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Sherry L. Harbin, Ph.D.

AIMBE College of Fellows Class of 2020
For developing collagen formulations that rapidly self-assemble at physiological conditions into mechanically and proteolytic stable material that promotes tissue regeneration.

Tissue-engineered implants provide new hope for vocal injuries

Via Purdue University | February 23, 2021

New technology from Purdue University and Indiana University School of Medicine innovators may one day help patients who suffer devastating vocal injuries from surgery on the larynx.

A collaborative team consisting of Purdue biomedical engineers and clinicians from IU has tissue-engineered component tissue replacements that support reconstruction of the larynx. The team’s work is published in The Laryngoscope.

The larynx is a very complex human organ consisting of outer cartilage for structural support, inner muscle that contracts to permit voicing, swallowing, and breathing, and inner vibratory lining… Continue reading.

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Dr. Sherry Harbin Inducted into AIMBE College of Fellows

Via AIMBE | March 30, 2020

WASHINGTON, D.C. — The American Institute for Medical and Biological Engineering (AIMBE) has announced the induction of Sherry L. Harbin, Ph.D., Professor, Weldon School of Biomedical Engineering, Purdue University, to its College of Fellows.

Election to the AIMBE College of Fellows is among the highest professional distinctions accorded to a medical and biological engineer. The College of Fellows is comprised of the top two percent of medical and biological engineers. College membership honors those who have made outstanding contributions to “engineering and medicine research, practice, or education” and to “the pioneering of new and developing fields of technology, making major advancements in traditional fields of medical and biological engineering, or developing/implementing innovative approaches to bioengineering education.”

Dr. Harbin was nominated, reviewed, and elected by peers and members of the College of Fellows for “developing collagen formulations that rapidly self-assemble at physiological conditions into mechanically and proteolytic stable material that promotes tissue regeneration.

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