Jump to content

Life expectancy

From Wikipedia, the free encyclopedia
(Redirected from Mean life span)

Life expectancy and healthy life expectancy in various countries of the world in 2019, according to WHO[1]
Life expectancy and healthy life expectancy by sex[1]
Map of the life expectancy at birth in the world in 2023 (UN estimate, smooth palette)[2]
  85 ⩾
  82.5
  80
  77.5
  75
  72.5
  70
  67.5
  65
  62.5
  60
  57.5
  55
  ⩽ 53
Life expectancy at age 15 years[2]
  70
  67.5
  65
  62.5
  60
  57.5
  55
  52.5
  50
  47.5
Life expectancy at age 65 years[2]
  22.5
  20
  17.5
  15
  12.5
Life expectancy at age 80 years[2]
  10
  7.5
  5
Life expectancy development in some big countries of the world since 1960
Life expectancy at birth, measured by region, between 1950 and 2050
Life expectancy by world region, from 1770 to 2018
“Gender Die Gap”: global female life expectancy gap at birth for countries and territories as defined by WHO for 2019. Open the original svg-file and hover over a bubble to show its data. The square of the bubbles is proportional to country population based on estimation of the UN.

Human life expectancy is a statistical measure of the estimate of the average remaining years of life at a given age. The most commonly used measure is life expectancy at birth (LEB, or in demographic notation e0, where ex denotes the average life remaining at age x). This can be defined in two ways. Cohort LEB is the mean length of life of a birth cohort (in this case, all individuals born in a given year) and can be computed only for cohorts born so long ago that all their members have died. Period LEB is the mean length of life of a hypothetical cohort[3][4] assumed to be exposed, from birth through death, to the mortality rates observed at a given year.[5] National LEB figures reported by national agencies and international organizations for human populations are estimates of period LEB.

Human remains from the early Bronze Age indicate an LEB of 24.[6] In 2019, world LEB was 73.3.[7] A combination of high infant mortality and deaths in young adulthood from accidents, epidemics, plagues, wars, and childbirth, before modern medicine was widely available, significantly lowers LEB. For example, a society with a LEB of 40 would have relatively few people dying at exactly 40: most will die before 30 or after 55. In populations with high infant mortality rates, LEB is highly sensitive to the rate of death in the first few years of life. Because of this sensitivity, LEB can be grossly misinterpreted, leading to the belief that a population with a low LEB would have a small proportion of older people.[8] A different measure, such as life expectancy at age 5 (e5), can be used to exclude the effect of infant mortality to provide a simple measure of overall mortality rates other than in early childhood. For instance, in a society with a life expectancy of 30, it may nevertheless be common to have a 40-year remaining timespan at age 5 (but not a 60-year one[dubiousdiscuss]).

Aggregate population measures—such as the proportion of the population in various age groups—are also used alongside individual-based measures—such as formal life expectancy—when analyzing population structure and dynamics. Pre-modern societies had universally higher mortality rates and lower life expectancies at every age for both males and females.

Life expectancy, longevity, and maximum lifespan are not synonymous. Longevity refers to the relatively long lifespan of some members of a population. Maximum lifespan is the age at death for the longest-lived individual of a species. Mathematically, life expectancy is denoted [a] and is the mean number of years of life remaining at a given age , with a particular mortality.[9] Because life expectancy is an average, a particular person may die many years before or after the expected survival.

Life expectancy is also used in plant or animal ecology,[10] and in life tables (also known as actuarial tables). The concept of life expectancy may also be used in the context of manufactured objects,[11] though the related term[dubiousdiscuss] shelf life is commonly used for consumer products, and the terms "mean time to breakdown" and "mean time between failures" are used in engineering.

History

[edit]

The earliest documented work on life expectancy was done in the 1660s by John Graunt,[12] Christiaan Huygens, and Lodewijck Huygens.[13]

Human patterns

[edit]

Maximum

[edit]

The longest verified lifespan for any human is that of Frenchwoman Jeanne Calment, who is verified as having lived to age 122 years, 164 days, between 21 February 1875 and 4 August 1997. This is referred to as the "maximum life span", which is the upper boundary of life, the maximum number of years any human is known to have lived.[14] According to a study by biologists Bryan G. Hughes and Siegfried Hekimi, there is no evidence for limit on human lifespan.[15][16] However, this view has been questioned on the basis of error patterns.[17] A theoretical study shows that the maximum life expectancy at birth is limited by the human life characteristic value δ, which is around 104 years.[18]

Variation over time

[edit]

The following information is derived from the 1961 Encyclopædia Britannica and other sources, some with questionable accuracy. Unless otherwise stated, it represents estimates of the life expectancies of the world population as a whole. In many instances, life expectancy varied considerably according to class and gender.

Life expectancy at birth takes account of infant mortality and child mortality but not prenatal mortality.

Era Life expectancy at birth in years Notes
Paleolithic 22–33[19] With modern hunter-gatherer populations' estimated average life expectancy at birth of 33 years, life expectancy for the 60% reaching age 15 averages 39 remaining years.[20]
Neolithic 20[21]–33[22] Based on Early Neolithic data, life expectancy at age 15 would be 28–33 years.[23]
Bronze Age and Iron Age[24] 26 Based on Early and Middle Bronze Age data, life expectancy at age 15 would be 28–36 years.[23]
Classical Greece[25] 25[26]–28[27] Based on Athens Agora and Corinth data, life expectancy at age 15 would be 37–41 years.[23] Most Greeks and Romans died young. About half of all children died before adolescence. Those who survived to the age of 30 had a reasonable chance of reaching 50 or 60. The truly elderly, however, were rare. Because so many died in childhood, life expectancy at birth was probably between 20 and 30 years.[28]
Ancient Rome 20–33

[29][30][31][28][19][32]

Data is lacking, but computer models provide the estimate. If a person survived to age 20, they could expect to live around 30 years more. Life expectancy was probably slightly longer for women than men.[33]

Life expectancy at age 1 reached 34-41 remaining years for the 67[29]–75% surviving the first year. For the 55-65% surviving to age 5, remaining life expectancy reached around 40–45,[31] while the ~50% reaching age 10 could expect another 40 years of life.[29] Average remaining years fell to 33–39 at age 15; ~20 at age 40;[29] 14–18 at age 50; ~10–12 at age 60; and ~6–7 at age 70.[31][33]

Wang clan of China, 1st century AD – 1749 35 Life expectancy at age 1 reached 47 years for the 72% surviving the first year.[34][35]
Early Middle Ages (Europe, from the late 5th or early 6th century to the 10th century) 30–35 A Gaulish boy surviving to age 20 might expect to live 25 more years, while a woman at age 20 could normally expect about 17 more years. Anyone who survived until 40 had a good chance of another 15 to 20 years.[36]
Pre-Columbian Mesoamerica 20-40 Expectation of life at birth 13–36 years for various Pre-Columbian Mesoamerican cultures, most of the results lying in the range 24–32 years.[37] Aztec life expectancy 41.2 years for men and 42.1 for women.[38]
Late medieval English peerage[39][40] 30–33[32] Around a third of infants died in their first year.[19] Life expectancy at age 10 reached 32.2 remaining years, and for those who survived to 25, the remaining life expectancy was 23.3 years. Such estimates reflected the life expectancy of adult males from the higher ranks of English society in the Middle Ages, and were similar to that computed for monks of the Christ Church in Canterbury during the 15th century.[32] At age 21, life expectancy of an aristocrat was an additional 43 years.[41]
Early modern Britain (16th – 18th century)[24] 33–40 18th-century male life expectancy at birth was 34 years.[42] Female expectation of remaining years at age 15 rose from ~33 years around the 15th-16th centuries to ~42 in the 18th century.[43]
18th-century England[44][19] 25–40 For most of the century it ranged from 35 to 40; but in the 1720s it dipped as low as 25.[44] During the second half of the century it averaged 37,[45] while for the elite it passed 40 and approached 50.[34]
Pre-Champlain Canadian Maritimes[46] 60 Samuel de Champlain wrote that in his visits to Mi'kmaq and Huron communities, he met people over 100 years old. Daniel Paul attributes the incredible lifespan in the region to low stress and a healthy diet of lean meats, diverse vegetables, and legumes.[47]
18th-century Prussia[42] 24.7 For males.[42]
18th-century France[42] 27.5–30 For males:[42] 24.8 years in 1740–1749, 27.9 years in 1750–1759, 33.9 years in 1800–1809.[35]
18th-century American colonies[19] 28 Massachusetts colonists who reached the age of 50 could expect to live until 71, and those who were still alive at 60 could expect to reach 75.
Beginning of the 19th century[44] ~29 At the beginning of the 19th century, no country in the world had a life expectancy at birth longer than 40 years, England, Belgium and the Netherlands came closest, each reaching 40 years by the 1840s (by which time they had been surpassed by Norway, Sweden and Denmark). India's life expectancy is estimated at ~25 years,[44] while Europe averaged ~33 years.[45]
Early 19th-century England[24][44][34] 40 Remaining years of life averaged ~45[34]–47 for the 84% who survived the first year. Life expectancy fell to ~40 years at age 20, then ~20 years at age 50 and ~10 years at age 70.[44] For a 15-year-old girl it was ~40–45.[43] For the upper-class, LEB rose from ~45 to 50.[34]

