Non-invasive integrative analysis of contraction energetics in intact beating heart

The comprehensive study of human pathologies has revealed the complexity of the interactions involved in cardiovascular physiology. The recent validation of system's biology approaches – like our Modular Control and Regulation Analysis (MoCA) – motivates the current interest for new integrative...

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Published in:The international journal of biochemistry & cell biology 2013-01, Vol.45 (1), p.4-10
Main Authors: Deschodt-Arsac, Véronique, Calmettes, Guillaume, Gouspillou, Gilles, Chapolard, Mathilde, Raffard, Gérard, Rouland, Richard, Jais, Pierre, Haissaguerre, Michel, Dos Santos, Pierre, Diolez, Philippe
Format: Article
Language:English
Subjects:
Adaptation, Physiological
Adrenaline
Animals
Biochemistry
Bioenergetics
Biology
Calcium
cell biology
Control
Control systems
drugs
elasticities
energy
Energy Metabolism
Heart
Heart - physiology
Human
Human pathology
Humans
Levosimendan
magnetic resonance imaging
Mitochondria, Heart - physiology
Modular
Modular control and regulation analysis
Myocardial Contraction - physiology
Myocardium - metabolism
Non-invasive 31P NMR
nuclear magnetic resonance spectroscopy
Perfused heart
physiology
System's biology
therapeutics
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Summary:The comprehensive study of human pathologies has revealed the complexity of the interactions involved in cardiovascular physiology. The recent validation of system's biology approaches – like our Modular Control and Regulation Analysis (MoCA) – motivates the current interest for new integrative and non-invasive analyses that could be used for medical study of human heart contraction energetics. By considering heart energetics as a supply–demand system, MoCA gives access to integrated organ function and brings out a new type of information, the “elasticities”, which describe in situ the regulation of both energy demand and supply by cellular energetic status. These regulations determine the internal control of contraction energetics and may therefore be a key to the understanding of the links between molecular events in pathologies and whole organ function/dysfunction. A wider application to the effects of cardiac drugs in conjunction with the direct study of heart pathologies may be considered in the near future. MoCA can potentially be used not only to detect the origin of the defects associated with the pathology (elasticity analyses), but also to provide a quantitative description of how these defects influence global heart function (regulation analysis) and therefore open new therapeutic perspectives. Several key examples of current applications to intact isolated beating heart are presented in this paper. The future application to human pathologies will require the use of non-invasive NMR techniques for the simultaneous measurement of energy status (31P NMR) and heart contractile activity (3D MRI). This article is part of a Directed Issue entitled: Bioenergetic dysfunction, adaptation and therapy.
ISSN:1357-2725
1878-5875
DOI:10.1016/j.biocel.2012.07.007