Understanding the mechanism of proton conduction in hydrogen-bonded solids is of considerable interest owing to their potential application as proton conduction electrolytes in fuel cells.
The development of electrochemical methods in vivo attracts much attention since the microelectrodes are much favorable for monitoring changes of neurotransmitters [1].
Electrochemical cytometry is a new method that can be used to separate nanometer vesicles,lyse them on an electrode surface,and amperometrically detect the active contents of each vesicle in a high th
In last two years,we continued to bring nanotechnology and molecular biological technology into the design of electrochemical biosensing strategies,which led to a series of amplified methods for sensi