概率模型的人口指标

IF 0.6 Q4 GERIATRICS & GERONTOLOGY Advances in Gerontology Pub Date : 2024-04-01 DOI:10.1134/S2079057024600307
G. A. Shilovsky, A. V. Seliverstov
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引用次数: 0

摘要

摘要-- 使用平均指标来描述死亡率动态而不考虑变异性,可能会得出平均结果,从而妨碍对死亡率大幅上升时期的生存曲线模式进行分析,尤其是在最年长或最年轻的年龄段。因此,人们越来越多地使用其他方法,而不是普遍接受的贡珀茨方法,这些方法依赖于各种人口指标的比较。在人类中,与不依赖年龄的急性凋亡不同,慢性凋亡表现为生存曲线的矩形化,由于社会、科学和技术的进步,出生时的预期寿命也同时延长。仅通过研究贡珀茨-马凯汉方程中的最优系数很难发现矩形化现象,这主要是因为不可避免的计算误差。根据预期寿命的分布计算人口指标可以避免这种情况:基菲茨熵、基尼系数和寿命变异系数。我们研究了几种死亡率随年龄增长的亚冈珀茨模型,这些模型描述了线虫和昆虫的衰老过程。在亚冈珀尔茨衰老模型中,无脊椎动物随年龄增长而增加的死亡率被量化为这些人口统计指标所估算的生存函数的矩形化。另一方面,随着科学技术的发展,生存函数的矩形化程度越来越高,这表现在凯菲兹熵的下降,以及人类预期寿命的延长,这也与哺乳动物整体死亡率随年龄增长的假说十分吻合。对老龄化模型的计算表明,使用凯菲茨熵和基尼系数作为重要的人口统计指标是有效的。使用这些指标似乎更为可取,特别是对于线虫类,它们适用于亚冈珀茨衰老模型,而对于脊椎动物,主要是哺乳动物,在某些限制条件下,则适用于冈珀茨-马凯姆定律。考虑与年龄相关的提高存活率的动态变化的方法,如研究寿命的不平衡,可增进我们对衰老机制的了解。反过来,这将有助于开发更准确的方法来评估老年学中使用的生物活性物质(如抗衰老药物和老年保护剂)的效果。
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Demographic Indicators of Probability Models

Describing mortality dynamics using average indicators without considering variability can yield average results, impeding the analysis of survival-curve patterns during periods of significant mortality spikes, especially at the oldest or youngest ages. Therefore, instead of the generally accepted Gompertz method, other methods are increasingly used, which rely on comparisons of various demographic indicators. In humans, chronic phenoptosis, in contrast to age-independent acute phenoptosis, manifests as a rectangularization of the survival curve with a simultaneous increase in the life expectancy at birth due to the advancement of social, scientific, and technological progress. Rectangularization is difficult to notice solely by examining the optimal coefficients in the Gompertz—Makeham equation, primarily because of the inevitable calculation errors. This can be avoided by calculating demographic indicators based on the spread of the life expectancy: Keyfitz entropy, Gini coefficient, and coefficient of variation of lifespan. We examine several sub-Gompertzian models of mortality growth with age, which describe the aging of nematodes and insects. Within the sub-Gompertzian model of aging, the increase in mortality with age in invertebrates is quantified as a rectangularization of the survival function estimated by these demographic indicators. On the other hand, the increasing rectangularization of the survival function with the development of scientific and technological progress, demonstrated by a decrease in the Keyfitz entropy, along with a simultaneous increase in the life expectancy in humans, also aligns well with the hypothesis of an age-dependent increase in mortality in mammals overall. Calculations on aging models demonstrate the effectiveness of using Keyfitz entropy and the Gini coefficient as important demographic indicators. The use of these indicators seems preferable, especially for nematodes, where the sub-Gompertzian model of aging is applicable, and for vertebrates, primarily mammals, with certain restrictions, the Gompertz–Makeham law is applicable. Approaches that consider dynamic age-related shifts in improved survival, such as studying imbalances in lifespan, enhance our understanding of the mechanisms of aging. This, in turn, will contribute to the development of more accurate methods for assessing the effects of biologically active substances used in gerontology, such as anti-aging drugs and geroprotectors.

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来源期刊
Advances in Gerontology
Advances in Gerontology GERIATRICS & GERONTOLOGY-
CiteScore
0.80
自引率
16.70%
发文量
45
期刊介绍: Advances in Gerontology focuses on biomedical aspects of aging. The journal also publishes original articles and reviews on progress in the following research areas: demography of aging; molecular and physiological mechanisms of aging, clinical gerontology and geriatrics, prevention of premature aging, medicosocial aspects of gerontology, and behavior and psychology of the elderly.
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