People have long been interested in making their lives longer and healthier. The most anсient Egyptian, Indian and Chinese books contain reasoning about aging. Ancient Egyptians used garlic in large quantities to extend
theirlifespan.
Hippocrates (
c. 460 – c. 370 BC), in his Aphorisms, and
Aristotle (
384 –
322 BC), in On youth and old age, expressed their opinions about reasons for old age and gave advice about lifestyle. Medieval
Persian physician
Ibn Sina (c. 980 – 1037), known in the West as Avicenna, summarized the achievements of earlier generations about this issue.[1][2][3]
Background
Descriptions of rejuvenation and immortality remedies are often found in the writings of alchemists. But all those remedies did not allow even alchemists themselves to live longer than a hundred years.[1][2][3]
Though the
average lifespan of people through the past millennia increased significantly,[4] maximum lifespan almost did not change - even in ancient times there were fairly well and unbiasedly documented cases when some people lived for more than a hundred years (for example,
Terentia who lived 103 or 104 years). While among the billions of people of the modern world, there is only one case of life over 120 years (
Jeanne Calment, 122 years). The super-long lives of people that are mentioned in ancient books, apparently, are highly exaggerated, since archaeological data show that even the oldest of the ancient people lived no more than modern
supercentenarians.[2] In some cases the exaggeration, possibly, is not intentional but occurs due to errors in translation between languages and
synchronization of chronological systems. The species limit of human life is estimated by scientists at 125–127 years,[5][6] and even in the most ideal conditions a person will not live longer due to aging of the body.
Some scientists believe that, even if medicine learns how to treat all major diseases, that will increase the average lifespan of people in developed countries by only about 10 years.[2] For example, biogerontologist
Leonard Hayflick stated that the natural average lifespan for humans is 92 years.[7] Meanwhile, the
life expectancy for Japanese already now is more than 84 years,[8] and for
Monaco it is reported to be more than 89 years.[9] It may not be possible to achieve further increases without development of new
biomedical technologies and approaches. Searches of various equivalents of the elixir of youth happened yet in ancient times: people hoped to find a miraculous remedy in faraway territories, tried to use magic and alchemy. Scientific and technological attempts began at the end of the 19th century. For their intended purpose, all of them turned out to be inefficient at best, sometimes led to premature death, but they had many useful and sometimes unexpected consequences.
Timeline
Ancient
350 BC — The Greek philosopher
Aristotle, arguably the first philosopher to make a serious attempt to scientifically explain aging, proposes his thesis on aging. He suggests that aging is a process by which human and animal bodies, which are naturally hot and wet, gradually become dry and cold, and theorizes that more moisture delays aging.[10][11]
259–210 BC — years of life of the Chinese emperor
Qin Shi Huang, who united China under his rule. All his life he persistently searched for an
elixir of youth and died trying, presumably taking "
pills of immortality", containing mercury.
156–
87 BC — years of life of the Chinese emperor
Wu of Han, who persistently tried to find a way to achieve immortality, mainly by means of magic. He used services of various magicians. But Wu of Han was not a naive person – he thoroughly rechecked their abilities and if he identified the person as a quack, he executed him.
63 BC–
14 AD — years of life of
Caesar Augustus, the first Roman emperor, who is considered one of the most effective leaders of the Ancient Rome. For him an
eternal youth was an obsession. In particular, contrary to the Roman tradition to create statues as realistic as possible, he always ordered to portray himself young. There are many of his "youthful" statues but researchers still don't know how he looked in old age.
3rd–17th century — the period of
alchemy. There are several directions in alchemy, and it was distributed over a huge territory. But almost everywhere, in one form or another, there was the concept of a "
philosopher's stone" – some substance that is able to turn other metals into gold, and when taken internally in small doses, heal all diseases, rejuvenate an old body and even give biological immortality. Alternatively, there were attempts to prepare "pills of immortality". During centuries alchemy gradually
transformed to chemistry, in parallel giving birth to many adjacent sciences or enriching them. It is worth noticing the direction of
iatrochemistry – a rational direction of alchemy with the main goal of preparing medicinal products. The pioneers of iatrochemistry were
Paracelsus (1493–1541),
Jan Baptist van Helmont (1580–1644) and
Franciscus Sylvius (1614–1672). The converging field of alchemy was transformed into
pharmacy.
