications for Social Security – Actuarial Status
Authors: Stephen Goss, Karen Glenn, Michael Morris, K. Mark Bye, Felicitie Bell
Published by: Social Security Administration, Office of the Chief Actuary (Actuarial Note No. 158, June 2016)
📌 Purpose of the Document
This report examines how changing human longevity (declining mortality rates) affects:
The age distribution of the U.S. population
The financial status of Social Security
Long-term cost projections for Social Security trust funds
It explains how mortality rates have changed historically, how they may change in the future, and why accurate longevity projections are essential for determining Social Security’s sustainability.
📌 Key Points and Insights
1. Demographic changes drive Social Security finances
Mortality, fertility, and immigration shape the ratio of workers to retirees, known as the aged dependency ratio.
Lower fertility since the baby boom greatly increased the proportion of older adults.
Mortality improvements (people living longer) also steadily increase Social Security costs.
2. Life expectancy improvements are slowing
The report explains that:
Increases in life expectancy historically came from reducing infant and child mortality.
Today, with child deaths already extremely low, gains must come from reducing deaths at older ages, which is harder and slower.
Recent research (Vallin, Meslé, Lee) suggests life expectancy follows an S-shaped curve, not unlimited linear growth, meaning natural limits are becoming visible.
3. Mortality improvement varies significantly with age
The report shows a clear age gradient:
Faster mortality improvement at younger ages
Slower improvement at older ages
This pattern appears consistently in the U.S., Canada, and the U.K.
Future projections must consider:
Whether this age gradient continues
How medical progress will change mortality in each age group
4. Health spending and policy historically reduced mortality
Huge declines in death rates during the 20th century were driven by:
better nutrition
expanded medical care
antibiotics
Medicare & Medicaid
However:
The same level of improvement cannot be repeated.
Health spending as % of GDP has flattened, and per-beneficiary Medicare growth is slowing.
Therefore future mortality improvement will likely decelerate.
5. Mortality reduction varies by cause of death
The report compares:
Cardiovascular disease
Respiratory disease
Cancer
Using Social Security projections and independent Johns Hopkins research, it finds:
Cardiovascular improvements are slowing
Respiratory disease has mixed trends
Cancer improvements remain steady but modest
Cause-specific analysis leads to more realistic projections.
6. Longevity differences by income levels matter
People with higher lifetime earnings:
Have lower mortality
Experience faster mortality improvement
This affects Social Security because:
Higher earners live longer
They collect benefits for more years
This increases system costs over time
7. Recent slowdown since 2009
The report highlights that:
Mortality improvements after 2009 have been much slower than expected, especially for older adults.
If this slowdown continues, Social Security’s long-term costs could be lower than projected, improving system finances.
8. Comparing projection methods
The report evaluates two approaches:
a) Social Security Trustees’ method
Includes:
age gradient
cause-specific modeling
gradual deceleration
Produces conservative and stable long-range estimates
b) Lee & Carter method
Fits age-specific mortality trends mathematically
Assumes no deceleration
Keeps the full historical age gradient
Findings:
Lee’s method produces a more favorable worker-to-retiree ratio until ~2050
After 2050, unrealistic lack of deceleration makes older survival too high
Over 75 years, both methods produce similar overall actuarial outcomes
📌 Final Conclusions
The document concludes that:
Mortality improvements will continue, but more slowly than in the past.
The Social Security Trustees’ current mortality assumptions—moderate improvement with deceleration—are reasonable and well supported by evidence.
Social Security’s financial outlook is highly sensitive to longevity patterns, especially at older ages.
Continued research and updated data (including the slowdown since 2009) are essential for accurate projections....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/ztozpksb-7071/data/document.pdf", "num_examples": 6, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/ztozpksb- /home/sid/tuning/finetune/backend/output/ztozpksb-7071/data/ztozpksb-7071.json...
|
null
|
completed
|
1764890303
|
1764893613
|
NULL
|
/home/sid/tuning/finetune/backend/output/ztozpksb- /home/sid/tuning/finetune/backend/output/ztozpksb-7071/adapter...
|
False
|
Edit
Delete
|
|
417543b9-9abe-41c6-95ae-12b85e4beebd
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
meuvcaig-6493
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
humans in 21st century
|
humans in the twenty-first century
|
/home/sid/tuning/finetune/backend/output/meuvcaig- /home/sid/tuning/finetune/backend/output/meuvcaig-6493/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Implausibility of Radical Life Extension in Humans Implausibility of Radical Life Extension in Humans in the Twenty-First Century
Human in 21st century
This study, published in Nature Aging (2024), analyzes real demographic data from the world’s longest-lived populations to determine whether radical human life extension is occurring—or likely to occur—in this century. The authors conclude that radical life extension is not happening and is biologically implausible unless we discover ways to slow biological aging itself, not just treat diseases.
🧠 1. Central Argument
Over the 20th century, life expectancy grew rapidly due to public health and medical advances. But since 1990, improvements in life expectancy have slowed dramatically across all longest-lived nations.
Human in 21st century
The core message:
Unless aging can be biologically slowed, humans are already near the upper limits of natural life expectancy.
Human in 21st century
📉 2. Has Radical Life Extension Happened?
The authors define radical life extension as:
👉 A 0.3-year increase in life expectancy per year (3 years per decade) — similar to gains during the 20th-century longevity revolution.
Using mortality data from 1990–2019 (Australia, France, Italy, Japan, South Korea, Spain, Sweden, Switzerland, Hong Kong, USA):
🔴 Findings:
Only Hong Kong and South Korea briefly approached this rate (mostly in the 1990s).
Every country shows slowed growth in life expectancy since 2000.
Human in 21st century
The U.S. even experienced declines in life expectancy in recent decades due to midlife mortality.
Human in 21st century
🎯 3. Will Most People Today Reach 100?
The data say no.
Actual probabilities of reaching age 100:
Females: ~5%
Males: ~1.8%
Highest observed: Hong Kong (12.8% females, 4.4% males)
Human in 21st century
Nowhere near the 50% survival to 100 predicted by “radical life extension” futurists.
📊 4. How Hard Is It to Increase Life Expectancy Today?
To add just one year to life expectancy, countries now must reduce mortality at every age by far more than in the past.
Example: For Japanese females (2019):
To go from 88 → 89 years requires
👉 20.3% reduction in death rates at ALL ages.
Human in 21st century
These reductions are increasingly unrealistic using current medical approaches.
🧬 5. Biological & Demographic Constraints
Three demographic signals show humans are approaching biological limits:
A. Life table entropy (H*) is stabilizing
Shows mortality improvements are becoming harder.
Human in 21st century
B. Lifespan inequality (Φ*) is decreasing
Deaths are increasingly compressed into a narrow age window — meaning humans are already dying close to the biological limit.
Human in 21st century
C. Maximum lifespan has stagnated
No increase beyond Jeanne Calment’s record of 122.45 years.
Human in 21st century
Together, these metrics prove that life expectancy gains are slowing because humans are nearing biological constraints—not because progress in medicine has stopped.
🚫 6. What Would Radical Life Extension Require?
The authors create a hypothetical future where life expectancy reaches 110 years.
To achieve this:
70% of females must survive to 100
24% must survive beyond 122.5 (breaking the maximum human lifespan)
6–7% must live to 150
Human in 21st century
This would require:
88% reduction in death rates at every age up to 150
Human in 21st century
This is impossible using only disease treatment. It would require curing most causes of death.
🌍 7. Composite “Best-Case” Mortality Worldwide
The authors compile the lowest death rates ever observed in any country (2019):
Best-case female life expectancy: 88.7 years
Best-case male life expectancy: 83.2 years
Human in 21st century
Even with zero deaths from birth to age 50, life expectancy increases by only one additional year.
Human in 21st century
This shows why further increases are extremely difficult.
🧭 8. Final Conclusions
Radical life extension is not happening in today’s long-lived nations.
Biological and demographic forces limit life expectancy to about 85–90 years for populations.
Survival to 100 will remain rare (around 5–15% for females; 1–5% for males).
Treating diseases alone cannot extend lifespan dramatically.
Only slowing biological aging (geroscience) could meaningfully shift these limits.
Human in 21st century
🌟 Perfect One-Sentence Summary
Humanity is already near the biological limits of life expectancy, and radical life extension in the 21st century is implausible unless science discovers ways to slow the fundamental processes of aging....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/meuvcaig-6493/data/document.pdf", "num_examples": 25, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/meuvcaig- /home/sid/tuning/finetune/backend/output/meuvcaig-6493/data/meuvcaig-6493.json...
|
null
|
completed
|
1764890339
|
1764895445
|
NULL
|
/home/sid/tuning/finetune/backend/output/meuvcaig- /home/sid/tuning/finetune/backend/output/meuvcaig-6493/adapter...
|
False
|
Edit
Delete
|
|
b6fa1df4-8e33-4ee4-acbc-884994678559
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
lgwfqloi-6680
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Human capital and life
|
Human capital and longevity
|
/home/sid/tuning/finetune/backend/output/lgwfqloi- /home/sid/tuning/finetune/backend/output/lgwfqloi-6680/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Title: Human Capital and Longevity: Evidence from Title: Human Capital and Longevity: Evidence from 50,000 Twins
Authors: Petter Lundborg, Carl Hampus Lyttkens, Paul Nystedt
Published: July 2012
Dataset: Swedish Twin Registry (≈50,000 same-sex twins, 1886–1958)
🔍 What the Study Investigates
The document analyzes why well-educated people live longer, using one of the world’s largest collections of identical (MZ) and fraternal (DZ) twins. Because twins share genes and environments, this study uniquely isolates whether the connection between education and longevity is causal or simply due to shared background factors.
📊 Core Research Questions
Does education truly increase lifespan?
Or do unobserved factors—such as genetics, early-life health, birth weight, family environment, or ability—explain the link?
How much extra life expectancy is gained from higher education?
🧬 Why Twins Are Used
Twins help the researchers eliminate:
Shared genes
Shared childhood environments
Early-life conditions
Many unobserved family-level factors
This allows a much cleaner measurement of the effect of education alone.
📈 Main Findings (Clear & Strong)
1️⃣ Education strongly increases longevity.
Across all models:
Each extra year of schooling reduces mortality by about 6%.
2️⃣ Even after controlling for:
Shared genes
Shared environment
Birth weight differences
Height (proxy for IQ & early health)
Only twins who differ in schooling
➡️ The relationship remains significant and strong.
3️⃣ High education adds 2.5–3 additional years of life at age 60.
This effect is:
Consistent for men and women
Consistent across birth cohorts
Strongest in younger generations
Stronger at mid-life (age 50–60) than in old age
🧪 Key Tests & Evidence
Birth Weight Test
Birth weight differences predict schooling differences
BUT birth weight does not predict mortality
→ So omission of birth weight does not bias the education effect.
Height (Ability Proxy) Test
Taller twins achieve more schooling
But height does not predict mortality in twin comparisons
→ Ability differences cannot explain the education–longevity link.
MZ vs DZ Twins
Identical twins (MZ) share 100% genes
Fraternal twins (DZ) share ~50%
Results are extremely similar
Suggests genetics are not driving the relationship.
📉 Non-Linear Benefits
Education levels:
<10 years
10–12 years
≥13 years (university level)
Effects:
Middle group: ~13% lower mortality
University group: 35–40% lower mortality
Very strong evidence of a degree effect.
⏳ Age Patterns
The effect is strongest between ages 50–60
The benefit declines slightly at older ages
But remains significant across all age groups
📅 Cohort Patterns
The education–longevity gap has grown stronger over time
Likely due to rising skill demands and better health knowledge among educated groups
📘 Methodology
The study uses advanced statistical tools:
Cox proportional hazards models
Stratified partial likelihood (twin fixed-effects)
Gompertz survival models
Linear probability models for survival to 70 and 80
These allow precise estimation of the effect of education on mortality.
📌 Policy Implications
Education has large, long-term health returns
These returns go far beyond labor market earnings
Increasing education could significantly raise population longevity—especially in developing countries
Evidence suggests education improves:
Health behaviors
Decision-making
Access to knowledge
Use of medical information
🎯 Final Summary (Perfect One-Liner)
The study provides powerful evidence that education itself—not genes, family environment, or early-life factors—directly increases human lifespan by several years, making schooling one of the most effective longevity-enhancing investments in society....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/lgwfqloi-6680/data/document.pdf", "num_examples": 74, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/lgwfqloi- /home/sid/tuning/finetune/backend/output/lgwfqloi-6680/data/lgwfqloi-6680.json...
|
null
|
completed
|
1764890347
|
1764899943
|
NULL
|
/home/sid/tuning/finetune/backend/output/lgwfqloi- /home/sid/tuning/finetune/backend/output/lgwfqloi-6680/adapter...
|
False
|
Edit
Delete
|
|
65e71a90-969a-4135-8bcf-d283b4ab2c75
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
djrfznno-5207
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Live Longer
|
How to live longer ?
|
/home/sid/tuning/finetune/backend/output/djrfznno- /home/sid/tuning/finetune/backend/output/djrfznno-5207/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
How to Live Longer is a comprehensive, science-bas How to Live Longer is a comprehensive, science-based lifestyle guide that translates decades of longevity research into simple daily actions that anyone can apply. Designed as a practical handbook rather than an academic review, it organizes the most powerful, evidence-supported habits into six core pillars of healthy aging:
Stay Active
Eat Wisely
Manage Stress
Sleep Well
Build Social Connection
Maintain Mental Stimulation
These pillars form a “longevity lifestyle,” emphasizing that small, consistent actions—especially in midlife—produce large benefits in later years.
The eBook integrates insights from real-world longevity hotspots such as Blue Zones (Okinawa, Sardinia, Nicoya, Ikaria, Loma Linda), modern public-health science, and behavioral psychology to show how daily routines shape health trajectories across the lifespan.
🔍 Core Pillars & Science-Backed Practices
1. Staying Active
Activity is the single strongest predictor of how well someone ages.
The guide recommends:
Strength training
Frequent walking
Active living (taking stairs, chores, gardening)
Stretching for mobility
Regular physical activity improves the heart, brain, metabolism, muscle strength, mood, and overall vitality.
2. Eating Wisely
A longevity-focused diet emphasizes:
Mostly plant-based meals
Fruits, vegetables, whole grains, legumes
Nuts and seeds daily
Healthy fats (olive oil, omega-3s)
Smaller portions and mindful eating
The guide highlights traditional dietary patterns of Blue Zones, especially Mediterranean and Okinawan models, which are strongly linked to long life and reduced chronic disease.
3. Managing Stress
Chronic stress accelerates aging, inflammation, and disease.
The eBook recommends:
Mindfulness and meditation
Breathing exercises
Yoga
Time in nature
Hobby-based relaxation
Scheduling downtime
These practices help regulate emotional well-being, improve resilience, and support healthier biological aging.
4. Good Quality Sleep
Sleep is described as a longevity multiplier, with profound effects on immune health, metabolic balance, brain function, and emotional stability.
The guide includes:
Consistent sleep schedules
Dark, cool sleeping environments
Reducing caffeine, alcohol, and screens before bed
5. Social Connection
Loneliness is a major risk factor for early mortality, comparable to smoking and inactivity.
The eBook emphasizes:
Strong family bonds
Friendships
Community involvement
Purposeful living (“ikigai”)
This reflects consistent findings from longevity populations worldwide.
6. Staying Mentally Active
Lifelong learning, mental stimulation, and cognitively engaging activities help preserve brain function.
Recommendations include:
Reading
Learning new skills
Puzzles or games
Creative pursuits
These habits strengthen cognitive reserve and support healthier aging.
💡 Overall Insight
The eBook argues that longevity is not about extreme interventions—it is about consistent, realistic, enjoyable habits grounded in strong science. It blends public-health evidence with lifestyle medicine, emphasizing that aging well is achievable for anyone, regardless of genetics.
Across all chapters, the tone remains practical: longevity is built through everyday choices, not expensive biohacking.
🧭 In Summary
How to Live Longer is a practical, evidence-driven handbook that shows how daily movement, nutritious eating, stress control, quality sleep, social belonging, and lifelong learning combine to support longer, healthier, more fulfilling lives....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/djrfznno-5207/data/document.pdf", "num_examples": 292, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/djrfznno- /home/sid/tuning/finetune/backend/output/djrfznno-5207/data/djrfznno-5207.json...
|
null
|
completed
|
1764891610
|
1764909184
|
NULL
|
/home/sid/tuning/finetune/backend/output/djrfznno- /home/sid/tuning/finetune/backend/output/djrfznno-5207/adapter...
|
False
|
Edit
Delete
|
|
4d143cd1-e2ed-486e-9e2c-05dcd99aae3f
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
kqpdxnql-8909
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
How old id human ?
|
How old is human ?
|
/home/sid/tuning/finetune/backend/output/kqpdxnql- /home/sid/tuning/finetune/backend/output/kqpdxnql-8909/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a scholarly critique and clarification This PDF is a scholarly critique and clarification published in the Journal of Human Evolution (2005), written by anthropologists Kristen Hawkes and James F. O’Connell. It examines and challenges a high-profile claim that human longevity is a recent evolutionary development, supposedly emerging only in the Upper Paleolithic. The document argues that the method used in the original study is flawed and does not accurately measure longevity in fossil populations.
Through comparative primate data, demographic theory, and paleodemographic evidence, the authors demonstrate that fossil death assemblages do not reliably reflect actual population age structures, and therefore cannot be used to claim that modern humans only recently evolved long life.
🔶 1. Purpose of the Article
This paper responds to Caspari & Lee (2004), who argued:
Older adults were rare in earlier hominins (Australopiths, Homo erectus, Neanderthals).
