Difference between revisions of "Plasmonic Detection of Bioelectrical signals"

From Applied Optics Wiki
Jump to: navigation, search
Line 1: Line 1:
This project investigates the utilisation of surface plasmon resonance as a voltage sensor for biological applications. Electrical signals are used by cells to communicate with each others, creating a coherent higher level function. For instance, information processing in the nervous system is mediated by electrical signals. Also, the function of the different types of muscle cells are controlled by electrical excitation. Accurate and reliable measurements of these signals at the cell level provides valuable in-vitro models for physiological and pharmocological investigations.Unlike the popular flourescent and electrodes methods, surface plasmon resonance is a label-free, non-invasive way to measure localized signals at the cell-substrate interface.
+
 
 +
 
 +
 
 +
This project investigates the utilisation of surface plasmon resonance as a voltage sensor for biological applications. Electrical signals are used by cells to communicate with each others, creating a coherent higher level function. For instance, information processing in the nervous system is mediated by electrical signals. Also, the function of the different types of muscle cells is controlled by electrical excitation. Accurate and reliable measurements of these signals at the cell level provides valuable in-vitro models for physiological and pharmacological investigations.Unlike the popular fluorescent and electrodes methods, surface plasmon resonance is a label-free, non-invasive way to measure localized signals at the cell-substrate interface.

Revision as of 18:14, 22 March 2015


This project investigates the utilisation of surface plasmon resonance as a voltage sensor for biological applications. Electrical signals are used by cells to communicate with each others, creating a coherent higher level function. For instance, information processing in the nervous system is mediated by electrical signals. Also, the function of the different types of muscle cells is controlled by electrical excitation. Accurate and reliable measurements of these signals at the cell level provides valuable in-vitro models for physiological and pharmacological investigations.Unlike the popular fluorescent and electrodes methods, surface plasmon resonance is a label-free, non-invasive way to measure localized signals at the cell-substrate interface.