Thomas H. Brown

Yale University, New Haven, CT 
"Thomas Brown"
Mean distance: 17.63 (cluster 17)


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John Patrick McGann grad student 2003 Yale
Sharon C. Furtak grad student 2006 Yale
Dianna B. Kholodar-Smith grad student 2008 Yale
Sun Jung Bang grad student 2009 Yale
Brianne A. Kent grad student 2010-2011 Yale
Ashwini Parsana grad student 2012 Yale
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Calub CA, Furtak SC, Brown TH. (2018) Revisiting the autoconditioning hypothesis for acquired reactivity to ultrasonic alarm calls. Physiology & Behavior
Baysinger AN, Kent BA, Brown TH. (2012) Muscarinic receptors in amygdala control trace fear conditioning. Plos One. 7: e45720
Kent BA, Brown TH. (2012) Dual functions of perirhinal cortex in fear conditioning. Hippocampus. 22: 2068-79
Parsana AJ, Moran EE, Brown TH. (2012) Rats learn to freeze to 22-kHz ultrasonic vocalizations through autoconditioning. Behavioural Brain Research. 232: 395-9
Navaroli VL, Zhao Y, Boguszewski P, et al. (2012) Muscarinic receptor activation enables persistent firing in pyramidal neurons from superficial layers of dorsal perirhinal cortex. Hippocampus. 22: 1392-404
Parsana AJ, Li N, Brown TH. (2012) Positive and negative ultrasonic social signals elicit opposing firing patterns in rat amygdala. Behavioural Brain Research. 226: 77-86
Moyer JR, Furtak SC, McGann JP, et al. (2011) Aging-related changes in calcium-binding proteins in rat perirhinal cortex. Neurobiology of Aging. 32: 1693-706
Bang SJ, Brown TH. (2009) Muscarinic receptors in perirhinal cortex control trace conditioning. The Journal of Neuroscience : the Official Journal of the Society For Neuroscience. 29: 4346-50
Bang SJ, Brown TH. (2009) Perirhinal cortex supports acquired fear of auditory objects. Neurobiology of Learning and Memory. 92: 53-62
Kholodar-Smith DB, Allen TA, Brown TH. (2008) Fear conditioning to discontinuous auditory cues requires perirhinal cortical function. Behavioral Neuroscience. 122: 1178-85
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