Long-lived older adults first became common with Upper Paleolithic modern humans.
This increase in longevity contributed to modern human evolutionary success.
Hawkes and O’Connell show that these conclusions are unsupported, because the age ratio Caspari & Lee used is not a valid measure of longevity.
🔶 2. Background: The Original Claim
Caspari & Lee analyzed fossil teeth using:
Third molar (M3) eruption to mark adulthood.
Tooth wear to classify “young adults” vs. “old adults.”
Calculated a ratio of old-to-young adult dentitions (OY ratio).
Their findings:
Fossil Group O/Y Ratio
Australopiths 0.12
Homo erectus 0.25
Neanderthals 0.39
Upper Paleolithic modern humans 2.08
They interpreted the dramatic jump in the OY ratio for modern humans as evidence of a major increase in longevity late in human evolution.
🔶 3. Main Argument of the Authors
Hawkes and O’Connell argue that:
⭐ The OY ratio does NOT measure longevity.
Even if ages are correctly estimated, the ratio is strongly influenced by:
Preservation bias (older bones deteriorate more)
Estimation errors (tooth wear ages are imprecise)
Non-random sampling of deaths
Archaeological context (burial practices, living conditions)
Thus, high or low representation of older adults in a fossil assemblage may reflect postmortem processes, not real lifespan differences.
🔶 4. Key Evidence Provided
⭐ A. Cross-primate comparison
The authors calculate OY ratios for:
Japanese macaques
Chimpanzees
Modern human hunter-gatherers
Despite huge differences in their real lifespans:
Macaques live ≈ 30 years
Chimpanzees ≈ 40–50 years
Humans ≈ 70+ years
Their O/Y ratios are nearly identical:
Species O/Y Ratio
Macaques 0.97
Chimpanzees 1.09
Humans 1.12
This proves that if the metric worked, there would be very little variation in OY ratios—even between species with very different longevity.
Therefore, the extreme fossil ratios (e.g., 0.12 to 2.08) cannot reflect real lifespan differences.
How old is human longevity
⭐ B. Paleodemographic Problems
The paper explains why skeletal assemblages almost never reflect real population age structures:
Age estimation errors (especially for adults)
Poor preservation of older individuals’ bones
Non-random sampling of deaths (cultural, ecological, and taphonomic factors)
Even large skeletal samples cannot be assumed to represent living populations.
How old is human longevity
🔶 5. Theoretical Implications
If Caspari & Lee’s OY ratios were valid, they would contradict:
Stable population theory
Known mammalian life-history invariants
Primate patterns linking maturity age with lifespan
Since all primates show a fixed proportional relationship between age at maturity and adult lifespan, drastic jumps in the OY ratio are biologically implausible.
Instead, the variation seen in fossil OY ratios most likely reflects sample bias, not evolutionary change.
🔶 6. Final Conclusion
Hawkes and O’Connell conclude:
❌ The claim that human longevity suddenly increased in the Upper Paleolithic is unsupported.
❌ Fossil age ratios do not measure longevity.
✔ Differences in OY ratios across fossil assemblages reflect archaeological and preservation biases, not biological evolution.
They emphasize that interpreting fossil age structures requires extreme caution, and that modern demographic and primate comparative data provide essential context for understanding ancient life histories.
⭐ Perfect One-Sentence Summary
This PDF demonstrates that the fossil tooth-wear ratio used to claim a late emergence of human longevity is not a valid measure of lifespan, and that differences across fossil assemblages reflect sampling and preservation biases—not real evolutionary changes in human longevity....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/kqpdxnql-8909/data/document.pdf"}...
|
/home/sid/tuning/finetune/backend/output/kqpdxnql- /home/sid/tuning/finetune/backend/output/kqpdxnql-8909/data/kqpdxnql-8909.json...
|
null
|
failed
|
1764891610
|
1764893416
|
NULL
|
/home/sid/tuning/finetune/backend/output/kqpdxnql- /home/sid/tuning/finetune/backend/output/kqpdxnql-8909/adapter...
|
False
|
Edit
Delete
|
|
74443e2b-6a9e-46eb-b276-b29fb3769c25
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
qpiqhaml-4104
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
How not to die ?
|
How not to die?
|
/home/sid/tuning/finetune/backend/output/qpiqhaml- /home/sid/tuning/finetune/backend/output/qpiqhaml-4104/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a summary-style medical-nutritional gu This PDF is a summary-style medical-nutritional guide based on Dr. Michael Greger’s bestselling book How Not to Die. It presents the scientific evidence showing how specific foods and lifestyle choices can prevent, treat, and even reverse the leading causes of death. The document is structured around the idea that diet is the strongest tool humans have to improve longevity, reduce disease risk, and strengthen the body’s natural defenses.
At its core, the PDF explains:
Most premature deaths are preventable through daily nutritional and lifestyle changes—especially a whole-food, plant-based diet.
🩺 1. Focus on Preventing the Top Killers
The PDF highlights how dietary patterns influence mortality from diseases such as:
Cardiovascular disease
High blood pressure
Cancer
Diabetes
Respiratory illnesses
Kidney disease
Neurological decline
How not to die - Michael Greger
The message is consistent: nutrition is medicine.
🌱 2. The Power of Whole Plant Foods
The document promotes a diet centered on:
Vegetables
Fruits
Legumes (beans, lentils)
Whole grains
Nuts & seeds
Herbs & spices
These foods contain fiber, antioxidants, phytonutrients, and anti-inflammatory compounds that protect against disease and support longevity.
How not to die - Michael Greger
🍇 3. “Daily Dozen” Longevity Checklist
Dr. Greger’s famous Daily Dozen appears in the text—a list of 12 food groups and habits to include every day.
These typically include:
Beans
Berries
Cruciferous vegetables
Greens
Whole grains
Nuts and seeds
Fruits
Spices (especially turmeric)
Water
Exercise
How not to die - Michael Greger
The Daily Dozen provides a simple, actionable structure for eating to extend lifespan.
❤️ 4. How Diet Reverses Disease
Key mechanisms highlighted:
✔ Reducing inflammation
Plant foods contain anti-inflammatory compounds that lower chronic disease risk.
✔ Improving endothelial (blood vessel) function
Essential for reversing heart disease.
✔ Reducing oxidative stress
Antioxidants in plants help prevent cellular damage and aging.
✔ Balancing blood sugar
Whole foods stabilize insulin and reduce diabetes risk.
✔ Supporting gut microbiome health
Fiber-rich foods promote healthy bacteria that protect longevity.
How not to die - Michael Greger
🚫 5. Foods and Habits Linked to Higher Mortality
The PDF warns against:
Processed meats
Excessive salt
Refined sugar
Ultra-processed foods
Sedentary lifestyle
Smoking
High intake of animal fats
How not to die - Michael Greger
These factors contribute significantly to premature death.
🧪 6. Evidence-Based Approach
Dr. Greger’s work is built on:
Peer-reviewed medical research
Epidemiological data
Clinical trials
Meta-analyses
The PDF reflects this, presenting diet as a scientifically grounded intervention—not a fad or trend.
How not to die - Michael Greger
👨⚕️ 7. Lifestyle as Medicine
Beyond nutrition, the document includes advice on:
Regular physical activity
Stress reduction
Adequate sleep
Social connection
These lifestyle pillars combine with diet to produce a powerful longevity effect.
How not to die - Michael Greger
⭐ Overall Summary
This PDF provides a clear, impactful overview of Dr. Michael Greger’s message: Most deaths from chronic diseases are preventable, and the most effective path to long life is a whole-food, plant-based diet combined with healthy daily habits. The document explains the foods that protect against disease, the biological mechanisms involved, and the lifestyle changes proven to extend lifespan.
How not to die - Michael Greger
If you want, I can also provide:
✅ A 5-line ultra-short summary
✅ A one-paragraph version
✅ A bullet-point cheat sheet
✅ Urdu/Hindi translation
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/qpiqhaml-4104/data/document.pdf", "num_examples": 5365, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/qpiqhaml- /home/sid/tuning/finetune/backend/output/qpiqhaml-4104/data/qpiqhaml-4104.json...
|
null
|
completed
|
1764891663
|
1764930053
|
NULL
|
/home/sid/tuning/finetune/backend/output/qpiqhaml- /home/sid/tuning/finetune/backend/output/qpiqhaml-4104/adapter...
|
False
|
Edit
Delete
|
|
d355b5ee-0bdd-41f1-b306-51d0d30a7f56
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
aihaukth-5364
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
How Long is Longevity
|
How Long is Long in Longevity
|
/home/sid/tuning/finetune/backend/output/aihaukth- /home/sid/tuning/finetune/backend/output/aihaukth-5364/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This paper explores a deceptively simple question: This paper explores a deceptively simple question: When does longevity actually begin?
Historically, societies have defined “old age” using fixed ages such as 60, 65, or 70, but this study shows that such ages are arbitrary, outdated, and demographically meaningless. Instead, the author proposes a scientific, population-based approach to define the true onset of longevity.
🧠 1. Main Argument
Traditional age thresholds (60–70 years) are not reliable indicators of longevity because:
They were created for social or economic reasons (military service, taxes, pensions).
They ignore how populations change over time.
They do not reflect biological, demographic, or evolutionary realities.
How Long is Long in Longevity
The study’s central idea:
Longevity should not be defined by chronological age—but by how many people remain alive at a given age.
How Long is Long in Longevity
The paper therefore redefines longevity in terms of survivorship, not age.
🔍 2. Why Chronological Age Is Misleading
The author reviews commonly used demographic indicators:
A. Life expectancy
Measures the average lifespan.
Useful, but only shows the mean and not the distribution.
How Long is Long in Longevity
B. Modal age at death (M)
The most common age at death.
Meaningful, but problematic in populations with high infant mortality.
How Long is Long in Longevity
C. Lifetable entropy threshold
Measures lifespan variability and identifies where mortality improvements matter most.
How Long is Long in Longevity
Each indicator gives partial insight, but none fully captures when a life becomes “long.”
🌱 3. A New Concept: Survivorship Ages (s-ages)
The author introduces s-ages, defined as:
x(s) = the age at which a proportion s of the population remains alive.
How Long is Long in Longevity
This is the inverse of the survival function:
s = 1 → birth
s = 0.5 → median lifespan
s = 0.37 → the proposed longevity threshold
S-ages reflect how survival shifts across generations and are mathematically tied to mortality, failure rates, and evolutionary pressures.
⚡ 4. The Key Scientific Breakthrough: Longevity Begins at x(0.37)
Why 37%?
Using the cumulative hazard concept from reliability theory, the author shows:
When cumulative hazard H(x) = 1, the population has experienced enough mortality to kill the average individual.
Mathematically, H(x) = −ln(s).
Setting H(x) = 1 gives s = e⁻¹ ≈ 0.37.
How Long is Long in Longevity
Interpretation:
Longevity begins at the age when only 37% of the population remains alive—x(0.37).
This is a scientifically grounded threshold based on:
Demography
Reliability theory
Evolutionary biology
Not arbitrary retirement-age traditions.
🧬 5. Biological Meaning (Evolutionary View)
Evolutionary biologists argue:
Natural selection weakens after reproductive ages.
Early-life forces determine vitality; later life is governed by “force of failure.”
How Long is Long in Longevity
By linking these views:
The onset of longevity is the point where natural selection stops dominating and accumulated damage becomes the main driver of survival.
This aligns perfectly with the hazard threshold H(x) = 1 → s = 0.37.
📊 6. Empirical Evidence (USA, Denmark, France, 1950–2020)
The paper shows survival curves and s-ages shifting toward older ages across decades.
Key patterns:
The longevity threshold x(0.37) consistently lies well above age 70.
It increases over time along with life expectancy, the entropy threshold, and modal age at death.
All indicators move upward together—showing that longevity is dynamic, not fixed.
How Long is Long in Longevity
In all countries studied:
People in the 1950s reached the x(0.37) longevity threshold much earlier than people today.
Meaning: survival to advanced ages is improving steadily.
🔑 7. Major Conclusions
✔ Longevity cannot be defined by a fixed age like 60 or 65.
✔ Longevity is a population-relative concept—based on survival, not age.
✔ The scientifically justified threshold is:
The age at which only 37% of the population remains alive — x(0.37).
✔ All longevity indicators point to a continuously increasing threshold over time.
✔ Old age today begins much later than traditional retirement ages.
🌟 Perfect One-Sentence Summary
Longevity should be defined not by chronological age but by the survival threshold x(0.37), where only 37% of the population is still alive—marking the scientifically grounded onset of a long life.
If you want, I can also create:
📌 A diagram of the 37% longevity threshold
📌 A mind map
📌 A short summary
📌 A comparison with your other longevity PDFs
📌 A PowerPoint presentation
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/aihaukth-5364/data/document.pdf", "num_examples": 31, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/aihaukth- /home/sid/tuning/finetune/backend/output/aihaukth-5364/data/aihaukth-5364.json...
|
null
|
completed
|
1764891665
|
1764894959
|
NULL
|
/home/sid/tuning/finetune/backend/output/aihaukth- /home/sid/tuning/finetune/backend/output/aihaukth-5364/adapter...
|
False
|
Edit
Delete
|
|
3e73ef7e-46ff-49fa-aa12-b9a92621455a
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
icofglqw-1630
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
How long do patients
|
How long do patients with chronic disease ?
|
/home/sid/tuning/finetune/backend/output/icofglqw- /home/sid/tuning/finetune/backend/output/icofglqw-1630/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
The PDF is a clinical research article that invest The PDF is a clinical research article that investigates how long patients with chronic medical conditions live, and how their survival compares with that of the general population. The study focuses on using cohort survival analysis to estimate life expectancy after diagnosis for individuals with chronic diseases.
The document is designed to help clinicians, patients, and caregivers better understand:
the prognosis of chronic illnesses,
the expected years of life after diagnosis, and
variations in survival based on disease type, risk factors, and demographics.
The study includes both model-based projections and observed survival curves from multiple patient populations.
📌 Main Purpose of the PDF
To provide accurate survival estimates for chronic disease patients by analyzing:
life expectancy after diagnosis,
mortality rates over time,
relative survival compared with age-matched individuals,
the effect of disease severity and comorbidities.
The paper aims to offer practical, medically meaningful data for planning long-term patient care.
🏥 Diseases Analyzed
The document examines survival patterns for multiple chronic illnesses (as shown in the extracted table), including:
Diabetes
Hypertension
Chronic Obstructive Pulmonary Disease (COPD)
Coronary artery disease
Cancer (various types)
Heart failure
Chronic kidney disease
Each condition has its own survival profile, reflecting its unique biological and clinical course.
📊 Key Findings
1. Survival varies greatly by disease type.
Some diseases show relatively long survival (e.g., controlled hypertension), while others show rapid decline (e.g., advanced heart failure or late-stage cancer).
2. Life expectancy decreases significantly with disease severity.
Mild and moderate stages allow longer survival.
Severe stages reduce life expectancy sharply.
3. Age at diagnosis has a major effect.
Younger patients typically lose more potential life years, even if they survive longer after diagnosis.
4. Comorbidities worsen survival outcomes.
Patients with multiple chronic conditions have significantly lower life expectancy than those with a single disease.
📈 Data & Tables Provided
The PDF includes a major table that lists:
Years lived after diagnosis
Average age at death
Expected survival window
Comparison with general population life expectancy
Example entries include life expectancy figures such as:
Patients living 5–8 years after diagnosis of certain diseases
Some conditions showing surviving 10–14 years
Severe diseases showing survival 3–6 years
All data illustrate how chronic illness reduces lifespan and initiates a predictable survival pattern.
🧪 Methodology
The study uses:
Cohort survival analysis
Longitudinal patient records over many years
Kaplan–Meier survival curves
Hazard ratio modeling
These methods provide precise, statistically robust estimates of life expectancy.
❤️ Why This Information Matters
The document helps:
Patients
Understand realistic expectations for future health and lifespan.
Clinicians
Plan treatment goals, monitoring frequency, and long-term care.
Caregivers & Families
Make informed decisions about support, lifestyle adjustments, and long-term planning.
🧾 Overall Conclusion
The PDF shows that chronic diseases significantly reduce life expectancy, but the extent varies widely depending on:
disease type,
severity,
patient age,
and comorbid conditions.
It provides clear survival data to guide medical decision-making and patient counseling.
If you want, I can also provide:
✅ a short summary
✅ a very simple explanation
✅ a list of life expectancies by disease
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/icofglqw-1630/data/document.pdf"}...
|
/home/sid/tuning/finetune/backend/output/icofglqw- /home/sid/tuning/finetune/backend/output/icofglqw-1630/data/icofglqw-1630.json...
|
null
|
failed
|
1764891680
|
1764897097
|
NULL
|
/home/sid/tuning/finetune/backend/output/icofglqw- /home/sid/tuning/finetune/backend/output/icofglqw-1630/adapter...
|
False
|
Edit
Delete
|
|
1c39c4ad-acbf-4b69-8902-960d7918d5a7
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
gbsjziqy-6720
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
How has the variance
|
How has the variance of longevity changed ?
|
/home/sid/tuning/finetune/backend/output/gbsjziqy- /home/sid/tuning/finetune/backend/output/gbsjziqy-6720/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This document is a comprehensive research paper th This document is a comprehensive research paper that examines how the variance of longevity (variation in age at death) has changed across different population groups in the United States over the past several decades. Rather than focusing only on life expectancy, it highlights how unpredictable lifespan is, which is crucial for retirement planning and the value of lifetime income products like annuities.
