Thermodynamics and Inflammation: Insights into Quantum Biology and Ageing

Q2 Physics and Astronomy
A. Nunn, G. Guy, Julie Dee Bell
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引用次数: 5

Abstract

Inflammation as a biological concept has been around a long time and derives from the Latin “to set on fire” and refers to the redness and heat, and usually swelling, which accompanies injury and infection. Chronic inflammation is also associated with ageing and is described by the term “inflammaging”. Likewise, the biological concept of hormesis, in the guise of what “does not kill you, makes you stronger”, has long been recognized, but in contrast, seems to have anti-inflammatory and age-slowing characteristics. As both phenomena act to restore homeostasis, they may share some common underlying principles. Thermodynamics describes the relationship between heat and energy, but is also intimately related to quantum mechanics. Life can be viewed as a series of self-renewing dissipative structures existing far from equilibrium as vortexes of “negentropy” that ages and dies; but, through reproduction and speciation, new robust structures are created, enabling life to adapt and continue in response to ever changing environments. In short, life can be viewed as a natural consequence of thermodynamics to dissipate energy to restore equilibrium; each component of this system is replaceable. However, at the molecular level, there is perhaps a deeper question: is life dependent on, or has it enhanced, quantum effects in space and time beyond those normally expected at the atomistic scale and temperatures that life operates at? There is some evidence it has. Certainly, the dissipative adaptive mechanism described by thermodynamics is now being extended into the quantum realm. Fascinating though this topic is, does exploring the relationship between quantum mechanics, thermodynamics, and biology give us a greater insight into ageing and, thus, medicine? It could be said that hormesis and inflammation are expressions of thermodynamic and quantum principles that control ageing via natural selection that could operate at all scales of life. Inflammation could be viewed as a mechanism to remove inefficient systems in response to stress to enable rebuilding of more functional dissipative structures, and hormesis as the process describing the ability to adapt; underlying this is the manipulation of fundamental quantum principles. Defining what “quantum biological normality” is has been a long-term problem, but perhaps we do not need to, as it is simply an expression of one end of the normal quantum mechanical spectrum, implying that biology could inform us as to how we can define the quantum world.
热力学与炎症:量子生物学与衰老
炎症作为一个生物学概念已经存在很长时间了,起源于拉丁语“放火”,指的是伴随损伤和感染的红肿,通常是肿胀。慢性炎症也与衰老有关,被称为“炎症”。同样,以“不会杀死你,让你更强壮”为幌子的兴奋症的生物学概念早已得到认可,但相比之下,它似乎具有抗炎和延缓衰老的特征。由于这两种现象都有恢复体内平衡的作用,它们可能有一些共同的基本原理。热力学描述热量和能量之间的关系,但也与量子力学密切相关。生命可以被视为一系列自我更新的耗散结构,这些耗散结构作为“负熵”的旋涡存在于远离平衡的地方,并随着年龄的增长而消亡;但是,通过繁殖和物种形成,新的坚固结构被创造出来,使生命能够适应并继续应对不断变化的环境。简而言之,生命可以被视为热力学耗散能量以恢复平衡的自然结果;这个系统的每个部件都是可更换的。然而,在分子水平上,也许还有一个更深层次的问题:生命在空间和时间上是否依赖于量子效应,或者它是否增强了量子效应,超过了在原子尺度和生命运行温度下通常预期的量子效应?它有一些证据。当然,热力学描述的耗散自适应机制现在正在扩展到量子领域。尽管这个话题很有趣,但探索量子力学、热力学和生物学之间的关系是否能让我们对衰老以及医学有更深入的了解?可以说,兴奋和炎症是热力学和量子原理的表达,这些原理通过自然选择控制衰老,可以在生命的各个阶段发挥作用。炎症可以被视为一种机制,以消除对压力的低效系统,从而重建更具功能的耗散结构,而兴奋是描述适应能力的过程;这背后是对基本量子原理的操纵。定义什么是“量子生物学常态”一直是一个长期的问题,但也许我们不需要这样做,因为它只是正常量子力学光谱一端的表达,这意味着生物学可以告诉我们如何定义量子世界。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Quantum Reports
Quantum Reports Physics and Astronomy-Physics and Astronomy (miscellaneous)
CiteScore
3.30
自引率
0.00%
发文量
33
审稿时长
10 weeks
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