An enzyme rate equation for the overall rate of reaction of gel‐immobilized glucose oxidase particles under buffered conditions. I. Pseudo‐one substrate conditions

Atkinson, B.; Lester, D. E.

doi:10.1002/bit.260161002

Cited by 25 publications

(11 citation statements)

References 17 publications

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“…Third, internal diffusion time could be decreased. Both of these mass transfer effects would increase the catalyst's effectiveness factor (53,54). Such studies were not done here because 200-400 mesh glass is the smallest controlled pore material available at this time.…”

Section: Resultsmentioning

confidence: 99%

Analytical aspects of immobilized enzyme columns

Rs¹,

Da²,

Ld³

et al. 1977

Anal. Chem.

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Section: Resultsmentioning

confidence: 99%

Analytical aspects of immobilized enzyme columns

Rs¹,

Da²,

Ld³

et al. 1977

Anal. Chem.

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“…(3), integrating twice, and applying the boundary conditions [eqs. (4)- (6)], we obtain C2 = Fl + A (9) where A is the following integration constant:…”

Section: Formulation Of the Modelmentioning

confidence: 99%

Diffusion and the limiting substrate in two‐substrate immobilized enzyme systems

Leypoldt¹,

Gough²

1982

Biotech & Bioengineering

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The effects of mass transport resistances on two-substrate immobilized enzyme systems are investigated theoretically. It is shown that the effects of mass transport resistances on the overall reaction rate are related mainly to the transport of the limiting substrate. In the absence of external mass transport resistances, the limiting substrate can be identified by knowing only the ratio of the bulk substrate concentrations, the permeability of the support to the two substrates, and the stoichiometry of the reaction. However, a combination of internal and external mass transport resistances may result in the other substrate becoming limiting. These effects are most significant when the mass transport resistances are high. Applications in the design of enzyme electrodes and chemical reactors are discussed.

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“…Depending on the enzyme loading and the substrate to be converted, biocatalysis with immobilized preparations of such enzymes may become diffusion limited. The classic methodology to identify kinetic parameters of highly active immobilized enzyme preparations consists of the following (e.g., 8−10): (1) determination of the intrinsic parameters on the basis of experiments with free soluble enzyme; and (2) adjusting the maximum catalytic velocity ( v max ) to compensate for the loss of enzyme activity upon immobilization and efficiency due to, for example, the extent of enzyme loading.…”

Section: Introductionmentioning

confidence: 99%

Investigations of Reaction Kinetics for Immobilized Enzymes—Identification of Parameters in the Presence of Diffusion Limitation

Berendsen

Lapin

Reuß

2006

Biotechnology Progress

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A method is proposed for identification of kinetic parameters when diffusion of substrates is limiting in reactions catalyzed by immobilized enzymes. This method overcomes conventional sequential procedures, which assume immobilization does not affect the conformation of the enzyme and, thus, consider intrinsic and inherent kinetics to be the same. The coupled equations describing intraparticle mass transport are solved simultaneously using numerical methods and are used for direct estimation of kinetic parameters by fitting modeling results to time-course measurements in a stirred tank reactor. While most traditional procedures were based on Michaelis-Menten kinetics, the method presented here is applicable to more complex kinetic mechanisms involving multiple state variables, such as ping-pong bi-bi. The method is applied to the kinetic resolution of (R/S)-1-methoxy-2-propanol with vinyl acetate catalyzed by Candida antarctica lipase B. A mathematical model is developed consisting of irreversible ping-pong bi-bi kinetics, including competitive inhibition of both enantiomers. The kinetic model, which fits to experimental data over a wide range of both substrates (5-95%) and temperatures (5-56 degrees C), is used for simulations to study typical behavior of immobilized enzyme systems.

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An enzyme rate equation for the overall rate of reaction of gel‐immobilized glucose oxidase particles under buffered conditions. I. Pseudo‐one substrate conditions

Cited by 25 publications

References 17 publications

Analytical aspects of immobilized enzyme columns

Analytical aspects of immobilized enzyme columns

Diffusion and the limiting substrate in two‐substrate immobilized enzyme systems

Investigations of Reaction Kinetics for Immobilized Enzymes—Identification of Parameters in the Presence of Diffusion Limitation

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