🔎 Main Purpose of the Study
The core purpose is to analyze:
How lifespan variation has changed from the 1970s to 2019
How differences vary across race, gender, and socioeconomic status (education level)
How changes in lifespan variability influence the economic value of annuities
The authors focus heavily on the implications for retirement planning, longevity risk, and financial security.
🔍 Populations Analyzed
The study evaluates five major groups:
General U.S. population
Annuitants (people who purchase annuities)
White—high education
White—low education
Black—high education
Black—low education
All groups are analyzed separately for men and women, and conditional on survival to ages 50, 62, 67, and 70.
📈 Key Findings (Perfect Summary)
1. Population-level variance has remained stable since the 1970s
Even though life expectancy increased, the spread of ages at death (standard deviation) remained mostly unchanged for the general population.
2. SES and racial disparities in lifespan variation remain large
Black and lower-education individuals have consistently greater lifespan variation.
They face higher risks of both premature death and very late death.
This inequality captures an important dimension of social and economic disadvantage.
3. Different groups show different trends (2000–2019)
Variance increased for almost all groups
→ especially high-education Black and low-education White individuals.
Exception: Low-education Black males
→ They showed a substantial decrease in variability mostly due to reduced premature mortality.
4. Annuitants have less lifespan variation at age 50
Those who purchase annuities tend to be healthier, wealthier, and show less lifespan uncertainty.
However, by age 67, the difference in variation between annuitants and the general population nearly disappears.
💰 Economic Insights: Impact on Annuity Value
Using a lifecycle model, the study calculates wealth equivalence — how much additional wealth a person would need to compensate for losing access to a fair annuity.
Key insight:
Even though longevity variance increased, the value of annuities actually declined over time.
Why?
Because life expectancy increased, delaying mortality credits to older ages — lowering annuity value in economic terms.
Quantitative Findings
A one-year increase in standard deviation → raises annuity value by 6.8% of initial wealth.
A one-year increase in life expectancy → reduces annuity value by 3.1%.
From 2000–2019:
General population saw only a 1.3–2.0% increase in annuity value due to rising variance.
By group:
High-education Black males: +13.6%
Low-education Black males: –6.1%
🔬 Methodology
The study uses:
SSA cohort life tables for the general population
Mortality estimates using NVSS & ACS data for race-education groups
Annuity mortality tables (1971 IAM, 1983 IAM, 2000, 2012 IAM) for annuitants
Lifespan variation measured using standard deviation of age at death (Sx)
Wealth equivalence is computed using a CRRA utility model with full annuitization and actuarially fair payouts.
🧠 Why This Matters
Lifespan uncertainty directly affects:
✔ Retirement planning
✔ Optimal savings behavior
✔ Need for annuities or guaranteed lifetime income
✔ Social welfare policy
Groups with higher lifespan uncertainty benefit more from annuities.
The study’s results emphasize:
Persistent inequalities in mortality patterns
The importance of accessible lifetime income options
The role of policy in addressing retirement security
📌 Perfect One-Sentence Summary
The document shows that while life expectancy has risen, the variance of longevity has remained stable overall but diverged notably across racial and socioeconomic groups, significantly influencing the economic value and importance of annuities in retirement planning.
If you want:
✅ A diagram
✅ A simplified student-friendly summary
✅ A PPT, PDF, or infographic
✅ A comparison table
✅ A visual chart
Just tell me — I can generate it!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/gbsjziqy-6720/data/document.pdf", "num_examples": 12, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/gbsjziqy- /home/sid/tuning/finetune/backend/output/gbsjziqy-6720/data/gbsjziqy-6720.json...
|
null
|
completed
|
1764891697
|
1764899216
|
NULL
|
/home/sid/tuning/finetune/backend/output/gbsjziqy- /home/sid/tuning/finetune/backend/output/gbsjziqy-6720/adapter...
|
False
|
Edit
Delete
|
|
06ff8cf8-a770-4a3a-b39d-d333c4550263
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
tllivfbe-3782
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
How chronic disease
|
How chronic disease affects ageing?
|
/home/sid/tuning/finetune/backend/output/tllivfbe- /home/sid/tuning/finetune/backend/output/tllivfbe-3782/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This monographic report, How Chronic Diseases Affe This monographic report, How Chronic Diseases Affect Ageing, provides a comprehensive and multidisciplinary analysis of how the global rise in life expectancy is directly influencing the prevalence, complexity, and long-term impact of chronic diseases in ageing populations. Drawing on international health organisations, national statistics, clinical research, and current care models, the document explains how chronic diseases—such as cardiovascular conditions, diabetes, chronic respiratory illnesses, cancer, and other age-associated disorders—shape the physical, functional, cognitive, emotional, and social dimensions of older adults.
The report examines demographic trends, theoretical frameworks, and epidemiological data to explain why chronicity is becoming one of the major public health challenges of the 21st century. It details the increasing coexistence of multiple chronic conditions (multimorbidity), the clinical complexities of polypharmacy, the progressive decline in autonomy, and the emergence of frailty—both physical and social—as a defining characteristic of advanced age.
Through a structured and evidence-based approach, the document outlines:
✔ Types of chronic diseases prevalent in ageing adults
Including cardiovascular disease, COPD, cancer, diabetes, arthritis, hypertension, osteoporosis, depression, and neurodegenerative disorders such as Alzheimer’s.
✔ The chronic patient profile
Describing levels of complexity, comorbidity, frailty, care dependence, and the growing role of multidisciplinary teamwork in long-term management.
✔ Risk factors
From modifiable lifestyle behaviours (tobacco, diet, activity) to metabolic, genetic, environmental, and socio-economic determinants.
✔ Key challenges
Such as medication reconciliation, treatment non-adherence, limited access to specialised geriatric resources, fragmented care systems, psychological burden, and nutritional vulnerabilities.
✔ Solutions and innovations
Including preventive strategies (primary, secondary, tertiary, quaternary), strengthened primary care, case management models, specialised geriatric resources, PROMs and PREMs for quality-of-life measurement, and advanced technologies—AI, remote monitoring, predictive models—to anticipate complications and personalise care.
✔ Conclusions
Highlighting the need for integrated, person-centred, preventive, predictive, and technologically supported healthcare models capable of addressing the growing burden of chronic diseases in an ageing world.
This report serves as an essential resource for healthcare professionals, policymakers, researchers, and organisations seeking to better understand, manage, and innovate within the intersection of chronicity and ageing.
If you want, I can also create:
✅ A short description
✅ A meta description for SEO
✅ A 100-word executive description
✅ A title, keywords, and index for the document
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/tllivfbe-3782/data/document.pdf", "num_examples": 6, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/tllivfbe- /home/sid/tuning/finetune/backend/output/tllivfbe-3782/data/tllivfbe-3782.json...
|
null
|
completed
|
1764891718
|
1764899539
|
NULL
|
/home/sid/tuning/finetune/backend/output/tllivfbe- /home/sid/tuning/finetune/backend/output/tllivfbe-3782/adapter...
|
False
|
Edit
Delete
|
|
194a372b-87c4-4e26-a935-ef24e7b7f767
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
sigapesq-1263
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Host Longevity Matters
|
Host Longevity Matters
|
/home/sid/tuning/finetune/backend/output/sigapesq- /home/sid/tuning/finetune/backend/output/sigapesq-1263/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
“Host Longevity Matters” investigates how the rema “Host Longevity Matters” investigates how the remaining lifespan of a host influences the basic reproduction number (R₀) of infectious diseases. Unlike traditional epidemiological models—which often assume infinite infectious duration or ignore host lifespan—the authors show that R₀ is deeply shaped by host longevity, especially for long-lasting infections.
The study combines two powerful components:
A within-host model capturing pathogen replication, mutation, immune response, and resource dynamics.
A between-host transmission model capturing contact structure, secondary infections, and network effects.
By integrating both layers, the paper explores how pathogen evolution depends on two internal parameters:
Replication rate (ρ)
Successful mutation probability (δ)
and one external ecological parameter:
Host contact rate (α)
The goal is to determine which pathogen strategy maximizes R₀ under different host lifespans.
🔍 Core Insight
Pathogens evolve toward one of two fundamental strategies:
1. Killer-like Strategy
Fast replication
Intermediate mutation rates
High pathogen load
Short, intense infections
Favors rapid spread when:
Host lifespan is short, OR
Host contact rates are low
2. Milker-like Strategy
Slow replication
High mutation rates
Low, sustained pathogen load
Long infection duration
Favors persistence when:
Host lifespan is long, AND/OR
Contact rates are high
The study demonstrates a sharp transition between these strategies depending on the combination of:
Host longevity (Dmax)
Contact rate (α)
This yields a bifurcation line separating killer-like from milker-like evolutionary optima.
📈 Key Findings
1. Host Longevity Strongly Shapes R₀
For short-lived hosts (e.g., insects), R₀ increases roughly linearly with contact rate.
For long-lived hosts (e.g., humans), R₀ rapidly reaches a plateau even with moderate contact.
The impact of longevity is large enough to change evolutionary conclusions from previous models.
2. Strategy Switch Depends on Contact Rate
There exists a critical contact rate αₙ, where pathogens switch from:
Killer strategy (fast replication)
to Milker strategy (slow replication)
The value of αₙ shifts strongly with host lifespan.
3. Above a Certain Longevity Threshold, Only Milker Strategy Is Optimal
For very long-lived hosts:
Killer-like strategies disappear entirely.
Pathogens evolve toward mild, persistent infections.
This explains why many long-standing human diseases show long-duration, low-virulence dynamics.
4. Zoonotic Diseases Are Exceptions
Because they originate from short-lived animals, zoonoses (e.g., avian influenza, Ebola) are often:
Highly virulent
Fast-replicating
Short-lasting (killer-like)
This aligns with the model’s predictions.
🧠 Implications
For Evolutionary Epidemiology
Host longevity must be included when predicting pathogen evolution.
Long-lived species tend to select for milder, persistent pathogens.
For Public Health
Models ignoring host lifespan may misestimate epidemic thresholds.
When evaluating disease control strategies, lifespan restriction (e.g., culling, selective breeding) can alter pathogen evolution.
For Theory
This model is among the first to show that R₀ is not purely a pathogen trait, but emerges from interaction between:
Host immune dynamics
Lifespan constraints
Contact structures
Pathogen mutation and replication
🧭 In Summary
“Host Longevity Matters” shows that the lifespan of a host is a critical, previously overlooked determinant of pathogen fitness and evolution.
Long-lived hosts push pathogens toward slow, stealthy, “milker-like” behavior.
Short-lived hosts favor fast, damaging “killer-like” pathogens.
This work demonstrates that R₀, infection strategy, and pathogen evolution are inseparable from host longevity....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/sigapesq-1263/data/document.pdf", "num_examples": 39, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/sigapesq- /home/sid/tuning/finetune/backend/output/sigapesq-1263/data/sigapesq-1263.json...
|
null
|
completed
|
1764892570
|
1764897369
|
NULL
|
/home/sid/tuning/finetune/backend/output/sigapesq- /home/sid/tuning/finetune/backend/output/sigapesq-1263/adapter...
|
False
|
Edit
Delete
|
|
5dd5b4a6-c6c5-438f-a358-fcb3168f4c2d
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
bgqcsiba-0421
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Healthy Longevity
|
Healthy Longevity
|
/home/sid/tuning/finetune/backend/output/bgqcsiba- /home/sid/tuning/finetune/backend/output/bgqcsiba-0421/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
“Healthy Longevity – National Academy of Medicine “Healthy Longevity – National Academy of Medicine (NAM)”**
This PDF is an official National Academy of Medicine (NAM) overview describing one of the most ambitious global initiatives on aging: the Healthy Longevity Global Grand Challenge. It outlines the accelerating demographic shift toward older populations, the opportunities created by scientific breakthroughs, the threats posed by aging societies, and NAM’s worldwide plan to spark innovation, research, and policy transformation to ensure people live not just longer, but healthier lives.
The central message:
Human life expectancy has increased dramatically—but longevity without health creates massive social, economic, and healthcare burdens. The world needs bold innovations to extend healthspan, not just lifespan.
🌍 1. The Global Context of Aging
The document opens with striking demographic realities:
8.5% of the world (617 million people) are already age 65+.
By 2050, this will more than double to 1.6 billion older adults.
The number of people aged 80+ will triple from 126 million to 447 million.
Healthy longevity
These trends threaten to overwhelm economies, healthcare systems, and social structures—but also create unprecedented opportunities for scientific innovation and societal redesign.
🧠 2. The Challenge: Extending Healthspan
Despite medical breakthroughs, societies are not fully prepared for extended longevity.
NAM argues that:
We must not just live longer, but better—functional, productive, and mentally and socially healthy.
Innovations in medicine, public health, technology, and social systems will be essential.
Healthy longevity
The document calls for multidisciplinary solutions involving science, policy, economics, and community design.
🚀 3. The Healthy Longevity Global Grand Challenge
NAM introduces a massive, multi-year, global movement with four main goals:
⭐ 1. Catalyze breakthrough ideas and research
Support innovations in disease prevention, mobility, social connectedness, and longevity.
⭐ 2. Achieve transformative, scalable innovation
Turn groundbreaking research into real-world solutions that can improve lives globally.
⭐ 3. Provide a global roadmap for healthy longevity
Produce an authoritative report detailing economic, social, scientific, and policy opportunities.
⭐ 4. Build a worldwide ecosystem of innovators
Uniting scientists, engineers, entrepreneurs, health leaders, policymakers, and the public.
Healthy longevity
🏆 4. The Prize Competition Structure
The competition is divided into three phases, each escalating in scope:
1) Catalyst Phase
Seeds bold, early-stage ideas that could extend healthspan—across biology, technology, social systems, prevention, mobility, etc.
2) Accelerator Phase
Provides funding and support to develop prototypes or pilot projects.
3) Grand Prize
Awards a transformative, real-world innovation that significantly extends healthy human lifespan.
Healthy longevity
This framework encourages continuous innovation—from idea to global impact.
🧭 5. Developing the Global Roadmap for Healthy Longevity
An international commission will produce a major report identifying:
Global challenges and opportunities
Best practices from around the world
Social, behavioral, and environmental determinants
Healthcare and public health strategies
Science, engineering, and technology solutions
Equity, financing, policy, and implementation considerations
Healthy longevity
The roadmap will guide countries in redesigning systems to support healthier, longer lives.
🧬 6. A Multidisciplinary Global Effort
The initiative brings together leaders across:
Medicine & public health
Science & engineering
Technology & AI
Policy & economics
Social sciences
Private-sector innovation
This reflects NAM’s belief that healthy longevity is not just a medical issue—but a societal transformation.
Healthy longevity
🏛 7. About the National Academy of Medicine
The PDF closes by describing NAM:
Founded in 1970 (formerly the Institute of Medicine)
Independent, nonprofit, science-based advisory body
Works alongside the National Academy of Sciences and National Academy of Engineering
Provides guidance on global health, policy, and innovation
Healthy longevity
NAM leverages its global reputation to push healthy longevity as a top priority.
⭐ Overall Summary
This PDF is a clear, persuasive introduction to NAM’s Healthy Longevity Global Grand Challenge, a worldwide effort to drive innovation, transform aging, and ensure future generations enjoy longer, healthier, more productive lives. It highlights the urgency created by global aging trends, the need for breakthroughs across science and society, and the structure of a major international prize competition designed to accelerate progress.
Healthy longevity
If you want, I can also provide:
✅ A 5-line summary
✅ A one-paragraph plain-language version
✅ Bullet-point quick notes
✅ Urdu/Hindi translation
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/bgqcsiba-0421/data/document.pdf"}...
|
/home/sid/tuning/finetune/backend/output/bgqcsiba- /home/sid/tuning/finetune/backend/output/bgqcsiba-0421/data/bgqcsiba-0421.json...
|
null
|
failed
|
1764892607
|
1764893209
|
NULL
|
/home/sid/tuning/finetune/backend/output/bgqcsiba- /home/sid/tuning/finetune/backend/output/bgqcsiba-0421/adapter...
|
False
|
Edit
Delete
|
|
7d81f0d8-d1f8-4053-adb9-5ded01f9e05f
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
dxnygstl-3313
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Healthy Living Guide
|
Healthy Living Guide
|
/home/sid/tuning/finetune/backend/output/dxnygstl- /home/sid/tuning/finetune/backend/output/dxnygstl-3313/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a polished, reader-friendly, research- This PDF is a polished, reader-friendly, research-backed wellness guide created to help people improve their overall health in the years 2020–2021. Designed as a practical lifestyle companion, it presents clear, evidence-based advice on nutrition, physical activity, weight management, mental well-being, and maintaining healthy habits during challenging times—especially the COVID-19 pandemic.
It combines scientific recommendations, simple tools, checklists, and motivational strategies into an accessible format that supports long-term healthy living.
🔶 1. Purpose of the Guide
The document aims to help readers:
Understand the core principles of healthy living
Build habits that support long-term physical and emotional well-being
Adapt their lifestyle to pandemic-era challenges
Apply simple, realistic changes to diet, movement, and daily routines
It brings together the most up-to-date public health and nutrition research into a single, user-friendly resource.
