[生物电生成的分子方面]。

E Schoffeniels
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引用次数: 1

摘要

动作电位是一个耗散过程,产生熵并使用自由能。这一点在以下几个方面得到了很好的证明:1)电压箝位条件下Na电导的演变,2)微热测量,3)电导变化过程中的热演变分析。最合适的解释必须涉及外源能量,因为离子流耗散的能量甚至应用刺激去极化都太小,无法解释整体能量平衡。三磷酸硫胺素可能是一种特殊操作物质。更重要的是,因为它是由三磷酸酶特异性水解,其活性由各种阴离子调节。因此,我们认为控制cl -通透性是我们理解动作电位能量学的关键,这一过程需要三磷酸硫胺素的水解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
[Molecular aspects of bioelectrogenesis].

The action potential is a dissipative process producing entropy and using free energy. This is well demonstrated by: 1) the evolution of the Na conductance under voltage clamping conditions, 2) the microcalorimetric measurements, 3) the analysis of heat evolution during the conductance changes. The most appropriate explanation must involve an exogenous energy source since the energy dissipated by the ionic flows or even the applied stimulus depolarization are far too small to account for the overall energy balance. Thiamine triphosphate is a likely candidate as specific operating substance. The more so, since it is specifically hydrolyzed by a triphosphatase the activity of which is modulated by various anions. It is therefore suggested that the control of the Cl-permeability, a process requiring the hydrolysis of thiamine triphosphate, is the key to our understanding of the energetics of the action potential.

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