Environmental Enrichment Improves Response Strength, Threshold, Selectivity, and Latency of Auditory Cortex Neurons

doi:10.1152/jn.00059.2004

Environmental Enrichment Improves Response Strength, Threshold, Selectivity, and Latency of Auditory Cortex Neurons

Navzer D. Engineer^*, Cherie R. Percaccio^*, Pritesh K. Pandya, Raluca Moucha, Daniel L. Rathbun and Michael P. Kilgard

Neuroscience Program, School of Behavioral and Brain Sciences, University of Texas at Dallas, Richardson, Texas 75083-0688

Submitted 16 January 2004; accepted in final form 8 March 2004

Over the last 50 yr, environmental enrichment has been shownto generate more than a dozen changes in brain anatomy. Theconsequences of these physical changes on information processinghave not been well studied. In this study, rats were housedin enriched or standard conditions either prior to or afterreaching sexual maturity. Evoked potentials from awake ratsand extracellular recordings from anesthetized rats were usedto document responses of auditory cortex neurons. This reportdetails several significant, new findings about the influenceof housing conditions on the responses of rat auditory cortexneurons. First, enrichment dramatically increases the strengthof auditory cortex responses. Tone-evoked potentials of enrichedrats, for example, were more than twice the amplitude of ratsraised in standard laboratory conditions. Second, cortical responsesof both young and adult animals benefit from exposure to anenriched environment and are degraded by exposure to an impoverishedenvironment. Third, housing condition resulted in rapid remodelingof cortical responses in <2 wk. Fourth, recordings made underanesthesia indicate that enrichment increases the number ofneurons activated by any sound. This finding shows that theevoked potential plasticity documented in awake rats was notdue to differences in behavioral state. Finally, enrichmentmade primary auditory cortex (A1) neurons more sensitive toquiet sounds, more selective for tone frequency, and alteredtheir response latencies. These experiments provide the firstevidence of physiologic changes in auditory cortex processingresulting from generalized environmental enrichment.

Address for reprint requests and other correspondence: M. P. Kilgard, Neuroscience Program, School of Behavioral and Brain Sciences, GR 41, Univ. of Texas at Dallas, Richardson, TX 75083-0688 (E-mail: kilgard{at}utdallas.edu).

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