1513 — searching for the
Fountain of Youth is in popular culture thought to be one of the purposes of the expedition of the Spanish conquistador
Juan Ponce de León, which lead to the discovery of Florida – however, there is no contemporary evidence of this, and this purpose is considered a myth by historians.[12]
1550 — a
Venetian nobleman
Luigi Cornaro published the book "The Art of Living Long", describing the style of life for the achievement of longevity.[13] The book was translated into many languages. The English version of the book till the 19th century went through more than 50 editions. The main idea of the book: in order to live many years, you need to live in moderation, eat simply and little. In his youth Cornaro led a free and immoderate life, as a result by the age of 35 he had many health problems. But by changing his lifestyle he was able to live to 98 (1467–1566).[14] (Though it is possible that he exaggerated his age by about 17 years to give his recommendations more weight.)
19th century to WWII
From the end of the 19th century, systematic scientific and technical studies began on the processes of slowing down aging and possible rejuvenation. The period of world history between the two world wars is a very complicated, difficult and ambiguous time of world history. In many spheres of life, there were ideas that were radical-bold, but not always intelligent, ethical and moral from the point of view of modern knowledge, foundations and norms. This also affected the aging research, the spirit of which corresponded to the spirit of that time: attempting bold experiments, often on people, intensively implementing in practice treatments that we may now consider ridiculous. Those attempts had both bad and good consequences. But those researches were already scientific. As it often happens in science, it is often difficult to establish priority considering, who was the first person beginning to use one or another approach. Usually the first experiments are done by enthusiasts and have doubtful positive effects. Some researchers work in parallel. Then at some moment the persons emerge who developed the approaches and made them public.
1825 The first publication of the
Gompertz–Makeham law of mortality that in the simplest form is: p = a + bx. According to the law, the probability of death p is defined as the sum of age-independent component a and the component depending on age bx which with age increases exponentially. If we place organisms in an absolutely protected environment and in this way make the first component negligible, the probability of death will be completely defined by the second component which actually describes the probability to die from aging.
1860sAlfred Russel Wallace writes down what is probably the first evolutionary theory of aging. In notes written sometime between 1865 and 1870, he proposed a
wear and tear theory of aging, suggesting that older animals which continue to consume resources, competing with their offspring in an environment with limited food, were disfavored by natural selection. Therefore, he suggested that aging was an evolved trait which allowed an organism's descendants to thrive.[11]
1889 Rejuvenation experiment conducted on himself by the French doctor
Charles-Édouard Brown-Séquard. He made himself a few subcutaneous injections from the testicles of young dogs and guinea pigs and claimed that the injections were accompanied by significant and long pain, but then he observed an improvement of the physical condition of the organism and increase of mental activity. Experiments of other scientists, at first, produced the same results but later it became clear that the period of reinforced activity is followed by a period of decline. At the moment of the experiment Charles-Édouard Brown-Séquard was 72 years old. After the experiment he claimed he felt as if he became younger by 30 years. However, 5 years later he died. But other doctors picked up this method and it created the foundation for the development of
hormone replacement therapy.[2][17][18][14]
1903Ilya Mechnikov coined the term "gerontology".[19][20][3] The term originates from the
Greekγέρων, geron, "old man" and -λογία, -logia, "study of". From 1897 to 1916 Mechnikov conducted many studies on the effect of acidified dairy products (especially Bulgarian
yogurt and
bacteria used for its production) on longevity and quality of life in old age. He developed the concept of
probiotic diet that promotes long healthy life.[17][18] In 1908 Mechnikov received the
Nobel Prize for his work on immunology (adjacent area of his research).[21] Adhering to his diet, Mechnikov lived a very long life compared to his short-lived relatives.[22]
1914 Dr. Frank Lydston from Chicago performed human testis transplants on several patients, including himself, and said that there were some rejuvenating consequences (such as returning his gray hair to its original color and improving of sexual performance).[14] These works remained little known. The work of
Leo L. Stanley, that he began to do since 1919, received much more prominence (see
further).
