Global ageing: challenges and perspectives

Enviar para

Título:
Global ageing: challenges and perspectives
Autor: Chereshnev, V.A. ; Khavinson, V.H. ; Mikhailova, O.N. ; Popovich, I.G. ; Chereshneva, M.V.
Bazarnyi, V. ; Kovtun, O.
Assuntos: Adaptability ; Age ; Age related diseases ; Aging ; Aging (natural) ; Allosteric properties ; Amino acids ; Antioxidants ; Antitumor activity ; Astrochemistry ; Atrophy ; Automatic control ; Biology ; Biosynthesis ; Body temperature ; Bone density ; Calcium ; Carcinogenesis ; Cardiovascular diseases ; Cell differentiation ; Circadian rhythms ; Codons ; Deoxyribonucleic acid ; Diabetes ; Diabetes mellitus ; Disease ; DNA ; Economic change ; Endocrine system ; Epigenetics ; Experimental research ; Experiments ; Food consumption ; Free radicals ; Gene regulation ; Genetic code ; Genetics ; Gerontology ; Globalization ; Heart diseases ; Homeostasis ; Immunology ; Influence ; Insulin ; International cooperation ; Kinases ; Life expectancy ; Life span ; Lipids ; Longevity ; Macromolecules ; Medical research ; Medicine ; Melatonin ; Metabolic disorders ; Metabolic syndrome ; Metabolism ; Metabolites ; Neurodegenerative diseases ; Nucleotide sequence ; Nucleotides ; Older people ; Organs ; Oxidative stress ; Peptides ; Physiology ; Population ; Population structure ; Prevention ; Protein synthesis ; Proteins ; Quality of life ; Reproductive system ; Restoration ; Retina ; Ribonucleic acid ; Risk factors ; RNA ; Sensitivity ; Signs and symptoms ; Uniqueness ; Vascular system ; Weight reduction
É parte de: BIO Web of Conferences, 2020, Vol.22, p.1001
Descrição: BIO Web of Conferences 22, 01001 (2020) Global ageing: challenges and perspectives V.A. Chereshnev1, V.H. Khavinson2, O.N. Mikhailova2*, I.G. Popovich2 and M.V. Chereshneva1 1 Institute of Immunology and Physiology, RAS Ural Branch, 620049, Pervomaiskaya st., 106, Yekaterinburg, Russia 2 St. Petersburg Institute of Bioregulation and Gerontology, 197110, Dinamo pr., 3, St. Petersburg, Russia * Corresponding author: ibg@gerontology.ru The evidence of the global population ageing elucidates major challenges and opportunities of the 21st century. The most comprehensive document on ageing which determines the contents for international collaboration and provides guidelines and recommendations for building national capacity is the Madrid International Plan of Action on Ageing (MIPAA) adopted in 2002. MIPAA has recognized population ageing as a ‘universal force that has the power to shape the future as much as globalization’ and called on the international community to ‘embrace the potential of the ageing population as a basis for future development’ [1]. The 2017 UN Report features data on the increase in life expectancy during the recent decades [2]. On the global scale, life expectancy at birth has risen by 3.6 years during 2000-2015, i.e. from 67.2 to 70.8 years. According to UN forecasts, by 2030 the population of our planet aged 60 and over will amount to 3.1 bn people. From 2000 up to 2050 , the number of people aged over 80 in the total population structure is predicted to increase from 70 mln to 401 mln, respectively. Thus, a global demographic imbalance is getting worse. In 40 years period, the number of people over 60 will exceed that of people under 15. Low birth rates and increased life expectancy in many countries are certain to cause problems in the labor market, and lack of labor resources in particular. Population ageing is one of the most important factors affecting politics in the multi-dimensional context of social and economic changes and transformations in the labor market. In this connection, the main reforms should be directed at using the potential of all generations and, particularly, that of the growing elder population. It is important to understand that the solution to the problems concerned with population ageing is only possible if all society members are aware that the citizen aged 65 and older constitute important potential for social development [3, 4]. As a rule, healthy people of older age are able to work till later age, compensating for the work force deficit caused by lower birth rate, thereby providing for the continuity of knowledge and experience of older generations. It is necessary to realize that the enhancement of the physiological resources of human vitality and healthy longevity cannot be implemented unless modern technologies are applied; programs for encouraging healthy life style are developed and implemented; educational and wellness strategies for persons of all ages are introduced; realistic approaches are implemented to financial support at the later stages in life; programs and plans concerned with ageing issues are coordinated. The ageing process must be considered not only in terms of ethical and social problems; it should be studied as a special physiological mechanism that has a certain evolutionary function. Humans species specific limit is by 30 – 40% higher than the actual average life span. The influence of various unfavorable factors on human body leads to changes in the gene expression and structure, which are accompanied by protein synthesis disruption and reduction of organism functions. Ageing has many dysfunctional levels and can be classified as a systemic syndrome [5, 6]. Ageing is characterized by the reduction of the body adaptability due to a decline in the functions of cells, systems and organs. Therefore, many researchers focus on the changes occurring in the major body systems: immune, cardio-vascular, central nervous and endocrine ones. The symptoms of ageing can be traced already at the end of the reproductive period and become more evident with further ageing. In the late 19th century, I. I. Mechnikov confirmed that improvement of cell immunity contributes to life span increase. He developed the phagocyte immunity theory in the belief that the human body has an inherent capacity to