🔶 2. Key Themes Covered
The guide addresses the essential pillars of health:
⭐ Healthy Eating
Emphasizes fruits, vegetables, whole grains, nuts, legumes, and healthy fats
Highlights the importance of high-quality food choices
Encourages limiting sugar, sodium, and processed foods
Offers practical meal planning and grocery tips
⭐ Healthy Weight
Explains the relationship between calorie intake, energy balance, and metabolism
Provides strategies for weight loss and weight maintenance
Introduces mindful eating and portion awareness
⭐ Healthy Movement
Encourages daily physical activity, not just structured exercise
Outlines benefits for cardiovascular health, muscle strength, mobility, and mood
Suggests ways to stay active at home
⭐ Mental and Emotional Well-Being
Provides guidance for reducing stress and supporting resilience
Highlights the role of sleep, social connection, and relaxation techniques
Offers coping strategies for pandemic-related anxiety
⭐ COVID-19 and Healthy Living
Explains how the pandemic influenced lifestyle patterns
Encourages maintaining routines for immunity and mental health
Offers science-based recommendations for safety and preventive care
🔶 3. Practical Tools Included
The guide contains numerous supportive features:
Healthy plate diagrams
Food quality rankings
Movement breaks and activity suggestions
Goal-setting templates
Simple recipes and snack ideas
Checklists for building healthy routines
These tools make it easy for readers to turn concepts into action.
🔶 4. Tone and Design
The document is:
Encouraging, positive, and supportive
Richly illustrated with colorful visuals
Organized into short, readable sections
Designed for both beginners and advanced health-conscious individuals
🔶 5. Core Message
The central idea of the guide is that healthy living is achievable through small, consistent, everyday decisions—not extreme diets or intense workout programs. It promotes balance, quality nutrition, regular movement, and mental well-being as the foundations of a long and healthy life.
⭐ Perfect One-Sentence Summary
This PDF is a clear, science-based, and practical guide that teaches readers how to improve their diet, activity levels, weight, and mental well-being—especially during the COVID-19 era—through simple, sustainable healthy living strategies....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/dxnygstl-3313/data/document.pdf"}...
|
/home/sid/tuning/finetune/backend/output/dxnygstl- /home/sid/tuning/finetune/backend/output/dxnygstl-3313/data/dxnygstl-3313.json...
|
null
|
failed
|
1764892616
|
1764901645
|
NULL
|
/home/sid/tuning/finetune/backend/output/dxnygstl- /home/sid/tuning/finetune/backend/output/dxnygstl-3313/adapter...
|
False
|
Edit
Delete
|
|
45e10f36-62a4-4a66-916a-d8c72cd4e215
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
nhhhywgu-7544
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Healthy longevity in the
|
Healthy longevity in the Asia
|
/home/sid/tuning/finetune/backend/output/nhhhywgu- /home/sid/tuning/finetune/backend/output/nhhhywgu-7544/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This report presents a comprehensive overview of h This report presents a comprehensive overview of how Asian societies are aging and how they can achieve healthy longevity — the ability to live long lives in good health, free from disease, disability, and social decline. It highlights the population changes, health challenges, and policy solutions required for Asia to benefit from the longevity revolution.
🧠 1. Core Idea
Asia is aging at an unprecedented speed, and many countries will become “super-aged” (≥20% of population aged 65+) within the next few decades.
Healthy longevity is no longer optional — it is a social, economic, and health imperative.
Healthy longevity in the Asia
The report argues that countries must shift from managing aging to maximizing healthy aging, preventing disease earlier, redesigning health systems, and building environments where people can live longer, healthier lives.
🌏 2. The Demographic Shift in Asia
✔ Asia is the world’s fastest-aging region
Nations like Japan, South Korea, Singapore, and China are experiencing rapid increases in older populations.
Life expectancy is rising while fertility declines.
Healthy longevity in the Asia
✔ The aging transition affects health, workforce, economy, and social systems
Older populations require more medical care, long-term care, and supportive environments.
✔ Many countries will reach a “super-aged” status by 2030–2050
Healthy longevity in the Asia
❤️ 3. What “Healthy Longevity” Means
The report defines healthy longevity as:
The state in which an individual lives both long and well — maintaining physical, mental, social, and economic well-being throughout old age.
Healthy longevity in the Asia
It is not just lifespan, but healthspan — the number of years lived in good health.
🧬 4. Key Determinants of Healthy Longevity in Asia
A. Health Systems Must Shift to Preventive Care
Focus on chronic disease prevention
Detect disease earlier
Improve access to healthcare
Healthy longevity in the Asia
B. Social Determinants Matter
Education
Income
Healthy behavior
Social connection
Healthy longevity in the Asia
C. Lifelong Health Behaviors
Smoking, diet, exercise, and social engagement strongly influence later-life health.
Healthy longevity in the Asia
D. Age-Friendly Cities & Infrastructure
Walkability, transportation, housing, technology, and safety play major roles.
Healthy longevity in the Asia
E. Technology & Innovation
Digital health, AI, robotics, and telemedicine are critical tools for elderly care.
Healthy longevity in the Asia
🏥 5. Challenges Facing Asia
1. Chronic Non-Communicable Diseases (NCDs)
Heart disease, cancer, diabetes, and stroke dominate morbidity and mortality.
Healthy longevity in the Asia
2. Unequal Access to Healthcare
Rural–urban gaps, poverty, and service shortages create disparities.
Healthy longevity in the Asia
3. Long-Term Care Needs Are Exploding
Asian families traditionally provided care, but modern lifestyles reduce this capacity.
Healthy longevity in the Asia
4. Financial Pressure on Health and Pension Systems
Governments face rising costs as populations age.
Healthy longevity in the Asia
🎯 6. Policy Recommendations
A. Promote Preventive Health Across the Lifespan
Encourage healthy behaviors from childhood to old age.
Healthy longevity in the Asia
B. Strengthen Primary Care
Shift from hospital-based to community-based systems.
Healthy longevity in the Asia
C. Build Age-Inclusive Environments
Urban design, transport, and housing must support healthy and active aging.
Healthy longevity in the Asia
D. Use Technology to Transform Elder Care
Smart homes, assistive devices, robotics, digital monitoring.
Healthy longevity in the Asia
E. Support Caregivers & Expand Long-Term Care Systems
Formal and informal caregivers both need training and resources.
Healthy longevity in the Asia
🌟 7. The Vision for Asia’s Healthy Longevity Future
By embracing innovation, prevention, community care, and age-friendly environments, Asia can transform aging into an opportunity rather than a crisis.
The report envisions societies where:
People stay healthy longer
Older adults remain active contributors
Healthcare is affordable and accessible
Cities and communities support aging with dignity
Healthy longevity in the Asia
🌟 Perfect One-Sentence Summary
Healthy longevity in Asia requires transforming health systems, environments, and societies to ensure people not only live longer but live better across their entire lifespan.
If you want, I can also provide:
📌 A diagram
📌 A mind map
📌 A short summary
📌 A 10-slide presentation
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/nhhhywgu-7544/data/document.pdf"}...
|
/home/sid/tuning/finetune/backend/output/nhhhywgu- /home/sid/tuning/finetune/backend/output/nhhhywgu-7544/data/nhhhywgu-7544.json...
|
null
|
failed
|
1764892626
|
1764897141
|
NULL
|
/home/sid/tuning/finetune/backend/output/nhhhywgu- /home/sid/tuning/finetune/backend/output/nhhhywgu-7544/adapter...
|
False
|
Edit
Delete
|
|
8a79b710-547a-4f71-ae54-cb52c6750cb8
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
xofkgdzk-4012
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Healthy lifestyle
|
Healthy lifestyle and life expectancy
|
/home/sid/tuning/finetune/backend/output/xofkgdzk- /home/sid/tuning/finetune/backend/output/xofkgdzk-4012/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a scientific study that examines how f This PDF is a scientific study that examines how four major lifestyle behaviors affect life expectancy, especially in people with and without chronic diseases. The research evaluates how combinations of healthy habits can increase lifespan, even for individuals already diagnosed with long-term medical conditions.
It provides evidence on how lifestyle choices—including smoking, alcohol consumption, physical activity, and body weight—change the number of years a person can expect to live from age 50 onward.
The paper includes summary tables, life expectancy comparisons, and detailed statistical analysis across three chronic diseases.
📌 Main Purpose of the Study
To quantify how healthy lifestyle patterns influence:
✔ Life expectancy at age 50
✔ Additional years lived with and without chronic disease
✔ Survival differences between lifestyle groups
✔ The impact of disease type on lifestyle benefits
The research aims to show that lifestyle improvement is beneficial at any health status, including for patients with:
Cancer
Cardiovascular disease
Type 2 diabetes
🧬 Key Lifestyle Behaviors Analyzed
The study focuses on four major risk factors:
Smoking status
Body Mass Index (BMI)
Physical activity levels
Alcohol intake
Participants are grouped into three lifestyle categories (as shown in the table):
Unhealthy lifestyle
Intermediate lifestyle
Healthy lifestyle
📊 Major Findings
1️⃣ Healthy lifestyle significantly increases life expectancy
For all participants, adopting a healthy lifestyle increases life expectancy at age 50 by:
5.2 additional years for men
4.9 additional years for women
Even moderate improvement (intermediate lifestyle) adds several years of life.
2️⃣ Benefits apply to people WITH chronic diseases
Individuals with existing chronic diseases also gain extra years from healthier behaviors.
Cancer patients
Healthy lifestyle adds 6.1 years
Cardiovascular disease patients
Healthy lifestyle adds 5.0 years
Patients with diabetes
Healthy lifestyle adds 3.4 years
This proves that lifestyle still matters, even after disease onset.
3️⃣ Unhealthy lifestyle causes large losses in life expectancy
For the unhealthy lifestyle group, expected life after age 50 drops below:
20.7 years for men
24.1 years for women
—significantly lower than those living healthily.
4️⃣ Healthy lifestyle increases disease-free years
The study shows that individuals with healthier habits spend:
more years without chronic disease
fewer years with disability
more years with better physical functioning
📉 Data Table Summary (from PDF)
The table in the PDF summarizes life expectancy under 4 conditions:
Without disease ("—")
Cancer
Cardiovascular disease (CVD)
Diabetes
Life expectancy from age 50 varies by lifestyle:
Healthy lifestyle (best outcomes)
≈ 29.0–31.0 additional years
Intermediate
≈ 26.0–28.0 years
Unhealthy lifestyle
≈ 20.7–24.1 years
The table clearly displays the contribution of each lifestyle category and disease state to total remaining lifespan.
🧾 Overall Conclusion
The PDF concludes that a healthy lifestyle dramatically increases life expectancy, regardless of disease status.
Key takeaways:
✔ Lifestyle improvements reduce mortality
✔ Benefits apply to both healthy individuals and those with chronic disease
✔ Smokers, inactive individuals, and those with obesity have significantly shorter lives
✔ Healthy habits add 4–7 years of life after age 50
The message is clear:
It is never too late to adopt a healthier lifestyle.
If you'd like, I can also create:
✅ a short summary
✅ a very easy explanation
✅ a comparison with other longevity papers
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/xofkgdzk-4012/data/document.pdf", "num_examples": 5, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/xofkgdzk- /home/sid/tuning/finetune/backend/output/xofkgdzk-4012/data/xofkgdzk-4012.json...
|
null
|
completed
|
1764892643
|
1764897450
|
NULL
|
/home/sid/tuning/finetune/backend/output/xofkgdzk- /home/sid/tuning/finetune/backend/output/xofkgdzk-4012/adapter...
|
False
|
Edit
Delete
|
|
bb21b439-9974-441f-9bf9-bdb5693d16ea
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
atmaowak-0526
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Healthy lifestyle
|
Healthy lifestyle and life expectancy with
|
/home/sid/tuning/finetune/backend/output/atmaowak- /home/sid/tuning/finetune/backend/output/atmaowak-0526/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This scientific study investigates how healthy lif This scientific study investigates how healthy lifestyle behaviors in midlife influence life expectancy, both with and without major chronic diseases, over a 20-year period. The research uses data from 57,053 Danish adults aged 50–69 years from the well-known Diet, Cancer and Health cohort.
The authors aim to understand how everyday lifestyle choices shape long-term health, disease onset, multimorbidity, and healthcare use.
🔑 Purpose of the Study
The study asks:
How does a combined healthy lifestyle score relate to:
Life expectancy free of major chronic diseases
Life expectancy with disease
Multimorbidity (2+ simultaneous chronic illnesses)
Days of hospitalization over 20 years?
It quantifies how much longer and healthier people live as their lifestyle improves.
🧪 How the Study Was Conducted
Population
57,053 men and women, ages 50–69
Denmark, followed for up to 21.5 years
Free of major disease at the start (1997)
Lifestyle Health Score (0–9 points)
Based on 5 behavioral factors:
Smoking (0–2 points)
Sport activity (0–1 point)
Alcohol intake (0–2 points)
Diet quality (0–2 points)
Waist circumference (0–2 points)
A higher score = healthier lifestyle.
Diseases included
Participants were tracked for the development of:
Cancer
Type 2 diabetes
Stroke
Heart disease
Dementia
COPD
Asthma
Follow-up outcomes
Life expectancy without disease
Life expectancy with disease
Time with one disease and multi-disease
Hospitalization days
📊 Key Findings (Perfect Summary)
🟢 1. Healthy behavior significantly extends disease-free life
For 65-year-old participants, each 1-point increase in the health score resulted in:
+0.83 years of disease-free life for men
+0.86 years for women
People with the highest score (9) lived ~7.5 more years disease-free compared to those with the lowest score (0).
🔴 2. Healthy lifestyle reduces the years lived with chronic disease
For each 1-point increase in health score:
Men: –0.18 years with disease
Women: –0.37 years with disease
Women gained the most reduction.
🔵 3. Multimorbidity drops sharply with higher health scores
Among 65-year-olds:
Men with a low score spent 16.8% of life with 2+ diseases
Men with high scores spent only 3.6%
The pattern is similar in women.
Healthy lifestyle greatly compresses time lived with multiple illnesses.
🟣 4. Healthy lifestyle dramatically cuts hospitalization days
For 65-year-old men:
Score 0 → 6.1 days/year in the hospital
Score 9 → 2.4 days/year
For women:
Score 0 → 5.5 days/year
Score 9 → 2.5 days/year
Healthier behaviors = less burden on healthcare systems.
🔥 Which behavior mattered most?
1. Smoking (largest impact)
Current smoking reduced disease-free life by:
–3.20 years in men
–3.74 years in women
And increased years with disease.
2. High waist circumference
Reduced disease-free years by:
–2.54 years (men)
–1.90 years (women)
3. Diet, exercise, & alcohol
These had moderate but meaningful positive effects.
🧠 Final Interpretation
The study clearly shows:
Healthy living in midlife extends life, delays disease, and reduces hospital use.
Even small lifestyle improvements make measurable differences.
The health score is a simple but powerful predictor of later-life health outcomes.
📌 One Perfect Sentence Summary
A healthy lifestyle combining no smoking, regular activity, optimal diet, balanced alcohol intake, and healthy waist size can extend disease-free life by more than 7 years, reduce multimorbidity, and significantly cut hospitalization over 20 years.
If you'd like, I can create:
✅ A simple student summary
✅ A diagram/flowchart
✅ A presentation (PPT)
✅ A PDF summary
✅ A visual table of results
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/atmaowak-0526/data/document.pdf", "num_examples": 66, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/atmaowak- /home/sid/tuning/finetune/backend/output/atmaowak-0526/data/atmaowak-0526.json...
|
null
|
completed
|
1764892660
|
1764897757
|
NULL
|
/home/sid/tuning/finetune/backend/output/atmaowak- /home/sid/tuning/finetune/backend/output/atmaowak-0526/adapter...
|
False
|
Edit
Delete
|
|
60b98694-b72b-4e9d-a780-cd2f78b70412
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
rrdtmrbz-3489
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
healthy lifespan
|
Healthy lifespan inequality
|
/home/sid/tuning/finetune/backend/output/rrdtmrbz- /home/sid/tuning/finetune/backend/output/rrdtmrbz-3489/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This document provides a comprehensive global anal This document provides a comprehensive global analysis of healthy lifespan inequality (HLI)—a groundbreaking indicator that measures how much variation exists in the age at which individuals first experience morbidity. Unlike traditional health metrics that capture only averages, such as life expectancy (LE) and health-adjusted life expectancy (HALE), HLI reveals the distribution and timing of health deterioration within populations.
Using data from the Global Burden of Disease Study 2019, the authors reconstruct mortality and morbidity curves to compare lifespan inequality (LI) with healthy lifespan inequality across 204 countries and territories from 1990 to 2019. This analysis uncovers significant global patterns in how early or late people begin to experience disease, disability, or less-than-good health.
The document presents several key findings:
1. Global Decline in Healthy Lifespan Inequality
Between 1990 and 2019, global HLI decreased for both sexes, indicating progress in narrowing the spread of ages at which morbidity begins. However, high-income countries experienced stagnation, showing no further improvement despite increases in longevity.
2. Significant Regional Differences
Lowest HLI is observed in high-income regions, East Asia, and Europe.
Highest HLI is concentrated in Sub-Saharan Africa and South Asia.
Countries such as Mali, Niger, Nigeria, Pakistan, and Haiti exhibit the widest variability in morbidity onset.
3. Healthy Lifespan Inequality Is Often Greater Than Lifespan Inequality
Across most regions, HLI exceeds LI—meaning variability in health loss is greater than variability in death. This indicates populations are becoming more equal in survival but more unequal in how and when they experience disease.
4. Gender Differences
Women tend to experience higher HLI than men, reinforcing the “health–survival paradox”:
Women live longer
But spend more years in poor health
And experience more uncertainty about when morbidity begins.
5. Rising Inequality After Age 65
For older adults, HLI65 has increased globally, signaling that while people live longer, the onset of morbidity is becoming more unpredictable in later life. Longevity improvements do not necessarily compress morbidity at older ages.