1915–1917 Experiments to find out the effects of food restriction on the life duration of rats, conducted by Thomas Osborne. Apparently, these were the first systematic experiments in this direction.[2][23] These experiments remained little known. The method was popularized by Clive McCay in 1934–1935 (see
further).
1910s–1930s Austrian physiologist
Eugen Steinach was trying to achieve rejuvenation effects by means of different surgical operations such as partial
vasectomy for men, ligation of fallopian tubes for women, transplantation of testicles, etc. And although later these operations were found to be ineffective, they allowed the researchers to recognize the role of the sexual glands and sexual hormones in the formation of the first and secondary sex characteristics, enriched physiology, laid the foundation for the science of
sexology, formed the basis for sex reassignment surgeries. From 1921 to 1938, Eugen Steinach was nominated for the Nobel Prize many times (according to various sources, from 6 to 11 times), but never received it.[17][18][24][25][26]
1910s–1930s Numerous experiments for obtaining rejuvenating effects by means of transplantation of organs and tissues. Among the most notable researchers who worked in this direction, there were
Alexis Carrel (who developed the technology of
anastomosis of blood vessels and advanced
asepsis, a Nobel laureate of 1912[27]),
Mathieu Jaboulay,
Emerich Ullmann,
Jacques Loeb,
John Northrop,
Porfiry Bakhmetiev. And although such interventions were later found to be ineffective for their intended purposes, those works led to the creation of
tissue engineering, techniques for
cardiopulmonary bypass and
dialysis, established the foundation for the technologies for storing organs extracted from a person outside the body (which now are used, for example, during
organ donation), the emergence of
cryobiology.[17][18]
1920s–1930s In medical practice, sex gland transplants were introduced to obtain rejuvenating effects. (Though separate experiments in this direction were done even earlier, even in antiquity.) The earlier mentioned operations of Dr. Frank Lydston in 1914 remained almost unnoticed. But the works of
Leo Leonidas Stanley quickly received widespread scientific notice. Stanley was a physician at a prison in California and began to do these operations since 1919, using glands of executed criminals.[14] In the following years, such operations were done by dozens of physicians (including Eugen Steinach) but they became most famous due to the activity of the French surgeon of Russian extraction
Serge/Samuel Voronoff. It was believed that transplantation of sex glands provides more durable effects than injection of a
suspension of ground glands. In case of transplantation from human to human, the glands of executed criminals were usually used. But due to a shortage of materials, the sex glands of young healthy monkeys were widely used, which were specially grown for this purpose (usually thin sections of the glands were implanted). In some cases soon after the operation, there were indeed noticeable positive changes in appearance and behavior (with a rapid senility of the body soon following). There were many messages about wonderful results of the operations that, apparently, were false advertising of unscrupulous doctors. But numerous failures became apparent, for which the method was sharply criticized and banned.[2] Serge Voronoff and some other doctors, who claimed producing wonderful results after the operations, got bad reputation. However, despite the failure in the main direction, the conducted research led to the emergence of
allotransplantation and
xenotransplantation directions in surgery, brought significant knowledge about the effect of
sex hormones on the body, stimulated their study.[17][18] It may be just a coincidence but in 1929–33 several varieties of
estrogen were discovered, and
testosterone was isolated in 1935. Also these experiments formed the basis for several works of public culture (for example, Heart of a Dog by Mikhail Bulgakov, The Adventure of the Creeping Man from the series about Sherlock Holmes, a song Monkey-Doodle-Doo of
Irving Berlin).
1926–1928 Experiments on rejuvenation by blood transfusion, conducted by
Alexander Bogdanov in the world's first
Institute for Blood Transfusion especially created for that purpose. Bogdanov himself died during one of the experiments, because at that time little was known about the factors of blood compatibility of different people.[2][18] The institute, having undergone several renames, exists and is still actively working. The second head of the institute was Alexander Bogomolets (see
further).
