Honors & News
June 18, 2015
Jong-Hoon Nam Receives NIH R01 Grant
March 17, 2015
John Cormack visits RCBU
John Cormack returned to Rochester and presented a lecture for the RCBU titled
Propagation of plane nonlinear shear waves in soft solids.John is a 2014 UR alumnus and is currently a graduate student at UT Austin working with Professor Mark Hamilton in the Applied Physics Laboratory. John's presentation to RCBU members provided an analytical approach to modeling the nonlinear propagation of shear waves in soft biological materials. While at the UR, John conducted research with Professor Sheryl Gracewski (ME) and Professor Jong-Hoon Nam (ME, BME).
January 18, 2014
Dr. Jong-Hoon Nam Receives HSCCI Pilot Grant
Dr. Jong-Hoon Nam lab's research titled 'Computational analysis of micro-fluidic mechanotransduction in the mammalian cochlea' will be supported by the University of Rochester Office of the Provost and the School of Medicine and Dentistry Dean's office via the HSCCI (Health Sciences Center for Computational Innovation). The HSCCI supports health sciences research using high performance computational resources.
Dr. Nam's lab investigates the mechano-transduction of the inner ear — how the inner ear selects and amplifies external stimuli.
May 11, 2013
Yanju Liu Wins 1st Place in the CIRC (Center for Integrated Research Computing) Annual Poster Session
Yanju Liu won 1st place for her presentation in the CIRC (Center for Integrated Research Computing) Annual Poster Session that took place on Friday, May 10th. Congrats Yanju!
September 11, 2012
Dr. Jong-Hoon Nam Awarded NSF Grant
Jong-Hoon Nam, Ph.D., assistant professor of Biomedical Engineering and Mechanical Engineering, has been awarded a three year grant from the National Science Foundation (NSF). The objective of the project, entitled Multi-Scale Analysis of Mechanotransduction in the Organ of Corti, is to establish a coherent theory of how the organ of Corti (cochlear sensory epithelium) optimizes the force from the outer hair cells in order to magnify tiny vibrations of the basilar membrane.
With ME and BME professor, Sheryl Gracewski, Ph.D. as Co-PI, the research will take two innovative approaches. First, it will integrate cellular physiology and macro/micro mechanics of the cochlea. Second, computational and experimental models will be investigated in parallel to reduce the animal use while maximizing the research outcome. This will make a direct impact on understanding various hearing disorders. Besides hearing sensation, mechano-transduction plays a crucial role in other tissues such as muscle, bone and articular cartilage. Therefore, the findings of this research will advance the general understanding of mechano-sensation.
For more information please visit the Nam Lab.
- Underestimated sensitivity of mammalian cochlear hair cells due to splay between stereociliary columns.Biophys J. 108, 2633-47. (2015 Jun 02).
- Two-compartment passive frequency domain cochlea model allowing independent fluid coupling to the tectorial and basilar membranes.J Acoust Soc Am. 137, 1117-25. (2015 Mar 01).