6. A Shift in Global Health Inequalities
The study reveals that as mortality declines worldwide, inequalities are shifting away from death and toward disease and disability. This transition marks an important transformation in modern population health and has major implications for:
healthcare systems
pension planning
resource allocation
long-term care
public health interventions
7. Policy Implications
The findings stress that improving average lifespan is not enough. Policymakers must also address when morbidity begins and how uneven that experience is across populations. Rising heterogeneity in morbidity onset, especially among older adults, requires:
stronger preventative health strategies
lifelong health monitoring
reduction of socioeconomic and regional disparities
integration of morbidity-related indicators into national health assessments
In Short
This study reveals a crucial and previously overlooked dimension of global health: even as people live longer, the timing of health deterioration is becoming more unequal, especially in high-income and aging societies. Healthy lifespan inequality is emerging as a vital metric for understanding the true dynamics of global aging and for designing health systems that prioritize not only longer life, but fairer and healthier life.
If you want, I can also create:
✅ A shorter perfect description
✅ An executive summary
✅ A diagram for HLI vs LI
✅ A simplified student-level explanation...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/rrdtmrbz-3489/data/document.pdf", "num_examples": 54, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/rrdtmrbz- /home/sid/tuning/finetune/backend/output/rrdtmrbz-3489/data/rrdtmrbz-3489.json...
|
null
|
completed
|
1764892679
|
1764897466
|
NULL
|
/home/sid/tuning/finetune/backend/output/rrdtmrbz- /home/sid/tuning/finetune/backend/output/rrdtmrbz-3489/adapter...
|
False
|
Edit
Delete
|
|
250632b8-ddec-491c-97aa-aeb4de573fe1
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
xaxkkpem-6210
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Healthy life expectancy,
|
Healthy life expectancy, mortality, and age
|
/home/sid/tuning/finetune/backend/output/xaxkkpem- /home/sid/tuning/finetune/backend/output/xaxkkpem-6210/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This paper explains why traditional measures of He This paper explains why traditional measures of Healthy Life Expectancy (HLE) can be misleading when they rely only on age-specific morbidity (illness/disability) rates.
The authors show that many health conditions in older ages are not primarily driven by age, but by Time-To-Death (TTD)—how close someone is to dying. Because of this, the usual practice of linking health problems to chronological age produces distorted results, especially when comparing populations or tracking trends over time.
Key Insights
Morbidity often rises sharply in the final years before death, regardless of the person's age.
Therefore, when life expectancy increases, the population shifts so that more people are farther from death, leading to lower observed disability at a given age—even if the true underlying health process hasn’t changed.
This means that improvements in mortality alone can make it appear that morbidity has decreased or that people are healthier at older ages.
As a result, period HLE estimates may falsely suggest real health improvements, when the change actually comes from mortality declines—not better health.
What the Study Demonstrates
Using U.S. Health and Retirement Study data and mortality tables:
They model disability patterns based on TTD and convert them into apparent age patterns.
They show mathematically and empirically how mortality changes distort age-based morbidity curves.
They test how much bias enters standard health expectancy decompositions (e.g., Sullivan method).
They find that a 5-year increase in life expectancy after age 60 can artificially reduce disability estimates by up to 1 year, even if actual morbidity is unchanged.
Core Message
Age-based prevalence of disease/disability cannot be reliably interpreted without understanding how close individuals are to death.
Thus, comparing HLE between populations—or within a population over time—can be biased unless TTD dynamics are considered....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/xaxkkpem-6210/data/document.pdf", "num_examples": 21, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/xaxkkpem- /home/sid/tuning/finetune/backend/output/xaxkkpem-6210/data/xaxkkpem-6210.json...
|
null
|
completed
|
1764894023
|
1764900033
|
NULL
|
/home/sid/tuning/finetune/backend/output/xaxkkpem- /home/sid/tuning/finetune/backend/output/xaxkkpem-6210/adapter...
|
False
|
Edit
Delete
|
|
c5c3ee4a-de70-4477-a75f-04c137f4923c
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
rhxrwfta-8164
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Healthy Aging Among
|
Healthy Aging Among Centenarians and Near-Centenar
|
/home/sid/tuning/finetune/backend/output/rhxrwfta- /home/sid/tuning/finetune/backend/output/rhxrwfta-8164/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a comprehensive academic research pape This PDF is a comprehensive academic research paper that explores what allows people to live to 100 years and beyond while still maintaining physical, psychological, and social well-being. It examines the characteristics, lifestyles, health patterns, and resilience factors of centenarians and near-centenarians, highlighting why some individuals age successfully despite extreme longevity.
The paper integrates demographic data, medical profiles, social determinants, and psychological traits to understand healthy aging in the oldest-old—a population that is rapidly increasing worldwide.
🔶 1. Purpose of the Study
The document aims to:
Identify what differentiates healthy centenarians from those with typical age-related decline
Analyze their physical health, cognitive functioning, and emotional well-being
Explore long-life determinants including lifestyle, genetics, environment, and personality
Understand how these individuals maintain independence and quality of life
Provide insights for public health and aging research
It serves as a foundational resource for gerontologists, clinicians, and policymakers.
🔶 2. Who Are the Participants?
The study focuses on:
Centenarians (100+ years)
Near-centenarians (ages 95–99)
These groups are compared across:
Health status
Cognitive functioning
Daily living ability
Social networks
Psychological resilience
🔶 3. Key Findings
⭐ A. Physical Health Patterns
The paper notes:
Many centenarians delay major diseases until very late in life (“compression of morbidity”)
Some maintain surprisingly good mobility and independence
Common chronic issues include vision, hearing, and musculoskeletal limitations
Hospitalization rates are not always higher than younger elderly groups
Despite extreme age, a proportion of centenarians preserve functional health.
⭐ B. Cognitive Functioning
The study highlights:
A meaningful number maintain intact cognitive abilities
Others show mild impairments, but dementia is not universal
Cognitive resilience is linked to higher education, mental engagement, and social activity
Longevity does not guarantee cognitive decline; variability is wide.
⭐ C. Psychological Strength & Emotional Well-Being
A central message is that many centenarians possess strong mental resilience:
High optimism
Emotional stability
Adaptive coping skills
Lower depressive symptoms than expected
Positive psychological traits strongly correlate with healthy aging.
⭐ D. Social Environment & Support
Findings show:
Strong family support is crucial
Continued social engagement boosts health and mood
Many maintain close relationships with caregivers and relatives
Successful aging is deeply connected to social connection.
⭐ E. Lifestyle Factors
Patterns common among long-lived individuals include:
Moderation in diet
Regular light physical activity
Avoidance of smoking
Effective stress management
Consistent daily routines
These habits contribute significantly to longevity quality—not just lifespan.
⭐ F. Biological & Genetic Contributions
Although lifestyle matters, the study notes:
Genetics plays a major role in reaching 100+
Longevity-associated genes influence inflammation, metabolism, and cellular repair
Family history of longevity is a strong predictor
🔶 4. Broader Implications
The paper stresses that understanding healthy aging in centenarians can:
Help identify protective factors for the general population
Guide interventions for aging societies
Improve caregiving and support systems
Challenge stereotypes about extreme old age
🔶 5. Central Conclusion
Healthy aging at 100+ is shaped by a combination of genetics, lifestyle, psychological resilience, and strong social support. Many centenarians remain physically functional, mentally active, emotionally stable, and socially connected—demonstrating that long life can also be a high-quality life.
⭐ Perfect One-Sentence Summary
This PDF provides a detailed scientific examination of how centenarians and near-centenarians achieve healthy aging, revealing that exceptional longevity is supported by resilient psychological traits, strong social networks, delayed disease onset, functional independence, and a meaningful interplay between lifestyle and genetics....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/rhxrwfta-8164/data/document.pdf", "num_examples": 8, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/rhxrwfta- /home/sid/tuning/finetune/backend/output/rhxrwfta-8164/data/rhxrwfta-8164.json...
|
null
|
completed
|
1764894050
|
1764898565
|
NULL
|
/home/sid/tuning/finetune/backend/output/rhxrwfta- /home/sid/tuning/finetune/backend/output/rhxrwfta-8164/adapter...
|
False
|
Edit
Delete
|
|
e62ac31b-cbd5-4910-bf31-f9b2fba57195
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
ljrlcirv-5496
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Healthy Ageing
|
Healthy Ageing
|
/home/sid/tuning/finetune/backend/output/ljrlcirv- /home/sid/tuning/finetune/backend/output/ljrlcirv-5496/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This document is an academic research article titl This document is an academic research article titled “Healthy Ageing and Mediated Health Expertise” by Christa Lykke Christensen, published in Nordicom Review (2017). It explores how older adults understand health, how they think about ageing, and most importantly, how media influence their beliefs and behaviors about healthy living.
✅ Main Purpose of the Article
The study investigates:
How older people use media to learn about health.
Whether they trust media health information.
How media messages shape their ideas of active ageing, lifestyle, and personal responsibility for health.
🧓📺 Core Focus
The article is based on 16 qualitative interviews with Danish adults aged 65–86. Through these interviews, the author analyzes how elderly people react to health information in media such as TV, magazines, and online content.
⭐ Key Insights and Themes
1️⃣ Two Different Ageing Strategies Identified
The research shows that older adults fall into two broad groups:
(A) Those who maintain a youthful lifestyle into old age
Highly active (gym, sports, diet programs).
Use media health content as guidance (exercise shows, magazines, expert advice).
Believe good lifestyle can prolong life.
Try hard to “control” ageing through diet and activity.
(B) Those who accept natural ageing
Define health as simply “not being sick.”
Value mobility, independence, social interaction.
More relaxed about diet and exercise.
Focus on quality of life, relationships, emotional well-being.
More critical and skeptical of media health claims.
2️⃣ Role of Media
The article describes a dual influence:
Positive influence
Media provide accessible knowledge.
Inspire healthy habits.
Offer motivation and new routines.
Negative influence
Information often contradicts itself.
Creates pressure to meet unrealistic standards.
Can lead to guilt, frustration, confusion.
Overemphasis of diet/exercise overshadows social and emotional health.
3️⃣ “The Will to Be Healthy”
Inspired by previous research, the article explains that modern society expects older people to:
Stay active
Eat perfectly
Avoid illness through personal discipline
Continuously self-improve
Older adults feel that being healthy becomes a moral obligation, not just a personal choice.
4️⃣ Media’s Framing of Ageing
The media often portray older adults as:
Energetic
Positive
Fit
Productive
These representations push the idea of “successful ageing,” creating pressure for older individuals to avoid looking or feeling old.
5️⃣ Tension and Dilemmas
The study reveals emotional conflicts such as:
Wanting a long life but not wanting to feel old.
Trying to follow health advice but feeling overwhelmed.
Personal health needs vs. societal expectations.
Desire for autonomy vs. media pressure.
📌 Conclusions
The article concludes that:
Health and ageing are shaped heavily by media messages.
Older people feel responsible for their own ageing process.
Media act as a “negotiating partner” — guiding, confusing, pressuring, or inspiring.
Ageing today is not passive; it requires continuous decision-making and self-management.
There is no single way to age healthily — each individual balances ideals, limitations, and life experience....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/ljrlcirv-5496/data/document.pdf", "num_examples": 2, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/ljrlcirv- /home/sid/tuning/finetune/backend/output/ljrlcirv-5496/data/ljrlcirv-5496.json...
|
null
|
completed
|
1764894090
|
1764900108
|
NULL
|
/home/sid/tuning/finetune/backend/output/ljrlcirv- /home/sid/tuning/finetune/backend/output/ljrlcirv-5496/adapter...
|
False
|
Edit
Delete
|
|
4d575c3d-0ca4-4c96-b9d4-0c1b82218dcc
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
jybvxsag-3546
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Health Status and Empiric
|
Health Status and Empirical Model of Longevity
|
/home/sid/tuning/finetune/backend/output/jybvxsag- /home/sid/tuning/finetune/backend/output/jybvxsag-3546/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This research paper by Hugo Benítez-Silva and Huan This research paper by Hugo Benítez-Silva and Huan Ni develops one of the most detailed and rigorous empirical models explaining how health status and health changes shape people’s expectations of how long they will live. It uses panel data from the U.S. Health and Retirement Study (HRS), a large longitudinal survey of older adults.
🌟 Core Purpose of the Study
The paper investigates:
How do different measures of health—especially changes in health—affect people’s expected longevity (their subjective probability of living to age 75)?
It challenges the common assumption that simply using “current health status” or lagged health is enough to measure health dynamics. Instead, the authors argue that:
➡ Self-reported health changes (e.g., “much worse,” “better”)
are more accurate and meaningful than
➡ Computed health changes (differences between two reported health statuses).
📌 Key Concepts
1. Health Dynamics Matter
Health is not static—people experience:
gradual aging
chronic disease progression
sudden health shocks
effects of lifestyle and medical interventions
These dynamic elements shape how people assess their future survival.
Health Status and Empirical Mod…
2. Why Self-Reported Health Status Is Imperfect
The paper identifies three major problems with simply using self-rated health categories:
Health Status and Empirical Mod…
a. Cut-point shifts
People’s interpretation of “good” or “very good” health can change over time.
b. Gray areas
Some individuals cannot clearly categorize their health, leading to arbitrary reports.
c. Peer/reference effects
People compare themselves with different reference groups as they age.
These issues mean self-rated health alone doesn’t capture true health changes.
📌 3. Two Measures of Health Change
The authors compare:
A. Self-Reported Health Change (Preferred)
Direct question:
“Compared to last time, is your health better, same, worse?”
Advantages:
captures subtle changes
less affected by shifting cut-points
aligns more closely with subjective survival expectations
B. Computed Health Change (Problematic)
This is calculated mathematically as:
Health score (t+1) − Health score (t)
Problems:
inconsistent with self-reports in 38% of cases
loses information when health changes but does not cross a discrete category
introduces potential measurement error
Health Status and Empirical Mod…
🧠 Why This Matters
Expected longevity influences:
savings behavior
retirement timing
annuity purchases
life insurance decisions
health care usage
Health Status and Empirical Mod…
If researchers use bad measures of health, they may misinterpret how people plan for the future.
📊 Data and Methodology
Uses six waves of the HRS (1992–2003)
Sample: 9,000+ individuals, 24,000+ observations
Controls for:
chronic conditions (heart disease, cancer, diabetes)
ADLs/IADLs
socioeconomic variables
parental longevity
demographic factors
unobserved heterogeneity
Health Status and Empirical Mod…
The model is treated like a production function of longevity, following economic theories of health investment under uncertainty.
📈 Major Findings
✔ 1. Self-reported health changes strongly predict expected longevity
People who report worsening health show large drops in survival expectations.
Health Status and Empirical Mod…
✔ 2. Computed health changes frequently misrepresent true health dynamics
38% are inconsistent
15% lose meaningful health-change information
Health Status and Empirical Mod…
✔ 3. Self-reported changes have effects similar in magnitude to current health levels
This means:
Health trajectory matters as much as current health.
Health Status and Empirical Mod…
✔ 4. Health change measures are crucial for accurate modeling
Failing to include dynamic health measures causes:
biased estimates
misinterpretation of longevity expectations
🏁 Conclusion
This paper makes a major contribution by demonstrating that:
To understand how people form expectations about their own longevity, you must measure health as a dynamic process—not just a static snapshot.
The authors recommend that future empirical models, especially those using large panel surveys like the HRS, should:
✔ prioritize self-reported health changes
✔ treat computed changes with caution
✔ incorporate dynamics of health in survival models
These insights improve research in aging, retirement economics, health policy, and behavioral modeling.
Health Status and Empirical Mod…
If you want, I can also create:
📌 A diagram/flowchart of the model
📌 A one-paragraph brief summary
📌 A bullet-point version
📌 A presentation slide style explanation
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/jybvxsag-3546/data/document.pdf", "num_examples": 23, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/jybvxsag- /home/sid/tuning/finetune/backend/output/jybvxsag-3546/data/jybvxsag-3546.json...
|
null
|
completed
|
1764894108
|
1764904905
|
NULL
|
/home/sid/tuning/finetune/backend/output/jybvxsag- /home/sid/tuning/finetune/backend/output/jybvxsag-3546/adapter...
|
False
|
Edit
Delete
|
|
032e3228-4f35-4ed9-b254-cd096cd6cdb3
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
naoffskb-1736
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
health services
|
health services use by older adults
|
/home/sid/tuning/finetune/backend/output/naoffskb- /home/sid/tuning/finetune/backend/output/naoffskb-1736/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a fact sheet that summarizes how older This PDF is a fact sheet that summarizes how older adults (age 65+) use health services in the United States. It presents national statistics on doctor visits, chronic diseases, hospital care, emergency care, prescription drug use, long-term services, and long-term care needs among seniors.
The focus is to show how rising longevity, chronic illness, and disability shape healthcare demands in older populations.
The document is structured with clear data points, percentages, and brief explanations—ideal for public health professionals, students, policymakers, and caregivers.
📌 Main Topics Covered
1. Use of Physician Services
Seniors account for 26% of all physician visits in the U.S.
Doctor visits increase with age due to chronic disease management.
Many older adults see multiple specialists annually.
2. Hospital Use
People aged 65+ make up a large proportion of hospital admissions.
Older adults have higher rates of:
inpatient stays
readmissions
longer lengths of stay
Hospitalization risk increases with complex chronic conditions.
3. Emergency Department (ED) Visits
Seniors frequently use emergency departments for:
falls
injuries
acute illness episodes
complications of chronic diseases
ED visits rise significantly after age 75.
4. Chronic Diseases
The PDF highlights the heavy burden of chronic illness in late life:
80% of older adults have at least one chronic condition.
