Delay-tuned neurons in the inferior colliculus of the mustached bat: implications for analyses of target distance.
Creator
Portfors C V; Wenstrup J J
Publisher
Journal of neurophysiology
Date
1999
1999-09
Description
We examined response properties of delay-tuned neurons in the central nucleus of the inferior colliculus (ICC) of the mustached bat. In the mustached bat, delay-tuned neurons respond best to the combination of the first-harmonic, frequency-modulated (FM1) sweep in the emitted pulse and a higher harmonic frequency-modulated (FM2, FM3 or FM4) component in returning echoes and are referred to as FM-FM neurons. We also examined H1-CF2 neurons. H1-CF2 neurons responded to simultaneous presentation of the first harmonic (H1) in the emitted pulse and the second constant frequency (CF2) component in returning echoes. These neurons served as a comparison as they are thought to encode different features of sonar targets than FM-FM neurons. Only 7% of our neurons (14/198) displayed a single excitatory tuning curve. The rest of the neurons (184) displayed complex responses to sounds in two separate frequency bands. The majority (51%, 101) of neurons were facilitated by the combination of specific components in the mustached bat's vocalizations. Twenty-five percent showed purely inhibitory interactions. The remaining neurons responded to two separate frequencies, without any facilitation or inhibition. FM-FM neurons (69) were facilitated by the FM1 component in the simulated pulse and a higher harmonic FM component in simulated echoes, provided the high-frequency signal was delayed the appropriate amount. The delay producing maximal facilitation ("best delay") among
Responses to combinations of tones in the nuclei of the lateral lemniscus.
Creator
Portfors C V; Wenstrup J J
Publisher
Journal of the Association for Research in Otolaryngology : JARO
Date
2001
2001-06
Description
Combination-sensitive neurons integrate specific spectral and temporal elements in biologically important sounds, and they may underlie the analysis of biosonar and social vocalizations. Combination-sensitive neurons are found in the forebrain of a variety of vertebrates. In the mustached bat, they also occur in the central nucleus of the inferior colliculus (ICC). However, it is not known where combination-sensitive response properties emerge. To address this question, we used a two-tone paradigm to examine responses of single units to combination stimuli in a brainstem structure, the nuclei of the lateral lemniscus (NLL). We recorded and histologically localized 101 single units in the NLL. The majority (82%) of units had a single excitatory frequency tuning curve. Seven units had two separate excitatory frequency tuning curves but displayed no combinatorial interaction. Twelve units were combination-sensitive. Of these, three units were facilitated by the combination of two separate frequency bands and nine units were inhibited by combinatorial stimuli. The three facilitatory neurons had excitatory responses tuned to the second harmonic constant frequency (CF2, 57-60 kHz) component of the biosonar signal and were facilitated by a second signal within the first harmonic (Hl, 24-30 kHz) of the biosonar call. Most of the inhibitory interactions occurred between signals in the frequency bands associated with the frequency-modulated (FM) components of the biosonar call. The strongest combinatorial effects (facilitatory and inhibitory) were elicited by simultaneous onset of the two signals (i.e., 0 ms delay). All combination-sensitive units were in the intermediate nucleus of the NLL (INLL), which in bats is a hypertrophied structure that projects strongly to combination-sensitive neurons in the ICC. Thus, the combination-sensitive neurons in the INLL may impart their response properties onto ICC neurons. However, the small number of facilitatory combination-sensitive neurons in the NLL suggests that the majority of these combinatorial responses originate in the ICC.
Topographical distribution of delay-tuned responses in the mustached bat inferior colliculus.
Creator
Portfors C V; Wenstrup J J
Publisher
Hearing research
Date
2001
2001-01
Description
In the mustached bat, delay-tuned neurons respond best to specific delays between the first harmonic frequency modulated (FM) component (FM1; 24-29 kHz) of the emitted biosonar pulse and a higher harmonic FM component in returning echoes (e.g. FM3, 72-89 kHz). These delay-tuned, combinatorial responses predominate in the inferior colliculus (IC) of the mustached bat. This study examined the topographical distribution of delay-tuned neurons in the 72-89 kHz frequency representation of the IC. We recorded and histologically localized 163 single units. Ninety units were facilitated and 41 were inhibited by the combination of two frequencies in the 24-29 kHz and 72-89 kHz ranges. The facilitatory responses were selective for delays up to 20 ms between the two signals. To determine if delay-tuned neurons were topographically organized, we plotted the dorsomedio-ventrolateral and caudo-rostral positions of each unit versus its best delay. Best delay was not correlated with either location. Response latency to best frequency tones was topographically organized, but was not correlated with best delay. This indicates that the latency axis in the IC is unrelated to the delay tuning of these combinatorial neurons. Because delay-tuned neurons are not topographically organized in the IC but are in the auditory cortex, our findings suggest that the creation and organization of delay-tuned neurons occur at different stages in the ascending auditory system.