Convergent Input from Brainstem Coincidence Detectors onto Delay-Sensitive Neurons in the Inferior Colliculus

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The Journal of Neuroscience, August 1, 1998, 18(15):6026-6039

Convergent Input from Brainstem Coincidence Detectors onto Delay-Sensitive Neurons in the Inferior Colliculus
David McAlpine, Dan Jiang, Trevor M. Shackleton, and Alan R. Palmer
Medical Research Council Institute of Hearing Research, University of Nottingham, Nottingham NG7 2RD, United Kingdom

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Responses of low-frequency neurons in the inferior colliculus (IC) of anesthetized guinea pigs were studied with binauralbeats to assess their mean best interaural phase (BP) to a rangeof stimulating frequencies. Phase plots (stimulating frequencyvs BP) were produced, from which measures of characteristic delay(CD) and characteristic phase (CP) for each neuron were obtained.The CD provides an estimate of the difference in travel time fromeach ear to coincidence-detector neurons in the brainstem. TheCP indicates the mechanism underpinning the coincidence detectorresponses. A linear phase plot indicates a single, constant delaybetween the coincidence-detector inputs from the two ears. Inmore than half (54 of 90) of the neurons, the phase plot was notlinear. We hypothesized that neurons with nonlinear phase plotsreceived convergent input from brainstem coincidence detectorswith different CDs. Presentation of a second tone with a fixed,unfavorable delay suppressed the response of one input, linearizingthe phase plot and revealing other inputs to be relatively simplecoincidence detectors. For some neurons with highly complex phaseplots, the suppressor tone altered BP values, but did not resolvethe nature of the inputs. For neurons with linear phase plots,the suppressor tone either completely abolished their responsesor reduced their discharge rate with no change in BP. By selectivelysuppressing inputs with a second tone, we are able to reveal thenature of underlying binaural inputs to IC neurons, confirmingthe hypothesis that the complex phase plots of many IC neuronsare a result of convergence from simple brainstem coincidencedetectors.

Key words: binaural hearing; interaural phase differences; inferior colliculus; phase plots; convergent binaural input; suppressor tones

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Localization of low-frequency (<1500 Hz) sounds in azimuth is based on the sensitivity of the auditory system to small differencesin the timing of the sound at each ear (Rayleigh, 1907). At lowfrequencies, these time differences give rise to interaural phasedifferences (IPDs). Neurons in the medial superior olive (MSO)of the superior olivary complex (SOC) receive excitatory inputfrom both ears via axons of different lengths, providing the basisfor a mechanism first proposed by Jeffress (1948), in which aseries of coincidence detectors, fed by delay lines, convert interauraltime differences (ITDs) into changes in neuronal discharge rate(Goldberg and Brown, 1969; Yin and Chan, 1990; Spitzer and Semple,1995, Batra et al., 1997). In this simple model, coincidencesresult in maximal or peak discharge rates (peak-type). The differencein the conduction time from each ear [the characteristic delay(CD)] offsets the time delay caused by the sound source location.The CD can be estimated from the slope of the function relatingbest interaural phase to stimulus frequency (the phase plot) which,for simple coincidence detectors, is a linear function. Otherneurons, either in the MSO or in the lateral superior olive (LSO)are believed to receive excitation from one ear and inhibitionfrom the other to produce sensitivity to interaural time differences(Goldberg and Brown, 1969; Finlayson and Caspary, 1991; Batraet al., 1997; Joris, 1996): coincidental arrival of the activityfrom contralateral ear inhibits the response elicited by the ipsilateralear to give a CD at a minimum in the discharge rate (trough-type).

Although the SOC is the primary site of binaural interactions, the inferior colliculus (IC; the target nucleus for the brainstemneurons) has been the subject of the majority of studies of low-frequencybinaural hearing (Yin and Kuwada, 1983a,b; Kuwada et al., 1987,1989; Palmer et al., 1990, McAlpine et al., 1996). Many IC neuronsshow either nonlinear phase plots or linear phase plots whoseCD is at neither a peak nor a trough in the delay function (intermediate-type).Such phase plots are incompatible with simple coincidence detectionwhen the inputs are matched in frequency. A likely explanationfor their appearance in the IC is the convergence of inputs fromthe lower brainstem nuclei onto single IC neurons (Beyerl, 1978;Adams, 1979; Brunso-Bechtold et al., 1981).

Here, we investigate whether such convergence provides an adequate explanation for nonlinear and intermediate-type phase plotsin the IC. By selectively inactivating inputs to an IC neuronusing a suppressor tone, we can reveal the delay characteristicsof its other inputs. The data are consistent with the hypothesisthat nonlinear and intermediate-type phase plots result from convergence,at the level of the IC, of inputs from coincidence detectors inthe lower brainstem. After selective suppression, the neuronsoften showed linear phase plots, indicative of simple peak-typeor trough-type behavior.

  MATERIALS AND METHODS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Preparation and recording. Recordings were made from the right IC of 300-400 gm guinea pigs anesthetized with Urethane (1.3gm/kg in 20% solution) with additional analgesia obtained usingphenoperidine (1 mg/kg). A premedication of atropine sulfate (0.06mg/kg) was administered to reduce bronchial secretions. Supplementarydoses of Urethane (one-half to one-third of the induction dose)or phenoperidine were administered when required. All animalswere tracheotomised, and core temperature was maintained at 37°Cwith a heating blanket and rectal probe. Most animals respiredspontaneously, but a few were artificially respired with 95% O₂and 5% CO₂, and end-tidal CO₂ was monitored.

