The square-wave approach to impedance measurement of brain tissue water dynamics.

Electrical properties of living soft tissue have been used to analyze their structure and function. Presently, the 'admittance locus' method, with the sine-wave signal of changing frequency, is the most informative continuous method for analyzing extra-and intracellular water content in brain tissue. Using the square-wave signal in lieu of the sine-wave signal, we can avoid cumbersome and costly measurements and facilitate real-time data processing. An isolation-calibration device was developed for the present study in order to condition and stabilize electrical current through the brain cortex. This device was also used for impedance calibration before and after the experiments. We propose a simple algorithm for data analysis on the basis of equivalent circuit approach, which allows to develop a computer program for data processing. Preliminary experiments on rat brains were carried out with a 0.2-0.5 mm stainless-steel tetrapolar electrode system. These studies showed good linearity between stimulating currents (I = 5-30 microA) through the external electrodes in the brain cortex and a drop in voltage which was measured by 2 inner electrodes. The results of the device and the program accuracy tests allow us to choose the optimal range for the working current. We can recommend this method for usage in animal experiments.