Only half of the people born in the early 19th century made it past their 50th birthday. In contrast, 97% of the people born in 21st century England and Wales can expect to live longer than 50 years.[44]

19th-century British India[48] 25.4
19th-century world average[44] 28.5–32 Over the course of the century: Europe rose from ~33 to 43, the Americas from ~35 to 41, Oceania ~35 to 48, Asia ~28, Africa 26.[44] In 1820s France, LEB was ~38, and for the 80% that survived, it rose to ~47. For Moscow serfs, LEB was ~34, and for the 66% that survived, it rose to ~36.[34] Western Europe in 1830 was ~33 years, while for the people of Hau-Lou in China, it was ~40.[45] The LEB for a 10-year-old in Sweden rose from ~44 to ~54.[44]
1900 world average[49] 31–32[44] Around 48 years in Oceania, 43 in Europe, and 41 in the Americas.[44] Around 47 in the U.S.[19] and around 48 for 15-year-old girls in England.[43]
1950 world average[49] 45.7–48[44] Around 60 years in Europe, North America, Oceania, Japan, and parts of South America; but only 41 in Asia and 36 in Africa. Norway led with 72, while in Mali it was merely 26.[44]
2019–2020 world average 72.6–73.2
[44][50][51]
  • Females: 75.6 years
  • Males: 70.8 years
  • Range: ~54 (Central African Republic) – 85.3 (Hong Kong)[51]

English life expectancy at birth averaged about 36 years in the 17th and 18th centuries, one of the highest levels in the world although infant and child mortality remained higher than in later periods. Life expectancy was under 25 years in the early Colony of Virginia,[52] and in seventeenth-century New England, about 40% died before reaching adulthood.[53] During the Industrial Revolution, the life expectancy of children increased dramatically.[54] Recorded deaths among children under the age of 5 years fell in London from 74.5% of the recorded births in 1730–49 to 31.8% in 1810–29,[55][56] though this overstates mortality and its fall because of net immigration (hence more dying in the metropolis than were born there) and incomplete registration (particularly of births, and especially in the earlier period). English life expectancy at birth reached 41 years in the 1840s, 43 in the 1870s and 46 in the 1890s, though infant mortality remained at around 150 per thousand throughout this period.

Life expectancy in 1800, 1950, and 2015 – visualization by Our World in Data

Public health measures are credited with much of the recent increase in life expectancy. During the 20th century, despite a brief drop due to the 1918 flu pandemic,[57] the average lifespan in the United States increased by more than 30 years, of which 25 years can be attributed to advances in public health.[58]

Regional variations

[edit]

There are great variations in life expectancy between different parts of the world, mostly caused by differences in public health, medical care, and diet.

Human beings are expected to live on average 30–40 years in Eswatini[59] and 82.6 years in Japan.[b] An analysis published in 2011 in The Lancet attributes Japanese life expectancy to equal opportunities, excellent public health, and a healthy diet.[61][62]

The World Health Organization announced that the COVID-19 pandemic reversed the trend of steady gain in life expectancy at birth. The pandemic wiped out nearly a decade of progress in improving life expectancy.[63]

Africa

[edit]
Graphs of life expectancy at birth for some sub-Saharan countries showing the fall in the 1990s primarily due to the HIV pandemic[64]

During the last 200 years, African countries have generally not had the same improvements in mortality rates that have been enjoyed by countries in Asia, Latin America, and Europe.[65][66] This is most apparent by the impact of AIDS on many African countries. According to projections made by the United Nations in 2002, the life expectancy at birth for 2010–2015 (if HIV/AIDS did not exist) would have been:[67]

  • 70.7 years instead of 31.6 years, Botswana
  • 69.9 years instead of 41.5 years, South Africa
  • 70.5 years instead of 31.8 years, Zimbabwe

Eastern Europe

[edit]

On average, eastern Europeans tend to live shorter lives than their western counterparts. For example, Spaniards from Madrid can expect to live to 85, but Bulgarians from the region of Severozapaden are predicted to live just past their 73rd birthday. This is in large part due to poor health habits, such as heavy smoking and high alcoholism in the region, and environmental actors, such as high air pollution.[68]

United States

[edit]
Life expectancy from 1990 to 2021 in the US, UK, Netherlands, and Austria

In 2022, the life expectancy was 77.5 in the United States, a decline from 2014, but an increase from 2021. In what has been described as a "life expectancy crisis", there were a total of 13 million "missing Americans" from 1980 to 2021, deaths that would have been averted if it had the standard mortality rate of "wealthy nations".

The annual number of "missing Americans" has been increasing, with 622,534 in 2019 alone.[69] Most excess deaths in the United States can largely be attributed to increasing obesity, alcoholism, drug overdoses, car accidents, suicides, and murders, with poor sleep, unhealthy diets, and loneliness being linked to most of them.[70]

Black Americans have generally shorter life expectancies than their White American counterparts. For example, white Americans in 2010 are expected to live until age 78.9, but black Americans only until age 75.1. This 3.8-year gap, however, is the lowest it has been since 1975 at the latest, the greatest difference being 7.1 years in 1993.[71] In contrast, Asian American women live the longest of all ethnic and gender groups in the United States, with a life expectancy of 85.8 years.[72] The life expectancy of Hispanic Americans is 81.2 years.[71]

Japan

[edit]

In 2023, the life expectancy was 84.5 in Japan, 4.2 years above the OECD average, and one of the highest in the world. Japan's high life expectancy can largely be explained by their healthy diets, which are low on salt, fat, and red meat. For these reasons, Japan has a low obesity rate, and ultimately low mortality from heart disease and cancers[73]

In cities

[edit]

Cities also experience a wide range of life expectancy based on neighborhood breakdowns. This is largely due to economic clustering and poverty conditions that tend to associate based on geographic location. Multi-generational poverty found in struggling neighborhoods also contributes. In American cities such as Cincinnati, the life expectancy gap between low income and high-income neighborhoods touches 20 years.[74]

Plot of life expectancy vs. GDP per capita in 2009. This phenomenon is known as the Preston curve.

Economic circumstances

[edit]
Life expectancy is higher in rich countries with low economic inequality.[75]
Life expectancy vs healthcare spending of rich OECD countries. US average of $10,447 in 2018.[76]

Economic circumstances also affect life expectancy. For example, in the United Kingdom, life expectancy in the wealthiest and richest areas is several years higher than in the poorest areas. This may reflect factors such as diet and lifestyle, as well as access to medical care. It may also reflect a selective effect: people with chronic life-threatening illnesses are less likely to become wealthy or to reside in affluent areas.[77] In Glasgow, the disparity is amongst the highest in the world: life expectancy for males in the heavily deprived Calton area stands at 54, which is 28 years less than in the affluent area of Lenzie, which is only 8 km (5.0 mi) away.[78][79]

A 2013 study found a pronounced relationship between economic inequality and life expectancy.[80] However, in contrast, a study by José A. Tapia Granados and Ana Diez Roux at the University of Michigan found that life expectancy actually increased during the Great Depression, and during recessions and depressions in general.[81] The authors suggest that when people are working at a more extreme degree during prosperous economic times, they undergo more stress, exposure to pollution, and the likelihood of injury among other longevity-limiting factors.

Life expectancy is also likely to be affected by exposure to high levels of highway air pollution or industrial air pollution. This is one way that occupation can have a major effect on life expectancy. Coal miners (and in prior generations, asbestos cutters) often have lower life expectancies than average. Other factors affecting an individual's life expectancy are genetic disorders, drug use, tobacco smoking, excessive alcohol consumption, obesity, access to health care, diet, and exercise.

Sex differences

[edit]
Pink: Countries where female life expectancy at birth is higher than males. Blue: A few countries in southern Africa where females have shorter lives due to AIDS.[82]

In the present, female human life expectancy is greater than that of males, despite females having higher morbidity rates (see health survival paradox). There are many potential reasons for this. Traditional arguments tend to favor sociology-environmental factors: historically, men have generally consumed more tobacco, alcohol, and drugs than women in most societies, and are more likely to die from many associated diseases such as lung cancer, tuberculosis, and cirrhosis of the liver.[83] Men are also more likely to die from injuries, whether unintentional (such as occupational, war, or car wrecks) or intentional (suicide).[83] Men are also more likely to die from most of the leading causes of death (some already stated above) than women. Some of these in the United States include cancer of the respiratory system, motor vehicle accidents, suicide, cirrhosis of the liver, emphysema, prostate cancer, and coronary heart disease.[14] These far outweigh the female mortality rate from breast cancer and cervical cancer. In the past, mortality rates for females in child-bearing age groups were higher than for males at the same age.