All experiments were conducted in a sound-attenuating chamber. The animals were placed in a stereotaxic frame with hollowearbars into which fitted 12.7 mm Brüel and Kjær condenser earphones,and 1 mm probe tubes fitted to 12.7 mm Brüel and Kjær microphones.In every experiment the probe tube microphone was used to calibratethe sound system in decibels re: 20 µPa a few millimeters fromthe tympanic membrane. The sound systems for each ear were flatto within ±5 dB from 100-10,000 Hz and were matched to within±2 dB.

A silver wire electrode was placed on the round window of one side via a hole in the posterior aspect of the bulla, and thethreshold of the cochlear action potential evoked by short tonepips (10 msec duration, 1 msec rise-fall time) was measured automaticallyas a function of frequency (from 500-30,000 Hz) periodically throughoutthe experiment to monitor the condition of the cochlea. A thin(0.5 mm diameter) polythene tube was sealed into the bulla ofboth sides to provide pressure equalization while maintainingclosed-field recording conditions. Threshold elevations were generallyeither caused by deterioration of the preparation, which affectedboth ears equally, or build-up of fluid in the bulla. Given thatthe presence of the silver wire was a major cause of condensationand capillary action in causing the fluid build-up, monitoringof one ear only to detect systemic changes was considered sufficient.

Single-neuron action potentials were recorded using tungsten-in-glass microelectrodes (Merrill and Ainsworth, 1972; Bullocket al., 1988). After positioning the electrode stereotaxicallyto ~2 mm above the surface of the IC, it was advanced in a dorsal-to-ventraldirection using a Burleigh IW-700/710 Inchworm from outside therecording chamber.

Stimulus production and presentation. Stimuli were delivered separately to each ear via attenuators and closed-field soundsystems. Search stimuli consisted of 50 msec bursts of white noisepresented diotically. When a single neuron was isolated, its bestfrequency (BF) and threshold to binaural tones at zero interauraldelay were determined audiovisually. The binaural frequency versuslevel response area of the neuron was then mapped for frequenciesfrom two octaves above to four octaves below the BF of the neuronand in 5 dB steps from 20 dB below the audiovisually determinedthreshold at BF up to full-system output.

Binaural beats were used to examine the interaural delay sensitivity of IC neurons. Binaural beats are produced when tonesof different frequencies are presented, one to each ear, usingclosed-field speakers (Yin and Kuwada, 1983a). The frequency differencecauses the tones to move in and out of phase with each other,and the rate at which this occurs, equal to the frequency differencebetween the two tones, is known as the beat frequency. In thepresent study, the signal delivered to the left ear (contralateralto the recording site) was always 1 Hz greater than that deliveredto the right (ipsilateral) ear. This resulted in the phase atthe contralateral ear "leading" that at the ipsilateral ear duringthe first half-cycle. The total duration of each beat stimuluswas 3000 msec and, with the entire range of possible IPDs beingpresented over each 1000 msec interval (1 Hz), this produced threecomplete cycles of IPD for every repetition of the beat stimulus.Ten repetitions of the three-cycle beat stimulus were presented,and the mean best phase (BP) and the vector strength (R) of theresponse to binaural beats, binned using 100 bins per cycle ofIPD, were calculated from the middle two cycles of the beat response(from 0.5 to 2.5 cycles), using the method described by Goldbergand Brown (1969). The plots of the resulting IPD functions werebinned using 50 bins per cycle of IPD for the sake of clarity.Binaural beats were presented over a range of different carrierfrequencies, including BF, to examine the delay sensitivity asa function of the stimulating frequency. The number of frequenciesexamined ranged from 7 to 24, with a mean of 12 frequencies examinedper neuron. Responses to binaural beats were measured at 50 Hzintervals, except for neurons with very low BFs (<200 Hz), inwhich responses were measured at 25 Hz intervals. From the responsesat each frequency, the CD and characteristic phase (CP) valuesof the neurons were calculated. The CD is calculated as the slopeof the plot of stimulating frequency versus BP, and the CP, theintersection of the regression line with the phase (ordinate)axis, gives an indication of the type of interaction. CD and CPvalues were obtained from the weighted, multiple regression ofthe resulting phase plots in a similar manner to that describedby Kuwada et al. (1987) and Spitzer and Semple (1995), in whicheach data point in the phase plot was weighted by the vector strengthof the response (Bevington and Robinson, 1992). Phase plots wereconsidered linear if the linear regression component exceededthe 0.005 level of significance, and no other higher-order regressioncomponent was significant at this level. A CP close to zero indicatesthat the CD occurs near the peak of the delay function, a CP closeto 0.5 indicates that the CD occurs near a trough in the delayfunction, and a CP between these values indicates that the CDoccurs on the slope of the delay function (Rose et al., 1966;Yin and Kuwada, 1983b). Neurons with CPs within ±0.1 cycles ofzero or 1.0 were classified as peak-type, and those with CPs within± 0.1 cycles of ± 0.5 were classified as trough-type. All otherneurons were classified as intermediate-type.

Suppressing binaural inputs with a worst-delay tone. Responses to binaural beats were also examined in the presence of a secondtone with a fixed delay, chosen to suppress selected binauralinputs. The second, suppressing tone was presented at the samelevel as the binaural beat stimulus (usually +20 dB re: threshold).The frequency was chosen by visual inspection of the phase plotto be (1) effective in driving the neuron at some IPD and (2)within a relatively linear region of the phase plot. The fixeddelay for the tone was selected to be the delay at which the neuronresponded least (i.e., its worst, or most unfavorable, delay)judged from its binaural beat response at that frequency. Thesuppressor tone was presented simultaneously (summed electronically)with the binaural beat stimulus that was used to measure the delaysensitivity to the other frequencies. The BP and vector strengthwere again calculated from the middle two cycles of the responseto the beats in the presence of the suppressor and, where possible,values of CD and CP were obtained.

