用于解决溶解气体对组织代谢的浓度依赖性影响的流体制备系统。

Fluidics system for resolving concentration-dependent effects of dissolved gases on tissue metabolism.

机构信息

University of Washington Medicine Diabetes Institute, University of Washington, Seattle, United States.

Department of Biochemistry, University of Washington, Seattle, United States.

出版信息

Elife. 2021 Nov 4;10:e66716. doi: 10.7554/eLife.66716.

DOI:10.7554/eLife.66716

PMID:34734803

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8660022/

Abstract

Oxygen (O) and other dissolved gases such as the gasotransmitters HS, CO, and NO affect cell metabolism and function. To evaluate effects of dissolved gases on processes in tissue, we developed a fluidics system that controls dissolved gases while simultaneously measuring parameters of electron transport, metabolism, and secretory function. We use pancreatic islets, retina, and liver from rodents to highlight its ability to assess effects of O and HS. Protocols aimed at emulating hypoxia-reperfusion conditions resolved a previously unrecognized transient spike in O consumption rate (OCR) following replenishment of O, and tissue-specific recovery of OCR following hypoxia. The system revealed both inhibitory and stimulatory effects of HS on insulin secretion rate from isolated islets. The unique ability of this new system to quantify metabolic state and cell function in response to precise changes in dissolved gases provides a powerful platform for cell physiologists to study a wide range of disease states.

摘要

氧气 (O) 和其他溶解气体，如气体递质 HS、CO 和 NO，会影响细胞代谢和功能。为了评估溶解气体对组织内过程的影响，我们开发了一种流体系统，该系统可控制溶解气体，同时测量电子传输、代谢和分泌功能的参数。我们使用来自啮齿动物的胰岛、视网膜和肝脏来突出其评估 O 和 HS 影响的能力。旨在模拟缺氧再灌注条件的方案解决了 O 消耗率 (OCR) 在补充 O 后出现的先前未被认识到的短暂尖峰，以及缺氧后 OCR 的组织特异性恢复。该系统揭示了 HS 对分离胰岛中胰岛素分泌率的抑制和刺激作用。这种新系统具有独特的能力，可以定量测量代谢状态和细胞功能对溶解气体精确变化的反应，为细胞生理学家研究广泛的疾病状态提供了强大的平台。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6814/8660022/7bb521e147d2/elife-66716-fig1.jpg

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用于解决溶解气体对组织代谢的浓度依赖性影响的流体制备系统。

Fluidics system for resolving concentration-dependent effects of dissolved gases on tissue metabolism.

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