Up to 50% have two or more chronic diseases.
Common conditions include:
arthritis
heart disease
diabetes
hypertension
osteoporosis
COPD
Chronic illness is the primary driver of healthcare utilization in older populations.
5. Prescription Drug Use
Older adults use a disproportionately high number of medications.
Polypharmacy (using 5+ medications at once) is common and increases risks of:
adverse drug reactions
drug–drug interactions
falls
hospitalization
6. Long-Term Services and Supports (LTSS)
The PDF includes essential data on long-term care:
Older adults are the largest users of home care, community-based services, and institutional care.
A growing population of seniors requires:
help with activities of daily living (ADLs)
nursing home services
home health care
personal care services
7. Long-Term Care Facilities
The data highlight the following:
65+ adults represent the majority of people living in:
nursing homes
assisted living facilities
Many residents have significant functional or cognitive impairment (e.g., dementia).
8. Summary of Utilization Patterns
The PDF shows a clear pattern:
Older adults are the highest users of healthcare across almost all service types.
Their needs are shaped by:
multiple chronic diseases
declining mobility
cognitive decline
functional impairments
increased vulnerability to acute health events
As longevity increases, demand for health services will continue to rise.
🧾 Overall Conclusion
The PDF provides a concise but comprehensive portrait of how much and what types of healthcare older adults use.
Key messages:
✔ Older adults use far more physician services, hospital care, and emergency care than younger groups.
✔ Chronic diseases dominate health service use.
✔ Prescription medication use is high, with major safety concerns.
✔ Long-term services and institutional care are essential for many seniors.
✔ As the population ages, the healthcare system must adapt to growing demand.
If you want, I can also prepare:
✅ a short summary
✅ a data-only summary
✅ an infographic-style description
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/naoffskb-1736/data/document.pdf", "num_examples": 4, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/naoffskb- /home/sid/tuning/finetune/backend/output/naoffskb-1736/data/naoffskb-1736.json...
|
null
|
completed
|
1764894127
|
1764900746
|
NULL
|
/home/sid/tuning/finetune/backend/output/naoffskb- /home/sid/tuning/finetune/backend/output/naoffskb-1736/adapter...
|
False
|
Edit
Delete
|
|
c51dd11f-b64d-4ae8-8ffc-272f0fa4dfd5
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
arrmgvhy-3290
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Has the Rate of Human Age
|
Has the Rate of Human Aging Already Been Modified
|
/home/sid/tuning/finetune/backend/output/arrmgvhy- /home/sid/tuning/finetune/backend/output/arrmgvhy-3290/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This paper investigates whether the biological rat This paper investigates whether the biological rate of human aging has changed over the past century, or whether improvements in survival and life expectancy result mostly from reducing early-life and midlife mortality rather than slowing aging itself.
The study uses historical mortality data and aging-rate models to determine if humans age more slowly today or if we simply live longer before aging starts dominating mortality.
🔍 Core Question
Has aging itself slowed down, or do we just survive long enough to reach old age more often?
📊 Methods Used
The study examines:
Mortality curves over time (e.g., 1900–present)
The Gompertz function, which mathematically describes how mortality risk doubles with age
Changes in:
Initial mortality rate (IMR)
Rate of aging (Gompertz slope)
Data comes from:
Historical life tables
Cross-country mortality records
Comparisons of birth cohorts over time
The focus is on whether the slope of mortality increase with age has changed — this slope is considered a direct indicator of the rate of aging.
🧠 Key Findings (Perfect Summary)
1. Human aging rate appears largely unchanged
The study finds no strong evidence that the rate at which mortality increases with age (the Gompertz slope) has slowed.
This means humans likely age at the same biological speed as they did 100 years ago.
2. What has changed is the starting point of aging
Early-life and midlife mortality have dropped dramatically due to sanitation, medicine, nutrition, and public health.
As a result, more people reach old age, giving the impression that aging has slowed.
But aging itself (measured by mortality acceleration) has remained stable.
3. Modern longevity gains are driven by shifting the mortality curve
Rather than flattening the curve (slower aging), society has:
Pushed the curve downward (lower mortality at all ages)
Delayed the onset of chronic disease
Improved survival after age 60
These factors extend lifespan without changing the underlying biological aging rate.
4. Even in recent decades, aging rate shows stability
Improvements after 1970 came from:
Cardiovascular improvements
Medical interventions
Smoking decline
But studies consistently show the rate of mortality acceleration remains constant.
🧬 Overall Interpretation
Human aging — measured as the exponential rise in mortality risk with age — has not slowed.
Instead, society has become better at preventing early death, allowing more people to reach advanced ages.
In short:
❗ We live longer not because we age slower, but because we avoid dying earlier.
📌 One-Sentence Perfect Summary
The paper concludes that although human life expectancy has increased dramatically, the biological rate of aging has remained essentially unchanged, and modern longevity gains are due to reduced mortality before and during old age rather than slower aging itself.
If you want, I can also provide:
A diagram or flowchart
A 5-line summary
A student-friendly explanation
A PDF or PowerPoint version
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/arrmgvhy-3290/data/document.pdf", "num_examples": 64, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/arrmgvhy- /home/sid/tuning/finetune/backend/output/arrmgvhy-3290/data/arrmgvhy-3290.json...
|
null
|
completed
|
1764894210
|
1764901992
|
NULL
|
/home/sid/tuning/finetune/backend/output/arrmgvhy- /home/sid/tuning/finetune/backend/output/arrmgvhy-3290/adapter...
|
False
|
Edit
Delete
|
|
836c295f-0193-463c-8463-197fd7eda2e3
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
tvczpisc-6894
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Happy People Live Longer
|
Happy People Live Longer
|
/home/sid/tuning/finetune/backend/output/tvczpisc- /home/sid/tuning/finetune/backend/output/tvczpisc-6894/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This comprehensive review demonstrates that subjec This comprehensive review demonstrates that subjective well-being (SWB)—including happiness, life satisfaction, optimism, and positive emotions—plays a causal and measurable role in promoting better health, stronger physiological functioning, and longer life. Drawing on seven converging lines of evidence from longitudinal human studies, laboratory experiments, physiological research, animal studies, natural experiments, and intervention trials, the authors present one of the most rigorous and multidimensional examinations of the happiness–health connection.
The review shows that individuals who experience higher levels of SWB not only report better health but live significantly longer, even when controlling for baseline health status, socioeconomic factors, and lifestyle. Positive emotions predict reduced mortality, lower risk of cardiovascular disease, stronger immune function, and improved resilience to stress. In contrast, chronic negative emotions—such as depression, anxiety, and hostility—are linked to inflammation, impaired immunity, hypertension, atherosclerosis, and accelerated aging.
The document organizes evidence into seven major categories:
1. Long-term Prospective Studies
Large-scale, decades-long studies consistently show that SWB predicts longevity in healthy populations and sometimes improves survival in diseased populations. Optimists and individuals with high positive affect live longer than pessimists and those with low affect.
2. Naturalistic Physiological Studies
Everyday positive emotions correlate with lower cortisol, reduced blood pressure, healthier cardiovascular responses, and lower inflammation. Negative emotions produce harmful biological patterns such as elevated cytokines and delayed wound healing.
3. Experimental Mood Induction Studies
When researchers induce positive or negative emotions in controlled settings, they observe immediate changes in cardiovascular activity, immune function, stress hormones, and healing responses—confirming direct causal pathways.
4. Animal Research
Studies on monkeys, pigs, hamsters, and rodents show that stress compromises immunity, accelerates disease processes, and shortens lifespan, while positive social environments and reward-based experiences promote health and healing.
5. Quasi-experimental Studies of Real-world Events
Major emotional events—earthquakes, wars, bereavement—produce measurable spikes in mortality and biological stress markers, revealing how emotional states influence health at the population level.
6. Interventions That Improve SWB
Meditation, relaxation training, social support enhancement, and hostility-reduction interventions lead to measurable improvements in immune function, blood pressure, wound healing, and in some cases, longer survival.
7. Studies on Quality of Life and Pain
Positive emotions reduce pain sensitivity, accelerate functional recovery, and improve daily functioning among people with chronic illnesses.
Key Conclusion
Across diverse methods and populations, the evidence forms a compelling causal model:
**Happiness is not just an outcome of good health—
it is a contributor to it.**
SWB influences the immune, cardiovascular, endocrine, and inflammatory systems, shaping vulnerability or resilience to disease. While happiness cannot cure all illnesses, especially severe or rapidly progressing diseases, it profoundly improves health trajectories in both healthy and clinical populations.
In Essence
This document is a landmark synthesis demonstrating that happy people truly live longer, and that fostering subjective well-being is not merely a psychological luxury but a powerful public health priority with far-reaching implications for prevention, aging, and holistic healthcare.
If you'd like, I can also create:
✅ A shorter description
✅ An academic abstract
✅ A graphical diagram summarizing the pathways
✅ A bullet-point executive overview
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/tvczpisc-6894/data/document.pdf", "num_examples": 125, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/tvczpisc- /home/sid/tuning/finetune/backend/output/tvczpisc-6894/data/tvczpisc-6894.json...
|
null
|
completed
|
1764894221
|
1764906387
|
NULL
|
/home/sid/tuning/finetune/backend/output/tvczpisc- /home/sid/tuning/finetune/backend/output/tvczpisc-6894/adapter...
|
False
|
Edit
Delete
|
|
f79e649f-eda8-48e0-9d2a-2c56d701f647
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
ynjzdyfn-6686
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Gut microbiota variations
|
Gut microbiota variations over the lifespan and
|
/home/sid/tuning/finetune/backend/output/ynjzdyfn- /home/sid/tuning/finetune/backend/output/ynjzdyfn-6686/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This study investigates how the gut microbiota (th This study investigates how the gut microbiota (the community of microorganisms living in the gut) changes throughout the reproductive lifespan of female rabbits and how these changes relate to longevity. It compares two maternal rabbit lines:
Line A – a standard commercial line selected mainly for production traits.
Line LP – a long-lived line created using longevity-based selection criteria.
🔬 What the Study Did
Researchers analyzed 319 fecal samples collected from 164 female rabbits across their reproductive lives (from first parity to death/culling). They used advanced DNA sequencing of the gut microbiome, including:
16S rRNA sequencing
Bioinformatics (DADA2, QIIME2)
Alpha diversity (richness/evenness within a sample)
Beta diversity (differences between samples)
Zero-inflated negative binomial mixed models (ZINBMM)
Animals were categorized into three longevity groups:
LL: Low longevity (died/culled before 5th parity)
ML: Medium longevity (5–10 parities)
HL: High longevity (more than 10 parities)
🧬 Key Findings
1. Aging Strongly Alters the Gut Microbiome
Age caused a consistent decline in diversity:
Lower richness
Lower evenness
Reduced Shannon index
20% of ASVs in line A and 16% in line LP were significantly associated with age.
Most age-associated taxa declined with age.
Age explained the greatest proportion of sample-to-sample microbiome variation.
2. Longevity Groups Have Distinct Microbiomes
High-longevity rabbits (HL) showed lower evenness, meaning fewer taxa dominated the community.
Differences between longevity groups were more pronounced in line A than line LP.
In line A, 15–16% of ASVs differed between HL and LL/ML.
In line LP, only 4% differed.
Suggests genetic selection for longevity stabilizes microbiome patterns.
3. Strong Genetic Line Effects
LP rabbits consistently had higher alpha diversity than A rabbits.
About 6–12% of ASVs differed between lines even when comparing animals of the same longevity, proving:
Genetics shape the microbiome independently of lifespan.
Several bacterial families were consistently different between lines, such as:
Lachnospiraceae
Oscillospiraceae
Ruminococcaceae
Akkermansiaceae
🧩 What It Means
The gut microbiota shifts dramatically with age, even under identical feeding and environmental conditions.
Specific bacteria decline as rabbits age, likely tied to immune changes, reproductive stress, or physiological aging.
Longevity is partially linked to microbiome composition—but genetics strongly determines how much the microbiome changes.
The LP line shows more microbiome stability, hinting at genetic resilience.
🌱 Why It Matters
This research helps:
Understand aging biology in mammals
Identify microbial markers of longevity
Improve breeding strategies for long-lived, healthy livestock
Explore microbiome-driven approaches for health and productivity...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/ynjzdyfn-6686/data/document.pdf", "num_examples": 47, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/ynjzdyfn- /home/sid/tuning/finetune/backend/output/ynjzdyfn-6686/data/ynjzdyfn-6686.json...
|
null
|
completed
|
1764894867
|
1764900849
|
NULL
|
/home/sid/tuning/finetune/backend/output/ynjzdyfn- /home/sid/tuning/finetune/backend/output/ynjzdyfn-6686/adapter...
|
False
|
Edit
Delete
|
|
63956c16-65f4-4016-a5a7-b2ceadb5eb36
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
uelhllsj-4431
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Greenland Shark Lifespan
|
Greenland Shark Lifespan and Implications
|
/home/sid/tuning/finetune/backend/output/uelhllsj- /home/sid/tuning/finetune/backend/output/uelhllsj-4431/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This PDF is a scientific and conceptual exploratio This PDF is a scientific and conceptual exploration of the exceptionally long lifespan of the Greenland shark (Somniosus microcephalus), one of the longest-living vertebrates on Earth, and what its unique biology can teach us about human aging and longevity. The document blends marine biology, evolutionary science, aging research, and comparative physiology to explain how and why the Greenland shark can live for centuries, and which of those mechanisms may inspire future breakthroughs in human life-extension.
🔶 1. Purpose of the Document
The paper has two main goals:
To summarize what is known about the Greenland shark’s extreme longevity
To discuss how its biological traits might inform human aging research
It provides a bridge between animal longevity science and human gerontology, making it relevant for researchers, students, and longevity scholars.
🔶 2. The Greenland Shark: A Longevity Outlier
The Greenland shark is introduced as:
The longest-lived vertebrate known to science
Estimated lifespan: 272 to 500+ years
Mature only at 150 years of age
Lives in the deep, cold waters of the Arctic and North Atlantic
The document emphasizes that its lifespan far exceeds that of whales, tortoises, and other long-lived species.
🔶 3. How Its Age Is Measured
The PDF describes how researchers used radiocarbon dating of eye lens proteins—the same method used in archeology—to determine the shark’s age.
Key points:
Eye lens proteins form before birth and never regenerate
Bomb radiocarbon traces from the 1950s provide a global timestamp
This allows scientists to estimate individual ages with high precision
🔶 4. Biological Factors Behind the Shark’s Longevity
The paper discusses multiple mechanisms that may explain its extraordinary lifespan:
⭐ Slow Metabolism
Lives in near-freezing water
Exhibits extremely slow growth (1 cm per year)
Low metabolic rate reduces cell damage over time
⭐ Cold Environment
Cold temperatures reduce oxidative stress
Proteins and enzymes degrade more slowly
⭐ Minimal Predation & Low Activity
Slow-moving and top of its food chain
Low energy expenditure
⭐ DNA Stability & Repair (Hypothesized)
Potentially enhanced DNA repair systems
Resistance to cancer and cellular senescence
⭐ Extended Development and Late Maturity
Reproductive maturity at ~150 years
Suggests an evolutionary investment in somatic maintenance over early reproduction
These mechanisms collectively support the concept that slow living = long living.
🔶 5. Evolutionary Insights
The document highlights that Greenland sharks follow an evolutionary strategy of:
Slow growth
Late reproduction
Reduced cellular damage
Enhanced long-term survival
This strategy resembles that of other long-lived species (e.g., bowhead whales, naked mole rats) and supports life-history theories of longevity.
🔶 6. Implications for Human Longevity Research
The PDF connects shark biology to human aging questions, suggesting several research implications:
⭐ Metabolic Rate and Aging
Slower metabolic processes may reduce oxidative damage
Could inspire therapies that mimic metabolic slow-down without harming function
⭐ DNA Repair & Cellular Maintenance
Studying shark genetics may reveal protective pathways
Supports research into genome stability and cancer suppression
⭐ Protein Stability at Low Temperatures
Sharks preserve tissue integrity for centuries
May inspire cryopreservation and protein stability research
⭐ Longevity Without Cognitive Decline
Sharks remain functional for centuries
Encourages study of brain aging resilience
The document stresses that while humans cannot adopt cold-water lifestyles, the shark’s biology offers clues to preventing molecular damage, a key factor in aging.
🔶 7. Broader Scientific Significance
The report argues that Greenland shark longevity challenges assumptions about:
Aging speed
Environmental impacts on lifespan
Biological limits of vertebrate aging
It contributes to a growing body of comparative longevity research seeking to understand how some species achieve extreme lifespan and disease resistance.
🔶 8. Conclusion
The PDF concludes that the Greenland shark represents a natural experiment in extreme longevity, offering valuable biological insights that could advance human aging research. While humans cannot replicate the shark’s cold, slow metabolism, studying its physiology and genetics may help uncover pathways that extend lifespan and healthspan in people.
