Enhancement of the Temporal Resolution of Fluorescent Signals Acquired by the Confocal Microscope

© Microscopy Society of America 2020. Here, we describe a method of acquisition of fast fluorescent signals with the help of the laser scanning confocal microscope (LSCM). Our method permits an increase in the temporal resolution of acquired signals. The method is based on LSCM recordings of fast fluorescent signals with the shortest achievable time sweep, which are performed with the help of a proprietary algorithm. A series of recordings is made in multiple steps; at each step, the fluorescent signal is incremented by a time interval smaller than the time sweep of the frame of LSCM. The size of the increment determines the achievable time resolution. The convolution of the recorded images results in a signal with the temporal resolution determined by the chosen time increment. This method was applied to register the change in fluorescence (calcium transient) of calcium dye preloaded into peripheral nerve endings by electrical stimulation of the motor nerve. Calculated parameters of the calcium transient were identical to the parameters obtained earlier with the help of a high-speed camera and photodiode. We conclude that the method described here can be applied for the registration of fast fluorescent signals by LSCM with a high spatial and temporal resolution

Calcium Transients and Transmitter Secretion in Different Parts of Frog Nerve Endings in Different Conditions of Calcium Ion Influx

© 2020, Springer Science+Business Media, LLC, part of Springer Nature. Experiments on frog neuromuscular preparations were performed to study the characteristics of the calcium response and the quantum secretion of acetylcholine in different pats of extended nerve terminals in different conditions of calcium influx. A calcium-sensitive fluorescent dye was used to analyze Ca2+ influx (Ca2+ transients) into the proximal and distal parts of nerve endings in conditions of increased K+ ion content, in response to blockers of N- and L-type calcium channels, and on blockade of calcium-activated potassium channels. These studies showed that at a uniform distribution density of voltage-gated calcium channels along nerve endings, the proximal-to-distal decrement in calcium transients and quantum secretion intensity persisted in conditions of additional opening of voltage-gated calcium channels by potassium depolarization, on “thinning” of these channels using specific blockers, but changed on blockade of calcium-activated potassium channels