1930s Beginning of attempts of rejuvenation by methods of cell injections. A special role belongs here to the Swiss physician
Paul Niehans – he was not the first but he was the one who developed this approach the most. Among his patients there were many famous people (including
Winston Churchill,
Charles de Gaulle,
Pope Pius XII).[2][17] So, in 1952, about 3000 injections of about 10 cm3 of cell suspension were reported. As a consequence,
cell therapy and
regenerative medicine were formed. Since the 1960s, attempts have been made to inject not only whole cells but also their constituent parts (such as isolated DNA and RNA).[17][18] But usage of embryonic drugs sometimes caused serious complications, so the American association of physicians recognized the method of cell therapy as dangerous.[2]
1930 The first world's journal about aging and longevity. It was established in Japan and has the name Acta Gerontologica Japonica (Yokufuen Chosa Kenkyu Kiyo).[28]
1933 The first institute in the world dedicated to study of aging. It was created in
Kishinev (at that time inside the
Kingdom of Romania) by
Dimu Kotsovsky. Initially the institute was maintained by his own means, and was subsequently recognized by the Romanian government. The name is
Romanian: Institutul Pentru Studierea si Combaterea Batranetii = German: Institut für Altersforschung und Altersbekämpfung = Institute for The Study and Combat of Aging.[29]
1934 The first widely known scientific publication on the impact of dietary restriction on life expectancy, authored by
Clive McCay.[30][31][32] McCay's group carried out intensive research in this direction in 1930–43, soon other scientists began to do related research.[2] The effect of increasing life expectancy by starvation is usually observed in rats and mice, whose development until puberty is very
labile (growth retardation and puberty, decreased metabolism and body temperature). In larger animals, such as rabbits, dogs and monkeys, the effect is less pronounced. The impact of fasting on human life expectancy still remains a question where not everything is clear and is unambiguous.[2]
1936 The first European (and Western) journal about aging and longevity. It was published in Kishinev by Dimu Kotsovsky. During the first year of existence it was called Monatsberichte,[33] then got the name German: Altersprobleme: Zeitschrift für Internationale Altersforschung und Altersbekämpfung = "Problems of Aging: Journal for the International Study and Combat of Aging". The journal published materials mostly in the German language, less in French and English.[29]
1937 A Ukrainian Soviet
pathophysiologistAlexander Bogomolets created
antireticular cytotoxic serum in the hope to extend life of people to 150 years. Although the drug did not achieve its main goal, it has become widely used for the treatment of a number of diseases, especially infectious diseases and fractures.[2][17][18] The serum of Bogomolets was actively used in Soviet hospitals during WWII. For his work, Alexander Bogomolets received in 1941 the Stalin Prize,[34] which for Soviet scientists of those years was even more important than the Nobel Prize.
1938 The first specialized society dedicated to the study of aging. It was formed in Germany,
Leipzig and was named the German Society for Aging Research (German: Deutsche Gesellschaft für Altersforschung, soon renamed to Deutsche Gesellschaft für Alternsforschung). The founder is
Max Bürger [
de]. He also established the specialized journal Zeitschrift für Altersforschung – it is already the third such journal in the world after the previously mentioned Japanese and Romanian journals.[35]
1938 The world's first scientific conference on aging and longevity in 1938 in Kiev, that was convened by Alexander Bogomolets.[1][36]
After
World War II, research tools and technologies of another level appeared. Thanks to these technologies, it became understandable what really occurs inside cells and between them (for example, the model of the DNA double helix was created in 1953). At the same time, changed ethical norms did not allow cardinal experiments to be performed on humans, as had been possible in previous decades. Consequently, the influence of different factors could be estimated only indirectly.
1950 Largely thanks to the collaborative efforts of Korenchevsky and Cowdry, the International Association of Gerontology is formed, later renamed to the
International Association of Gerontology and Geriatrics (IAGG). The organization was registered in Belgium, and that is where its first conference took place. Slowly, gradually, the ideas began to spread that the problems of aging cannot be solved within the framework and efforts of one nation – therefore the international interaction is necessary.[1]
1954Vladimir Dilman formulated the hypothesis of aging that at first become known only in the USSR, as the elevation hypothesis. In 1968 it took the form and became known as the neuroendocrine theory of aging.[38][39][40]
1961 Discovery by
Leonard Hayflick of the limit of divisions for
somatic cells, named the
Hayflick limit. Hayflick found that normal human cells, extracted from fetus, are able to divide only about 50 times, after that they enter a
senescence phase.