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Responses from 90 delay-sensitive neurons in the IC of 30 guinea pigs were examined using binaural beats. Phase plots forrepresentative IC neurons are shown in Figure 1. Those on thetop row (Figs. 1A-C) were linear according to our criterion and,thus, could be characterized by a single fixed delay, the CD.Forty percent (36 of 90) of IC neurons we recorded had linearphase plots; 22 neurons were peak-type (Fig. 1A), 2 were trough-type(Fig. 1B), and 12 were intermediate-type (Fig. 1C). Those in thebottom row (Figs. 1D-F) are nonlinear and, as such, cannot bedescribed as having a CD; the regression lines fitted to theseplots serve merely to highlight the extent to which the phaseplot deviated from linearity. Nonlinear phase plots accountedfor 60% (54 of 90) of neurons recorded in our study. Thus, only27% (24 of 90) of our sample had phase plots explicable in termsof simple brainstem coincidence detection (i.e., peak-type ortrough-type).

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Figure 1. Phase plots of six representative IC neurons. Those in the top row (A-C) were linear according to our criterion (see Materials and Methods), indicating peak-type (A), trough-type (B), or intermediate-type (C) responses. Those in the bottom row (D-F) were nonlinear. The regression lines for the nonlinear phase plots serve to highlight how poorly they fit the data.

We hypothesize that neurons with complex or intermediate-type phase plots receive convergent input from more than one binauralcoincidence detector in the brainstem. The top part of Figure2 illustrates this hypothesis and the effect that it has on ITDprocessing in the IC. The diagram on the left of the panel isa schematic representation of two binaural inputs from the brainstemconverging onto the same IC neuron in the midbrain. Shown in themiddle of the top part are individual frequency versus level responseareas of the brainstem inputs, as well as that of the IC neuron,whose response area is the combined response area of the two inputs.The IPD functions on the right illustrate the IPD sensitivityin response to a binaural beat at a particular frequency and level(solid dot inside response areas), for the two brainstem neurons,and the IPD sensitivity of the IC neuron which, once again, reflectsthe sum of the two inputs. It is this combining of IPD sensitivityfrom different binaural brainstem inputs that we hypothesize isresponsible for the appearance of complex or intermediate-typephase plots. The bottom part of Figure 2 illustrates how thishypothesis might be tested. The schema is the same as in the toppart of Figure 2, except that now another stimulus has been added.This stimulus, denoted by an asterisk in the response areas, isa tone fixed at its worst ITD, and it sits inside the responsearea of one of the brainstem inputs only. In the ideal scenario,the presumed effect is to suppress the response of that brainsteminput. It thus no longer influences the response of the IC neuron.This suppression is reflected in the response of the IC neuronto binaural beats, which now shows the same IPD sensitivity asthe remaining, unsuppressed brainstem input.

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Figure 2. Schematic representation of the convergence hypothesis and how it has been tested. See Results for description.

We tested our hypothesis by examining the responses of 42 IC neurons to concurrent presentation of suppressor tones and binauralbeats. Of these, 37 of 42 were defined as "complex," having eithernonlinear or intermediate-type phase plots, and 5 were "pure,"having either peak-type or trough-type phase plots.

IC neurons with linear peak-type or trough-type phase plots

Figure 3 shows responses from an IC neuron to binaural beats at 62 dB sound pressure level (SPL). The neuron responded tobinaural beats at this stimulus level from 100 to 275 Hz, andresponses were obtained at 25 Hz intervals. The resulting phaseplot (Fig. 3A) indicates a CD of +853 µsec and a CP of $-$ 0.02,characteristic of peak-type units. The discharge of the unit tobinaural beats as a function of time is shown as a peristimulustime histogram (PSTH) in Figure 3C for binaural beats at 225 Hz,in which responses to binaural beats presented alone are shownby the open bars. Because the stimulus is a 1 Hz binaural beat,the abscissa performs the function of both a time and an IPD axis;3 sec of stimulus equates to three complete cycles of IPD. Theopen bars in Figures 3D-F show IPD histograms of the responseat three frequencies: 225 (Fig. 3D, the same data as in Fig. 3C),200 (Fig. 3E), and 250 (Fig. 3F) Hz. Finally, the data from allthe different frequencies that contributed to the phase plot areplotted in Figure 3B as a function of the interaural delay andindicate that the delays of the maxima at each frequency are closelyaligned. When a 250 Hz suppressor was presented at its worst delay(+2674 µsec) and 62 dB SPL, no responses were evoked at any ofthe frequencies tested (125, 150, 172, or 225 Hz). This reflectedthe general ease with which we were able to suppress responsesto binaural beats using worst delay tones. When a 125 Hz suppressorwas presented at its worst delay (+4489 µsec) and 62 dB SPL, responsesto binaural beats were evoked at 200, 225, and 250 Hz, but notat any other frequencies. These responses are shown as lines inFigures 3C-F. Clearly, they are attenuated relative to the responseto the binaural beats alone. A similar pattern was observed forthe other pure peak-type neurons examined. Responses were verypoor, or completely absent, when a suppressor tone was presentedsimultaneously at the same stimulus level. Figure 3G replots thephase plot of Figure 3A, but with the mean BP values to binauralbeats alone at 200, 225, and 250 Hz now shown as open squaresand the mean BP values obtained at these frequencies in the presenceof the 125 Hz suppressor shown as circles. There is little changein the BP values in the presence of the suppressor.

