Bioelectrochemistry of MembranesDieter Walz, Justin Teissié, Giulio Milazzo Bioelectrochemistry of Membranes is the last volume in the book series "Bioelectrochemistry: Principles and Practice" that provides a comprehensive compilation of physicochemical aspects of different biochemical and physiological processes. This sixth volume introduces basic knowledge and important electrochemical and biophysical aspects of membrane potentials, lipid bilayers and cell membranes. The volumes of this book series serve as source books for advanced students and researchers at all levels of bioelectrochemistry. |
Other editions - View all
Bioelectrochemistry of Membranes Dieter Walz,Justin Teissié,Giulio Milazzo No preview available - 2011 |
Bioelectrochemistry of Membranes Dieter Walz,Justin Teissié,Giulio Milazzo No preview available - 2012 |
Common terms and phrases
acid Acta acyl chains amplitude applied aqueous bilayer lipid membrane Biochemistry Biochim Biol biological membranes Biophys Blume brane capacitance cell membranes cell surface changes Chem chemical cholesterol concentration conductance conformational constant curve dependence dielectric diffusion dipole DMPC effect elec electric field electrical breakdown electrodes electrolyte electropermeabilization Electroporation electrostatic energy enzyme erythrocytes fatty field pulse field strength fluctuations fluorescence frequency function head groups hydration hydrophilic hydrophilic pores hydrophobic increase induced interactions interface ionic ions kinetics line shapes lipid bilayers lipid molecules liposomes measurements membrane dipole potential membrane potential membrane surface method micelles molecular monolayers Na+/K+-ATPase observed obtained orientation peptide permeabilization phase transition phosphatidylcholine phosphatidylethanolamine phospholipid Phys probes properties proteins pulse duration radius resonance shown in Fig solution spectra spectroscopy structure surface potential surfactant techniques Teissié temperature tion titration transmembrane potential difference transport Tsong TY unilamellar V/cm vesicles