Intrinsic optical signals from rat primary auditory cortex in response to sound stimuli presented to contralateral, ipsilateral and bilateral ears

In the auditory cortex, primitive features of acoustic stimuli are represented for auditory scene analysis. A typical example of a feature representation is the tonotopic map, in which sound frequencies are spatially arranged in an orderly manner. Some neurons in the auditory cortex are sensitive to sound source location, which is another important feature for auditory scene analysis. In the present study, using the intrinsic optical imaging technique, we attempted to visualize the two-dimensional pattern of neuronal population responses in the primary auditory cortex of rats to pure tones presented at various frequencies and sound intensities. The observed arrangements of sound frequencies were consistent with those obtained by electrophysiological mapping, which indicates that our intrinsic optical recording can visualize populational responses of neurons. We also found different temporal patterns of intrinsic signals elicited in response to contralateral, ipsilateral, and bilateral ear stimulations. Finally we try to explain the observed differential time courses of intrinsic signal responses from the theoretical point of view on the conduction of neural activities, based on the so far anatomically identified neural pathways in the rodent auditory system.

[1]  G. Gratton,et al.  Shedding light on brain function: the event-related optical signal , 2001, Trends in Cognitive Sciences.

[2]  J. Mendelson,et al.  Responses to time-varying stimuli in rat auditory cortex , 1998, Hearing Research.

[3]  H. Herbert,et al.  Topography of descending projections from the inferior colliculus to auditory brainstem nuclei in the rat , 1993, The Journal of comparative neurology.

[4]  A. Ryan,et al.  Effects of stimulus frequency and intensity on c‐fos mRNA expression in the adult rat auditory brainstem , 1999, The Journal of comparative neurology.

[5]  M. L. Sutter,et al.  Functional topography of cat primary auditory cortex: response latencies , 1997, Journal of Comparative Physiology A.

[6]  Y Matsuda,et al.  Arrangement of orientation pinwheel centers around area 17/18 transition zone in cat visual cortex. , 2000, Cerebral cortex.

[7]  E. G. Jones,et al.  Patterns of axon collateralization of identified supragranular pyramidal neurons in the cat auditory cortex. , 1991, Cerebral cortex.

[8]  Stanley J. Watson,et al.  The rat brain in stereotaxic coordinates (2nd edn) by George Paxinos and Charles Watson, Academic Press, 1986. £40.00/$80.00 (264 pages) ISBN 012 547 6213 , 1987, Trends in Neurosciences.

[9]  N. Harel,et al.  Tonotopic mapping in auditory cortex of the chinchilla , 1996, Hearing Research.

[10]  N Suga,et al.  Cortical computational maps control auditory perception , 1991, Science.

[11]  Paul J. Abbas,et al.  A chronic microelectrode investigation of the tonotopic organization of human auditory cortex , 1996, Brain Research.

[12]  J. Zook,et al.  Geniculo-collicular descending projections in the gerbil , 2000, Brain Research.

[13]  L. Swanson The Rat Brain in Stereotaxic Coordinates, George Paxinos, Charles Watson (Eds.). Academic Press, San Diego, CA (1982), vii + 153, $35.00, ISBN: 0 125 47620 5 , 1984 .

[14]  Robert V. Harrison,et al.  Three Distinct Auditory Areas of Cortex (AI, AII, and AAF) Defined by Optical Imaging of Intrinsic Signals , 2000, NeuroImage.

[15]  J. Bakin,et al.  Suprathreshold auditory cortex activation visualized by intrinsic signal optical imaging. , 1996, Cerebral cortex.

[16]  J. Rauschecker Processing of complex sounds in the auditory cortex of cat, monkey, and man. , 1997, Acta oto-laryngologica. Supplementum.

[17]  J. Saunders,et al.  Sensitivity to simulated directional sound motion in the rat primary auditory cortex. , 1999, Journal of neurophysiology.

[18]  G Gratton,et al.  The event-related optical signal: a new tool for studying brain function. , 2001, International journal of psychophysiology : official journal of the International Organization of Psychophysiology.

[19]  Ben Godde,et al.  Optical Imaging of Cat Auditory Cortex Cochleotopic Selectivity Evoked by Acute Electrical Stimulation of a Multi‐channel Cochlear Implant , 1997, The European journal of neuroscience.

[20]  Peter Herscovitch,et al.  Tonotopic organization in human auditory cortex revealed by positron emission tomography , 1985, Hearing Research.

[21]  M. Kilgard,et al.  Distributed representation of spectral and temporal information in rat primary auditory cortex , 1999, Hearing Research.

[22]  Risto Näätänen,et al.  RAPID COMMUNICATION Scalp-Recorded Optical Signals Make Sound Processing in the Auditory Cortex Visible? , 1999, NeuroImage.