withstand pathological ageing (Nobel Prize in Physiology or Medicine shared with P. Erlich, 1908) [7]. A hundred years later, P. Doggerty and P. Zinkernagel accomplished detailed research of cell immunity specificity at viral infection, which largely confirmed Mechnikov’s conclusions (Nobel Prize in Physiology or Medicine, 1996). In 1962, D. Watson and F. Crick received a Nobel Prize in Physiology or Medicine «for the discovery of the molecular structure of nucleic acids and its role in transferring information in live tissues». In 1961, F. Jakob and J. Monod proposed a genetic regulation model of protein synthesis involving low-molecular collagen, which displaces the depressor triggering allosteric conformational transition in the DNA structure and the bacterial cell (Nobel Prize in Physiology or Medicine shared with A.Lvov, 1965) [8]. As a result of a lengthy work, M. Nirenberg and H. Khorana managed to decipher the genetic code and determine the codons (nucleotide triplets) for each of the twenty amino acids (Nobel Prize in Physiology and Medicine shared with R. Holley, 1968). Fundamental research into the biochemistry of nucleic acids and determination of the RNA and DNA sequences were accomplished in the 60-ties and 70-ties of the 20th century by P. Berg, W. Gilbert and F. Sanger (Nobel Prize in Chemistry, 1980). All these fundamental discoveries in molecular biology formed the basis for research into theoretical and experimental gerontology. It should be emphasized that application of geroprotectors to physiologically stimulate an ageing body is scientifically based on modern concepts of ageing mechanisms, which means that we can virtually influence and, to a certain extent, control human ageing process [9, 10]. Searching for new effective means of influencing an ageing body, finding the most rational combinations of geroprotective agents is a vital task. During a recent decade the achievements in theoretical and applied gerontology allowed implementing targeted regulation of age-related changes. The progress in practical medicine is obviously dependent on the research achievements in molecular medicine, i.e. genetics, molecular and cell biology which often result in creation of new medications and technologies. By now, there have been identified genes which regulate the mechanisms of individual development and occurrence of many diseases [9]. As the cell proliferation and differentiation processes are reduced with age, there is a chance of correcting these dysfunctions by monitoring gene expression. Research into the genetic mechanisms of ageing and development of age-related pathologies forms the basis for regular therapy, involving application of transcription modulators, which hinder and reverse age-related genetic changes. Development of effective bioregulators facilitating achievement of species-related life span limit and preservation of the main physiological functions is one of the most urgent problems in modern biogerontology. Of special interest is the restricted calorie diet (RCD). One of the most well-known studies is the work by L. Fontana et al. [11], which evaluated the reduction of calorie consumption in people who had been on this diet for 6 years on average, as compared to the healthy controls who had been on an ordinary diet. As a result it was established that the people who had been on a restricted calorie diet had lost weight, reduced the levels of general cholesterol, low-level lipoprotein, triglyceride, glucose, insulin, C-reactive protein, etc., as compared to the control group. These data suggests that RCD significantly reduces the risk of developing the metabolic syndrome and ischemic heart disease [12]. It was also established that the people who voluntarily restrict their food, and hence calorie consumption live longer than those who do not. Recent investigations manifested a decrease in cardio-metabolic risk factors in humans without signs of obesity who followed moderate calorie restriction. These data point out potential advantages and usefulness of the moderate caloric restriction for cardio-vascular health of young and middle-aged people [13]. One of the mechanisms providing positive effect of the restricted calorie diet is increased body sensitivity to insulin, which prevents development of a number of age-related diseases and ageing. One of the popular ageing theories is that of free radicals, proposed by D. Harman [14], who stated that over time, organisms accumulate macromolecular cell damage (of DNA, proteins and lipids), caused by free radicals, mainly by reactive oxygen forms. Accumulation of such damage causes cardio-vascular, neurodegenerative and oncological disorders, as well as age-related immunodepression and a number of other pathological changes. It is believed that reactive oxygen forms damage the membranes, collagen, DNA, chromatin, and structural proteins, and are also involved in epigenetic maintenance of nuclear and mitochondrial gene regulation, influencing the intracellular calcium level, etc. [15]. The fact that the products of reactive oxygen interaction with macromolecules persistently occur in various organs and tissues shows that the anti-oxidative systems are not effective enough and that the cells are subject to oxidative stress. Enhancement of antioxidative protection could play a substantial role in the geroprotective mechanism. Among antioxidants, a special place belongs to resveratrol, which is a vegetable polyphenole [16]. In experimental research resveratrol was shown to increase the life span of yeast, worms and flies, as well as short-living fish [17]. Resveratrol also exhibit antit
Editor: Les Ulis: EDP Sciences
Idioma: Inglês

Global ageing: challenges and perspectives

Chereshnev, V.A. ; Khavinson, V.H. ; Mikhailova, O.N. ; Popovich, I.G. ; Chereshneva, M.V. Bazarnyi, V. ; Kovtun, O.

Les Ulis: EDP Sciences

Buscando em bases de dados remotas. Favor aguardar.