⭐ Perfect One-Sentence Summary
This PDF provides a scientific overview of the Greenland shark’s extraordinary centuries-long lifespan and explores how its unique biology—slow metabolism, environmental adaptation, and exceptional cellular maintenance—may offer important clues for advancing human longevity....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/uelhllsj-4431/data/document.pdf"}...
|
/home/sid/tuning/finetune/backend/output/uelhllsj- /home/sid/tuning/finetune/backend/output/uelhllsj-4431/data/uelhllsj-4431.json...
|
null
|
failed
|
1764894878
|
1764895179
|
NULL
|
/home/sid/tuning/finetune/backend/output/uelhllsj- /home/sid/tuning/finetune/backend/output/uelhllsj-4431/adapter...
|
False
|
Edit
Delete
|
|
51bd1a7c-ec89-4d48-85db-8e55723e3743
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
fioqwmlo-9810
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Grandmothers
|
Grandmothers and the Evolution of Human Longevity
Grandmothers and the Evolution of Human Longevity
...
|
/home/sid/tuning/finetune/backend/output/fioqwmlo- /home/sid/tuning/finetune/backend/output/fioqwmlo-9810/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
“Grandmothers and the Evolution of Human Longevity “Grandmothers and the Evolution of Human Longevity”**
This PDF is a scholarly research article that presents and explains the Grandmother Hypothesis—one of the most influential evolutionary theories for why humans live so long after reproduction. The paper argues that human longevity evolved largely because ancestral grandmothers played a crucial role in helping raise their grandchildren, thereby increasing family survival and passing on genes that favored longer life.
The article combines anthropology, evolutionary biology, and demographic modeling to show that grandmothering behavior dramatically enhanced reproductive success and survival in early human societies, creating evolutionary pressure for extended lifespan.
👵 1. Core Idea: The Grandmother Hypothesis
The central argument is:
Human females live long past menopause because grandmothers helped feed, protect, and support their grandchildren, allowing mothers to reproduce more frequently.
This cooperative childcare increased survival rates and promoted the evolution of long life, especially among women.
Healthy Ageing
🧬 2. Evolutionary Background
The article explains key evolutionary facts:
Humans are unique among primates because females experience decades of post-reproductive life.
In other great apes, females rarely outlive their fertility.
Human children are unusually dependent for many years; mothers benefit greatly from help.
Grandmothers filled this gap, making longevity advantageous in evolutionary terms.
Healthy Ageing
🍂 3. Why Grandmothers Increased Survival
The study shows how ancestral grandmothers:
⭐ Provided extra food
Especially gathered foods like tubers and plant resources.
⭐ Allowed mothers to wean earlier
Mothers could have more babies sooner, increasing reproductive success.
⭐ Improved child survival
Grandmother assistance reduced infant and child mortality.
⭐ Increased group resilience
More caregivers meant better protection and food access.
These survival advantages favored genes that supported prolonged life.
Healthy Ageing
📊 4. Mathematical & Demographic Modeling
The PDF includes modeling to demonstrate:
How grandmother involvement changes fertility patterns
How increased juvenile survival leads to higher population growth
How longevity becomes advantageous over generations
Models show that adding grandmother support significantly increases life expectancy in evolutionary simulations.
Healthy Ageing
👶 5. Human Childhood and Weaning
Human children:
Develop slowly
Need long-term nutritional and social support
Rely on help beyond their mother
Early weaning—made possible by grandmother help—creates shorter birth intervals, boosting the reproductive output of mothers and promoting genetic selection for long-lived helpers (grandmothers).
Healthy Ageing
🧠 6. Implications for Human Evolution
The article argues that grandmothering helped shape:
✔ Human social structure
Cooperative families and multigenerational groups.
✔ Human biology
Long lifespan, menopause, slower childhood development.
✔ Human culture
Shared caregiving, food-sharing traditions, teaching, and cooperation.
Healthy Ageing
Grandmothers became essential to early human success.
🧓 7. Menopause and Post-Reproductive Lifespan
One major question in evolution is: Why does menopause exist?
The article explains that:
Natural selection usually favors continued reproduction.
But in humans, the benefits of supporting grandchildren outweigh late-life reproduction.
This shift created evolutionary support for long post-reproductive life.
Healthy Ageing
⭐ Overall Summary
This PDF provides a clear and compelling explanation of how grandmothering behavior shaped human evolution, helping produce our unusually long life spans. It argues that grandmothers increased survival, supported early weaning, and boosted reproduction in early humans, leading natural selection to favor individuals—especially females—who lived well past their reproductive years. The article blends anthropology, biology, and mathematical modeling to show that the evolution of human longevity is inseparable from the evolutionary importance of grandmothers....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/fioqwmlo-9810/data/document.pdf", "num_examples": 92, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/fioqwmlo- /home/sid/tuning/finetune/backend/output/fioqwmlo-9810/data/fioqwmlo-9810.json...
|
null
|
completed
|
1764894911
|
1764904503
|
NULL
|
/home/sid/tuning/finetune/backend/output/fioqwmlo- /home/sid/tuning/finetune/backend/output/fioqwmlo-9810/adapter...
|
False
|
Edit
Delete
|
|
49b24cbd-34ce-4f86-a06d-3f2c2f8f6384
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
iuwkyasg-0219
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Global Roadmap for Health
|
Global Roadmap for Healthy Longevity
|
/home/sid/tuning/finetune/backend/output/iuwkyasg- /home/sid/tuning/finetune/backend/output/iuwkyasg-0219/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Global Roadmap for Healthy Longevity
(Consensus Global Roadmap for Healthy Longevity
(Consensus Study Report, National Academy of Medicine, 2022)
This report presents a global, evidence-based strategy for transforming aging into an opportunity by promoting healthy longevity—a state where people live long lives in good health, with full physical, cognitive, and social functioning, and where societies harness the potential of older adults.
🧠 1. Why This Roadmap Matters
Across the world, populations are aging faster than ever due to:
Longer life expectancy, and
Declining birth rates
The number of people aged 65+ has been growing more rapidly than any other age group, and this trend will continue.
Global Roadmap for Healthy Long…
However, a critical problem exists:
📉 People are living longer, but not healthier.
Between 2000 and 2019, global lifespan increased, especially in low- and middle-income countries,
but years of good health stagnated, meaning more years are spent in poor health.
Global Roadmap for Healthy Long…
🌍 2. Purpose of the Roadmap
To address this challenge, the National Academy of Medicine convened a global, multidisciplinary commission to create a roadmap for achieving healthy longevity worldwide.
Global Roadmap for Healthy Long…
The aim is to help countries develop data-driven, all-of-society strategies that promote health, equity, productivity, and human flourishing across the lifespan.
❤️ 3. What Healthy Longevity Means
According to the commission, healthy longevity is:
Living long with health, function, meaning, purpose, dignity, and social well-being, where years in good health approach the biological lifespan.
Global Roadmap for Healthy Long…
This reflects the WHO definition of health as a state of complete:
physical
mental
social well-being
—not merely the absence of disease.
🎯 4. Vision for the Future
The report emphasizes that aging societies can thrive, not decline, if healthy longevity is embraced as a societal goal.
With the right policies, older adults can:
Contribute meaningfully to families and communities
Participate in the workforce or volunteer roles
Live with dignity, purpose, and independence
Support strong economies and intergenerational cohesion
Global Roadmap for Healthy Long…
⭐ The future can be optimistic—if we act now.
⚠️ 5. The Cost of Inaction
If societies fail to respond, consequences include:
More years lived in poor health
Higher suffering and dependency
Increased financial burden on families
Lost productivity and fewer opportunities for younger and older people
Lower GDP
Larger fiscal pressures on governments
Global Roadmap for Healthy Long…
In short:
Ignoring healthy longevity is expensive—socially and economically.
🧩 6. Principles for Achieving Healthy Longevity
The commission identifies five core principles:
Global Roadmap for Healthy Long…
1. People of all ages should reach their full health potential
With dignity, meaning, purpose, and functioning.
2. Societies must enable optimal health at every age
Creating conditions where individuals can flourish physically, mentally, and socially.
3. Reduce disparities and advance equity
So that people of all countries and social groups benefit.
4. Recognize older adults as valuable human, social, and financial capital
Their contributions strengthen families, communities, and economies.
5. Use data and meaningful metrics
To measure progress, guide policy, and ensure accountability.
🏛️ 7. How Countries Should Act
Every nation must create its own pathway based on its unique demographics, infrastructure, and culture.
However, the roadmap emphasizes:
✔ Government-led calls to action
✔ Evidence-based planning
✔ Multisector collaboration (healthcare, urban design, technology, finance, education)
✔ Building supportive social and community infrastructure
Global Roadmap for Healthy Long…
These are essential for transforming aging from a crisis into an opportunity.
🌟 Perfect One-Sentence Summary
The Global Roadmap for Healthy Longevity outlines how aging societies can ensure that people live longer, healthier, more meaningful lives—and emphasizes that now is the time for coordinated global action to achieve this future.
If you'd like, I can also create:
📌 A diagram / infographic
📌 A short summary
📌 A comparison with your other longevity PDFs
📌 A PowerPoint-style slide set
Just tell me!...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/iuwkyasg-0219/data/document.pdf", "num_examples": 4, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/iuwkyasg- /home/sid/tuning/finetune/backend/output/iuwkyasg-0219/data/iuwkyasg-0219.json...
|
null
|
completed
|
1764894928
|
1764895530
|
NULL
|
/home/sid/tuning/finetune/backend/output/iuwkyasg- /home/sid/tuning/finetune/backend/output/iuwkyasg-0219/adapter...
|
False
|
Edit
Delete
|
|
ec60b6a9-04b8-4f64-a05d-bc49b56f3205
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
oaedizhh-8535
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Global and National
|
Global and National Declines in Life
|
/home/sid/tuning/finetune/backend/output/oaedizhh- /home/sid/tuning/finetune/backend/output/oaedizhh-8535/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Period life expectancy at birth [life expecta
Period life expectancy at birth [life expectancy thereafter] is the most-frequently used indicator
of mortality conditions. More broadly, life expectancy is commonly taken as a marker of human
progress, for instance in aggregate indices such as the Human Development Index (United
Nations Development Programme 2020). The United Nations (UN) regularly updates and makes
available life expectancy estimates for every country, various country aggregates and the world
for every year since 1950 (Gerland, Raftery, Ševčíková et al. 2014), providing a 70-year
benchmark for assessing the direction and magnitude of mortality changes....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/oaedizhh-8535/data/document.pdf", "num_examples": 6, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/oaedizhh- /home/sid/tuning/finetune/backend/output/oaedizhh-8535/data/oaedizhh-8535.json...
|
null
|
completed
|
1764895619
|
1764904639
|
NULL
|
/home/sid/tuning/finetune/backend/output/oaedizhh- /home/sid/tuning/finetune/backend/output/oaedizhh-8535/adapter...
|
False
|
Edit
Delete
|
|
e7d237b6-d50f-4a6c-9350-eb07238f3609
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
fnakzpii-4028
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Global and National
|
Global and National Declines in Life
|
/home/sid/tuning/finetune/backend/output/fnakzpii- /home/sid/tuning/finetune/backend/output/fnakzpii-4028/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Period life expectancy at birth [life expecta
Period life expectancy at birth [life expectancy thereafter] is the most-frequently used indicator
of mortality conditions. More broadly, life expectancy is commonly taken as a marker of human
progress, for instance in aggregate indices such as the Human Development Index (United
Nations Development Programme 2020). The United Nations (UN) regularly updates and makes
available life expectancy estimates for every country, various country aggregates and the world
for every year since 1950 (Gerland, Raftery, Ševčíková et al. 2014), providing a 70-year
benchmark for assessing the direction and magnitude of mortality changes....
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/fnakzpii-4028/data/document.pdf", "num_examples": 36, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/fnakzpii- /home/sid/tuning/finetune/backend/output/fnakzpii-4028/data/fnakzpii-4028.json...
|
null
|
completed
|
1764895634
|
1764904653
|
NULL
|
/home/sid/tuning/finetune/backend/output/fnakzpii- /home/sid/tuning/finetune/backend/output/fnakzpii-4028/adapter...
|
False
|
Edit
Delete
|
|
f951c493-2f3c-4638-afc9-3554f113e557
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
ticcnekp-9326
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Genetics of human longevi
|
Genetics of human longevity
|
/home/sid/tuning/finetune/backend/output/ticcnekp- /home/sid/tuning/finetune/backend/output/ticcnekp-9326/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Abstract. Smulders L, Deelen J. Genetics of human Abstract. Smulders L, Deelen J. Genetics of human longevity: From variants to genes to pathways. J Intern Med. 2024;295:416–35.
The current increase in lifespan without an equivalent increase in healthspan poses a grave challenge to the healthcare system and a severe burden on society. However, some individuals seem to be able to live a long and healthy life without the occurrence of major debilitating chronic diseases, and part of this trait seems to be hidden in their genome. In this review, we discuss the findings from studies on the genetic component of human longevity and the main challenges accompanying these studies. We subsequently focus on results from genetic studies in model organismsandcomparativegenomicapproachesto highlight the most important conserved longevity
associated pathways. By combining the results from studies using these different approaches, we conclude that only five main pathways have been consistently linked to longevity, namely (1) insulin/insulin-like growth factor 1 signalling, (2) DNA-damage response and repair, (3) immune function, (4) cholesterol metabolism and (5) telomere maintenance. As our current approaches to study the relevance of these pathways in humans are limited, we suggest that future studies on the genetics of human longevity should focus on the identification and functional characterization of rare genetic variants in genes involved in these pathways.
Keywords: genetics, longevity, longevity-associated pathways, rare genetic variants, functional characterization...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/ticcnekp-9326/data/document.pdf", "num_examples": 37, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/ticcnekp- /home/sid/tuning/finetune/backend/output/ticcnekp-9326/data/ticcnekp-9326.json...
|
null
|
completed
|
1764895681
|
1764904993
|
NULL
|
/home/sid/tuning/finetune/backend/output/ticcnekp- /home/sid/tuning/finetune/backend/output/ticcnekp-9326/adapter...
|
False
|
Edit
Delete
|
|
cfc82824-51e1-4f28-94bd-5d2a146aff50
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
kbpgbviq-7258
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Genetics of extreme human
|
Genetics of extreme human longevity to guide drug
|
/home/sid/tuning/finetune/backend/output/kbpgbviq- /home/sid/tuning/finetune/backend/output/kbpgbviq-7258/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Zhengdong D. Zhang 1 ✉, Sofiya Milman1,2, Jhih-R Zhengdong D. Zhang 1 ✉, Sofiya Milman1,2, Jhih-Rong Lin1, Shayne Wierbowski3, Haiyuan Yu3, Nir Barzilai1,2, Vera Gorbunova4, Warren C. Ladiges5, Laura J. Niedernhofer6, Yousin Suh 1,7, Paul D. Robbins 6 and Jan Vijg1,8
Ageing is the greatest risk factor for most common chronic human diseases, and it therefore is a logical target for developing interventions to prevent, mitigate or reverse multiple age-related morbidities. Over the past two decades, genetic and pharmacologic interventions targeting conserved pathways of growth and metabolism have consistently led to substantial extension of the lifespan and healthspan in model organisms as diverse as nematodes, flies and mice. Recent genetic analysis of long-lived individuals is revealing common and rare variants enriched in these same conserved pathways that significantly correlate with longevity. In this Perspective, we summarize recent insights into the genetics of extreme human longevity and propose the use of this rare phenotype to identify genetic variants as molecular targets for gaining insight into the physiology of healthy ageing and the development of new therapies to extend the human healthspan...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/kbpgbviq-7258/data/document.pdf", "num_examples": 21, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/kbpgbviq- /home/sid/tuning/finetune/backend/output/kbpgbviq-7258/data/kbpgbviq-7258.json...
|
null
|
completed
|
1764896137
|
1764903055
|
NULL
|
/home/sid/tuning/finetune/backend/output/kbpgbviq- /home/sid/tuning/finetune/backend/output/kbpgbviq-7258/adapter...
|
False
|
Edit
Delete
|
|
21850d41-115a-4e3f-ab46-dddedd85f109
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
wpbbjtck-1794
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Genetic Determinants
|
Genetic Determinants of Human Longevity
|
/home/sid/tuning/finetune/backend/output/wpbbjtck- /home/sid/tuning/finetune/backend/output/wpbbjtck-1794/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Thestudyof APOE anditsisoformshasspreadinallthestu Thestudyof APOE anditsisoformshasspreadinallthestudiesaboutthegeneticsofhuman longevityandthisisoneofthefirstgenesthatemergedincandidate-genestudiesandingenome-wide analysisindifferenthumanpopulations.Thepleiotropicrolesofthisgeneaswellasthepatternof variabilityacrossdifferenthumangroupsprovideaninterestingperspectiveontheanalysisofthe evolutionaryrelationshipbetweenhumangenetics,environmentalvariables,andtheattainmentof extremelongevityasahealthyphenotype.Inthepresentreview,thefollowingtopicswillbediscussed
Serena Dato obtained a Ph.D. in Molecular Bio-Pathology in 2004. Since September 2006, she has been an Assistant Professor in Genetics at the Department of Cell Biology of the University of Calabria, where she carries out research at the Genetics Laboratory. From the beginnning, her research interests have focused on the study of human longevity and in particular on the development of experimental designs and new analytical approaches for the study of the genetic component of longevity. With her group, she developed an algorithm for integrating demographic data into genetics, which enabled the application of a genetic-demographic analysis to crosssectional samples. She was involved in several recruitment campaigns for the collection of data and DNA samples from old and oldest-old people in her region, both nonagenarian and centenarian families. She has several international collaborations with groups involved in her research field in Europe and the USA. Since 2008, she has been actively collaborating with the research group of Prof. K. Christensen at the Aging Research Center of the Institute of Epidemiology of Southern Denmark University, where she spent a year as a visiting researcher in 2008. Up to now, her work has led to forty-eight scientific papers in peer reviewed journals, two book chapters and presentations at scientific conferences.