1974 Formation of the
National Institute on Aging (NIA) – the aging of the population began to be perceived as a problem deserving state attention (and not as a problem of separate scientific societies). Since 1984, the NIA has begun to contribute in every way to the work of the
National Archive of Computerized Data on Aging (NACDA).
1977 To explain aging,
Thomas Kirkwood proposed the
disposable soma theory. According to the theory, the organism has only a limited amount of resources that it has to allocate between different purposes (such as growth, reproduction, repair of damage). Aging occurs due to the limitation of resources that the body can afford to spend on repair.[4]
1986Reliability theory of aging and longevity proposed by Leonid Gavrilov and Natalia Gavrilova. At first it was published only in the USSR.[53] In English language the theory was published five years later, in 1991.[54][55][56]
1990 Formation of the
Gerontology Research Group (GRG) which searches for
supercentenarians around the world and verifies their age. Whenever possible, the organization tries to collect data on why these people live significantly longer than the average person. The organization regularly publishes a list of the oldest verified living supercentenarians.[57]
1992National Archive of Computerized Data on Aging (NACDA) published in the Internet the first 28 datasets related to aging. Gradually the number of published datasets has grown to over 1600 and continues to grow. These datasets are available to any researcher around the world at no charge, so they can search in them for new patterns. The site also provides some tools to facilitate analysis.[58]
1993Cynthia Kenyon and Ramon Tabtiang doubled the lifespan of C. elegans nematodes by partially disabling a gene, with the nematodes remaining relatively healthy for significantly longer. The discovery was a revolutionary breakthrough in aging research, demonstrating that the aging process could be controlled in the laboratory, and sparked more research into the molecular biology of aging.[59][60]
1995 Method for detection of
senescent cells using a cytochemical assay.[61]
1997 The absolute record for the duration of human life. The French woman
Jeanne Calment lived 122 years and 164 days (the record is still held).
1998 A record for the duration of life among males. The Danish-American
Christian Mortensen lived 115 years and 252 days.
1999 Establishment of the
Buck Institute for Research on Aging – the first institute originally established primarily to study intervention into the aging process.
1999Sierra Sciences, a biotechnology company focused on aging research with the goal of curing human aging, was founded by
William H. Andrews.
21st century
The research activity has increased. There is a shift of focus of the scientific community from the passive study of aging and theorizing to research aimed at intervening in the aging process to extend the lives of organisms beyond their
genetic limits. Scientific-commercial companies appear, which aim to create practical technologies for
measuring the biological age of a person (in contrast to chronological age) and extend the life of people to a greater extend than the
healthy lifestyle and
preventive medicine can provide. In society and media there are discussions not only about whether a significant prolongation of life is physically possible, but also whether it is appropriate, about the possibility of officially classifying aging as a disease, and about the possibility of mass testing on human volunteers.
2003 First evidence that aging of
nematodes is regulated via
TOR signaling.[30][63]
2003 Andrzej Bartke created a mouse that lived 1,819 days (8 days short of 5 years), while the maximum lifespan for this species is 1,030–1,070 days.[2] By human standards, such longevity is equivalent to about 180 years.[64]
2004 Aubrey de Grey coined the term "
longevity escape velocity" (LEV).[66] Though the concept per se has been present in the life extension community since at least the 1970s (for example,
Robert Wilson, essay Next Stop, Immortality, 1978[67]).
2004 As a result of the use of anti-aging therapy, a team of scientists led by Stephen Spindler managed to extend the life of a group of already adult mice to an average of 3.5 years. For this achievement, the first Methuselah Mouse Rejuvenation 'M Prize' was awarded.[68]
2004 Creation of the first curated
database of genes related to human ageing:
GenAge.[69]
2006 Creation of
induced stem cells (iSC) from somatic cells by the simultaneous action of several factors. First produced by the Japanese scientist
Shinya Yamanaka.[70][71][72] In 2012, Shinya Yamanaka and
John Gurdon received the
Nobel Prize for their work on reprogramming mature cells into pluripotent cells.[73]
2007 Extension of mouse lifespan via deletion of
insulin receptor in the brain.[30][74]
