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home > education+workforce development > undergraduate level programs > ibrp > m. hadjiargyrou

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Interdisciplinary Biomedical Research Program (IBRP)

IBRP Overview

Michael Hadjiargyrou, Ph.D.
Assistant Professor of Biomedical Engineering, Genetics and Orthopaedics.
Funding through the National Institutes of Arthritis, Musculoskeletal and Skin Diseases.

Michael Hadjiargyrou is interested in understanding the molecular mechanisms that underlie bone development and regeneration (i.e. fracture repair). The repair of a fractured bone is a complex biological event that essentially recapitulates embryonic development and requires the orchestration of a number of different cell types undergoing proliferation, migration, adhesion and differentiation, all under the direct control of a host of different genes. It is precisely for this reason that his laboratory investigates gene expression during the progression of a healing callus through its various stages (e.g. inflammation, intramembranous and endochondral ossification, remodeling). The latest methods in molecular/cellular biology are applied in the pursuit of gene discovery, gene structure and function analysis, expression studies and functional perturbations. By identifying and studying genes that play essential roles during the healing process, we hypothesize that this knowledge will facilitate a greater understanding in our ability to elucidate the process of bone development and regeneration and identify ideal gene candidates for possible therapeutic intervention, especially in fractures that have difficulty healing (e.g. delayed and non-unions).

Figure 1. DNA Microarray analysis. Left Panel shows an actual gene filter following hybridization with RNA derived from intact bone. This filter contains 5,000 different genes (1,700 known and 3,300 unknown). Differential expression is then determined by comparing levels of activity for a given gene represented by a "dot", with another membrane hybridized to fracture

Through the use of multiple molecular-based techniques (i.e. differential mRNA display, DNA microarrays and suppressive subtractive hybridization), we have identified thousands of genes that are differentially expressed during bone regeneration (Figure 1). We are now in the process of carrying out gene structure and function experiments in order to elucidate the nature of several of these genes and their significance in cells participating in wound healing. These types of experiments should facilitate future therapies for the augmentation of fracture repair.

Student Background: Students interested in learning molecular and cellular techniques to study the structure and function of genes/cells. Students with a background in cell and molecular biology and a desire to use engineering principles to study biological problems are encouraged to apply.

Contact Information
email: Michael.Hadjiargyrou@sunysb.edu
url: http://www.bme.sunysb.edu/bme/people/faculty/m_hadji.html