A paper from 2015 found that female foetuses have a higher mortality rate than male foetuses.[84] This finding contradicts papers dating from 2002 and earlier that attribute the male sex to higher in-utero mortality rates.[85][86][87] Among the smallest premature babies (those under 2 pounds (910 grams)), females have a higher survival rate. At the other extreme, about 90% of individuals aged 110 are female. The difference in life expectancy between men and women in the United States dropped from 7.8 years in 1979 to 5.3 years in 2005, with women expected to live to age 80.1 in 2005.[88] Data from the United Kingdom shows the gap in life expectancy between men and women decreasing in later life. This may be attributable to the effects of infant mortality and young adult death rates.[89]

Some argue that shorter male life expectancy is merely another manifestation of the general rule, seen in all mammal species, that larger-sized individuals within a species tend, on average, to have shorter lives.[90][91] This biological difference[clarification needed] occurs because women have more resistance to infections and degenerative diseases.[14]

In her extensive review of the existing literature, Kalben concluded that the fact that women live longer than men was observed at least as far back as 1750 and that, with relatively equal treatment, today males in all parts of the world experience greater mortality than females. However, Kalben's study was restricted to data in Western Europe alone, where the demographic transition occurred relatively early. United Nations statistics from mid-twentieth century onward, show that in all parts of the world, females have a higher life expectancy at age 60 than males.[92] Of 72 selected causes of death, only 6 yielded greater female than male age-adjusted death rates in 1998 in the United States. Except for birds, for almost all of the animal species studied, males have higher mortality than females. Evidence suggests that the sex mortality differential in people is due to both biological/genetic and environmental/behavioral risk and protective factors.[85]

One recent suggestion is that mitochondrial mutations which shorten lifespan continue to be expressed in males (but less so in females) because mitochondria are inherited only through the mother. By contrast, natural selection weeds out mitochondria that reduce female survival; therefore, such mitochondria are less likely to be passed on to the next generation. This thus suggests that females tend to live longer than males. The authors claim that this is a partial explanation.[93][94]

Another explanation is the unguarded X hypothesis. According to this hypothesis, one reason for why the average lifespan of males is not as long as that of females––by 18% on average, according to the study––is that they have a Y chromosome which cannot protect an individual from harmful genes expressed on the X chromosome, while a duplicate X chromosome, as present in female organisms, can ensure harmful genes are not expressed.[95][96]

In developed countries, starting around 1880, death rates decreased faster among women, leading to differences in mortality rates between males and females. Before 1880, death rates were the same. In people born after 1900, the death rate of 50- to 70-year-old men was double that of women of the same age. Men may be more vulnerable to cardiovascular disease than women, but this susceptibility was evident only after deaths from other causes, such as infections, started to decline.[97] Most of the difference in life expectancy between the sexes is accounted for by differences in the rate of death by cardiovascular diseases among persons aged 50–70.[98]

Genetics

[edit]

The heritability of lifespan is estimated to be less than 10%, meaning the majority of variation in lifespan is attributable due to differences in environment rather than genetic variation.[99] However, researchers have identified regions of the genome which can influence the length of life and the number of years lived in good health. For example, a genome-wide association study of 1 million lifespans found 12 genetic loci which influenced lifespan by modifying susceptibility to cardiovascular and smoking-related disease.[100] The locus with the largest effect is APOE. Carriers of the APOE ε4 allele live approximately one year less than average (per copy of the ε4 allele), mainly due to increased risk of Alzheimer's disease.[100]

"Healthspan, parental lifespan, and longevity are highly genetically correlated."[101]

In July 2020, scientists identified 10 genomic loci with consistent effects across multiple lifespan-related traits, including healthspan, lifespan, and longevity.[101] The genes affected by variation in these loci highlighted haem metabolism as a promising candidate for further research within the field. This study suggests that high levels of iron in the blood likely reduce, and genes involved in metabolising iron likely increase healthy years of life in humans.[102]

A follow-up study which investigated the genetics of frailty and self-rated health in addition to healthspan, lifespan, and longevity also highlighted haem metabolism as an important pathway, and found genetic variants which lower blood protein levels of LPA and VCAM1 were associated with increased healthy lifespan.[103]

Centenarians

[edit]

In developed countries, the number of centenarians is increasing at approximately 5.5% per year, which means doubling the centenarian population every 13 years, pushing it from some 455,000 in 2009 to 4.1 million in 2050.[104] Japan is the country with the highest ratio of centenarians (347 for every 1 million inhabitants in September 2010). Shimane Prefecture had an estimated 743 centenarians per million inhabitants.[105]

In the United States, the number of centenarians grew from 32,194 in 1980 to 71,944 in November 2010 (232 centenarians per million inhabitants).[106]

Mental illness

[edit]

Mental illness is reported to occur in approximately 18% of the average American population.[107][108]

Life expectancy in the seriously mentally ill is much shorter than the general population.[109]

The mentally ill have been shown to have a 10- to 25-year reduction in life expectancy.[110] Generally, the reduction of lifespan in the mentally ill population compared to the mentally stable population has been studied and documented.[111][112][113][114][115]

The greater mortality of people with mental disorders may be due to death from injury, from co-morbid conditions, or medication side effects.[116] For instance, psychiatric medications can increase the risk of developing diabetes.[117][118][119][120] It has been shown that the psychiatric medication olanzapine can increase risk of developing agranulocytosis, among other comorbidities.[121][122] Psychiatric medicines also affect the gastrointestinal tract; the mentally ill have a four times risk of gastrointestinal disease.[123][124][125]

As of 2020 and the COVID-19 pandemic, researchers have found an increased risk of death in the mentally ill.[126][127][128]

Other illnesses

[edit]

The life expectancy of people with diabetes, which is 9.3% of the U.S. population, is reduced by roughly 10–20 years.[129][130] People over 60 years old with Alzheimer's disease have about a 50% life expectancy of 3–10 years.[131] Other demographics that tend to have a lower life expectancy than average include transplant recipients[132] and the obese.[133]

Education

[edit]

Education on all levels has been shown to be strongly associated with increased life expectancy.[134] This association may be due partly to higher income,[135] which can lead to increased life expectancy. Despite the association, among identical twin pairs with different education levels, there is only weak evidence of a relationship between educational attainment and adult mortality.[134]

According to a paper from 2015, the mortality rate for the Caucasian population in the United States from 1993 to 2001 is four times higher[dubiousdiscuss] for those who did not complete high school compared to those who have at least 16 years of education.[134] In fact, within the U.S. adult population, people with less than a high school education have the shortest life expectancies.

Preschool education also plays a large role in life expectancy. It was found that high-quality early-stage childhood education had positive effects on health. Researchers discovered this by analyzing the results of the Carolina Abecedarian Project, finding that the disadvantaged children who were randomly assigned to treatment had lower instances of risk factors for cardiovascular and metabolic diseases in their mid-30s.[136]

Evolution and aging rate

[edit]

Various species of plants and animals, including humans, have different lifespans. Evolutionary theory states that organisms which—by virtue of their defenses or lifestyle—live for long periods and avoid accidents, disease, predation, etc. are likely to have genes that code for slow aging, which often translates to good cellular repair. One theory is that if predation or accidental deaths prevent most individuals from living to an old age, there will be less natural selection to increase the intrinsic life span.[137] That finding was supported in a classic study of opossums by Austad;[138] however, the opposite relationship was found in an equally prominent study of guppies by Reznick.[139][140]

One prominent and very popular theory states that lifespan can be lengthened by a tight budget for food energy called caloric restriction.[141] Caloric restriction observed in many animals (most notably mice and rats) shows a near doubling of life span from a very limited calorific intake. Support for the theory has been bolstered by several new studies linking lower basal metabolic rate to increased life expectancy.[142][143][144] That is the key to why animals like giant tortoises can live so long.[145] Studies of humans with life spans of at least 100 have shown a link to decreased thyroid activity, resulting in their lowered metabolic rate.[citation needed]

The ability of skin fibroblasts to perform DNA repair after UV irradiation was measured in shrew, mouse, rat, hamster, cow, elephant and human.[146] It was found that DNA repair capability increased systematically with species life span. Since this original study in 1974, at least 14 additional studies were performed on mammals to test this correlation.[147] In all, but two of these studies, lifespan correlated with DNA repair levels, suggesting that DNA repair capability contributes to life expectancy.[147] See DNA damage theory of aging.

In a broad survey of zoo animals, no relationship was found between investment of the animal in reproduction and its life span.[148]

Calculation

[edit]
A survival tree to explain the calculations of life-expectancy. Red numbers indicate a chance of survival at a specific age, and blue ones indicate age-specific death rates.

