Temporal Organization in Cells: A Dynamic Theory of Cellular Control ProcessesAcademic Press, 1963 - 163 pagine For the scientist with a training in physics this book will offer no difficulties. The biological background which is required is minimal, and except for certain aspects of enzymology on the one hand and embryology on the other, the exposition is self-contained. Actually the physicist will probably find the mathematical treatment definitely lacking in the rigour to which they are accustomed. The attempt has been made to steer a middle course between physics and biology, thus making the material accessible to scientists with a training on either side. |
Sommario
FOREWORD V | 1 |
SYSTEM AND ENVIRONMENT | 9 |
CONTROL SYSTEMS AND RHYTHMIC PHENOMENA IN CELLS | 16 |
Copyright | |
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Temporal Organization in Cells: A Dynamic Theory of Cellular Control Processes Brian C. Goodwin Visualizzazione estratti - 1963 |
Temporal Organization in Cells; A Dynamic Theory of Cellular Control Processes Brian C. Goodwin Anteprima non disponibile - 2018 |
Temporal Organization in Cells; A Dynamic Theory of Cellular Control Processes Brian C Goodwin Anteprima non disponibile - 2018 |
Parole e frasi comuni
activity amplitude analysis arise assumed basis becomes behaviour biochemical biological cells cellular Chapter competence complex components concentration consider considerable constant continuous control mechanisms control systems coupled defined depends described differential discussed dynamic effect energy enzyme epigenetic system equations equilibrium estimates experimental expression fact feed-back frequency function fundamental genetic give important increase integral interactions interest involved kind kinetic limit macromolecular manner mean mechanics messenger metabolic metabolite microscopic molecular molecules motion mRNA necessary non-linear observed obtained occur operating organization oscillations oscillatory parameters particular period phase phenomena physical pools population positive possible present probability procedure processes produce properties protein quantities regarded relation relaxation repression result sequence shown single species statistical mechanics steady strong structure suggest synthesis talandic temperature temporal theory thermodynamic tion values variables Y₁