Membrane systems: analysis and design : applications in biotechnology, biomedicine, and polymer science
Written by a preeminent expert in biochemical engineering and membrane technology, Membrane Systems: Analysis and Design covers the entire range of membrane systems, from artificial and synthetic to real and in vivo. It brings together theoretical, analytical, and quantitative approaches to the design of membranes and membrane bioreactors, and unifies the principles of diffusion and reaction that apply to biological and synthetic membrane systems at the molecular level. It shows researchers in such diverse fields as biotechnology, biomedicine, and polymer science how to design new and more efficient types of membrane systems. An especially important and timely chapter on recombinant cell reactors offers a complete description of the genetic control system and its stable functioning in a novel reactor configuration. Biochemists, organic chemists, microbiologists, biophysicists, neuroscientists, biochemical and chemical engineers, and biotechnologists will find Dr. Vieth's book invaluable to their own work in designing membranes and membrane bioreactors.
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Diffusion and Reaction in Microheterogeneous
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acetic activity binding Biochemical bioreactor biosensor membranes Biotechnol calcium calmodulin carbon dioxide catabolite repression cell concentration cell growth Chem chemical chemostat chemostat culture coli collagen collagen membrane constant counterdiffusion CSTR curves decrease Deff diffusion coefficient diffusional dilution rate dimensionless dual sorption effective diffusivity effectiveness factor enzyme enzyme biosynthesis equation equilibrium estimated experimental data expression fermentation Figure flux fraction galactosidase gene glassy polymers glucose isomerase gradient growth rate Henry's law immobilized cell IMRC bioreactor increased inducer inhibition interactions ions IPTG isotherm kinetics Koros lac operon lactose lactose concentration Langmuir maximum mechanism membrane systems methane modulator molecular molecules obtained penetrant permeability permeation plasmid polymer potential predicted pressure propionic acid protein Purkinje fiber reaction rate reactor receptor recombinant cell represents reverse osmosis simulation sodium solution specific specific growth rate steady substrate concentration synaptic temperature transient UASB upstream Venkatasubramanian vesicles W.R. Vieth