In actuarial notation, the probability of surviving from age to age is denoted and the probability of dying during age (i.e. between ages and ) is denoted . For example, if 10% of a group of people alive at their 90th birthday die before their 91st birthday, the age-specific death probability at 90 would be 10%. This probability describes the likelihood of dying at that age, and is not the rate at which people of that age die.[c] It can be shown that

(1)

The curtate future lifetime, denoted , is a discrete random variable representing the remaining lifetime at age , rounded down to whole years. Life expectancy, more technically called the curtate expected lifetime and denoted ,[a] is the mean of —that is to say, the expected number of whole years of life remaining, assuming survival to age .[149] So,

(2)

Substituting (1) into the sum and simplifying gives the final result [150]

(3)

If the assumption is made that, on average, people live a half year on the year of their death, the complete life expectancy at age would be , which is denoted by e̊x, and is the intuitive definition of life expectancy.

By definition, life expectancy is an arithmetic mean. It can also be calculated by integrating the survival curve from 0 to positive infinity (or equivalently to the maximum lifespan, sometimes called 'omega'). For an extinct or completed cohort (all people born in the year 1850, for example), it can of course simply be calculated by averaging the ages at death. For cohorts with some survivors, it is estimated by using mortality experience in recent years. The estimates are called period cohort life expectancies.

The starting point for calculating life expectancy is the age-specific death rates of the population members. If a large amount of data is available, a statistical population can be created that allow the age-specific death rates to be simply taken as the mortality rates actually experienced at each age (the number of deaths divided by the number of years "exposed to risk" in each data cell). However, it is customary to apply smoothing to remove (as much as possible) the random statistical fluctuations from one year of age to the next. In the past, a very simple model used for this purpose was the Gompertz function, but more sophisticated methods are now used.[151] The most common modern methods include:

  • fitting a mathematical formula (such as the Gompertz function, or an extension of it) to the data.
  • looking at an established mortality table derived from a larger population and making a simple adjustment to it (such as multiplying by a constant factor) to fit the data. (In cases of relatively small amounts of data.)
  • looking at the mortality rates actually experienced at each age and applying a piecewise model (such as by cubic splines) to fit the data. (In cases of relatively large amounts of data.)

The age-specific death rates are calculated separately for separate groups of data that are believed to have different mortality rates (such as males and females, or smokers and non-smokers) and are then used to calculate a life table from which one can calculate the probability of surviving to each age. While the data required are easily identified in the case of humans, the computation of life expectancy of industrial products and wild animals involves more indirect techniques. The life expectancy and demography of wild animals are often estimated by capturing, marking, and recapturing them.[152] The life of a product, more often termed shelf life, is also computed using similar methods. In the case of long-lived components, such as those used in critical applications (e.g. aircraft), methods like accelerated aging are used to model the life expectancy of a component.[11]

The life expectancy statistic is usually based on past mortality experience and assumes that the same age-specific mortality rates will continue. Thus, such life expectancy figures need to be adjusted for temporal trends before calculating how long a currently living individual of a particular age is expected to live. Period life expectancy remains a commonly used statistic to summarize the current health status of a population. However, for some purposes, such as pensions calculations, it is usual to adjust the life table used by assuming that age-specific death rates will continue to decrease over the years, as they have usually done in the past. That is often done by simply extrapolating past trends, but some models exist to account for the evolution of mortality, like the Lee–Carter model.[153]

As discussed above, on an individual basis, some factors correlate with longer life. Factors that are associated with variations in life expectancy include family history, marital status, economic status, physique, exercise, diet, drug use (including smoking and alcohol consumption), disposition, education, environment, sleep, climate, and health care.[14]

Healthy life expectancy

[edit]

To assess the quality of these additional years of life, 'healthy life expectancy' has been calculated for the last 30 years. Since 2001, the World Health Organization has published statistics called Healthy life expectancy (HALE), defined as the average number of years that a person can expect to live in "full health" excluding the years lived in less than full health due to disease and/or injury.[154][155] Since 2004, Eurostat publishes annual statistics called Healthy Life Years (HLY) based on reported activity limitations. The United States uses similar indicators in the framework of the national health promotion and disease prevention plan "Healthy People 2010". More and more countries are using health expectancy indicators to monitor the health of their population.

Healthy Life Expectancy (HALE) vs GDP per Capita in different countries
Healthy Life Expectancy (HALE) vs GDP per Capita in different countries

The long-standing quest for longer life led in the 2010s to a more promising focus on increasing HALE, also known as a person's "healthspan". Besides the benefits of keeping people healthier longer, a goal is to reduce health-care expenses on the many diseases associated with cellular senescence. Approaches being explored include fasting, exercise, and senolytic drugs.[156]

Forecasting

[edit]

Forecasting life expectancy and mortality form an important subdivision of demography. Future trends in life expectancy have huge implications for old-age support programs (like U.S. Social Security and pension) since the cash flow in these systems depends on the number of recipients who are still living (along with the rate of return on the investments or the tax rate in pay-as-you-go systems). With longer life expectancies, the systems see increased cash outflow; if the systems underestimate increases in life-expectancies, they will be unprepared for the large payments that will occur, as humans live longer and longer.

Life expectancy forecasting is usually based on one of two different approaches:

  1. Forecasting the life expectancy directly, generally using ARIMA or other time-series extrapolation procedures. This has the advantage of simplicity, but it cannot account for changes in mortality at specific ages, and the forecast number cannot be used to derive other life table results. Analyses and forecasts using this approach can be done with any common statistical/mathematical software package, like EViews, R, SAS, Stata, Matlab, or SPSS.
  2. Forecasting age-specific death rates and computing the life expectancy from the results with life table methods. This is usually more complex than simply forecasting life expectancy because the analyst must deal with correlated age-specific mortality rates, but it seems to be more robust than simple one-dimensional time series approaches. It also yields a set of age-specific rates that may be used to derive other measures, such as survival curves or life expectancies at different ages. The most important approach in this group is the Lee-Carter model,[157] which uses the singular value decomposition on a set of transformed age-specific mortality rates to reduce their dimensionality to a single time series, forecasts that time series, and then recovers a full set of age-specific mortality rates from that forecasted value. The software includes Professor Rob J. Hyndman's R package called 'demography' and UC Berkeley's LCFIT system.

Policy uses

[edit]

Life expectancy is one of the factors in measuring the Human Development Index (HDI) of each nation along with adult literacy, education, and standard of living.[158]

Life expectancy is used in describing the physical quality of life of an area. It is also used for an individual when the value of a life settlement is determined a life insurance policy is sold for a cash asset.[clarification needed]

Disparities in life expectancy are often cited as demonstrating the need for better medical care or increased social support. A strongly associated indirect measure is income inequality. For the top 21 industrialized countries, if each person is counted equally, life expectancy is lower in more unequal countries (r = −0.907).[159] There is a similar relationship among states in the U.S. (r = −0.620).[160]

Life expectancy vs. other measures of longevity

[edit]
"Remaining" life expectancy—expected number of remaining years of life as a function of current age—is used in retirement income planning.[161]

Life expectancy may be confused with the average age an adult could expect to live, creating the misunderstanding that an adult's lifespan would be unlikely to exceed their life expectancy at birth, even though having already avoided succumbing to childhood mortality, an adult will always outlive the lifespan calculated from their birth. One may compare the life expectancy of the period after childhood to estimate also the life expectancy of an adult.[162]

As a measure of the years of life remaining, life expectancy decreases with age after initially rising in early childhood, but the average age to which a person is likely to live increases as they survive to successive higher ages.[163] In the table above, the estimated modern hunter-gatherer average expectation of life at birth of 33 years (often considered an upper-bound for Paleolithic populations) equates to a life expectancy at 15 of 39 years, so that those surviving to age 15 will on average die at 54.

In England in the 13th–19th centuries with life expectancy at birth rising from perhaps 25 years to over 40, expectation of life at age 30 has been estimated at 20–30 years,[164] giving an average age at death of about 50-60 for those (a minority at the start of the period but two-thirds at its end) surviving beyond their twenties.

Life expectancy[161] increases with age already achieved.

The table above gives the life expectancy at birth among 13th-century English nobles as 30–33, but having surviving to the age of 21, a male member of the English aristocracy could expect to live:

  • 1200–1300: to age 64
  • 1300–1400: to age 45 (because of the bubonic plague)
  • 1400–1500: to age 69
  • 1500–1550: to age 71 [41]

A further concept is that of modal age at death, the single age when deaths among a population are more numerous than at any other age. In all pre-modern societies the most common age at death is the first year of life: it is only as infant mortality falls below around 33-34 per thousand (roughly a tenth of estimated ancient and medieval levels) that deaths in a later year of life (usually around age 80) become more numerous. While the most common age of death in adulthood among modern hunter-gatherers (often taken as a guide to the likely most favourable Paleolithic demographic experience) is estimated to average 72 years,[165] the number dying at that age is dwarfed by those (over a fifth of all infants) dying in the first year of life, and only around a quarter usually survive to the higher age.

