James C. Liao

James C. Liao

Department of Biology, University of Florida, The Whitney Laboratory for Marine Bioscience

Affiliated withUniversity of Florida, The Whitney Laboratory for Marine Bioscience

Research Area

Biography

James C. Liao is an Associate Professor of biology at the University of Florida and the Whitney Laboratory for Marine Bioscience, where he is also an Affiliate Professor in the Clayton Pruitt Family Department of Biomedical Engineering and an Affiliate Curator of Ichthyology at the Florida Museum of Natural History. His research integrates approaches from engineering, neuroscience and physiology to understand the fundamental principles of animal sensing and locomotion. In particular, he is interested in understanding how fishes behave from the perspective of multiple biological levels, from single neurons to group behavior. James received his B.A. magna cum laude in Biology from Wesleyan University, and his M.A. and Ph.D. in Biomechanics from Harvard University. He was then an NIH postdoc and Research Associate in the Department of Neurobiology and Behavior at Cornell University. He has won research awards from The Society for Experimental Biology and the American Society for Ichthyologists and Herpetologists, and has been recognized multiple times by the Derek Bok Center for Excellence in Teaching at Harvard.

JoVE Journal Publications

ArticleTotal : 1
Year
Activity of Posterior Lateral Line Afferent Neurons during Swimming in Zebrafish
Publication title

Cited by 6

2021

Other Publications

Article
Year
Synaptic Ribbons Require Ribeye for Electron Density, Proper Synaptic Localization, and Recruitment of Calcium Channels.

Cell reports| PubMed ID: 27292637

2016
2010
2011
2011
2012
The effect of flow speed and body size on Kármán gait kinematics in rainbow trout.

The Journal of experimental biology| PubMed ID: 23737556

2013
A kinematic model of Kármán gaiting in rainbow trout.

The Journal of experimental biology| PubMed ID: 24115054

2013
2014
2015
2015
Refuging rainbow trout selectively exploit flows behind tandem cylinders.

The Journal of experimental biology| PubMed ID: 27445401

2016
2017
Accelerating fishes increase propulsive efficiency by modulating vortex ring geometry.

Proceedings of the National Academy of Sciences of the United States of America| PubMed ID: 29229818

2017
2018
Head width influences flow sensing by the lateral line canal system in fishes.

The Journal of experimental biology| PubMed ID: 30194249

2018
2017
2019
An Algorithmic Approach to Natural Behavior.

Current biology : CB| PubMed ID: 32516620

2020
2020