31P光谱模量(PSM)作为代谢状态的测定。

IF 4.3 3区 生物学 Q1 BIOLOGY Biology-Basel Pub Date : 2025-02-02 DOI:10.3390/biology14020152
Jack V Greiner, Tamara I Snogren, Thomas Glonek
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引用次数: 0

摘要

磷-31 (31P)光谱模量(PSM)是衡量细胞、组织和器官代谢状态的指标。PSM可以通过从细胞、组织或器官制备中获得的31P核磁共振(31P NMR)谱来计算。这些31P核磁共振光谱可以测量完整的活细胞,组织或器官,或这些制剂的适当生化提取物。31P核磁共振谱由来自有机磷代谢物的信号组成,这些信号在磷化学位移δ尺度上从10 δ到-25 δ共振。PSM是高能磷酸盐与低能磷酸盐光谱积分的比值。这些积分可以方便地分为高能和低能光谱区域,分别在-0.13 δ到-25 δ和10 δ到-0.13 δ之间的31P化学位移。高能磷酸盐通常被描述为提供细胞代谢活动所需的能量;化学上,它们含有一个或多个磷酸酐键。本研究表明,(1)一般情况下,代谢活性越高,PSM越高;(2)模量计算不需要高分辨率的31P谱,可以单独从积分中计算。计算正常、病变和应激的细胞、组织和器官的PSM。在患病(平均1.29±0.73)和应激(平均1.23±0.75)细胞、组织和器官中,PSM值相对于正常细胞、组织或器官(平均1.65±0.90)通常较低或较低,根据时间过程测量,处于动态下降状态。PSM可用于确定细胞、组织或器官的代谢状态,并可作为一种可计算的数值分析,用于确定静态或随时间变化的健康状态。采用低信噪比谱进行PSM计算;它依赖于检测具有清晰的光谱积分拐点(约-0.13 δ)的积分曲线所需的最小分辨率。即使在磷浓度低到无法检测单个或组代谢物(如体内或离体细胞、组织或器官测定)的水平,单独检测积分曲线也可以计算出PSM。本研究(1)介绍了PSM的基础和基本原理,PSM是组织代谢健康的活指数,(2)展示了光谱扫描分析在生物学和医学上的新应用,可以在一系列可检测的水平上测量应激和病变组织的代谢状态,以监测治疗干预措施。
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The 31P Spectral Modulus (PSM) as an Assay of Metabolic Status.

The phosphorus-31 (31P) spectral modulus (PSM) is a measure of the metabolic status of cells, tissues, and organs. The PSM can be calculated from 31P nuclear magnetic resonance (31P NMR) spectra obtained from cell, tissue, or organ preparations. These 31P NMR spectra can be a measure of intact living cells, tissues, or organs, or appropriate biochemical extracts of such preparations. The 31P NMR spectrum is comprised of signals derived from organophosphate metabolites that resonate from 10 δ to -25 δ on the phosphorus chemical shift δ scale. The PSM is the ratio of the high-energy phosphate to that of the low-energy phosphate spectral integrals. These integrals may be conveniently grouped into high-energy and low-energy spectral regions, respectively, into 31P chemical shifts located between -0.13 δ to -25 δ and between 10 δ to -0.13 δ. High-energy phosphates are typically described as providing the energy necessary for the activity of cellular metabolism; chemically, they contain one or more phosphate anhydride bonds. This study demonstrates that, (1) in general, the higher the metabolic activity, the higher the PSM, and (2) the modulus calculation does not require a highly resolved 31P spectrum and can be calculated solely from the integral. The PSM was calculated among cells, tissues, and organs considered normal, diseased, and stressed. In diseased (mean 1.29 ± 0.73) and stressed (mean 1.23 ± 0.75) cells, tissues, and organs, PSM values are typically low or low relative to normal cells, tissues, or organs (mean 1.65 ± 0.90), following time-course measurements, in dynamic decline. The PSM is useful in determining the metabolic status of cells, tissues, or organs and can be employed as a calculable numeric assay for determining health status statically or over time. Calculation of the PSM can be carried out with spectra of low signal-to-noise; it relies on the minimal resolution required to detect an integral curve having a clear spectral integral inflection point at ca. -0.13 δ. Detection of an integral curve alone enables the calculation of a PSM even at levels of phosphorus concentration so low as to prevent detection of the individual or groups of metabolites, such as with in vivo or ex vivo cell, tissue, or organ determinations. This study (1) presents the foundations and fundamentals of the PSM, a living index of tissue metabolic health, and (2) demonstrates the use of spectral scan analysis in opening new vistas of biology and medicine for measuring the metabolic status of stressed and diseased tissues at a range of detectable levels for monitoring therapeutic interventions.

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Biology-Basel
Biology-Basel Biological Science-Biological Science
CiteScore
5.70
自引率
4.80%
发文量
1618
审稿时长
11 weeks
期刊介绍: Biology (ISSN 2079-7737) is an international, peer-reviewed, quick-refereeing open access journal of Biological Science published by MDPI online. It publishes reviews, research papers and communications in all areas of biology and at the interface of related disciplines. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. Electronic files regarding the full details of the experimental procedure, if unable to be published in a normal way, can be deposited as supplementary material.
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