生物应激作为自然规律:文献综述

C. Cortez, Dílson Silva
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引用次数: 0

摘要

本文试图用物理学现象学的观点,将生物应力的概念近似于物理学中的应力概念,探讨生物应力状态产生力的来源。在文献的基础上,对这两个概念进行了比较,并对开放系统中的稳态和生物系统中的稳态进行了讨论。利用热力学熵和信息熵的概念,并比较生命系统和非生命系统中的压力,我们试图建立一个基础,将压力视为与物质的适应性属性相关的自然原理,而不是熵。众所周知,在一个复杂系统中可能的微态数量的增加会增加熵。在这种情况下,熵与指定系统的确切物理状态所需的附加信息的数量有关,给定其宏观规格。通过控制代谢过程(分解代谢-合成代谢)来减少熵,压力减少了生命系统可能进化的状态的数量,避免了“生命信息”的丢失,保留了生命的特征,防止了生命的灭绝。生态系统中一个物种的功能丧失或器官中细胞的功能丧失可能表明压力原理的极限被“超越”了。即压力的强度和/或持续时间超过了生物体处理从压力源中提取的信息并重新编程其生理机制的能力,激活其适应过程,同时保持其内部平衡。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Biological Stress as a Principle of Nature: A Review of Literature
This review paper attempts to approximate the concept of biological stress to the stress concept in Physics using the phenomenological view of physics to discuss the source of generator forces of biological stress state. Based on the literature, parallels are drawn between the two concepts and a discussion on the steady state in open systems and homeostatic state in biological systems is developed. Using the concepts of thermodynamic entropy and informational entropy, and comparing stress in living systems and nonliving, we attempt to build a basis for a view of stress as a principle of nature linked to the adaptability property of matter, opposing entropy. It is known that the increasing number of microstates possible in a complex system increases the entropy. In that way, entropy is related to the amount of additional information needed to specify the exact physical state of a system, given its macroscopic specification. By controlling the metabolic processes (catabolism-anabolism) to decrease the entropy, stress reduces the number of possible states for which the living system could evolve, avoiding the loss of “life information”, preserving its characteristics and preventing its extinction. The loss of function of a species within an ecosystem or of cells within an organ can be showing that the limits of the stress principle were “transgressed”. That is, the intensity and/or duration of stress exceeded the capacity of living organism to process of information extracted from stressor and reprogram its physiological mechanisms, activating its adaptability process, while its internal balance is preserved.
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