Electro-enzymatic synthesis of lactate using electron transfer chain biomimetic membranes

Controlling tissue microenvironments: biomimetics, transport phenomena, and reacting systems

The reconstruction of tissues ex vivo and production of cells capable of maintaining a stable performance for extended time periods in sufficient quantity for synthetic or therapeutic purposes are primary objectives of tissue engineering. The ability to characterize and manipulate the cellular microenvironment is critical for successful implementation of such cell-based bioengineered systems. As a result, knowledge of fundamental biomimetics, transport phenomena, and reaction engineering concepts is essential to system design and development. Once the requirements of a specific tissue microenvironment are understood, the biomimetic system specifications can be identified and a design implemented. Utilization of novel membrane systems that are engineered to possess unique transport and reactive features is one successful approach presented here. The limited availability of tissue or cells for these systems dictates the need for microscale reactors. A capstone illustration based on cellular therapy for type 1 diabetes mellitus via encapsulation techniques is presented as a representative example of this approach, to stress the importance of integrated systems.

Voltammetric and spectroelectrochemical characterization of a water-soluble viologen polymer and its application to electron-transfer mediator for enzyme-free regeneration of NADH

A water-soluble polyxylylviologen (PXV(2+)) was characterized with a view to making use of it as a redox electron-transfer (ET) mediator. Cyclic voltammetric and spectropotentiometric studies showed (i) that PXV(2+) gives two redox waves centering at -0.40 and -0.83 V (vs. Ag/AgCl (3.3 mol dm(-3) KCl)) and (ii) that the lifetime of its monocation radical (PXV(+.)) is two orders of magnitude greater than that of the well-utilized dimethyl viologen monocation radical. Subsequently, the reaction of the PXV(2+/+.) couple with NAD(+) was evaluated in the similar manners as above. On the basis of this evaluation and the bioluminescence assay using bacterial NADH/FMN oxidoreductase and luciferase, it was shown (i) that the PXV(2+/+.) couple functions as a useful electron-transfer mediator and (ii) that PXV(+.) reacts with NAD(+), leading to generation of the enzymatically active NADH, in the absence of any reductases.