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Figure 3. Responses of an IC neuron with simple peak-type behavior. A, Phase plot constructed from BP indicates a CD of +853 µsec and a CP of $-$ 0.02. B, ITD functions constructed from the response to binaural beats (see Materials and Methods). C, PSTH showing the response to binaural beats at 225 Hz presented alone or simultaneously with a 125 Hz suppressor tone. D-F, IPD histograms showing the response to binaural beats at 225 (D), 200 (E), and 250 (F) Hz, presented either alone (open bars) or in the presence of the 125 Hz suppressor (lines). G, Phase plot showing the new mean BP values as open circles and the old values as open squares.

A similar reduction in discharge without altering the BP is shown in Figure 4 for a linear, trough-type neuron; CP, 0.50;CD, $-$ 298 µsec (Fig. 4A, phase plot). The CD is indicated on theITD functions in Figure 4B by the vertical line. The PSTHs inFigure 4C show the response to three cycles of a 1 Hz binauralbeat at the BF of the neuron (478 Hz), either presented alone(open bars) or in the presence of a 300 Hz suppressor at worstdelay (lines) and 61 dB SPL. Figures 4D-F show IPD histogramsfor the binaural beat alone (open bars) or in the presence ofincreasing levels of suppressor (lines). As the level of the suppressorwas increased, the discharge rate evoked by binaural beats wasprogressively reduced to that at the trough until, for the highestlevel suppressor (66 dB SPL; Fig. 4G), the neuron was not sensitiveto the IPD. However, despite the progressive reduction in thedischarge rate with increasing suppressor level, the BP to the478 Hz beats remained unaltered (Fig. 4H).

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Figure 4. Responses of an IC neuron with simple trough-type behavior. A, Linear phase plot with a CD of $-$ 298 µsec and a CP of +0.50. B, ITD functions constructed from the response to binaural beats and highlighting the symmetrical arrangement of the discharge rate peaks around the trough in the discharge rate. C, PSTH of the response to binaural beats at BF (478 Hz, open bars) and to binaural beats presented simultaneously with a 300 Hz suppressor (lines) at 61 dB SPL. D-G, IPD histograms to binaural beats at BF (open bars) and to binaural beats presented simultaneously with the suppressor (lines) at levels of 46 (D), 56 (E), 61 (F), and 66 (G) dB SPL. H, Plot of the BP at BF as a function of suppressor level. NDS, Not delay-sensitive.

Convergence of peak-type inputs

In Figure 5A, the phase plot shows that, for this neuron, BP first increased for frequencies up to 500 Hz, but then decreasedwith increasing frequency up to 800 Hz. Although fitting a singleregression line to these data points gives a CD of +100 µsec anda CP of 0.06 (indicating a peak-type input), the linear fit isnot significant at the 0.005 level. Alternatively, fitting twolines to the phase plot (Fig. 5B) gives two values of CD; a peak-typeresponse (CP, $-$ 0.08) with a CD of +471 µsec over the lower-frequencyregion (250-500 Hz) and an intermediate-type response (CP, +0.22)with a CD of $-$ 134 µsec over the upper-frequency region (500-800Hz, open circles). Neither approach is entirely satisfactory:either the IC neuron receives a single peak-type input with apoor linear fit, or it receives two inputs, one a peak-type andone an intermediate-type. The two linear fits independently meetour statistical criterion for linearity, but one is not consistentwith simple coincidence detection. An alternative hypothesis isthat two or more simple binaural inputs converge onto the IC neuronto produce the complex phase plot. As we demonstrate below, suppressingone input produces data consistent with this hypothesis.

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Figure 5. A, Phase plot of an IC neuron with a BF of 679 Hz. B, Identical phase plot to that in A, except that here the phase plot has been divided into two local regions, each of which has been fitted with a regression line. C, PSTH of the response to binaural beats at 500 Hz alone (open bars) or presented simultaneously with a 300 Hz suppressor at worst delay (lines). D-G, IPD histograms to binaural beats (open bars) presented with the 300 Hz suppressor for binaural beat frequencies of 500 (D), 550 (E), 600 (F), and 650 (G) Hz. H, Phase plot showing BPs from the original phase plot in A (open squares) and BPs for the four frequencies in the presence of the worst delay tone (open circles). CD and CP values for the upper-frequency regions are shown (see Results for details).

Figure 5C shows the PSTH of the responses to three cycles of the 1 Hz binaural beats at 500 Hz either presented alone (openbars) or presented with a 300 Hz suppressor at worst delay (lines).At ~300 Hz, the phase plot (Fig. 5B) is linear with a slope suggestinga single peak-type input, which dominates that frequency region.From the period histograms in Figures 5D-G, it is clear that theeffect of the 300 Hz suppressor on the response of the neuronto binaural beats was frequency dependent. At 500 Hz, the dischargerate was reduced (Fig. 5D, compare line with open bars), and thepeak response occurred earlier, resulting in a shift in the BP(Fig. 5H, open circles). This shift was significant using a modifiedt test at the p < 0.05 level. We infer from this that the responseof the lower-frequency input that contributes at 500 Hz is reducedby the suppressor, and the response is then dominated by a second,putative input. Both the reduction in discharge rate and the changein BP decreased as the frequency moved away from that of the suppressoruntil, at 650 Hz (Fig. 5G), neither the discharge rate nor theBP response was altered by the addition of the suppressor. Thenew BP values for the four retested frequencies in Figure 5H alignwith those over the upper-frequency region of the original phaseplot. Under the influence of the suppressor, instead of showingintermediate-type behavior with a negative slope (Fig. 5B), theupper-frequency data indicate a peak-type input (CP, +0.02) witha CD of +126 µsec.