Maximum life span is an individual-specific concept, and therefore is an upper bound rather than an average.[162] Science author Christopher Wanjek writes, "[H]as the human race increased its life span? Not at all. This is one of the biggest misconceptions about old age: we are not living any longer." The maximum life span, or oldest age a human can live, may be constant.[162] Further, there are many examples of people living significantly longer than the average life expectancy of their time period, such as Socrates (71), Saint Anthony the Great (105), Michelangelo (88), and John Adams (90).[162]

However, anthropologist John D. Hawks criticizes the popular conflation of life span (life expectancy) and maximum life span when popular science writers falsely imply that the average adult human does not live longer than their ancestors. He writes, "[a]ge-specific mortality rates have declined across the adult lifespan. A smaller fraction of adults die at 20, at 30, at 40, at 50, and so on across the lifespan. As a result, we live longer on average... In every way we can measure, human lifespans are longer today than in the immediate past, and longer today than they were 2000 years ago... age-specific mortality rates in adults really have reduced substantially."[166]

See also

[edit]

Increasing life expectancy

[edit]

Notes

[edit]
  1. ^ a b In standard actuarial notation, ex refers to the expected future lifetime of (x) in whole years, while x (with a ring above the e) denotes the complete expected future lifetime of (x), including the fraction.
  2. ^ Japan's recorded life expectancy may have been very slightly increased by counting many infant deaths as stillborn.[60]
  3. ^ Note the different units: a probability is unit-less, whereas a mortality rate has units (such as deaths per population per year).

