Cerebral capillary oxygen diffusion: exploring the concept of intracapillary hemoglobin conformational changes.

IF 2.8 Q2 CRITICAL CARE MEDICINE Intensive Care Medicine Experimental Pub Date : 2024-11-28 DOI:10.1186/s40635-024-00691-y

Gurgen Harutyunyan, Varsenik Harutyunyan Jaghatspanyan, Garnik Harutyunyan Jaghatspanyan, Emma Martirosyan, Artur Cherkezyan, Armen Varosyan, Suren Soghomonyan

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Abstract

The mechanisms of oxygen diffusion in brain capillaries have not been fully clarified to date. According to the laws of physics, the well-documented phenomenon of hyperoxemia-induced excessive increases in brain tissue oxygen pressure (PbtO2) contradicts traditional models of cerebral capillary oxygen diffusion. Circulating models predict a significant drop in oxygen pressure (PO2), and some of them foresee the presence of hypoxic or anoxic corners near the capillary end, regardless of high PbtO2 levels. We propose that the cerebral intracapillary transformation of hemoglobin from the relaxed (R) to the tense (T) quaternary conformational state, driven by deoxygenation and an overload of negative allosteric effectors, and characterized by a lower, more hyperbolic dissociation curve, mitigates the oxygen pressure difference across cerebral capillaries, ensuring a homogeneous pericapillary distribution of oxygen. The hemoglobin R to T state transition is responsible for the high PbtO2 levels observed in viable cerebral tissue during hyperoxemia.

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脑毛细血管氧扩散：探讨毛细血管内血红蛋白构象变化的概念。

氧在脑毛细血管中的扩散机制至今尚未完全阐明。根据物理定律，高氧血症引起的脑组织氧压（PbtO2）过度升高的现象与传统的脑毛细血管氧扩散模型相矛盾。循环模型预测了氧压（PO2）的显著下降，其中一些模型预测了在毛细血管末端附近存在缺氧或缺氧角落，而不管PbtO2水平是否高。我们认为，在脱氧和负变构效应物过载的驱动下，脑毛细血管内血红蛋白从松弛(R)到紧张(T)的四元构象状态的转变，以更低、更双曲的解离曲线为特征，减轻了脑毛细血管间的氧压差，确保了毛细血管周围均匀的氧分布。血红蛋白R到T状态的转变是高氧血症期间活脑组织中观察到的高PbtO2水平的原因。

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