A further example is shown in Figure 6. The phase plot of this neuron met the criterion for a linear peak-type response (CP,+0.06) with a CD of +294 µsec (Fig. 6A). However, a detailed analysisof its responses with and without suppression reveals evidenceof more than one binaural input. Figure 6B indicates that thedelay functions did not align around the peak in the dischargerate (compare Fig. 3B). The lowest two frequencies (Fig. 6B, delayfunctions with open circles) had almost identical best delays,as calculated using the vector-averaging method (+670 µsec towithin a couple of microseconds). However, the peaks of the delayfunctions at other frequencies did not align at this delay, despitethe obviously strong delay tuning at each frequency. The upper-frequencyregion (400-600 Hz), depicted by filled circles in Figure 6B,was closely aligned around +400 µsec, whereas the intermediatefrequencies (250-400 Hz) showed peaks of their delay functions(no symbols) between +550 and +394 µsec. When a 600 Hz suppressorwas presented, and the middle-frequency range was reexamined (Fig.6C-H, lines), the BP values (Fig. 6I, open circles) shifted upwardsto align with those of the lowest two frequencies producing apeak-type response (CP, $-$ 0.02) with a CD of +762 µsec over thelower-frequency region (150-400 Hz). The delay functions for thesefrequencies are shown in Figure 6J. Linearity analysis of theBP values over this region (150-400 Hz) revealed that when binauralbeats were presented alone, this region alone was not linear (i.e.,not significant to the p < 0.005 level), but when the suppressedBP values between 250 and 400 Hz were used in the analysis, the150-400 Hz region met the linearity criteria. Using a 200 Hz suppressor,responses were, to a lesser extent, shifted in the opposite direction(Figs. 6G,H, gray bars; Fig. 6I, crosses) to align more with BPsover the upper-frequency range (450-600 Hz). Over a local, high-frequencyregion of the phase plot, the data were consistent with a secondpeak-type input (CP, $-$ 0.01), having a CD of +421 µsec >350-600Hz (Fig. 6K, ITD functions). Note that the CDs of the putativeinputs exposed by the suppression are both longer than that ofthe combined phase plot in Figure 6A.

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Figure 6. A, Linear phase plot of a peak-type (CP, +0.06) neuron with a CD of +294 µsec. B, ITD functions for all of the frequencies examined in A using binaural beats, open circles are 150 and 200 Hz, lines only are 250-350 Hz, filled circles are 400-600 Hz. Vertical line indicates the CD. C, PSTH of the response to 1 Hz binaural beats at 324 Hz and 70 dB SPL (open bars) alone and presented simultaneously with a 600 Hz suppressor (lines). D, IPD histogram constructed from the response in part C. E-H, Responses to binaural beats at 70 dB SPL alone (open bars) and presented simultaneously with a 600 Hz suppressor (lines) or a 200 Hz suppressor (gray bars) for stimulus frequencies of 250 (E), 300 (F), 350 (G), and 400 (H) Hz. I, Phase plot showing BPs from the original phase plot in A that were not reexamined with a suppressor (filled circles), those that were reexamined in conjunction with the 600 Hz suppressor (open circles), and the 200 Hz suppressor (crosses). J, ITD functions for the putative lower-frequency input. K, ITD functions for the putative upper-frequency input.

Convergence of peak-type and trough-type inputs

Figure 7 shows data from an IC neuron with a complex phase plot (Fig. 7A). PSTHs or period histograms to binaural beats alone(Fig. 7C-H, open bars) indicate that the response to each cycleof IPD was dominated by a main peak in the discharge rate, but,at most frequencies, there was also a strong second "lobe" ofactivity evoked during each cycle. The second lobe had the effectof shifting mean BP values upwards and away from those that wouldbe predicted by the main response peak of the discharge patternalone. This main response peak dominated the response for frequenciesat either end of the phase plot and was consistent with an underlyingpeak-type input (Fig. 7B, ITD functions). Lines in Figure 7C-Hshow responses to binaural beats in the presence of a 400 Hz suppressor,a frequency at which the response was dominated by the main peakof the response (data not shown). In the presence of the suppressor,BP values were shifted dramatically upwards to give a trough-typeresponse (CP, +0.41), with a CD of +138 µsec (Fig. 7I, open circles).Figure 7J shows ITD functions constructed from the response tobinaural beats + suppressor, clearly demonstrating the revealedtrough-type behavior. Subtracting the revealed trough-type ITDfunctions in Figure 7J from the original ITD functions in Figure7B leaves ITD functions (Fig. 7K) that reflect the peak-type responseevident in the original functions, shifted downwards as a resultof the elevated baseline response in Figures 7C-H. The gray barsin Figure 7, C and D, indicate a repeat measure of the responseto binaural beats alone, obtained after the response to binauralbeats and the suppressor indicating that the responses were stableover time.