References

[edit]
  1. ^ a b "Life expectancy and Healthy life expectancy, data by country". World Health Organization. 4 December 2020.
  2. ^ a b c d "World Population Prospects 2024" (XLSX). United Nations Department of Economic and Social Affairs. — see file "Compact (most used: estimates and medium projections)"
  3. ^ ""Life Expectancy" – What does this actually mean?". Our World in Data. Retrieved 31 August 2020.
  4. ^ "Period and cohort life expectancy explained: December 2019". Office for National Statistics. UK Government. Retrieved 31 August 2020.
  5. ^ Shryock HS, Siegel JS (1973). The Methods and Materials of Demography (rev. ed.). Washington, DC: Bureau of the Census, Government Printing Office.
  6. ^ MacLennan WJ, Sellers WI (January 1999). "Ageing through the ages". Proceedings of the Royal College of Physicians of Edinburgh. 29 (1): 71–5. doi:10.1177/147827159902900114. PMID 11623672.
  7. ^ "Life expectancy at birth (years) [Indicator]". World Health Organization. 2023. Retrieved 18 December 2023.
  8. ^ Laden G (1 May 2011). "Falsehood: "If this was the Stone Age, I'd be dead by now"". ScienceBlogs. Archived from the original on 11 November 2012. Retrieved 31 August 2014.
  9. ^ O'Sullivan A, Sheffrin SM (2003). Economics: Principles in Action. Pearson Prentice Hall. p. 473. ISBN 978-0-13-063085-8.
  10. ^ Contreras SC, Jurema AL, Claudino ES, Bresciani E, Caneppele TM (1983). "Monowave and polywave light-curing of bulk-fill resin composites: degree of conversion and marginal adaptation following thermomechanical aging". Biomaterial Investigations in Dentistry. 8 (1). Ecological Society of America: 72–78. Bibcode:1983Ecol...64..631M. doi:10.2307/1937181. JSTOR 1937181. PMC 8317947. PMID 34368776.
  11. ^ a b Zahavi E, Torbilo V (1996). Fatigue Design: Life Expectancy of Machine Parts. Boca Raton: CRC Press. ISBN 978-0-8493-8970-2.
  12. ^ Sutherland I (15 July 2005). "Graunt, John". Encyclopedia of Biostatistics. pp. 1–2. doi:10.1002/0470011815.b2a17055. ISBN 978-0-470-84907-1.
  13. ^ Johnson S (2021). Extra Life (1st ed.). Riverhead Books. p. 15. ISBN 978-0-525-53885-1.
  14. ^ a b c d Santrock J (2007). Life Expectancy. A Topical Approach to: Life-Span Development. New York, New York: The McGraw-Hill Companies, Inc. pp. 128–132. ISBN 978-0-07-313376-8.
  15. ^ "No detectable limit to how long people can live" (Press release). Science Daily. 28 June 2017. Retrieved 4 July 2017.
  16. ^ Hughes BG, Hekimi S (June 2017). "Many possible maximum lifespan trajectories". Nature. 546 (7660): E8–E9. Bibcode:2017Natur.546E...8H. doi:10.1038/nature22786. PMID 28658230. S2CID 4464500.
  17. ^ Newman SJ (December 2018). "Errors as a primary cause of late-life mortality deceleration and plateaus". PLOS Biology. 16 (12): e2006776. doi:10.1371/journal.pbio.2006776. PMC 6301557. PMID 30571676.
  18. ^ Liu X (December 2015). "Life equations for the senescence process". Biochemistry and Biophysics Reports. 4: 228–233. doi:10.1016/j.bbrep.2015.09.020. PMC 5669524. PMID 29124208.
  19. ^ a b c d e f Kotre JN, Hall E (1997). Seasons of Life: The Dramatic Journey from Birth to Death. University of Michigan Press. pp. 47–49. ISBN 978-0-472-08512-5.
  20. ^ Kaplan H, Hill K, Lancaster J, Hurtado AM (2000). "A Theory of Human Life History Evolution: Diet, Intelligence and Longevity" (PDF). Evolutionary Anthropology. 9 (4): 156–185. doi:10.1002/1520-6505(2000)9:4<156::AID-EVAN5>3.0.CO;2-7. S2CID 2363289. Retrieved 12 September 2010.
  21. ^ Galor O, Moav O (2007). "The Neolithic Revolution and Contemporary Variations in Life Expectancy" (PDF). Brown University Working Paper. Retrieved 12 September 2010.
  22. ^ Angel JL (1984), "Health as a crucial factor in the changes from hunting to developed farming in the eastern Mediterranean", Proceedings of Meeting on Paleopathology at the Origins of Agriculture: 51–73
  23. ^ a b c Angel JL (May 1969). "The bases of paleodemography". American Journal of Physical Anthropology. 30 (3): 427–437. doi:10.1002/ajpa.1330300314. PMID 5791021.
  24. ^ a b c Galor O, Moav O (2005). "Natural Selection and the Evolution of Life Expectancy" (PDF). Brown University Working Paper. Retrieved 4 November 2010.
  25. ^ Morris I (2004). "Economic Growth in Ancient Greece". Journal of Institutional and Theoretical Economics. 160 (4): 709–742. doi:10.1628/0932456042776050. JSTOR 40752487.
  26. ^ Hansen MH (2006). The shotgun method: the demography of the ancient Greek city-state culture. University of Missouri Press. p. 55. ISBN 978-0-8262-6548-7.
  27. ^ "Mortality". Britannica.com. Retrieved 4 November 2010.
  28. ^ a b Ryan G (1 September 2021). Naked Statues, Fat Gladiators, and War Elephants: Frequently Asked Questions about the Ancient Greeks and Romans. Rowman & Littlefield. p. 44. ISBN 978-1-63388-703-9.
  29. ^ a b c d Boatwright MT (2021). Imperial Women of Rome: Power, Gender, Context. Oxford University Press. p. 87. ISBN 978-0-19-045589-7.
  30. ^
  31. ^ a b c Saller RP (1997). Patriarchy, Property and Death in the Roman Family. Cambridge University Press. pp. 22–25. ISBN 978-0-521-59978-8.
  32. ^ a b c Carrieri MP, Serraino D (December 2005). "Longevity of popes and artists between the 13th and the 19th century". International Journal of Epidemiology. 34 (6): 1435–1436. doi:10.1093/ije/dyi211. PMID 16260451.
  33. ^ a b Frier B (2009). "Chapter 27: Demographics". The Cambridge Ancient History XI: The High Empire, A.D. 70–192. Cambridge University Press. pp. 788–789. ISBN 978-1-139-05439-3.
  34. ^ a b c d e f Maher G (2021). The Imperial Roman Economy. Kilnamanagh. pp. 123, 137, 123–151. ISBN 978-1-9996262-2-8.
  35. ^ a b Bagchi AK (2008). Perilous Passage: Mankind and the Global Ascendancy of Capital. Rowman & Littlefield Publishers. p. 138. ISBN 978-1-4617-0515-4.
  36. ^ Bitel LM (24 October 2002). Women in Early Medieval Europe, 400-1100. Cambridge University Press. ISBN 978-0-521-59773-9.
  37. ^ McCaa R. "The Peopling of Mexico from Origins to Revolution".
  38. ^ Mc Krause S. Life in the Aztec Empire. Brainy Bookstore Mckrause.
  39. ^ "Time traveller's guide to Medieval Britain". Channel4.com. Retrieved 4 November 2010.
  40. ^ "A millennium of health improvement". BBC News. 27 December 1998. Retrieved 4 November 2010.
  41. ^ a b Lancaster HO (1990). Expectations of Life. Springer Science & Business Media. p. 8. ISBN 978-0-387-97105-6.
  42. ^ a b c d e Pomeranz K (2000), The Great Divergence: China, Europe, and the Making of the Modern World Economy, Princeton University Press, p. 37, ISBN 978-0-691-09010-8
  43. ^ a b c Griffin JP (December 2008). "Changing life expectancy throughout history". Journal of the Royal Society of Medicine. 101 (12): 577. doi:10.1258/jrsm.2008.08k037. PMC 2625386. PMID 19092024. Note: Author is clearly using the term "life expectancy" to mean total years, as is evident from the fact that a life expectancy of 79.2 is given for a 15 year old girl in 1989.
  44. ^ a b c d e f g h i j k l m n o Roser M, Ortiz-Ospina E, Ritchie H (2019) [2013]. "Life Expectancy". Our World in Data. How did life expectancy change over time?.
  45. ^ a b c Li B (2021). An Early Modern Economy in China. Cambridge University Press. pp. 246–247. ISBN 978-1-108-47920-2.
  46. ^ Francis D (2006). Voices and Visions: A Story of Canada. Canada: Oxford University Press. p. 21. ISBN 978-0-19-542169-9.
  47. ^ Paul DN (1993). We Were Not the Savages: A Micmac Perspective on the Collision of European and Aboriginal Civilizations (1st ed.). Nimbus. ISBN 978-1-55109-056-6.
  48. ^ "Life expectancy". Our World in Data. Retrieved 28 August 2018.
  49. ^ a b Prentice T. "Health, history and hard choices: Funding dilemmas in a fast-changing world" (PDF). World Health Organization: Global Health Histories. Retrieved 4 November 2010.
  50. ^ 72.6 72.7
  51. ^ a b "Life Expectancy by Country and in the World". Worldometer.
  52. ^ "Medicine & Health". Stratfordhall.org. Archived from the original on 15 February 2020.
  53. ^ "Death in Early America". Digital History. Archived from the original on 30 December 2010.
  54. ^ "Population Change Modernization". Encyclopædia Britannica. 25 May 2024.
  55. ^ Buer MC (1926). Health, Wealth and Population in the Early Days of the Industrial Revolution. London: George Routledge & Sons. p. 30. ISBN 978-0-415-38218-2.
  56. ^ "History—The Foundling Hospital". BBC. 1 May 2001.
  57. ^ "Gapminder World". Gapminder Foundation.
  58. ^ CDC (April 1999). "Ten great public health achievements—United States, 1900-1999". MMWR. Morbidity and Mortality Weekly Report. 48 (12): 241–243. PMID 10220250. Reprinted in: "From the Centers for Disease Control and Prevention. Ten great public health achievements—United States, 1900-1999". JAMA. 281 (16): 1481. April 1999. doi:10.1001/jama.281.16.1481. PMID 10227303. S2CID 2030845.
  59. ^ "The World Factbook — Central Intelligence Agency". 4 November 2021.
  60. ^ Coale AJ, Banister J (December 1996). "Five decades of missing females in China". Proceedings of the American Philosophical Society. 140 (4): 421–450. JSTOR 987286. Also printed as Coale AJ, Banister J (August 1994). "Five decades of missing females in China". Demography. 31 (3): 459–479. doi:10.2307/2061752. JSTOR 2061752. PMID 7828766. S2CID 24724998.
  61. ^ Boseley S (30 August 2011). "Japan's life expectancy 'down to equality and public health measures'". The Guardian. London. Retrieved 31 August 2011. Japan has the highest life expectancy in the world but the reasons says an analysis, are as much to do with equality and public health measures as diet.... According to a paper in a Lancet series on healthcare in Japan....
  62. ^ Ikeda N, Saito E, Kondo N, Inoue M, Ikeda S, Satoh T, et al. (September 2011). "What has made the population of Japan healthy?". Lancet. 378 (9796): 1094–1105. doi:10.1016/S0140-6736(11)61055-6. PMID 21885105. S2CID 33124920. Reduction in health inequalities with improved average population health was partly attributable to equal educational opportunities and financial access to care.