2007 The book Ending Aging written by Aubrey de Grey and his research assistant Michael Rae.
2008 (approximately) It was observed that different variants of
FOXO3 gene are associated with human longevity. Since then, research has been conducted to better understand its functions and the mechanism of action.[76][77][78][79]
2009 Association of genetic variants in
insulin/
IGF1 signaling with human longevity.[30][80]
2009 A second pharmacological agent (namely,
rapamycin) was shown to be capable to increase the lifespan of mice. For this discovery Davе Sharp receive a special prize from the Methuselah Foundation.[30][81][82]
2012 It was discovered that protein
Sirtuin 6 (SIRT6) regulates the lifespan of male mice (but not female mice).[30][84]
2013 The pan-tissue
Epigenetic clock is a molecular biomarker by
Steve Horvath that facilitates the measurement of the age of all human tissues based on cytosine methylation.[85]
2013 The scientific journal Cell published the article "The Hallmarks of Aging", that was translated to several languages and determined the directions of many studies.[86]
2013 A record for the duration of life among males. Japanese
Jiroemon Kimura lived 116 years and 54 days (that is 167 days longer than the previous record).
2013 It was discovered that brain-specific overexpression of
Sirtuin 1 (SIRT1) is also capable to extend lifespan and delay aging in mice.[30][87]
2013 Google and other investors created the company
Calico to combat aging and related diseases. Investors provided Calico with more than a billion dollars of funding.
Arthur Levinson became CEO of the company and one of its investors.[88][89][90][91]
2014 Establishment of the
Dog Aging Project at the
University of Washington, a decade-long study of aging in dogs which includes clinical trials of
rapamycin in some of them to test its effects on lifespan, with the project's ultimate goal being to translate the results into further understanding aging in humans and ways to target it.
2010s second half The emergence of official discussions about the possibility of recognizing aging
as a disease.[94][95][96][97][98]
2016 It was found that the replenishment of
NAD+ in the organism of mice through precursor molecules improves the functioning of
mitochondria and
stem cells, and also leads to an increase in their lifespan.[30][99] One of these NAD+ precursor molecules is
NMN.[100][101]
2016 Demonstration that a combination of longevity associated drugs can additively extend lifespan, at least in mice.[30][102]
2016 As part of the implementation of the
SENS programs, researchers managed to make two mitochondrial genes,
ATP8 and
ATP6, stably express from the cell nucleus in the cell culture.[103]
2016 Scientists show that expressing
Yamanakareprogramming factors in mice with premature aging can extend their lifespan by about 20%.[104][105][106]
2017 The discovery that a naturally occurring
polymorphism in human signaling pathways is in some cases associated with health and longevity. It was also detected that, the same as in mice, this association can depend on the sex (it can be observed for one sex but not for another). This indicates that by correctly influencing these pathways, it is theoretically possible to alter lifespan and healthspan in humans.[30][107]
2017AgeX Therapeutics, a biotechnology company focused on medical therapeutics related to longevity, was founded.
2018 The
Nobel Prize for cancer research was awarded to
James Allison and
Tasuku Honjo.[108] (The main cause of cancer is the accumulation of
errors in DNA. So the topic of cancer research is closely related to research on aging.)
