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Peter Christian Petersen, Ph.D.

Affiliations: 
2011-2015 University of Copenhagen, København, Denmark 
 2016- Institute of Neuroscience NYU Langone Medical Center 
Area:
Systems Neuroscience
Website:
http://petersen.neuroscience.rocks
Google:
"https://scholar.google.dk/citations?user=RywQhd8AAAAJ&hl=da"
Mean distance: 27878.1 (cluster 35)
 
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Publications

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Petersen PC, Vöröslakos M, Buzsaki G. (2022) Brain temperature affects quantitative features of hippocampal sharp wave ripples. Journal of Neurophysiology
Petersen PC, Siegle JH, Steinmetz NA, et al. (2021) CellExplorer: A framework for visualizing and characterizing single neurons. Neuron
Vöröslakos M, Miyawaki H, Royer S, et al. (2021) 3D-printed Recoverable Microdrive and Base Plate System for Rodent Electrophysiology. Bio-Protocol. 11: e4137
Vöröslakos M, Petersen PC, Vöröslakos B, et al. (2021) Metal microdrive and head cap system for silicon probe recovery in freely moving rodent. Elife. 10
Petersen PC, Buzsáki G. (2020) Cooling of Medial Septum Reveals Theta Phase Lag Coordination of Hippocampal Cell Assemblies. Neuron
Radosevic M, Willumsen A, Petersen PC, et al. (2019) Decoupling of timescales reveals sparse convergent CPG network in the adult spinal cord. Nature Communications. 10: 2937
Petersen PC, Berg RW. (2017) Spinal Cord Preparation from Adult Red-eared Turtles for Electrophysiological Recordings during Motor Activity. Bio-Protocol. 7: e2381
Petersen P, Berg R. (2017) Spinal Cord Preparation from Adult Red-eared Turtles for Electrophysiological Recordings during Motor Activity Bio-Protocol. 7
Petersen PC, Berg RW. (2016) Lognormal firing rate distribution reveals prominent fluctuation-driven regime in spinal motor networks. Elife. 5
Petersen PC, Berg RW. (2016) Author response: Lognormal firing rate distribution reveals prominent fluctuation–driven regime in spinal motor networks Elife
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