Modeling the non-steady-state response of an enzyme electrode for lactose

An enzyme electrode which uses the organic conductmg salt N-methylphenazmmm tetracyanoqumodnnethane (NMP TCNQ) IS reported A steady-state model for the electrode IS used to rdenbfy the rate-hnutmg step of the device Kmetlc parameters of the electrode are also obtamed from this model The model descri

fNTRODIJCTION In a previous paper[l] we presented a generalized model of various electrocrystallization processes using an immigration-propagation formalism to describe the steady-state. For the particular case of the 2D spreading of a crystal we showed that the steady-state spreading rate was of th

A mathematical model is derived to describe the steady-state response properties of the fiber-optic ammonia sensor. Unlike our previous model, the present model permits any concentration of total ammonia nitrogen initially present in the internal solution of the sensor. A cubic equation is solved to

A special mixing device for initiating enzyme-catalyzed reactions is used to rapidly achieve an unperturbed quasi-steady state. An on-line computer is employed to sample the initial conditions, the mixing time, and concentrations that change as a function of time during this quasi-steady state phase