2018 The
World Health Organization included in the international classification of diseases
ICD-11 a special additional code XT9T, signaling the relationship of a disease with age. Due to this, after the final approval of the ICD-11 in May 2019, aging began to be officially recognized as a fundamental factor that increases the risk of diseases, the severity of their course and the difficulty of treatment.[96][109][110][111][112]
2019
The lifespan of Caenorhabditis elegans (free-living
nematodes) was increased by 5–6 times (by 400–500%) using simultaneous impact in
IIS and
TOR pathways. This is equivalent to how a human would live 400–500 years.[113][114][115][116]
Scientists at the
Mayo Clinic report the first successful use of
senolytics, a new class of drug with potential anti-aging benefits, to remove
senescent cells from human patients with a kidney disease.[117][118]
Researchers at Harvard Medical School identify a link between neural activity and human longevity. Neural excitation is linked to shorter life, while suppression of overactivity appears to extend lifespan.[121][122]
Scientists report that after mice exercise their livers secrete the protein
GPLD1, which is also elevated in elderly humans who exercise regularly, that this is associated with improved cognitive function in aged mice and that increasing the amount of GPLD1 produced by the mouse liver in old mice could yield many
benefits of regular exercise for their brains – such as increased BDNF-levels, neurogenesis, and improved cognitive functioning in tests.[126][127]
Scientists report that yeast cells of the same genetic material and within the same environment age in two distinct ways, describe a biomolecular mechanism that can determine which process dominates during aging and
genetically engineer a novel aging route with substantially extended lifespan.[128][129]
A study shows that
reprogramming induced with the OSK-genes can restore youthful epigenetic patterns as well as revert age-related vision loss.[134][135]
Scientists demonstrate a tool to calculate a person's
inflammatory age (iAge) based on patterns of systemic age-related inflammation and identify
cytokineCXCL9 as a key suppression target.[142][143]
A study highlight the importance of
extending healthspans, not just lifespans and especially as life expectancy rises and demographics shift.[151] Biological aging or the healthspan-lifespan gap (LHG) comes with a great cost burden to society, including potentially rising health care costs (also depending on types and
costs of treatments).[151][152] Scientists have noted that "
[c]hronic diseases of aging are increasing and are inflicting untold costs on human quality of life".[152] Further reasons to prioritize healthspans as much as lifespans include global
quality of life or
wellbeing.[151]
A
scientific review concludes that accumulating data suggests
dietary restriction (DR) – mainly
intermittent fasting and
caloric restriction – results in many of the same beneficial changes in adult humans as in studied organisms, potentially
increasing health- and lifespan.[153][154] A review published a few days later provides an overview of DR as an intervention and develops a framework for a proposed field of "
precision nutrigeroscience".[155][156] A study published a few days later identifies
circadian-regulatedautophagy as a critical contributor to intermittent time-restricted fasting-mediated lifespan extension in Drosophila and suggests that only certain forms of and/or combinations with intermittent fasting – intervals during which no food but only e.g. water and tea/coffee are ingested[157] – may be effective beyond the benefits of healthy body weight.[158][159]
Results from the first controlled trial of
caloric restriction in healthy non-obese humans,
CALERIE, are published, confirming benefits and identifying a key protein that could be harnessed to extend health in humans,
PLA2G7.[168][169]
A study shows that 50+ aged users of the dietary program
SNAP "had about 2 fewer years of
cognitive aging over a 10-year period compared with non-users" despite it having nearly no conditions for the
sustainability and
healthiness of the food products purchased with the
coupons (or coupon-credits).[174][175]
Researchers report that the widely used
supplementsglycine and
NAC when combined as "GlyNAC", which previously showed various beneficial effects in humans i.a. in a small trial by the authors,[180]can extend lifespan by 24% in mice when taken at old age.[181][182]
A study reports that in model animals, treatment with
rapamycin – which typically has negative side-effects – for a limited timespan extended lifespan as much as life-long administration started at the same age and that it was most effective during early adulthood.[185][186]
Biological and biotechnical rejuvenation-related results
Scientists reversed aging in human skin cells for over 30 years by partially reprogramming them with the
Yamanaka factors, working better than previous reprogramming methods.[189][190]
A first spatiotemporal map reveals key insights about
axolotl brain regeneration.[194][195]Axolotls retain regenerative capacity in their aging throughout their lives.[196] It is thought that by "understanding the mechanisms of regeneration, we eventually will be able to enhance our intrinsic regenerative abilities in order to slow and even reverse the damage of aging."[197]
Researchers describe a way by which the aging of select
immune system
