Edward Hsiao, MD, PhD

Assistant Professor
Division of Endocrinology and Metabolism
Institute for Human Genetics
+1 415 476-9732
Research Description: 

MD: MD, PhD, Johns Hopkins Medical School, 2001
Residency: Johns Hopkins Hospital, Baltimore, MD, Internal Medicine, 2001-2004
Fellowship: UCSF, Division of Diabetes, Endocrinology and Metabolism, 2004-2007
Board Certifications: Internal Medicine, 2004; Endocrinology and Metabolism, 2006

My research is driven by a desire to understand how major hormonal and regulatory pathways determine the specification, differentiation, and morphogenesis of mesenchymal tissues such as bone, cartilage, muscle, and fat. Mis-regulation of these pathways leads to significant medical diseases, including the inappropriate formation of mineralized tissues in atherosclerosis, heterotopic ossification, and cancer.

My research focuses on understanding how these regulatory signals control normal and pathologic tissue formation as a way to identifying new therapeutic avenues for treating human diseases. Our laboratory takes a comprehensive approach to understanding hormone signaling in human diseases using synthetic biology approaches, mouse models, and human stem cell models.

By combining multiple approaches with state-of-the art methods, our laboratory is working to develop a broader understanding of the biology underlying skeletal development, devise novel therapeutic approaches for treating human skeletal disorders and bone injuries, and examine how hormone signals affect important tissues such as fat, muscle, bone, cartilage, and blood vessels.

General Endocrinology with an interest in inherited skeletal diseases, including fibrous dysplasia of the bone (FD), McCune-Albright syndrome (MAS), and fibrodysplasia ossificans progressiva (FOP).

Appointments: 415-353-2350
Availability: General Endocrinology, 3rd Tuesday PM of each month

Laboratory website: http://tiny.ucsf.edu/hsiaolab

Primary Thematic Area: 
Tissue / Organ Biology & Endocrinology
Secondary Thematic Area: 
Developmental & Stem Cell Biology
Research Summary: 
Hormonal and genetic regulation of human skeletal disease
Mentorship Development: 

4/30/20    Mental Health in a Pandemic: Q&A for Faculty
2/16/21    Three Truths and Three Tries: Facing and Overcoming Critical Social Justice Challenges at the Micro, Mezzo, and Macro Levels


Featured Publications: 

Osteoblast expression of an engineered Gs-coupled receptor dramatically increases bone mass.

Proceedings of the National Academy of Sciences of the United States of America

Hsiao EC, Boudignon BM, Chang WC, Bencsik M, Peng J, Nguyen TD, Manalac C, Halloran BP, Conklin BR, Nissenson RA