  63. ^ "COVID-19 eliminated a decade of progress in global level of life expectancy". World Health Organization. 24 May 2024. Retrieved 3 July 2024.
  64. ^ "Life expectancy at birth, total (years)—Data". World Bank Group.
  65. ^ "Wealth & Health of Nations". Gapminder Foundation. Retrieved 26 June 2015.
  66. ^ "Life Expectancy in the U.S. Dropped for the Second Year in a Row in 2021". Centers for Disease Control and Prevention. 31 August 2022. Retrieved 31 August 2022.
  67. ^ World Population Prospects — The 2002 Revision. Vol. I: Comprehensive Tables. United Nations Secretariat, Department of Economic and Social Affairs, Population Division. 2003. p. 24. Archived from the original on 7 May 2022. Retrieved 15 December 2020.[dead link]
  68. ^ "Why life expectancy is lower in eastern Europe". The Economist. 20 September 2018. ISSN 0013-0613. Archived from the original on 31 July 2023. Retrieved 3 June 2024.
  69. ^ McKoy J (14 July 2023). "The Missing Americans: Unprecedented US Mortality Far Exceeds Other Wealthy Nations". School of Public Health. Boston University. Retrieved 3 June 2024.
  70. ^ Berg S (10 March 2023). "What doctors wish patients knew about falling U.S. life expectancy". American Medical Association. Retrieved 3 June 2024.
  71. ^ a b Murphy SL, Xu JQ, Kochanek KD, Curtin SC, Arias E (2013). "Deaths: Final Data for 2010" (PDF). National Vital Statistics Reports. 61 (4). Hyattsville, MD: National Center for Health Statistics=: 1–117. PMID 24979972.
  72. ^ "Asian American/Pacific Islander Profile". United States Department of Health and Human Services, Office of Minority Health. Archived from the original on 4 February 2012.
  73. ^ Tsugane S (June 2021). "Why has Japan become the world's most long-lived country: insights from a food and nutrition perspective". European Journal of Clinical Nutrition. 75 (6): 921–928. doi:10.1038/s41430-020-0677-5. PMC 8189904. PMID 32661353.
  74. ^ "The Root Causes of Poverty". Cincinnati, Ohio: Waterfields, LLC. Archived from the original on 6 September 2015. Retrieved 4 March 2015.
  75. ^ Wilkinson R, Pickett K (2009). The Spirit Level: Why Greater Equality Makes Societies Stronger. Bloomsbury Press. ISBN 978-1-60819-036-2.
  76. ^ Roser M (26 May 2017). "Link between health spending and life expectancy: US is an outlier". Our World in Data. Click the sources tab under the chart for info on the countries, healthcare expenditures, and data sources. See the later version of the chart here.
  77. ^ "Tackling health inequalities: Status report on the Programme for Action". UK: Department of Health. Archived from the original on 5 February 2007.
  78. ^ "Social factors key to ill health". BBC News. 28 August 2008. Retrieved 28 August 2008.
  79. ^ "GP explains life expectancy gap". BBC News. 28 August 2008. Retrieved 28 August 2008.
  80. ^ Fletcher MA (10 March 2013). "Research ties economic inequality to gap in life expectancy". Washington Post. Retrieved 23 March 2013.
  81. ^ University of Michigan (29 September 2009). "Did The Great Depression Have A Silver Lining? Life Expectancy Increased By 6.2 Years". ScienceDaily. Retrieved 3 April 2011.
  82. ^ Pele L. "How long will I live? Estimate remaining life expectancy for all countries in the world".
  83. ^ a b World Health Organization (2004). "Annex Table 2: Deaths by cause, sex and mortality stratum in WHO regions, estimates for 2002" (PDF). The world health report 2004 – changing history. Retrieved 1 November 2008.
  84. ^ Orzack SH, Stubblefield JW, Akmaev VR, Colls P, Munné S, Scholl T, et al. (April 2015). "The human sex ratio from conception to birth". Proceedings of the National Academy of Sciences of the United States of America. 112 (16): E2102–11. Bibcode:2015PNAS..112E2102O. doi:10.1073/pnas.1416546112. PMC 4413259. PMID 25825766.
  85. ^ a b Kalben BB (October 2000). "Why men die younger: causes of mortality differences by sex" (PDF). North American Actuarial Journal. 4 (4): 83–111. doi:10.1080/10920277.2000.10595939. Archived from the original (PDF) on 13 September 2017. Retrieved 31 October 2011.
  86. ^ Naeye RL, Burt LS, Wright DL, Blanc WA, Tatter D (December 1971). "Neonatal mortality, the male disadvantage". Pediatrics. 48 (6): 902–906. doi:10.1542/peds.48.6.902. PMID 5129451.
  87. ^ Waldron I (1 January 1983). "Sex differences in human mortality: the role of genetic factors". Social Science & Medicine. 17 (6): 321–333. doi:10.1016/0277-9536(83)90234-4. PMID 6344225.
  88. ^ Hitti M (28 February 2005). "U.S. Life Expectancy Best Ever, Says CDC". eMedicine. WebMD. Retrieved 18 January 2011.
  89. ^ "Life expectancy—care quality indicators". QualityWatch. Nuffield Trust & Health Foundation. Retrieved 16 April 2015.
  90. ^ Stindl R. "Telemores, sexual size dimorphism and gender gap in life expectancy". Jerrymondo.tripod.com. Retrieved 4 November 2010.
  91. ^ Samaras TT, Heigh GH. "How human size affects longevity and mortality from degenerative diseases". Townsend Letter for Doctors & Patients. 159 (78–85): 133–139.
  92. ^ "World Population Ageing 2015 (ST/ESA/SER.A/390)" (PDF). Department of Economic and Social Affairs. United Nations. p. 53. Retrieved 11 March 2021.
  93. ^ "Fruit flies offer DNA clue to why women live longer". BBC News. 2 August 2012 – via bbc.co.uk.
  94. ^ Myers PZ (6 February 2013). "Mother's Curse".
  95. ^ Gilbert L (4 March 2020). "Why men (and other male animals) die younger: It's all in the Y chromosome". phys.org. Retrieved 5 April 2020.
  96. ^ Xirocostas ZA, Everingham SE, Moles AT (March 2020). "The sex with the reduced sex chromosome dies earlier: a comparison across the tree of life". Biology Letters. 16 (3): 20190867. doi:10.1098/rsbl.2019.0867. PMC 7115182. PMID 32126186.
  97. ^ Rettner R (6 July 2015). "When Did Women Start to Outlive Men?". Live Science. Retrieved 8 July 2015.
  98. ^ Beltrán-Sánchez H, Finch CE, Crimmins EM (July 2015). "Twentieth century surge of excess adult male mortality". Proceedings of the National Academy of Sciences of the United States of America. 112 (29): 8993–8. Bibcode:2015PNAS..112.8993B. doi:10.1073/pnas.1421942112. PMC 4517277. PMID 26150507.
  99. ^ Ruby JG, Wright KM, Rand KA, Kermany A, Noto K, Curtis D, et al. (November 2018). "Estimates of the Heritability of Human Longevity Are Substantially Inflated due to Assortative Mating". Genetics. 210 (3): 1109–1124. doi:10.1534/genetics.118.301613. PMC 6218226. PMID 30401766.
  100. ^ a b Timmers PR, Mounier N, Lall K, Fischer K, Ning Z, Feng X, et al. (January 2019). "Genomics of 1 million parent lifespans implicates novel pathways and common diseases and distinguishes survival chances". eLife. 8 (e39856). doi:10.7554/eLife.39856. PMC 6333444. PMID 30642433.
  101. ^ a b Timmers PR, Wilson JF, Joshi PK, Deelen J (July 2020). "Multivariate genomic scan implicates novel loci and haem metabolism in human ageing". Nature Communications. 11 (1): 3570. Bibcode:2020NatCo..11.3570T. doi:10.1038/s41467-020-17312-3. PMC 7366647. PMID 32678081.
  102. ^ University of Edinburgh (20 July 2020). "Blood iron levels could be key to slowing ageing, gene study shows". phys.org. Retrieved 18 August 2020.
  103. ^ Timmers PR, Tiys ES, Sakaue S, Akiyama M, Kiiskinen TT, Zhou W, et al. (January 2022). "Mendelian randomization of genetically independent aging phenotypes identifies LPA and VCAM1 as biological targets for human aging". Nature Aging. 2 (1): 19–30. doi:10.1038/s43587-021-00159-8. hdl:20.500.11820/1bac547c-2eb9-47e1-b4b8-e80d741941c7. PMID 37118362. S2CID 246093885.
  104. ^ United Nations "World Population Ageing 2009"; ST/ESA/SER.A/295, Population Division, Department of Economic and Social Affairs, United Nations, New York, October 2010, liv + 73 pp.
  105. ^ "Centenarians to Hit Record 44,000". Japan Times. 15 September 2010. Okinawa 667 centenarians per 1 million inhabitants in September 2010, had been for a long time the Japanese prefecture with the largest ratio of centenarians, partly because it also had the largest loss of young and middle-aged population during the Pacific War.
  106. ^ "Resident Population. National Population Estimates for the 2000s. Monthly Postcensal Resident Population, by single year of age, sex, race, and Hispanic Origin". Bureau of the Census. Archived from the original on 10 October 2013. Different figures, based on earlier assumptions (104,754 centenarians on Nov.1, 2009) are provided in "Older Americans Month" (PDF). Facts for Features. Bureau of the Census. May 2010. p. 5. Archived from the original (PDF) on 16 February 2016.
  107. ^ Bekiempis V (28 February 2014). "Nearly 1 in 5 Americans Suffers From Mental Illness Each Year". Newsweek.
  108. ^ Steel Z, Marnane C, Iranpour C, Chey T, Jackson JW, Patel V, et al. (April 2014). "The global prevalence of common mental disorders: a systematic review and meta-analysis 1980-2013". International Journal of Epidemiology. 43 (2): 476–493. doi:10.1093/ije/dyu038. PMC 3997379. PMID 24648481.
  109. ^ "Morbidity and Mortality in People With Serious Mental Illness" (PDF). National Association of State Mental Health Program Directors. 2006.
  110. ^ Khullar D (30 May 2018). "The Largest Health Disparity We Don't Talk About". The New York Times.
  111. ^ Wahlbeck K, Westman J, Nordentoft M, Gissler M, Laursen TM (December 2011). "Outcomes of Nordic mental health systems: life expectancy of patients with mental disorders". The British Journal of Psychiatry. 199 (6): 453–458. doi:10.1192/bjp.bp.110.085100. PMID 21593516.
  112. ^ Reininghaus U, Dutta R, Dazzan P, Doody GA, Fearon P, Lappin J, et al. (May 2015). "Mortality in schizophrenia and other psychoses: a 10-year follow-up of the ӔSOP first-episode cohort". Schizophrenia Bulletin. 41 (3): 664–673. doi:10.1093/schbul/sbu138. PMC 4393685. PMID 25262443.
  113. ^ Laursen TM, Munk-Olsen T, Vestergaard M (March 2012). "Life expectancy and cardiovascular mortality in persons with schizophrenia". Current Opinion in Psychiatry. 25 (2): 83–88. doi:10.1097/YCO.0b013e32835035ca. PMID 22249081. S2CID 13646442.