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Figure 7. A, Complex, nonlinear phase plot for an IC neuron with a BF of 242 Hz. B, ITD functions constructed from the response to binaural beats. C, PSTH of the response to binaural beats at BF (242 Hz) presented alone (open and gray bars) or presented simultaneously with a 400 Hz suppressor (lines). D, IPD histograms constructed from the PSTH responses in part C. E-H, IPD histograms for stimulus frequencies of 175 (E), 200 (F), 300 (G), and 350 (H) Hz. I, Phase plot showing BPs from the original phase plot in A (open squares) and BPs in the presence of the suppressor (open circles). The dotted regression line at the bottom of the phase plot indicates a possible slope for the putative peak-type input, the input that dominates the frequencies at either end of the phase plot. J, ITD functions of the revealed trough-type input. K, ITD functions of the main peak-type input, derived by subtracting the ITD functions of the trough-type input in part J from the ITD functions in part B.

Thus, the most parsimonious explanation of the complex phase plot of Figure 7A is convergence from a peak-type input and atrough-type input from the brainstem onto a single neuron in theIC.

Convergence explains linear intermediate-type phase plots

One class of linear phase plot that requires explanation because it is inconsistent with the simple coincidence detectionmodel is the intermediate-type. As with linear peak-type and trough-typephase plots, intermediate-type phase plots are characterized bya CD, but one that occurs somewhere between the peak and the troughof the delay function.

Figure 8 shows responses from an IC neuron with an intermediate-type phase plot (Fig. 8A, CP, +0.35) and a CD of $-$ 112 µsec.The PSTH (Fig. 8C, BF response) and the IPD histograms (Figs.8D-H) to binaural beats and the ITD functions (Fig. 8B) providean explanation for this behavior. As with the example in Figure7, there is a secondary lobe of activity that shifted mean BPvalues away from those associated with the peak-type behaviorof the major peak in the response. Unlike the previous examples,there are no parts of the phase plot that are indicative of simplepeak-type or trough-type behavior. This suggests that the responsiveareas of the putative inputs to this IC neuron are completelyoverlapping. Nevertheless, suppression with a 450 Hz tone revealedevidence of a peak-type input for this neuron. The lines in Figures8C-H indicate that the suppressor abolished the main peak of theresponse, leaving a peak-type input (Fig. 8I, open circles) witha CP of +0.96 and a CD of $-$ 1644 µsec. This is confirmed by theITD functions in Figure 8J. When a 200 Hz suppressor was used,BP values were shifted in the opposite direction (Fig. 8I, crosses),toward values consistent with the main peak in the ITD functions,although this shift was not enough to produce a peak-type phaseplot. Subtracting the ITD functions in Figure 8J from those inFigure 8B produces the ITD functions in Figure 8K, which providessupporting evidence that a peak-type input is present.

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Figure 8. Same format as in Figure 7, showing responses of an IC neuron with an intermediate-type phase plot with a CD of $-$ 112 µsec and a CP of +0.35 (A). B, ITD functions showing the main response peak and a secondary lobe of activity at each frequency. PSTH (C) and IPD histogram (D) of the response to 67 dB SPL binaural beats at 315 Hz either presented alone (open bars) or in conjunction with a 450 Hz suppressor (lines). E-H, IPD histograms of the response to binaural beats at 315 Hz either presented alone (open bars) or in conjunction with a 450 Hz suppressor (lines) or a 200 Hz suppressor (gray bars) for stimulus frequencies of 200 (E), 250 (F), 300 (G), and 350 (H) Hz. I, Phase plot showing BPs from the original phase plot in A for frequencies not reexamined (filled circles), frequencies that were reexamined (open squares), and those BPs obtained in the presence of the suppressor (open circles). J, ITD functions of the revealed peak-type input. K, ITD functions that remain after subtracting the ITD functions of the peak-type input in part J from the ITD functions in part B.

Figure 9 shows a second example of a neuron with an intermediate-type phase plot (Fig. 9A), having a CP of +0.20 and a CDof +102 µsec. For this neuron, the PSTH (Fig. 9C) and the IPDhistograms in response to binaural beats (Figs. 9D-H) show onlya single peak in the discharge rate for each cycle of IPD; unlikein Figure 8, there is no secondary lobe of activity influencingthe mean BP values. Responses to binaural beats were reexaminedin the presence of a 100 Hz suppressor. At the lowest frequencyexamined (150 Hz), the response was completely demodulated, andno IPD-sensitive component was evident. However, as the frequencywas increased, the response became increasingly IPD-sensitive,and the BP was shifted toward lower IPD values, such that IPDsthat previously evoked no activity now strongly activated theneuron in the presence of the suppressor (Fig. 9C-H, lines). Thehigher frequencies indicated peak-type behavior (CP, +0.03 overthe range of 350-550 Hz), with a CD of +210 µsec. We suggest thatthis IC neuron receives a delay-sensitive inhibitory input thatcounters an excitatory input. At the lowest frequencies (up to300 Hz), the suppressor tone is only partially successful in suppressingthe inhibitory input and, as a result, BPs (Fig. 9I, open circles)were only partially shifted. For frequencies >300 Hz, however,the suppression of the inhibitory input was complete, and BPswere shifted to indicate a peak-type. This explanation is supportedby Figure 9J, which shows ITD functions for those frequencies>300 Hz in Figure 9I. The ITD functions are clearly symmetricalaround a peak (at +210 µsec) in the discharge rate, and this accountsfor the peak-type behavior. A possible explanation for this behavioris that excitatory and inhibitory inputs, whose frequency representationoverlaps completely, are present. The possibility of this scenarioexisting in the IC, which is consistent with recent explanationsby other researchers, is examined further in the Discussion.

