Map of epigenetic age acceleration: A worldwide analysis.

We present a systematic analysis of epigenetic age acceleration based on by far the largest collection of publicly available DNA methylation data for healthy samples (93 datasets, 23 K samples), focusing on the geographic (25 countries) and ethnic (31 ethnicities) aspects around the world. We employed the most popular epigenetic tools for assessing age acceleration and examined their quality metrics and ability to extrapolate to epigenetic data from different tissue types and age ranges different from the training data of these models. In most cases, the models proved to be inconsistent with each other and showed different signs of age acceleration, with the PhenoAge model tending to systematically underestimate and different versions of the GrimAge model tending to systematically overestimate the age prediction of healthy subjects. Referring to data availability and consistency, most countries and populations are still not represented in GEO, moreover, different datasets use different criteria for determining healthy controls. Because of this, it is difficult to fully isolate the contribution of "geography/environment", "ethnicity" and "healthiness" to epigenetic age acceleration. Among the explored metrics, only the DunedinPACE, which measures aging rate, appears to adequately reflect the standard of living and socioeconomic indicators in countries, although it has a limited application to blood methylation data only. Invariably, by epigenetic age acceleration, males age faster than females in most of the studied countries and populations.

Hypercapnic hypoxia as a potential means to extend life expectancy and improve physiological activity in mice.

The application of combined hypoxia and hypercapnia (hypercapnic hypoxia) during respiratory exercises results in a maximum increase in resistance to acute hypoxia and ischemic tolerance of the brain. The results of those researches allow the assumption that hypercapnic hypoxia is a promising method for prophylaxis, treatment, and rehabilitation, as well as a means to increase life expectancy. The study was conducted to verify the hypothesis that it is possible to extend the life span through regular courses of respiratory exercises with hypercapnic hypoxia. In the present experimental research carried out on mice, the geroprotective effect of regular hypercapnic-hypoxic exercises (PO2-90 mm Hg and PCO2-50 mm Hg) was assessed in the context of the average life expectancy and the main criteria of its quality (reproductive function, muscle strength, and behavior). Results suggest that with regular training, life span is extended significantly by 16%. This result was accompanied by improved reproductive and cognitive functions, increased motor and search activities, and physical stamina in old age mices. This important phenomenon is accompanied by improved reproductive and cognitive functions, high motor function and search activity, as well as better physical stamina in old-aged mices. Recurring respiratory training under combined hypoxia and hypercapnia (hypercapnic hypoxia) during the lifetime significantly extended the life span of mice in the experiments.