We live in times of paradigmatic changes for the biological sciences. Reductionism, that for the last six decades has been the philosophical basis of biochemistry and molecular biology, is being displaced by Systems Biology, which favors the study of integrated systems. Historically, Systems Biology - defined as the higher level analysis of complex biological systems - was pioneered by Claude Bernard in physiology, Norbert Wiener with the development of cybernetics, and Erwin Schrödinger in his thermodynamic approach to the living. Systems Biology applies methods inspired by cybernetics, network analysis, and non-equilibrium dynamics of open systems. These developments follow very precisely the dialectical principles of development from thesis to antithesis to synthesis discovered by Hegel. Systems Biology opens new perspectives for studies of the integrated processes of energy metabolism in different cells. These integrated systems acquire new, system-level properties due to interaction of cellular components, such as metabolic compartmentation, channeling and functional coupling mechanisms, which are central for regulation of the energy fluxes. State of the art of these studies in the new area of Molecular System Bioenergetics is analyzed

Abraham

Agutter

Alberghina

Alekseev

Aliev

Alon

Anesti

Anmann

Appaix

Ball

Barabasi

Barros

Bassingthwaighte

Beard

Benard

Bereiter-Hahn

Bernard

Berridge

Bers

Bertrand

Bessman

Bianchi

Bing

Boogerd

Bruggeman

Capetenaki

Carafoli

Carmeliet

Carrasco

Claire Monge

Collins

Cortassa

Crawford

Dzeja

Endoh

Fawcett

Gudbjarnason

Hegel

Honda

Huang

Hunter

Jacobson

Jafri

Kaasik

Kammermeier

Karbowski

Kennedy

Kinsey

Kitano

Klipp

Korzeniewski

Kuhn

Kupriyanov

Lorenz

Mannella

Matsuoka

Matthews

McLellan

Meyer

Milner

Mitchell

Monge

Neely

Neubauer

Nicolis

Noble

Noma

Ovàdi

Pacher

Palsson

Prigogine

Pucar

Qian

Ravasz

Rita Guzun

Rizzuto

English

PubMed

International audienceWe live in times of paradigmatic changes for the biological sciences. Reductionism, that for the last six decades has been the philosophical basis of biochemistry and molecular biology, is being displaced by Systems Biology, which favors the study of integrated systems. Historically, Systems Biology - defined as the higher level analysis of complex biological systems - was pioneered by Claude Bernard in physiology, Norbert Wiener with the development of cybernetics, and Erwin Schrödinger in his thermodynamic approach to the living. Systems Biology applies methods inspired by cybernetics, network analysis, and non-equilibrium dynamics of open systems. These developments follow very precisely the dialectical principles of development from thesis to antithesis to synthesis discovered by Hegel. Systems Biology opens new perspectives for studies of the integrated processes of energy metabolism in different cells. These integrated systems acquire new, system-level properties due to interaction of cellular components, such as metabolic compartmentation, channeling and functional coupling mechanisms, which are central for regulation of the energy fluxes. State of the art of these studies in the new area of Molecular System Bioenergetics is analyzed

Saks, Valdur, A.

Monge, Claire

Guzun, Rita

Hal - Université Grenoble Alpes

Philosophical basis and some historical aspects of systems biology: from hegel to noble - applications for bioenergetic research.

Valdur Saks

Saks

Szallasi

Westerhoff

Vignais

Wiener

Schrödinger

Schneider

Wheatley

Welch

Srivastava

Weiss

Rosing

Veech

Yoshizaki

Vendelin

Selivanov

Rube

Wallimann

Seppet

Wang

Rostovtseva

Twig

Zorov

Crossref

Philosophical Basis and Some Historical Aspects of Systems Biology: From Hegel to Noble - Applications for Bioenergetic Research

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Philosophical Basis and Some Historical Aspects of Systems Biology: From Hegel to Noble - Applications for Bioenergetic Research

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