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Figure 9. Similar format to those in Figures 7 and 8 showing responses of an IC neuron with an intermediate-type phase plot with a CD of +102 µsec and a CP of +0.20 (A). B, ITD functions of all frequencies. PSTH (C) and IPD histogram (D) of the response to binaural beats at 250 Hz either presented alone (open bars) or in conjunction with a 100 Hz suppressor (lines). E-H, IPD histograms of the response to binaural beats either presented alone (open bars) or in conjunction with the suppressor (lines) for stimulus frequencies of 150 (E), 350 (F), 450 (G), and 550 (H) Hz. I, Phase plot showing BPs from the original phase plot in A for frequencies not reexamined (filled circles), frequencies that were reexamined (open squares), and those BPs obtained in the presence of the suppressor (open circles). J, ITD functions of the revealed peak-type input.

Responses of the population of IC neurons to suppressive tones

Table 1 summarizes the initial phase plots that were observed for the 43 neurons examined with the suppressor tone and theinputs revealed after suppression. The number of neurons in eachcategory of initial phase plot is indicated at the head of eachcolumn. Of the 37 complex (intermediate-type or nonlinear) neuronsexamined with the suppressor method, we were able to demonstratefor 46% (17 of 37) of them the existence of at least one inputthat accorded with the Jeffress model of coincidence detection.However, for neurons in which we were unable to demonstrate unequivocallythe presence of a simple input, changes nevertheless were observed.These neurons are categorized as having "no resolution" in thebottom row of Table 1. Changes such as these fell into threemain categories. The first category contained those neurons forwhich shifts in responses were observed over a range of frequencies,but although the change was in the direction of a peak or trough,the simple response type was not fully resolved. A common observationwith these neurons was that increasing the level of the suppressorin an attempt to remove more of the response of one putative inputoften had a completely suppressive effect, either demodulatingthe response completely or reducing the response to the baseline.Thus, for a further 19% (7 of 37) of neurons we judged the changeto be consistent with evidence of a simpler underlying input.In each case, the change was toward that expected of a peak-typeresponse, but no definitive classification of type was assigned.In the second category, changes were seen at one or two frequenciesthat looked to be consistent with a single input (i.e., one peakof a multipeaked response was abolished), but no consistent evidenceof change was observed at other frequencies. Again, by increasingthe level of the suppressor, the response was usually abolishedcompletely without revealing a simple input. In the third category,responses were complex to start with and, after suppression witha worst-delay tone, remained complex throughout, despite changesat some frequencies.


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Table 1. Summary of initial phase plots and the inputs revealed after suppression

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

We have demonstrated that nonlinear and intermediate-type linear phase plots of IC neurons are consistent with summation ofbinaural inputs from simple brainstem coincidence detectors, assuggested previously (Yin et al., 1986, 1987; Kuwada et al., 1987;Batra et al., 1989). Because even those IC neurons whose phaseplots are linear by our criteria may receive convergent binauralinput, detailed analyses are required to judge whether singleor multiple inputs to an IC neuron are present. The novel aspectof the current study is the selective suppression of one of theputative convergent inputs to the IC to reveal the characteristicsof the remaining inputs.

Using suppressor tones to determine the binaural inputs to IC neurons

The effect of suppressor tones on peak-type neurons with linear phase plots (Figs. 3, 4, reduced discharge rate without ashift in BP) is quite difficult to explain. If the addition ofthe suppressor tone merely introduced extra spikes by linear superposition(Yin et al., 1986, 1987), the response of the binaural processorto binaural beats would not be reduced. Rather, the extra spikesshould coincide with spikes caused by the beat at all delays.Thus, there would be a demodulation of the beat response withdischarge rates in the troughs increasing without a change indischarge rate at best delay. This is not observed. Because thestimulus to each ear is a two-tone complex, the effect may reflectthe action of two-tone suppression on the discharge of auditorynerve fibers (Arthur et al., 1971): a second tone below BF couldreduce the number of spikes from each ear reaching the coincidencedetector. Alternatively, rather than a simple reduction in thenumber of spikes evoked, synchrony capture (or synchrony suppression;Rose et al., 1967, 1974; Javel, 1981) may lead to increased effectivenessof the suppressor over the binaural beat. Certainly, a synchrony-captureargument appears sufficient for the trough-type neuron shown inFigure 4. Here, the suppressor dominates the synchronization atthe input of the coincidence detector and reduces the dischargerate for all IPDs to that at the trough IPD.

It seems unlikely that two-tone suppression could explain all of the phase shifts we have observed in the absence of convergentinput to the IC. If the suppressor caused complete synchrony capturein the auditory nerve (Rose et al., 1967; Javel, 1981), therewould have been no response to the binaural beat and, hence, nobest IPD. Alternatively, if the suppressor had no effect on synchronizationto the beat component, the best IPD would be unaffected. Betweenthese extremes, where both tones are represented, synchrony suppressionmight have a role to play. However, in these experiments therewas no fixed phase relation between the suppressor and the binauralbeat tones because of the large frequency difference. Therefore,systematic phase shifts in a particular direction are unlikely.

It appears that two-tone suppression cannot explain effects in the absence of convergence beyond the coincidence detectors.However, if we assume convergence, synchrony capture may be importantfor switching off one of the inputs to the IC. Both binaural beatand suppressor will activate inputs whose response areas overlap,but the more effective tone will dominate the phase locking tothe exclusion of the other (Rose et al., 1967; Javel, 1981). Thus,the input to the "suppressed" SOC neuron will be dominated bythe anti-phase suppressor tone and hardly affected by the binauralbeat tone.

