Chappell M A, Payne S J
Department of Engineering Science, University of Oxford, Parks Road, Oxford OX1 3PJ, UK.
Respir Physiol Neurobiol. 2006 Sep 28;153(2):166-80. doi: 10.1016/j.resp.2005.10.006. Epub 2005 Nov 22.
Moving bubbles have been observed in the blood during or after decompression using ultrasonic techniques. It has been proposed that these may grow from nuclei housed on the blood vessel wall. One candidate for bubble nucleation is hydrophobic crevices. This work explores the growth of gas pockets that might exist in conical crevices and the release of bubbles from these crevices under decompression. An existing dynamic mathematical model for the stability of gas pockets in crevices [Chappell, M.A., Payne, S.J., in press. A physiological model of gas pockets in crevices and their behavior under compression. Respir. Physiol. Neurobiol.] is extended to include the behavior as the gas pocket reaches the crevice mouth and bubbles seed into the bloodstream. The behavior of the crevice bubble is explored for a single inert gas, both alone and with metabolic gases included. It was found that the presence of metabolic gases has a significant effect on the behavior under decompression and that this appears to be due to the high diffusivity of these gases.
在减压过程中或减压后,利用超声技术已观察到血液中有移动的气泡。有人提出,这些气泡可能从血管壁上的核生长而来。气泡成核的一个候选因素是疏水裂缝。这项工作探讨了可能存在于锥形裂缝中的气穴的生长以及在减压情况下这些裂缝中气泡的释放。一个现有的关于裂缝中气穴稳定性的动态数学模型[查佩尔,M.A.,佩恩,S.J.,即将发表。裂缝中气穴的生理模型及其在压缩下的行为。呼吸生理学与神经生物学]被扩展,以包括气穴到达裂缝口且气泡进入血流时的行为。针对单一惰性气体,分别研究了有代谢气体和无代谢气体时裂缝气泡的行为。研究发现,代谢气体的存在对减压情况下的行为有显著影响,这似乎是由于这些气体的高扩散性所致。