"77" . "GB - Spojen\u00E9 kr\u00E1lovstv\u00ED Velk\u00E9 Brit\u00E1nie a Severn\u00EDho Irska" . "3"^^ . . . "Journal of Chemical Technology and Biotechnology" . "membrane reactor; penicillin acylase; electric field; steady state analysis; periodic switching"@en . "1" . "643896" . "[6E01D2D0DAA7]" . . "0"^^ . "4"^^ . "0"^^ . . "Dynamics of penicillin G hydrolysis in an electro-membrane reactor" . . . . "Hasal, Pavel" . . . . "Dynamics of penicillin G hydrolysis in an electro-membrane reactor"@en . "P\u0159ibyl, Michal" . . "P(GA104/01/1319)" . "Dynamics of penicillin G hydrolysis in an electro-membrane reactor" . . "Chmel\u00EDkov\u00E1, R\u016F\u017Eena" . "RIV/60461373:22340/02:00007194" . "Analysis of penicillin G hydrolysis in a membrane reactor with membrane-entrapped penicillin G acylase is performed using a mathematical model of the reactor system. An electric field imposed to the reactor is considered to enhance transport rates of reaction components and reaction rate. The analysis focuses on possible effects of principal operational parameters (electric field intensity, inlet substrate concentration, membrane thickness) on reactor performance. Multiplicities of steady states are frequently encountered. The membrane reactor performance can be easily targeted towards required reaction regime by constant or periodically varying electric field applied to the system. The periodic alternation of the polarity of the electric field substantially increases the effectiveness factor of penicillin hydrolysis compared to the steady state operation. Proper adjustments of electric field intensity may also compensate for the enzyme activity decay." . "Dynamics of penicillin G hydrolysis in an electro-membrane reactor"@en . . . . "12"^^ . . . "0268-2575" . "Analysis of penicillin G hydrolysis in a membrane reactor with membrane-entrapped penicillin G acylase is performed using a mathematical model of the reactor system. An electric field imposed to the reactor is considered to enhance transport rates of reaction components and reaction rate. The analysis focuses on possible effects of principal operational parameters (electric field intensity, inlet substrate concentration, membrane thickness) on reactor performance. Multiplicities of steady states are frequently encountered. The membrane reactor performance can be easily targeted towards required reaction regime by constant or periodically varying electric field applied to the system. The periodic alternation of the polarity of the electric field substantially increases the effectiveness factor of penicillin hydrolysis compared to the steady state operation. Proper adjustments of electric field intensity may also compensate for the enzyme activity decay."@en . "51-62" . "Marek, Milo\u0161" . "RIV/60461373:22340/02:00007194!RIV/2004/GA0/223404/N" . . "22340" . .