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home > education+workforce development > undergraduate level programs > ibrp > y. qin

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Interdisciplinary Biomedical Research Program (IBRP)

IBRP Overview

Yi-Xian Qin, Ph.D.
Asst. Professor, Department of Biomedical Engineering
Funding through the National Space Biomedical Research Institute (NSBRI), US Army Medical Research, and National Institute of Health (NIH).

Figure 1. Finite element modeling of a porous coated implant and the interface with bone, examining the mechanical characteristics of osseointegration. This work demonstrates the specific mechanical environment which promotes bony ingrowth, and therefore stabilization, of the implant.

Figure 2. Bone fluid flow is hypothesized to play a critical regulatory role in bone remodeling, and is closely coupled to the dynamic loading conditions of the bone (e.g., frequency and strain rate). Under identical strain amplitudes, high frequency mechanical stimuli (30 Hz) creates approximately a 10-fold increase in fluid flow, as compared to low frequency loading (0.1 Hz).

Research in my lab is focused on the physical mechanisms involved in the control of tissue growth, healing, and homeostasis, especially bone adaptation influenced by mechanical environment. And how these mechanisms can be utilized in the treatment and prevention of disease and injury. It is clear that bone senses and responds to biomechanical stimuli towards the achievement and maintenance of a structurally appropriate skeletal structure. In addition to strain magnitude, bone tissue has the ability to differentiate between shear and normal strain, cycle number, loading frequency, and even fluid pressure and its gradients. The interdependent roles of these mechanical signals are investigated through empiric and analytic models to provide support for the complex interactive mechanism of bone remodeling.

My research also focuses on the development of non-invasive scanning acoustic diagnostic system for tissue quality. The goal of this project is to develop a new technology, which will lead to a better understand of the progressive adaptation of bone loss in aging populations and microgravity environment. The technology will be used for assessing musculoskeletal complications such as osteoporosis.

IBRP intern will be expected to work in the lab with other graduate and undergraduate students on a dedicated project which will include hands-on experiment and data analysis. Computational background, and/or materials characterization interests, would bring assets to the lab.

Contact Information
email: yi-xian.qin@sunysb.edu
url: http://www.bme.sunysb.edu/bme/people/faculty/y_qin.html