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home > education+workforce development > undergraduate level programs > ibrp > p. khalsa

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Interdisciplinary Biomedical Research Program (IBRP)

IBRP Overview

Partap S. Khalsa, D.C., Ph.D.
Assistant Professor of Biomedical Engineering, Neurobiology, and Orthopaedics; Graduate Program Director for BME.
Funding through the National Institutes of Arthritis, Musculoskeletal and Skin Diseases.

Research in our laboratory focuses on molecular, cellular and tissue level mechanisms involved in transduction of mechanical forces in soft tissues by mechanically sensitive neurons. We seek to understand how these mechanisms can be utilized in the diagnosis, prevention and treatment of somatic pain, neuromuscular disease and injury. Electrophysiological recordings of single an populations of neurons are made while robustly controlling the applied mechanical stimulus (Figure 1).

Figure 1. Neural (mechano-nociceptor) population response to a noxious indentation in rat, hairy skin. In A & C (on left), the estimated population response is represented a contour plot (darker regions have higher neural firing rates. In B & D (right), the same data is displayed a 3-D plot.

In a parallel track of investigations, we are exploring the biomechanics of capsular ligaments of the lumbar spine during physiological motions. Direct optical measurements of capsule strain are made while actuating spine specimens under "normal" and "abnormal" loading paradigms. A finite element model of the spine is being developed that will include material properties of the joint capsules (Figure 2).

Figure 2. Three-dimensional lumber spine FEM. Geometry was determined by human anatomical lower lumber spine. Soft tissues, disc and ligament, were attached at the contact surface and point.

Investigations use a broad range of tools including immunohistochemistry (to determine types of membrane adhesive proteins to the extracellular matrix), electrophysiology (to record neural responses of single neurons and populations of neurons), and continuum mechanics and finite element analysis (to measure biomechanics of soft tissues and develop computational models).

Student Background: Students who bring training in force, stress, strain, material properties, electrical or mechanical engineering, signal processing or computational modeling become valuable members of our research team.

Contact Information
email: Partap.Khalsa@sunysb.edu
url: http://www.bme.sunysb.edu/bme/people/faculty/p_khalsa.html