Our ability to deconstruct complex phase plots of IC neurons into simpler phase plots that reflect the underlying inputs frombrainstem nuclei is critically dependent on being able to suppressselectively an input, while leaving other inputs largely intact.Initially, we chose suppressors from a local region of the phaseplot that showed peak-type or trough-type behavior, i.e., in whichthe response locally is characteristic of simple coincidence detection.In such cases, the suppressor often completely suppressed oneinput to reveal another peak-type or trough-type input. However,even when suppressor was chosen from a linear frequency regionthat was not peak-type or trough-type, or was nonlinear, simplepeak-type or trough-type inputs were often revealed.

Most functional studies of IC inputs have used pharmacological techniques (Faingold et al., 1991; Sally and Kelly, 1992; Yanget al., 1992; Kelly and Sally, 1993; Park and Pollak, 1993) overwhich the present method has some advantages. First, it is technicallystraightforward; it does not require any neuropharmacologicalagent to be delivered to either the IC or the nuclei that projectto it, to block neurotransmitter release or destroy neurons. Second,it is reversible simply by switching off the second tone. Kainicacid lesions are irreversible, and neuropharmacological agentsapplied by iontophoresis require extensive recovery times. Third,the data are consistent with the hypothesis that the effect issite-specific. The presumed site for the effect of the suppressortone is the SOC, specifically on those neurons that project tothe IC neuron under study.

One disadvantage is that it may not always be possible to suppress completely any one of the inputs. This is particularlythe case for some neurons with highly complex phase plots, orwith linear, intermediate-type phase plots.

Sources of binaural projections to the IC

There are numerous binaural projections into the IC, including three direct projections: the ipsilateral MSO, the ipsilateraland contralateral LSO, and at least three indirect sources, includingthe ipsilateral and contralateral dorsal nucleus of the laterallemniscus (DNLL) and the contralateral IC.

The most likely source of excitatory binaural inputs to IC neurons are the MSO and the LSO. MSO neurons are largely peak-type(Batra et al., 1995; Spitzer and Semple, 1995), showing maximain their delay functions at positive CDs (Yin and Chan, 1990).In the present study, all linear peak-type neurons had positiveCDs, consistent with a projection from the ipsilateral MSO. Neuronsin the low-frequency lobe of the LSO, which projects to both contralateraland ipsilateral IC, may be either peak-type or trough-type (Jorisand Yin, 1995).

The data shown in Figure 9 suggested that inhibitory effects also play a role in shaping some phase plots. There are at leasttwo sources of delay-sensitive inhibitory input to IC neurons.First, the LSO provides direct inhibitory synapses in IC (Brunso-Bechtoldet al., 1994; Oliver et al., 1995). Second, IC neurons may receiveinhibitory input from the DNLL, particularly high-frequency neuronssensitive to interaural level differences and to ITDs in the envelopesof high-frequency stimuli (Kidd and Kelly, 1996), and low-frequencyneurons sensitive to ITD (Brugge et al., 1970, Fitzpatrick etal., 1996). However, whether the source of inhibition is director indirect, suppression probably occurs at the level of the primarybinaural neurons in the SOC. In the case of binaural inhibitoryinputs derived directly from the SOC, suppression reduces theiroutput as well as their inhibitory effect in the IC. In the caseof inhibition mediated through the an indirect pathway, suppressionreduces the excitatory input, which in turn reduces any inhibitoryeffect on target neurons in the IC.

Interestingly, the form of the response shown in Figure 9 is remarkably similar to that suggested in a possible model forIC neurons that show "sawtooth" ITD functions (Kuwada et al.,1997). These authors suggested that DNLL inputs might sharpenthe tuning of the IC neurons, effectively removing the excitatoryresponses at particular IPDs. Consistent with this, in Figure9, the effect of adding the suppressor was to expand the rangeof IPDs to which the neuron responded on one flank of the delayfunction only (compare Fig. 8 in Kuwada et al., 1997). This supportsour interpretation that the inhibitory input was suppressed toreveal the nature of the excitatory input.

Convergence and the role of delay-sensitive neurons in the IC

One possible role of convergence of delay-sensitive inputs from the brainstem onto IC neurons is the processing of auditorymotion. Many neurons in the IC are sensitive to the depth anddirection of dynamic IPD cues (Spitzer and Semple, 1993), whereasmost neurons in the MSO are not (Spitzer and Semple, 1992). Inaddition, MSO neurons insensitive to dynamic IPD cues have phase-lockedmonaural inputs, consistent with them being primary binaural neurons,whereas the few MSO neurons that are sensitive to motion cueshave nonphase-locked inputs (M. W. Spitzer and M. N. Semple, personalcommunication), consistent with them receiving descending input,possibly from the IC. We are investigating the responses of ICneurons to binaural beats and auditory motion stimuli, using thesecond-tone paradigm to determine whether the enhanced sensitivityto motion depends on convergent input from brainstem coincidencedetectors.

  FOOTNOTES

Received Nov. 11, 1997; revised May 15, 1998; accepted May 20, 1998.

We thank the two anonymous reviewers who provided insightful and useful comments. We especially thank David Marshall for hisadvice on data analysis.
Correspondence should be addressed to Dr. David McAlpine, Department of Biomedical Science, University of Sheffield, WesternBank, Sheffield, S10 2TN, UK.

Dr. Jiang's present address: Department of Otorhinolaryngology, Head and Neck Surgery, Queens Medical Centre, Nottingham,UK.

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Results
Discussion
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