  114. ^ "Antipsychotics Linked to Mortality in Parkinson's". Medscape. Retrieved 9 April 2018.
  115. ^ Rosenbaum L (October 2016). "Closing the Mortality Gap - Mental Illness and Medical Care". The New England Journal of Medicine. 375 (16): 1585–1589. doi:10.1056/NEJMms1610125. PMID 27797313.
  116. ^ "Inquest told there was a "lost opportunity" to treat mental health patient who died following severe constipation". Archived from the original on 9 April 2019. Retrieved 25 July 2017.
  117. ^ Kumar PN, Thomas B (April 2011). "Hyperglycemia associated with olanzapine treatment". Indian Journal of Psychiatry. 53 (2): 176–177. doi:10.4103/0019-5545.82562. PMC 3136028. PMID 21772658.
  118. ^ "Lilly Adds Strong Warning Label to Zyprexa, a Schizophrenia Drug". The New York Times. 6 October 2007. Retrieved 9 April 2018.
  119. ^ Codario RA (28 October 2007). Type 2 Diabetes, Pre-Diabetes, and the Metabolic Syndrome. Springer Science & Business Media. ISBN 978-1-59259-932-5 – via Google Books.
  120. ^ "Antipsychotic-Related Metabolic Testing Falls Far Short". MedScape. Retrieved 9 April 2018.
  121. ^ Alvir JM, Lieberman JA, Safferman AZ, Schwimmer JL, Schaaf JA (July 1993). "Clozapine-induced agranulocytosis. Incidence and risk factors in the United States". The New England Journal of Medicine. 329 (3): 162–167. doi:10.1056/NEJM199307153290303. PMID 8515788.
  122. ^ "Zyprexa Prescribing Information" (PDF). U.S. Food Drug and Administration. 2010.
  123. ^ Philpott HL, Nandurkar S, Lubel J, Gibson PR (January 2014). "Drug-induced gastrointestinal disorders". Frontline Gastroenterology. 5 (1): 49–57. doi:10.1136/flgastro-2013-100316. PMC 5369702. PMID 28839751.
  124. ^ Rege S, Lafferty T (June 2008). "Life-threatening constipation associated with clozapine". Australasian Psychiatry. 16 (3): 216–219. doi:10.1080/10398560701882203. PMID 18568631. S2CID 32093594.
  125. ^ Hibbard KR, Propst A, Frank DE, Wyse J (2009). "Fatalities associated with clozapine-related constipation and bowel obstruction: a literature review and two case reports". Psychosomatics. 50 (4): 416–419. doi:10.1176/appi.psy.50.4.416. PMID 19687183.
  126. ^ Nemani K, Li C, Olfson M, Blessing EM, Razavian N, Chen J, et al. (April 2021). "Association of Psychiatric Disorders With Mortality Among Patients With COVID-19". JAMA Psychiatry. 78 (4): 380–386. doi:10.1001/jamapsychiatry.2020.4442. PMC 7841576. PMID 33502436.
  127. ^ Wang Q, Xu R, Volkow ND (February 2021). "Increased risk of COVID-19 infection and mortality in people with mental disorders: analysis from electronic health records in the United States". World Psychiatry. 20 (1): 124–130. doi:10.1002/wps.20806. PMC 7675495. PMID 33026219.
  128. ^ Li L, Li F, Fortunati F, Krystal JH (September 2020). "Association of a Prior Psychiatric Diagnosis With Mortality Among Hospitalized Patients With Coronavirus Disease 2019 (COVID-19) Infection". JAMA Network Open. 3 (9): e2023282. doi:10.1001/jamanetworkopen.2020.23282. PMC 7527869. PMID 32997123.
  129. ^ "Diabetes Life Expectancy – Type 1 and Type 2 Life Expectancy". 15 January 2019.
  130. ^ Centers for Disease Control and Prevention
  131. ^ Zanetti O, Solerte SB, Cantoni F (2009). "Life expectancy in Alzheimer's disease (AD)". Archives of Gerontology and Geriatrics. 49 (Suppl 1): 237–243. doi:10.1016/j.archger.2009.09.035. PMID 19836639.
  132. ^ Kiberd BA, Keough-Ryan T, Clase CM (May 2003). "Screening for prostate, breast and colorectal cancer in renal transplant recipients". American Journal of Transplantation. 3 (5): 619–625. doi:10.1034/j.1600-6143.2003.00118.x. PMID 12752319. S2CID 20247054.
  133. ^ Diehr P, O'Meara ES, Fitzpatrick A, Newman AB, Kuller L, Burke G (January 2008). "Weight, mortality, years of healthy life, and active life expectancy in older adults". Journal of the American Geriatrics Society. 56 (1): 76–83. doi:10.1111/j.1532-5415.2007.01500.x. PMC 3865852. PMID 18031486.
  134. ^ a b c Hummer RA, Hernandez EM (June 2013). "The Effect of Educational Attainment on Adult Mortality in the United States". Population Bulletin. 68 (1): 1–16. PMC 4435622. PMID 25995521.
  135. ^ Torpey E. "Measuring the value of education : Career Outlook: U.S. Bureau of Labor Statistics". bls.gov. Retrieved 10 March 2019.
  136. ^ Campbell F, Conti G, Heckman JJ, Moon SH, Pinto R, Pungello E, et al. (March 2014). "Early childhood investments substantially boost adult health". Science. 343 (6178). New York, N.Y.: 1478–85. Bibcode:2014Sci...343.1478C. doi:10.1126/science.1248429. PMC 4028126. PMID 24675955.
  137. ^ Williams G (1957). "Pleiotropy, natural selection, and the evolution of senescence". Evolution. 11 (4). Society for the Study of Evolution: 398–411. doi:10.2307/2406060. JSTOR 2406060.
  138. ^ Austad SN (1993). "Retarded senescence in an insular population of Virginia opossums". J. Zool. Lond. 229 (4): 695–708. doi:10.1111/j.1469-7998.1993.tb02665.x.
  139. ^ Reznick DN, Bryant MJ, Roff D, Ghalambor CK, Ghalambor DE (October 2004). "Effect of extrinsic mortality on the evolution of senescence in guppies". Nature. 431 (7012): 1095–1099. Bibcode:2004Natur.431.1095R. doi:10.1038/nature02936. PMID 15510147. S2CID 205210169.
  140. ^ Mitteldorf J, Pepper JW (August 2007). "How can evolutionary theory accommodate recent empirical results on organismal senescence?". Theory in Biosciences = Theorie in den Biowissenschaften. 126 (1): 3–8. doi:10.1007/s12064-007-0001-0. PMID 18087751. S2CID 7305206.
  141. ^ Kirkwood TB (November 1977). "Evolution of ageing". Nature. 270 (5635): 301–304. Bibcode:1977Natur.270..301K. doi:10.1038/270301a0. PMID 593350. S2CID 492012.
  142. ^ Hulbert AJ, Pamplona R, Buffenstein R, Buttemer WA (October 2007). "Life and death: metabolic rate, membrane composition, and life span of animals" (PDF). Physiological Reviews. 87 (4): 1175–1213. doi:10.1152/physrev.00047.2006. PMID 17928583. S2CID 11903260. Archived from the original (PDF) on 18 February 2019.
  143. ^ Olshansky SJ, Rattan SI (August 2005). "What determines longevity: Metabolic rate or stability?". Discovery Medicine. 5 (28): 359–362. PMID 20704872.
  144. ^ Aguilaniu H, Durieux J, Dillin A (October 2005). "Metabolism, ubiquinone synthesis, and longevity". Genes & Development. 19 (20): 2399–2406. doi:10.1101/gad.1366505. PMID 16230529.
  145. ^ "The Longevity Secret for Tortoises Is Held In Their Low Metabolism Rate". Archived from the original on 12 November 2013.
  146. ^ Hart RW, Setlow RB (June 1974). "Correlation between deoxyribonucleic acid excision-repair and life-span in a number of mammalian species". Proceedings of the National Academy of Sciences of the United States of America. 71 (6): 2169–73. Bibcode:1974PNAS...71.2169H. doi:10.1073/pnas.71.6.2169. PMC 388412. PMID 4526202.
  147. ^ a b Bernstein C, Bernstein H (1991). Aging, Sex, and DNA Repair. San Diego, CA: Academic Press. pp. 109–113.
  148. ^ Ricklefs RE, Cadena CD (October 2007). "Lifespan is unrelated to investment in reproduction in populations of mammals and birds in captivity". Ecology Letters. 10 (10): 867–872. Bibcode:2007EcolL..10..867R. doi:10.1111/j.1461-0248.2007.01085.x. PMID 17845285.
  149. ^ Kinney B (1 May 2019). "Curtate Expectation of Life". Infinity is Really Big. Retrieved 18 November 2022.
  150. ^ Cunningham R, Herzog T, London R (2008). Models for Quantifying Risk (Third ed.). Actex. ISBN 978-1-56698-676-2. page 92.
  151. ^ Anderson RN (2000). "A method for constructing complete annual U.S. life tables" (PDF). Vital and Health Statistics. Series 2, Data Evaluation and Methods Research (129): 1–28. PMID 11824050.
  152. ^ Young LJ, Young JH (1998). Statistical ecology: a population perspective. Boston: Kluwer Academic Publishers. p. 310. ISBN 978-0-412-04711-4.
  153. ^ Lee RD, Carter LR (September 1992). "Modeling and forecasting US mortality". Journal of the American Statistical Association. 87 (419): 659–671. doi:10.1080/01621459.1992.10475265.
  154. ^ "Healthy life expectancy (HALE) at 60 (years)". World Health Organization.
  155. ^ "Health Status Statistics: Mortality". World Health Organization. Archived from the original on 4 July 2012.
  156. ^ Lawton G (24 April 2019). "Anti-ageing drugs are coming that could keep you healthier for longer". New Scientist. Retrieved 2 May 2019.
  157. ^ "The Lee-Carter Method for Forecasting Mortality, with Various Extensions and Applications – SOA" (PDF). SOA. Archived from the original (PDF) on 7 March 2019. Retrieved 9 April 2018.
  158. ^ "International Human Development Indicators—UNDP". Hdrstats.undp.org. Archived from the original on April 20, 2009. Retrieved November 4, 2010.
  159. ^ De Vogli R, Mistry R, Gnesotto R, Cornia GA (February 2005). "Has the relation between income inequality and life expectancy disappeared? Evidence from Italy and top industrialised countries". Journal of Epidemiology and Community Health. 59 (2): 158–162. doi:10.1136/jech.2004.020651. PMC 1733006. PMID 15650149.
  160. ^ Kaplan GA, Pamuk ER, Lynch JW, Cohen RD, Balfour JL (April 1996). "Inequality in income and mortality in the United States: analysis of mortality and potential pathways". BMJ. 312 (7037): 999–1003. doi:10.1136/bmj.312.7037.999. PMC 2350835. PMID 8616393.
  161. ^ a b "Actuarial Life Table". U.S. Social Security Administration Office of Chief Actuary. 2020. Archived from the original on 8 July 2023.
  162. ^ a b c d Wanjek C (2002), Bad Medicine: Misconceptions and Misuses Revealed, from Distance Healing to Vitamin O, Wiley, pp. 70–71, ISBN 978-0-471-43499-3.
  163. ^ "Life Expectancy by Age, 1850–2011". InfoPlease.
  164. ^ Khan-ad-Din FM, Caidan Pentathlon M. "Old Age, Height and Nutrition: Common Misconceptions About Medieval England" (PDF).
  165. ^ Gurven M, Kaplan H (2007), "Longevity Among Hunter- Gatherers: A Cross-Cultural Examination", Population and Development Review, 33 (2): 321–365, doi:10.1111/j.1728-4457.2007.00171.x
  166. ^ Hawks J (2009), Human lifespans have not been constant for the last 2000 years.

Further reading

[edit]
[edit]