Wagner diagram for modeling O2pathway-calculation and graphical display by the Helsinki O2Pathway Tool.

IF 2.3 4区 医学 Q3 BIOPHYSICS
Antti-Pekka E Rissanen, Tom Mikkola, Dominique D Gagnon, Elias Lehtonen, Sakari Lukkarinen, Juha E Peltonen
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引用次数: 0

Abstract

Objective.Maximal O2uptake (V˙O2max) reflects the individual's maximal rate of O2transport and utilization through the integrated whole-body pathway composed of the lungs, heart, blood, circulation, and metabolically active tissues. As such,V˙O2maxis strongly associated with physical capacity as well as overall health and thus acts as one predictor of physical performance and as a vital sign in determination of status and progress of numerous clinical conditions. Quantifying the contribution of single parts of the multistep O2pathway toV˙O2maxprovides mechanistic insights into exercise (in)tolerance and into therapy-, training-, or disuse-induced adaptations at individual or group levels. We developed a desktop application (Helsinki O2Pathway Tool-HO2PT) to model numerical and graphical display of the O2pathway based on the 'Wagner diagram' originally formulated by Peter D. Wagner and his colleagues.Approach.The HO2PT was developed and programmed in Python to integrate the Fick principle and Fick's law of diffusion into a computational system to import, calculate, graphically display, and export variables of the Wagner diagram.Main results.The HO2PT models O2pathway both numerically and graphically according to the Wagner diagram and pertains to conditions under which the mitochondrial oxidative capacity of metabolically active tissues exceeds the capacity of the O2transport system to deliver O2to the mitochondria. The tool is based on the Python open source code and libraries and freely and publicly available online for Windows, macOS, and Linux operating systems.Significance.The HO2PT offers a novel functional and demonstrative platform for those interested in examiningV˙O2maxand its determinants by using the Wagner diagram. It will improve access to and usability of Wagner's and his colleagues' integrated physiological model and thereby benefit users across the wide spectrum of contexts such as scientific research, education, exercise testing, sports coaching, and clinical medicine.

O2pathway 建模的瓦格纳图 - 赫尔辛基 O2pathway 工具的计算和图形显示。
目标:最大氧气摄入量(V.̇O2max)反映了个体通过由肺、心脏、血液、循环和代谢活跃组织组成的全身综合途径运输和利用氧气的最大速率。因此,最大容氧量与体能和整体健康密切相关,是预测体能表现的指标之一,也是确定许多临床疾病的状态和进展的重要标志。量化多步氧途径中单个部分对 V̇O2max 的贡献,可以从机理上深入了解运动(不)耐受性以及治疗、训练或失用引起的个体或群体适应性。我们根据彼得-瓦格纳(Peter D. Wagner)及其同事最初制定的 "瓦格纳图",开发了一个桌面应用程序(赫尔辛基氧气通路工具--HO2PT),以数字和图形显示氧气通路模型:HO2PT 是用 Python 开发和编程的,它将费克原理和费克扩散定律整合到一个计算系统中,以导入、计算、图形显示和导出瓦格纳图的变量:HO2PT 根据瓦格纳图对 O2 途径进行数值和图形建模,适用于代谢活跃组织的线粒体氧化能力超过 O2 转运系统向线粒体输送 O2 的能力的情况。该工具基于 Python 开源代码和库,可免费在线公开使用,适用于 Windows、macOS 和 Linux 操作系统:HO2PT 为有兴趣使用瓦格纳图研究 V̇O2max 及其决定因素的人提供了一个新颖的功能性和演示性平台。它将提高瓦格纳及其同事的综合生理模型的可访问性和可用性,从而使科学研究、教育、运动测试、体育教练和临床医学等广泛领域的用户受益。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Physiological measurement
Physiological measurement 生物-工程:生物医学
CiteScore
5.50
自引率
9.40%
发文量
124
审稿时长
3 months
期刊介绍: Physiological Measurement publishes papers about the quantitative assessment and visualization of physiological function in clinical research and practice, with an emphasis on the development of new methods of measurement and their validation. Papers are published on topics including: applied physiology in illness and health electrical bioimpedance, optical and acoustic measurement techniques advanced methods of time series and other data analysis biomedical and clinical engineering in-patient and ambulatory monitoring point-of-care technologies novel clinical measurements of cardiovascular, neurological, and musculoskeletal systems. measurements in molecular, cellular and organ physiology and electrophysiology physiological modeling and simulation novel biomedical sensors, instruments, devices and systems measurement standards and guidelines.
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