Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
6269852 | Journal of Neuroscience Methods | 2011 | 12 Pages |
This technique proposes a new approach to correlate intra- and extracellular variations of the ionic concentrations in vivo by means of tapered optical waveguides coupled to standard electrophysiological electrodes to monitor in vivo simultaneously the intracellular and extracellular K+ concentration as well as the neighboring field potential. The optical fibers were tapered to a final diameter of approximately 10 μm and were used to guide the excitation light deep into the tissue and to collect the fluorescence emanating from the intracellular milieu. This fiber was coupled to a double barrel ion-sensitive electrode forming a micro-optrode with a final diameter around 15 μm. The method was successfully used to record the intracellular K+ evolution with the fluorescent indicator PBFI during three states: normal sleep-like patterns, paroxysmal seizures, and coma. While we could not disclose any phasic fluctuations of the intracellular K+ during normal sleep patterns, they were clearly present during seizures and coma. In the majority of cases (58%), paroxysmal discharges were associated with positive variations of the intracellular fluorescence of 62 ± 5% corresponding to extracellular K+ increases of 2.04 ± 0.4 mM. In the remaining cases (42%) intracellular K+ dropped by 44.4 ± 12% for an extracellular K+ increase of 2.62 ± 0.47 mM. We suggest that this differential behavior might reflect different cellular populations (glia vs. neurons, respectively). Comatose states were accompanied by an extracellular drop of K+ of 1.31 ± 0.13 mM, which was reflected, in all cases, by an intracellular K+ increase of 39 ± 4%.
Research highlightsⶠNew technique allowing simultaneous recording of extra- and intracellular K+ concentrations in vivo. ⶠElectrode based on composed electrical (electrophysiology) and optical probes. ⶠThe method suggests opposite behaviors of neurons and glia with respect to the transfer of K+ across membranes. ⶠTechnique successfully applied during normal sleep patterns and pathological (epileptic and comatose) states.