Mismatch negativity (MMN) in freely-moving rats with several experimental controls

Harms, Lauren; Fulham, W. Ross; Michie, Patricia T.; Todd, Juanita; Budd, Timothy W.; Hunter, Michael; Meehan, Crystal; Penttonen, Markku; Schall, Ulrich; Zavitsanou, Katerina; Hodgson, Deborah M.

Title: Mismatch negativity (MMN) in freely-moving rats with several experimental controls
Creator: Harms, Lauren; Fulham, W. Ross; Michie, Patricia T.; Todd, Juanita; Budd, Timothy W.; Hunter, Michael; Meehan, Crystal; Penttonen, Markku; Schall, Ulrich; Zavitsanou, Katerina; Hodgson, Deborah M.
Relation: NHMRC.1026070
Relation: PLoS ONE Vol. 9, Issue 10
Publisher Link: http://dx.doi.org/10.1371/journal.pone.0110892
Publisher: Public Library of Science
Resource Type: journal article
Date: 2014
Description: Mismatch negativity (MMN) is a scalp-recorded electrical potential that occurs in humans in response to an auditory stimulus that defies previously established patterns of regularity. MMN amplitude is reduced in people with schizophrenia. In this study, we aimed to develop a robust and replicable rat model of MMN, as a platform for a more thorough understanding of the neurobiology underlying MMN. One of the major concerns for animal models of MMN is whether the rodent brain is capable of producing a human-like MMN, which is not a consequence of neural adaptation to repetitive stimuli. We therefore tested several methods that have been used to control for adaptation and differential exogenous responses to stimuli within the oddball paradigm. Epidural electroencephalographic electrodes were surgically implanted over different cortical locations in adult rats. Encephalographic data were recorded using wireless telemetry while the freelymoving rats were presented with auditory oddball stimuli to assess mismatch responses. Three control sequences were utilized: the flip-flop control was used to control for differential responses to the physical characteristics of standards and deviants; the many standards control was used to control for differential adaptation, as was the cascade control. Both adaptation and adaptation-independent deviance detection were observed for high frequency (pitch), but not low frequency deviants. In addition, the many standards control method was found to be the optimal method for observing both adaptation effects and adaptation-independent mismatch responses in rats. Inconclusive results arose from the cascade control design as it is not yet clear whether rats can encode the complex pattern present in the control sequence. These data contribute to a growing body of evidence supporting the hypothesis that rat brain is indeed capable of exhibiting human-like MMN, and that the rat model is a viable platform for the further investigation of the MMN and its associated neurobiology.
Subject: control sequences; auditory cortex; electroencephalography; event-related potentials; frontal lobe; animal models; sequence analysis; skull
Identifier: http://hdl.handle.net/1959.13/1060764
Identifier: uon:16819
Identifier: ISSN:1932-6203
Language: eng
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