T cells can be prevented or is slowed down, with relevance to life extension and making vaccines more durable.[207][208]
Scientists report that some apparently
senescent cells – which are targeted by anti-aging
senolytics – are required for regeneration, and suggest tailoring senolytics to precisely target harmful senescent cells while leaving the ones involved in regeneration intact.[211][212]
A study indicates that aging shifts activity toward short genes or shorter transcript length and that this can be countered by interventions.[213][214]
Saudi Arabia has started a not-for-profit organization called "the Hevolution Foundation" with budget $1 billion per year for developing anti-aging technology.[222][223][224]
2023
Nutrition-related results
A study reports results of the first
longevitycaloric restriction (CR) trial,
CALERIE, finding that two years of nonintermittent CR slowed the pace of aging as measured by one of three
aging clocks (modest DunedinPACE effects).[226][227]
Development and application of aging clocks and combination therapies
A study reports the development of
deep learning software using anatomic magnetic resonance images to estimate
brain age with the highest accuracy for AI so far, including detecting early signs of Alzheimer's disease and varying
neuroanatomical patterns of neurological aging.[228][229]
The pan-mammalian
epigenetic clock is a molecular biomarker designed to measure the age of all mammalian tissues and species using cytosine methylation in highly conserved DNA regions.[235]
A study indicates
chest radiographs evaluated using AI could be a performant biomarker for aging clocks.[236]
A study using plasma proteomics aging clocks suggests nearly 20% of the population may show strongly accelerated age in one of 11 major organs, which it links to higher mortality risk.[237]
Biological and biotechnical rejuvenation-related results
In January, a team led by
David Sinclair shows in a 13-year-long international study how
DNA breaks or epigenetic damage are a major driver of
epigenetic change, and how the loss of epigenetic information is a cause of
aging in mammals. It concluded that the loss of epigenetic information can drive aging independently of changes to the genetic code, suggesting that epigenetic change is a primary driver of aging in mammals. Using a treatment based on
Yamanaka factors, they demonstrate an ability to drive aging in both the forward and reverse directions in mice.[238][239][240]
In a
preprint, another team of researchers of the biotechnology company
Rejuvenate Bio also reports the use of Yamanaka-
reprogramming to modestly extend the lives of elderly mice. However, if it was also applicable to humans, risks may include the formation of cancer.[239][241][242]
In July, the David Sinclair team at
Harvard Medical School release a study that claims to have discovered the first known chemical approach to reprogram cells to a younger state by delivering the Yamanaka factors directly, whereas previously this had only been achievable via gene therapy.[243]
A study identifies low levels of
taurine, which declines with age, as a driver of the aging process and suggests that taurine supplements may increase lifespan.[249]
Ora Biomedical announces the "million molecule challenge", an effort to assess 1 million potential longevity interventions within five years using
artificial intelligence.[250]
A study suggests chemical alternatives to
age reversal via
Yamanaka factors gene therapy are feasible via early in vitrofibroblasts data. These results have not yet been validated in an animal and via more reliable "improvements in age-related health metrics or lifespan".[251][needs update]
A study concludes that
retroviruses in the
human genomes can become awakened from dormant states and, in senescent cells and aged tissue, contribute to aging which can be blocked by
neutralizing antibodies, resulting in improved function.[256][257]
A previously unknown cell mechanism involved in
aging is discovered, which explains how cells 'remember' their identity when they divide – the cells' so-called
epigenetic memory.[260][additional citation(s) needed]
A team of scientists from
New York University identifies a potential cause of greying hair with age as the failure of
melanocyte stem cells to mature with age. The study was carried out using mice, which have identical cells for their fur. According to the research team, the results could provide a basis for reversing the hair greying process.[261][262]
Scientists at the
University of Colorado report what they believe to be the primary mechanism behind cognitive decline in aging, the mis-regulation of the brain protein
CaMKII.[268]
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News article mentioning this and other studies:
"How Old Are You, Really? New Tests Want to Tell You". WIRED. Retrieved 28 March 2023. These clocks were meant to be used by researchers to test the antiaging effects of drugs or lifestyle changes in animals or people. Indeed, studies have shown that people who test as biologically older than their chronological age are at increased risk of certain diseases and death. But companies have since sprung up to make clocks of their own or adapt existing ones into direct-to-consumer tests.
^"blueprint". blueprint.bryanjohnson.co. Retrieved 28 March 2023.
Stambler I (June 2014). "The unexpected outcomes of anti-aging, rejuvenation, and life extension studies: an origin of modern therapies". Rejuvenation Research. 17 (3): 297–305.
doi:
10.1089/rej.2013.1527.
PMID24524368.