Microsecond precision of interaural time differences processing in the medial superior olive studied by a computational model

Abstract

The medial superior olive (MSO) neural circuit in auditory brainstem computes sound azimuth from the interaural time difference (ITD) [1]. High spike timing precision in the order of tens of microseconds is necessary for this neural computation. This makes the MSO an ideal object to study spike time codes, as the relevant information is encoded by the spike timing relative to sound phase. In the MSO, spike timing precision deteriorates towards higher sound frequencies. Experimental recordings of Joris [4] demonstrate this by the vector strength (VS) function (see Figure ​Figure1A).1A). To explore the effects of the spike timing jitter on the MSO performance, we have introduced a model of the MSO circuit [2,3]. In our previous work, the model was explored using simulations, giving the value ranges of MSO circuit parameters which are necessary for proper functioning of the MSO in mammals [1]. In the present work we complement the simulations with several fits of smooth functions to the data and with analytical calculations. Figure. ​Figure.1A1A shows the shortest ITD detected by the model circuit, with its minimal value at sound frequency 1 kHz. Figure. 1B shows the MSO circuit precision in dependence on the spike timing jitter, which is defined as standard deviation of individual spike times relative to the sound phase. Figure ​Figure1B1B compares the simulated system, jagged line, and exponential curve fitted to the simulation with the analytical estimates of the just noticeable difference (JND) of ITD, line with circles. Figure 1 MSO precision in dependence on sound frequency and spike timing jitter. (A) Vector strength (VS), in units per cent shown together with the smallest detectable ITD in µs in dependence on sound frequency. Sound frequency 140 Hz used in [2] is shown ...