User:Nakamoto/About Kyle

Kyle T. Nakamoto Postdoctoral Researcher

EDUCATION

California State University Los Angeles	B.A. 1993-1999	Experimental Psych. / Classical Music

University of California Irvine	Ph.D.	       1999-2005	Cognitive Science

MRC-Institute of Hearing Research(postdoc)	2005-2008	Auditory Neurophysiology

Northeastern Ohio Univ. College of Medicine (postdoc)	2009	       Auditory Neuroanatomy

Memberships in professional societies:

Society for Neuroscience

Association for Research in Otolaryngology

American Physiologyical Society

B. Publications

Research Papers:

Zhang J, Nakamoto KT, and Kitzes LM. Binaural interaction revisited in the cat primary auditory cortex. J Neurophysiol 91: 101-117, 2004.

Nakamoto KT, Zhang J, and Kitzes LM. Response patterns along an isofrequency contour in cat primary auditory cortex (AI) to stimuli varying in average and interaural levels. J Neurophysiol 91: 118-135, 2004.

Zhang J, Nakamoto KT, and Kitzes LM. Modulation of level response areas and stimulus selectivity of neurons in cat primary auditory cortex. J Neurophysiol 94: 2263-2274, 2005.

Nakamoto KT, Zhang J, and Kitzes LM. Temporal nonlinearity during recovery from sequential inhibition by neurons in the cat primary auditory cortex. J Neurophysiol 95: 1897-1907, 2006.

Palmer AR, Hall DA, Sumner C, Barrett DJ, Jones S, Nakamoto K, and Moore DR. Some investigations into non-passive listening. Hear Res 229: 148-157, 2007.

Nakamoto KT, Jones SJ, and Palmer AR. Descending projections from auditory cortex modulate sensitivity in the midbrain to cues for spatial position. J Neurophysiol 99: 2347-2356, 2008.

Zhang J, Nakamoto KT, and Kitzes LM. Responses of neurons in the cat primary auditory cortex to sequential sounds. Neuroscience 161: 578-588, 2009.

Nakamoto KT, Shackleton TM, and Palmer AR. Responses in the Inferior Colliculus of the Guinea Pig to Concurrent harmonic series and the effect of Inactivation of Descending Controls. J Neurophysiol 2050-2061, 2010.

Nakamoto KT, Shackleton TM, and Palmer AR. Corticofugal control of binaural temporal integration in the inferior colliculus of the guinea pig. (in review).

Nakamoto K, and Palmer AR. The ability of primary auditory cortex (AI) cells, in the guinea pig, to follow amplitude modulated stimuli is affected by interaural level differences (in preparation).

Nakamoto KT, Shackleton TM, and Palmer AR. Corticofugal control of auditory object integration. (in preparation).

Abstracts:

Nakamoto KT, and Perrott DR. Detection of dynamic interaural phase differences and dynamic interaural intensity differences. In: Western Psychological Association Los Angeles, California, USA: 1999a.

Nakamoto KT, and Perrott DR. Discrimination of Dynamic Interaural Phase Differences at Different Azimuths. In: Western Psychological Association Los Angeles, California, USA: 1999b.

Nakamoto KT, Smith RL, and Berg BG. Modeling the temporal response of auditory nerve fibers with a leaky integrator. Acoustical Society of America, Chicago, Illinois, USA: 2000.

Nakamoto K, and Kitzes LM. Response patterns along an isofrequency contour in cat primary auditory cortex to fixed-frequency stimuli varying in average and interaural level. . In: Association for Research in Otolaryngology MidWinter Meeting. St. Petersburg Beach, Florida, USA: 2001.

Zhang J, Nakamoto KT, and Kitzes LM. Responses of cat primary auditory cortical neurons to sequential pure tones. In: Neuroscience. Orlando, Florida, USA: 2002.

Nakamoto KT, Zhang J, and Kitzes LM. Relationship among the topography of monaural responses and various binaural responses to stimulus level in the primary auditory cortex of the cat. In: Neuroscience. New Orleans, Louisiana, USA: 2003.

Kitzes LM, Nakamoto K, and zhang J. Proximity Trumps Stimulus Level in Cortical Masking. In: Association for Research in Otolaryngolog MidWinter Meeting. New Orleans, Louisiana, USA: 2005.

Nakamoto KT, and Palmer AR. The ability of primary auditory cortex (AI) cells, in the guinea pig, to follow amplitude modulated stimuli is affected by interaural level differences. In: Auditory Cortex. Grantham, Nottinghamshire, UK: 2006a.

Wallace MN, Nakamoto KT, Bailey JMS, and Palmer AR. Columnar responses in the two core areas of guinea pig auditory cortex. In: Auditory Cortex. Grantham, Nottinghamshire, UK: 2006.

Nakamoto KT, and Palmer AR. The effect of cortical cooling on ILD functions in the inferior colliculus neurons in the guinea pig. In: British Society of Audiology Short Papers Meeting. Cambridege, UK: 2006b.

Nakamoto K, and Palmer AR. Cooling Auditory Cortex Alters the Interaural Level Difference Sensitivity of Neurons in the Inferior Colliculus. In: Association for Research in Otolaryngolog MidWinter Meeting. Denver, CO, USA: 2007.

Nakamoto KT, Shackleton TM, and Palmer AR. Cortical cooling alters Inferior Colliculus responses to harmonic complexes. In: British Society of Audiology Short Papers Meeting. London, UK: 2007.

Nakamoto KT, Shackleton TM, and Palmer AR. The Corticofugal System to the Inferior Colliculus Separately Modulates the Responses to Inputs from the Two Ears In: Association for Research in Otolaryngology MidWinter Meeting. Phoenix, Arizaon, USA: 2008a.

Nakamoto KT, Shackleton TM, and Palmer AR. The ILD of spatially distinct concurrent sounds is represented in the temporal response of IC neurons in the guinea pig In: British Society of Audiology Short Papers Meeting. Newcastle, UK: 2008b.

Nakamoto K, Shackleton TM, and Palmer AR. How are Concurrent Stimuli with Different Spatial Location Encoded in the Inferior Colliculus. In: Association for Research in Otolaryngolog MidWinter Meeting Baltimore, Maryland, USA: 2009.