Srivatsun Sadagopan, Ph.D.
Affiliations: | Neurobiology | University of Pittsburgh, Pittsburgh, PA, United States |
Area:
auditory system, auditory cortex, vocalizationsWebsite:
https://auditory.pitt.edu/sadagopan-lab/pi/Google:
"Srivatsun Sadagopan"Mean distance: 13.41 (cluster 17) | S | N | B | C | P |
Parents
Sign in to add mentor| Xiaoqin Wang | grad student | 2001-2008 | Johns Hopkins | |
| (Feedforward processing of sounds in the primary auditory cortex.) | ||||
| David Ferster | post-doc | 2008-2011 | Northwestern | |
| Winrich A. Freiwald | post-doc | 2011-2014 | Rockefeller | |
Children
Sign in to add trainee| Manaswini Kar | grad student | 2018- | University of Pittsburgh |
| Lovisa LjungQvist Brinson | grad student | 2023- | University of Pittsburgh |
| Shi Tong Liu | grad student | 2015-2021 | University of Pittsburgh |
| Maryanna Owoc | grad student | 2017-2022 | University of Pittsburgh |
| Marianny Pernia | post-doc | 2019- | University of Pittsburgh |
| Pilar Montes-Lourido | post-doc | 2017-2021 | University of Pittsburgh |
| Satyabrata Parida | post-doc | 2021-2023 | University of Pittsburgh |
Collaborators
Sign in to add collaborator| Karl Kandler | collaborator | 2015- | University of Pittsburgh |
| Bharath Chandrasekaran | collaborator | 2017- | University of Pittsburgh |
BETA: Related publications
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Publications
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| Parida S, Liu ST, Sadagopan S. (2023) Adaptive mechanisms facilitate robust performance in noise and in reverberation in an auditory categorization model. Communications Biology. 6: 456 |
| Sadagopan S, Kar M, Parida S. (2023) Quantitative models of auditory cortical processing. Hearing Research. 429: 108697 |
| Pernia M, Kar M, Montes-Lourido P, et al. (2023) Pupillometry to Assess Auditory Sensation in Guinea Pigs. Journal of Visualized Experiments : Jove |
| Teichert T, Gnanateja GN, Sadagopan S, et al. (2022) A Linear Superposition Model of Envelope and Frequency Following Responses May Help Identify Generators Based on Latency. Neurobiology of Language (Cambridge, Mass.). 3: 441-468 |
| Kar M, Pernia M, Williams K, et al. (2022) Vocalization categorization behavior explained by a feature-based auditory categorization model. Elife. 11 |
| Montes-Lourido P, Kar M, Pernia M, et al. (2022) Updates to the guinea pig animal model for in-vivo auditory neuroscience in the low-frequency hearing range. Hearing Research. 424: 108603 |
| Owoc MS, Rubio ME, Brockway B, et al. (2022) Embryonic medial ganglionic eminence cells survive and integrate into the inferior colliculus of adult mice. Hearing Research. 420: 108520 |
| Gnanateja GN, Rupp K, Llanos F, et al. (2021) Frequency-following responses to speech sounds are highly conserved across species and contain cortical contributions. Eneuro |
| Montes-Lourido P, Kar M, David SV, et al. (2021) Neuronal selectivity to complex vocalization features emerges in the superficial layers of primary auditory cortex. Plos Biology. 19: e3001299 |
| Montes-Lourido P, Kar M, Kumbam I, et al. (2021) Pupillometry as a reliable metric of auditory detection and discrimination across diverse stimulus paradigms in animal models. Scientific Reports. 11: 3108 |