Physical Forces and the Mammalian Cell

Physical Forces and the Mammalian Cell

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This book examines the physical forces - fluid shear, stretch, and gravity - that play a role in the physiology of tissues and cellular functions. It gives special attention to the influences of the flow of blood and exercise on the growth of blood vessels and the flow of interstitial fluid on bone formation. Pathological conditions are also presented, such as the lack of mechanical loading on bone and osteoporosis. For biotechnologists, the problem of cell susceptibility to agitation-induced hydrodynamic forces in the scale-up of mammalian cell bioreactors is examined.
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Product details

  • Paperback | 381 pages
  • 156 x 234 x 25.4mm | 717g
  • Academic Press Inc
  • San Diego, United States
  • English
  • references, index
  • 0122653300
  • 9780122653308

Table of contents

Techniques for studying the effects of physical forces on mammalian cells and for measuring cell mechanical properties, R. Tran-Son-Tay; mechanical transduction across extracellular matrix and through the cytoskeleton, D. Ingber, et al; mechanical strain and the mammalian cell, A.J. Banes; henodynamic forces in relation to shear mechanosensitive ion channels in endothelial cells, P.F. Davies and R.O. Dull; effects of flow on anchorage-dependent mammalian cells - secreted products, F. Berthiaume and J.A. Frangos; shear stress effects on the morphology and cytomatrix of cultured vascular endothelial cells, P.R. Girard, et al; fluid shear stress-dependent stimulation of endothelial autacoid release - mechanisms and significance for the control of vascular tone, R. Busse and U. Pohl; chronic effects of blood flow on the artery wall, B.L. Langille; fluid stress effects on suspended cells, L.V. McIntire and S. Rajagopalan; physical forces in mammalian cell bioreactors, E.T. Papoutsakis and J. D. Michaels; gravity and the mammalian cell, P. Todd.
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