Kathleen E. Cullen
Affiliations: | McGill University, Montreal, QC, Canada |
Website:
http://www.medicine.mcgill.ca/physio/cullenlab/index.htmlGoogle:
"Kathleen Cullen"Mean distance: 13.92 (cluster 17) | S | N | B | C | P |
Parents
Sign in to add mentor| Robert A. McCrea | grad student | 1991 | Chicago |
| Daniel Guitton | post-doc | Montreal Neurological Institute |
Children
Sign in to add trainee| Ariana Andrei | grad student | McGill | |
| Sascha Dubrovsky | grad student | McGill | |
| Jillian McKee | grad student | McGill | |
| Diana Elizabeth Mitchell | grad student | McGill | |
| Marion Van Horn | grad student | McGill | |
| Gregory Wellenius | grad student | McGill | |
| Soroush G. Sadeghi | grad student | 2002- | McGill |
| Mohsen Jamali | grad student | 2006- | McGill |
| Jefferson E. Roy | grad student | 2003 | McGill |
| Pierre A. Sylvestre | grad student | 2004 | McGill |
| Jessica X. Brooks | grad student | 2011 | McGill |
| Alexis Dale Paez | grad student | 2009-2017 | McGill |
| Jerome Carriot | post-doc | 2008- | McGill |
| Mathieu Beraneck | post-doc | 2004-2006 | McGill |
| Corentin Massot | post-doc | 2006-2009 | McGill |
BETA: Related publications
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Publications
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| Hughes NC, Roberts DC, Tarchini B, et al. (2024) Instrumented swim test for quantifying motor impairment in rodents. Scientific Reports. 14: 29270 |
| Steinhardt CR, Mitchell DE, Cullen KE, et al. (2024) Pulsatile electrical stimulation creates predictable, correctable disruptions in neural firing. Nature Communications. 15: 5861 |
| Zobeiri OA, Cullen KE. (2024) Author Correction: Cerebellar Purkinje cells combine sensory and motor information to predict the sensory consequences of active self-motion in macaques. Nature Communications. 15: 4804 |
| Zobeiri OA, Cullen KE. (2024) Cerebellar Purkinje cells in male macaques combine sensory and motor information to predict the sensory consequences of active self-motion. Nature Communications. 15: 4003 |
| Mohammadi M, Carriot J, Mackrous I, et al. (2024) Neural populations within macaque early vestibular pathways are adapted to encode natural self-motion. Plos Biology. 22: e3002623 |
| Aryan R, Zobeiri OA, Millar JL, et al. (2024) Effect of vestibular loss on head-on-trunk stability in individuals with vestibular schwannoma. Scientific Reports. 14: 3512 |
| Cullen KE. (2023) Internal models of self-motion: neural computations by the vestibular cerebellum. Trends in Neurosciences. 46: 986-1002 |
| Wiboonsaksakul KP, Della Santina CC, Cullen KE. (2023) Prosthetic Stimulation of the Vestibular Nerve Can Evoke Robust Eye and Head Movements Despite Prior Labyrinthectomy. Otology & Neurotology : Official Publication of the American Otological Society, American Neurotology Society [and] European Academy of Otology and Neurotology |
| Cullen KE. (2023) Vestibular motor control. Handbook of Clinical Neurology. 195: 31-54 |
| Cullen KE, Chacron MJ. (2023) Neural substrates of perception in the vestibular thalamus during natural self-motion: A review. Current Research in Neurobiology. 4: 100073 |