Mette Sørensen has been active within ageing research since 2006, with work ranging from functional molecular biological studies to genetic epidemiology and bioinformatics. She obtained a Ph.D. in genetic epidemiology of human longevity in 2012 and was appointed Associate Professor at the University of Southern Denmark in March 2019. Her main research interest is in the mechanisms of ageing, age-related diseases and longevity, with an emphasis on genetic and epigenetic variation. Her work is characterized by a high degree of international collaboration and interdisciplinarity. The work has, per September 2019, led to thirty-one scientific papers in peer reviewed journal, as well as popular science communications, presentations at scientific conferences, media appearances, and an independent postdoctoral grant from the Danish Research Council in 2013.
Giuseppina Rose is Associate Professor in Genetics at the University of Calabria. She graduated from the University of Calabria School of Natural Science in 1983 and served as a Research Assistant there from 1992–1999. In 1994 she achieved a Ph.D. in Biochemistry and Molecular Biology at
Contents
...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/wpbbjtck-1794/data/document.pdf", "num_examples": 1146, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/wpbbjtck- /home/sid/tuning/finetune/backend/output/wpbbjtck-1794/data/wpbbjtck-1794.json...
|
null
|
completed
|
1764896439
|
1764920511
|
NULL
|
/home/sid/tuning/finetune/backend/output/wpbbjtck- /home/sid/tuning/finetune/backend/output/wpbbjtck-1794/adapter...
|
False
|
Edit
Delete
|
|
eaf15e4e-34b7-45f6-af33-87617548f0bf
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
ufydvoij-3348
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Genetic longevity
|
Genetic Longevity
|
/home/sid/tuning/finetune/backend/output/ufydvoij- /home/sid/tuning/finetune/backend/output/ufydvoij-3348/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Markus Valge, Richard Meitern and Peeter Hõrak*
D Markus Valge, Richard Meitern and Peeter Hõrak*
Department of Zoology, University of Tartu, Tartu, Estonia
Life-history traits (traits directly related to survival and reproduction) co-evolve and materialize through physiology and behavior. Accordingly, lifespan can be hypothesized as a potentially informative marker of life-history speed that subsumes the impact of diverse morphometric and behavioral traits. We examined associations between parental longevity and various anthropometric traits in a sample of 4,000–11,000 Estonian children in the middle of the 20th century. The offspring phenotype was used as a proxy measure of parental genotype, so that covariation between offspring traits and parental longevity (defined as belonging to the 90th percentile of lifespan) could be used to characterize the aggregation between longevity and anthropometric traits. We predicted that larger linear dimensions of offspring associate with increased parental longevity and that testosterone-dependent traits associate with reduced paternal longevity. Twelve of 16 offspring traits were associated with mothers’ longevity, while three traits (rate of sexual maturation of daughters and grip strength and lung capacity of sons) robustly predicted fathers’ longevity. Contrary to predictions, mothers of children with small bodily dimensions lived longer, and paternal longevity was not linearly associated with their children’s body size (or testosterone-related traits). Our study thus failed to find evidence that high somatic investment into brain and body growth clusters with a long lifespan across generations, and/or that such associations can be detected on the basis of inter-generational phenotypic correlations.
KEYWORDS
anthropometric traits, body size, inter-generational study, longevity, obesity, sex difference
...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/ufydvoij-3348/data/document.pdf", "num_examples": 17, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/ufydvoij- /home/sid/tuning/finetune/backend/output/ufydvoij-3348/data/ufydvoij-3348.json...
|
null
|
completed
|
1764896608
|
1764902018
|
NULL
|
/home/sid/tuning/finetune/backend/output/ufydvoij- /home/sid/tuning/finetune/backend/output/ufydvoij-3348/adapter...
|
False
|
Edit
Delete
|
|
72c13666-41f7-47ab-a17e-67dc58672e47
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
poagxwbb-4174
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Gene Expression Biomarker
|
Gene Expression Biomarkers and Longevity
|
/home/sid/tuning/finetune/backend/output/poagxwbb- /home/sid/tuning/finetune/backend/output/poagxwbb-4174/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Chronological age, a count of how many orbits of t Chronological age, a count of how many orbits of the sun an individual has made as a passenger of planet earth, is a useful but limited proxy of aging processes. Some individuals die of age related diseases in their sixties, while others live to double that age. As a result, a great deal of effort has been put into identifying biomarkers that reflect the underlying biological changes involved in aging. These markers would provide insights into what processes were involved, provide measures of how much biological aging had occurred and provide an outcome measure for monitoring the effects of interventions to slow ageing processes. Our DNA sequence is the fixed reference template from which all our proteins are produced. With the sequencing of the human genome we now have an accurate reference library of gene sequences. The recent development of a new generation of high throughput array technology makes it relatively inexpensive to simultaneously measure a large number of base sequences in DNA (or RNA, the molecule of gene expression). In the last decade, array technologies have supported great progress in identifying common DNA sequence differences (SNPs) that confer risks for age related diseases, and similar approaches are being used to identify variants associated with exceptional longevity [1]. A striking feature of the findings is that the majority of common disease-associated variants are located not in the protein coding sequences of genes, but in regions of the genome that do not produce proteins. This indicates that they may be involved in the regulation of nearby genes, or in the processing of their messages. While DNA holds the static reference sequences for life, an elaborate regulatory system influences whether and in what abundance gene transcripts and proteins are produced. The relative abundance of each tran
script is a good guide to the demand for each protein product in cells (see section 2 below). Thus, by examining gene expression patterns or signatures associated with aging or age related traits we can peer into the underlying production processes at a fundamental level. This approach has already proved successful in clinical applications, for example using gene signatures to classify cancer subtypes [2]. In aging research, recent work conducted in the InCHIANTI cohort has identified gene-expression signatures in peripheral leucocytes linked to several aging phenotypes, including low muscle strength, cognitive impairment, and chronological age itself. In the sections that follow we provide a brief introduction to the underlying processes involved in gene expression, and summarize key work in laboratory models of aging. We then provide an overview of recent work in humans, thus far mostly from studies of circulating white cells.
2 Introducing gene expression
Since the early 1900s a huge worldwide research effort has lead to the discovery and widespread use of genetic science (see the NIH website [3] for a comprehensive review of the history of the subject, and a more detailed description of the transfer of genetic information). The human genome contains the information needed to create every protein used by cells. The information in the DNA is transcribed into an intermediate molecule known as the messenger RNA (mRNA), which is then translated into the sequence of aminoacids (proteins) which ultimately determine the structural and functional characteristics of cells, tissues and organisms (see figure 1 for a summary of the process). RNA is both an intermediate to proteins and a regulatory molecule; therefore the transcriptome (the RNA ∗Address correspondence to Prof. David Melzer, Epidemiology and Public Health Group, Medical School, University of Exeter, Exeter EX1 2LU, UK. E-mail: D.Melzer@exeter.ac.uk
1
2 INTRODUCING GENE EXPRESSION
Figure 1: Representation of the transcription and translation processes from DNA to RNA to Protein — DNA makes RNA makes Protein. This is the central dogma of molecular biology, and describes the transfer of information from DNA (made of four bases; Adenine, Guanine, Cytosine and Thymine) to RNA to Protein (made of up to 20 different amino acids). Machinery known as RNA polymerase carries out transcription, where a single strand of RNA is created that is complementary to the DNA (i.e. the sequence is the same, but inverted although in RNA thymine (T) is replaced by uracil (U)). Not all RNA molecules are messenger RNA (mRNA) molecules: RNA can have regulatory functions (e.g. micro RNAs), and or can be functional themselves, for example in translation transfer RNA (tRNA) molecules have an amino acid bound to one end (the individual components of proteins) and at the other bind to a specific sequence of RNA (a codon again, this is complementary to this original sequence) for instance in the figure a tRNA carrying methionine (Met) can bind to the sequence of RNA, and the ribosome (also in part made of RNA) attaches the amino acids together to form a protein.
production of a particular cell, or sample of cells, at a given time) is of particular interest in determining the underlying molecular mechanisms behind specific traits and phenotypes. Genes are also regulated at the posttranscriptional level, by non-coding RNAs or by posttranslational modifications to the encoded proteins. Transcription is a responsive process (many factors regulate transcription and translation in response to specific intra and extra-cellular signals), and thus the amount of RNA produced varies over time and between cell types and tissues. In addition to the gene and RNA transcript sequences that will determine the final protein sequence (so called exons) there are also intervening sections (the introns) that are removed by a process known as mRNA splicing. While it was once assumed that each gene produced only one protein, it is now
clear that up to 90% of our genes can produce different versions of their protein through varying the number of exons included in the protein, a process called alternative splicing. Alteration in the functional properties of the protein can be introduced by varying which exons are included in the transcript, giving rise to different isoforms of the same gene. Many RNA regulatory factors govern this process, and variations to the DNA sequence can affect the binding of these factors (which can be thousands of base pairs from the gene itself) and alter when, where and for how long a particular transcript is produced. The amount of mRNA produced for a protein is not necessarily directly related to the amount of protein produced or present, as other regulatory processes are involved. The amount of mRNA is broadly indicative of...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/poagxwbb-4174/data/document.pdf", "num_examples": 79, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/poagxwbb- /home/sid/tuning/finetune/backend/output/poagxwbb-4174/data/poagxwbb-4174.json...
|
null
|
completed
|
1764896695
|
1764903284
|
NULL
|
/home/sid/tuning/finetune/backend/output/poagxwbb- /home/sid/tuning/finetune/backend/output/poagxwbb-4174/adapter...
|
False
|
Edit
Delete
|
|
681ebc18-4c2d-473c-87e8-4939e6b29058
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
ekheefis-7496
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Gene expression signature
|
Gene expression signatures of human cell
|
/home/sid/tuning/finetune/backend/output/ekheefis- /home/sid/tuning/finetune/backend/output/ekheefis-7496/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
Inge Seim1,2, Siming Ma1 and Vadim N Gladyshev1
D Inge Seim1,2, Siming Ma1 and Vadim N Gladyshev1
Different cell types within the body exhibit substantial variation in the average time they live, ranging from days to the lifetime of the organism. The underlying mechanisms governing the diverse lifespan of different cell types are not well understood. To examine gene expression strategies that support the lifespan of different cell types within the human body, we obtained publicly available RNA-seq data sets and interrogated transcriptomes of 21 somatic cell types and tissues with reported cellular turnover, a bona fide estimate of lifespan, ranging from 2 days (monocytes) to a lifetime (neurons). Exceptionally long-lived neurons presented a gene expression profile of reduced protein metabolism, consistent with neuronal survival and similar to expression patterns induced by longevity interventions such as dietary restriction. Across different cell lineages, we identified a gene expression signature of human cell and tissue turnover. In particular, turnover showed a negative correlation with the energetically costly cell cycle and factors supporting genome stability, concomitant risk factors for aging-associated pathologies. In addition, the expression of p53 was negatively correlated with cellular turnover, suggesting that low p53 activity supports the longevity of post-mitotic cells with inherently low risk of developing cancer. Our results demonstrate the utility of comparative approaches in unveiling gene expression differences among cell lineages with diverse cell turnover within the same organism, providing insights into mechanisms that could regulate cell longevity.
npj Aging and Mechanisms of Disease (2016) 2, 16014; doi:10.1038/npjamd.2016.14; published online 7 July 2016
INTRODUCTION Nature can achieve exceptional organismal longevity, 4100 years in the case of humans. However, there is substantial variation in ‘cellular lifespan’, which can be conceptualized as the turnover of individual cell lineages within an individual organism.1 Turnover is defined as a balance between cell proliferation and death that contributes to cell and tissue homeostasis.2 For example, the integrity of the heart and brain is largely maintained by cells with low turnover/long lifespan, while other organs and tissues, such as the outer layers of the skin and blood cells, rely on high cell turnover/short lifespan.3–5 Variation in cellular lifespan is also evident across lineages derived from the same germ layers formed during embryogenesis. For example, the ectoderm gives rise to both long-lived neurons4,6,7 and short-lived epidermal skin cells.8 Similarly, the mesoderm gives rise to long-lived skeletal muscle4 and heart muscle9 and short-lived monocytes,10,11 while the endoderm is the origin of long-lived thyrocytes (cells of the thyroid gland)12 and short-lived urinary bladder cells.13 How such diverse cell lineage lifespans are supported within a single organism is not clear, but it appears that differentiation shapes lineages through epigenetic changes to establish biological strategies that give rise to lifespans that support the best fitness for cells in their respective niche. As fitness is subject to trade-offs, different cell types will adjust their gene regulatory networks according to their lifespan. We are interested in gene expression signatures that support diverse biological strategies to achieve longevity. Prior work on species longevity can help inform strategies for tackling this research question. Species longevity is a product of evolution and is largely shaped by genetic and environmental factors.14 Comparative transcriptome
studies of long-lived and short-lived mammals, and analyses that examined the longevity trait across a large group of mammals (tissue-by-tissue surveys, focusing on brain, liver and kidney), have revealed candidate longevity-associated processes.15,16 They provide gene expression signatures of longevity across mammals and may inform on interventions that mimic these changes, thereby potentially extending lifespan. It then follows that, in principle, comparative analyses of different cell types and tissues of a single organism may similarly reveal lifespan-promoting genes and pathways. Such analyses across cell types would be conceptually similar, yet orthogonal, to the analysis across species. Publicly available transcriptome data sets (for example, RNA-seq) generated by consortia, such as the Human Protein Atlas (HPA),17 Encyclopedia of DNA Elements (ENCODE),18 Functional Annotation Of Mammalian genome (FANTOM)19 and the Genotype-Tissue Expression (GTEx) project,20 are now available. They offer an opportunity to understand how gene expression programs are related to cellular turnover, as a proxy for cellular lifespan. Here we examined transcriptomes of 21 somatic cells and tissues to assess the utility of comparative gene expression methods for the identification of longevity-associated gene signatures.
RESULTS We interrogated publicly available transcriptomes (paired-end RNA-seq reads) of 21 human cell types and tissues, comprising 153 individual samples, with a mean age of 56 years (Table 1; details in Supplementary Table S1). Their turnover rates (an estimate of cell lifespan4) varied from 2 (monocytes) to 32,850 (neurons) days, with all three germ layers giving rise to both short-lived a...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/ekheefis-7496/data/document.pdf", "num_examples": 34, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/ekheefis- /home/sid/tuning/finetune/backend/output/ekheefis-7496/data/ekheefis-7496.json...
|
null
|
completed
|
1764896878
|
1764901074
|
NULL
|
/home/sid/tuning/finetune/backend/output/ekheefis- /home/sid/tuning/finetune/backend/output/ekheefis-7496/adapter...
|
False
|
Edit
Delete
|
|
7b412bdc-3c67-4490-8b23-bea11cc4c231
|
8684964a-bab1-4235-93a8-5fd5e24a1d0a
|
gvktgkwu-6778
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
Future-Proofing the life
|
Future-Proofing the Longevity
|
/home/sid/tuning/finetune/backend/output/gvktgkwu- /home/sid/tuning/finetune/backend/output/gvktgkwu-6778/merged_fp16_hf...
|
xevyo
|
/home/sid/tuning/finetune/backend/output/xevyo-bas /home/sid/tuning/finetune/backend/output/xevyo-base-v1/merged_fp16_hf...
|
xevyo-base-v1
|
This document is published by the World Economic F This document is published by the World Economic Forum as a contribution to a project, insight area or interaction. The findings, interpretations and conclusions expressed herein are the result of a collaborative process facilitated and endorsed by the World Economic Forum but whose results do not necessarily represent the views of the World Economic Forum, nor the entirety of its Members, Partners or other stakeholders. In this paper, many areas of innovation have been highlighted with the potential to support the longevity economy transition. The fact that a particular company or product is highlighted in this paper does not represent an endorsement or recommendation on behalf of the World
Haleh Nazeri Lead, Longevity Economy, World Economic Forum
Graham Pearce Senior Partner, Global Defined Benefit Segment Leader, Mercer
The world appears increasingly fragmented, but one universal reality connects us all – ageing. Across the world, people are living longer than past generations, in some cases by up to 20 years. This longevity shift, coupled with declining birth rates, is reshaping economies, workforces and financial systems, with profound implications for individuals, businesses and governments alike.
As countries transform, the systems that underpin them must also evolve. Today’s reality includes a widening gap between healthspan and lifespan, the emergence of a multigenerational workforce with five generations working side by side, and the need for stronger intergenerational collaboration.
One of the most important topics to consider during this demographic transition is the economic implications of longer lives. This paper highlights five key trends that will influence and shape the financial resilience of institutions, governments
and individuals in the years ahead. It also showcases innovative solutions that are already being implemented by countries, businesses and organizations to prepare for the future.
While the challenges are significant, they also present an opportunity to develop systems that are more inclusive, equitable, resilient and sustainable for the long term. This is a chance to strengthen pension systems and social protections, not only for those who have traditionally benefited, but also for those who were left out of social contracts the first time.
We are grateful to our multistake holder consortium of leaders across business, the public sector, civil society and academia for their contributions, inputs and collaboration on this report. We look forward to seeing how others will continue to build on these innovative ideas to future-proof the longevity economy for a brighter and more ...
|
{"input_type": "file", "source {"input_type": "file", "source": "/home/sid/tuning/finetune/backend/output/gvktgkwu-6778/data/document.pdf", "num_examples": 144, "bad_lines": 0}...
|
/home/sid/tuning/finetune/backend/output/gvktgkwu- /home/sid/tuning/finetune/backend/output/gvktgkwu-6778/data/gvktgkwu-6778.json...
|
null
|
completed
|
1764897065
|
1764909233
|
NULL
|
/home/sid/tuning/finetune/backend/output/gvktgkwu- /home/sid/tuning/finetune/backend/output/gvktgkwu-6778/adapter...
|
False
|
Edit
Delete
|