可兴奋细胞的净水分摄取是疼痛信号产生的主要机制

S. Ayrapetyan
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引用次数: 5

摘要

痛觉神经和肌肉膜的异常(过度)兴奋,这种兴奋传递到中枢神经系统并产生痛觉因此,体内细胞对水的生物等效性决定了这种现象。由于疼痛可以由不同的现象产生,从机械损伤到不同代谢途径的破坏,一定有一个共同的细胞机制,各种物理、化学和代谢因素通过这个机制使细胞膜产生异常兴奋。已知痛觉可以在极弱的化学和物理信号的作用下发生改变,其强度甚至小于热阈值,并且具有非线性剂量依赖性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The net water uptake by excitable cells is a primary mechanism for pain signal generation
An abnormal (hyper) excitation of neuronal and muscle membranes, which is transmitted into central nervous system (CNS) and generates pain sensation. Hence, the bioequivalence of the water by the cells in the body determines the phenomenon. Since pain can be generated by different phenomena, starting from mechanical damage to the breakdown of different metabolic pathways, there must be a common cellular mechanism through which various physical, chemical and metabolic factors generate abnormal excitation of cell membrane. It is known that pain sensation can be changed upon the effect of extremely weak chemical and physical signals, having intensity even less than thermal threshold and non-linear dose-dependent character.
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