Faculty

The Rudnick lab seeks to gain an understanding of liver regeneration to improve the treatment of children with liver disease.

Faculty profile »

The Rutz lab is focused on bridging living systems and technologies through the design of materials and development of advanced manufacturing methods.

Rutz Lab »

The Sands lab studies the underlying pathophysiology of lysosomal storage diseases and develops therapies to treat them.

Faculty profile »

The Schedl lab investigates how stem cells choose between self renewal and differentiation and how sex determination is controlled.

Schedl Lab website »

The Scheller laboratory synthesizes concepts from cell biology, physiology, and bioengineering to study the relationships between the nervous system and the skeleton. They have a directed interest in understanding how neural signals contribute to skeletal homeostasis, and how perturbations to this system contribute to bone loss, impaired healing, and altered regeneration. They also seek to understand how skeletal cells and proteins coordinate and regulate nerve regeneration in and on the bone.

Scheller Lab website »

The Schuettpelz lab studies how inflammatory signals regulate hematopoietic stem cells.

Schuettpelz Lab website »

The Setton Lab focuses on engineering and design of novel materials and drug depots to support regeneration of tissues of the musculoskeletal system.

Setton Lab website »

The Sheets lab uses zebrafish as a model system to understand how senory hair cells of the auditory system develop, degenerate, and regenerate. A main focus of the lab is to identify biological pathways that promote nerve regeneration and hair-cell reinnervation with the goal of providing information toward clinical regenerative therapies.

Sheets Lab website »

Dr. Shen’s group studies biological and mechanical factors that regulate tendon development, injury, and repair, as a basis to develop new therapeutic approaches to improve tendon healing.

The Shen laboratory recently works on epigenetics of degenerative and regenerative processes in the muscuoskeletal system, e.g. osteoarthritis and bony fracture. They employ unbiased approaches to study the genomic and epigenomic alterations in skeletal diseases.

The Silva lab studies the mechanical and molecular factors that regulate loading-induced bone formation and bone injury response and repair.

The Skeath lab investigatesthe genetic and molecular basis of both asymmetric divisions and cell-type specific differentiation programs through the use of the Drosophila model system, focusing primarily on nervous system development.

Skeath Lab website »

The Snyder-Warwick Lab investigates cellular signaling at the neuromuscular junction and the roles of terminal Schwann cells during development, disease, neural regeneration and muscular reinnervation, and aging. The goals of our work are to identify the mechanisms of terminal Schwann cell function that may be manipulated into novel translational applications for clinical management of patients with nerve pathology.

Snyder-Warwick Lab website »

The Solnica-Krezel lab studies the cellular and molecular genetic mechanisms underlying vertebrate gastrulation in zebrafish and human embryonic stem cells.

Solnica-Krezel Lab website »

Dr. Stone studies the role of Fibroblast Growth Factors in Severe Insulin Resistance Syndromes. His research uses both murine and stem cell based models to better understand these rare and debilitating conditions, with the ultimate goal of providing new therapies for these patients.

The Stratman Lab is interesting in the mechanosensitive mechanisms that regulate tissue development and patterning, particularly of the cardiovascular system.  Utilizing zebrafish as a model, their goals focus on understanding developmental pathways that are reactivated during disease. 

Stratman Lab website »

The Tang lab integrates engineering and biology approaches to investigate mechanisms of degeneration relating to bone fragility and intervertebral disc degeneration, with an emphasis in the role of advanced glycation endproducts (AGEs) and RAGE signaling on the cells and tissues of the skeletal system.

Tang Lab website »

The Tavoni lab develops theories and models to understand how information is represented and processed in neuronal networks. Areas of focus in the lab include information-theoretic analyses of different forms of plasticity, including adult neurogenesis, and their role in efficient coding.

Tavoni Lab website »

The Teitelbaum lab investigates osteoclast development, function, and pathologies. 

Faculty profile »

The Theunissen lab investigates the molecular mechanisms regulating distinct pluripotent stem cell states and their applications in regenerative medicine.

Theunissen Lab website »

We are interested in infection and metastasis to the bone, materials for combating these pathologies, and quantitative imaging and targeted therapeutics to treat disease.

Lab Website »

The Tsai Lab is interested in the interplay between mechanical and biochemical signals underlying robust pattern formation and morphogenesis in the zebrafish embryos.

Tsai Lab website »

The Urano lab studies the molecular mechanisms of Wolfram Syndrome and investigates potential therapies.

Urano Lab website »

The Veis Laboratory studies NF-kB signaling pathways in bone cells, particularly in the context of pathological bone loss, such as in osteoporosis, inflammatory arthritis, and cancer metastasis to bone. A major focus is on the role of the alternative/non-canonical NF-kB pathway in osteoclasts, where it controls both differentiation and activity.

Veis Lab website »

The Wagenseil lab studies how mechanical stimuli regulate large artery formation and remodeling in development and disease.

Wagenseil Lab website »

Dr. Leyao Wang’s research focuses on lung microbiota and their role in lung inflammation and asthma. One of the lab’s current direction is to establish a lung organoid system so that they can use this model to investigate the interactions between microbes and epithelium.

Wang Lab website »

The Wang lab focuses on understanding genetic and epigenetic factors that determine cell fate, including cell fate decision in normal development and differentiation, abnormal cell fate choice in cancer, and how specific cell types evolve.

Wang Lab website »

The Warchol lab studies the molecular mechanism underlying development and regeneration of sensory hair cells of the inner ear and their neurons.

Warchol Lab website »

The Weihl lab studies neuromuscular disorders with special emphasis on degenerative myopathies.

Weihl Lab website »

The Williams lab is interested in selective neuronal vulnerability in degeneration and trauma. We use a combination of in vivo microscopy, transcriptomics, and viral mediated gene overexpression/knockout to manipulate neurons in the retina with the long term goal of increasing neuronal survival and axon regeneration in degenerative mouse models.

Williams Lab website »

The Woo lab studies vascular remodeling from the perspective of endothelial and smooth muscle cell reprogramming as induced by hypoxia.

Faculty profile website »

The Wood lab studies treatment paradigms for peripheral nerve injury.

Faculty profile »

The Yano Lab is interested in mechanisms leading to neurodegenerative diseases and brain tumors and the development of disease therapies.

Yano Lab website »

The Yoo lab studies how microRNAs control development, direct reprogramming, and aging in neurons.

Yoo Lab website »

The Zayed Laboratory studies the mechanisms that influence arterial collateral formation and peripheral arterial atheroprogression in the setting of diabetes. We are interested in better understanding why diabetic patients have a significantly higher incidence of developing peripheral arterial disease (PAD) and are at increased risk of malperfusion at healing surgical sites.

Lab Website »

The Zellers Lab (Tendon Rehabilitation Lab) is committed to improving care for people with tendon injury and dysfunction. Our research is aimed at advancing our understanding of person-specific factors that affect a tendon’s ability to respond to treatment. This includes local factors, like tendon structure, and systemic factors, like the presence of diabetes.

Zellers Lab website »

Engineering protein-based materials for applications in Regenerative Medicine.

Faculty Profile »

The Zhou lab is interested in developing novel optical imaging technologies for biomedical applications, especially in developing optical coherence tomography (OCT) and microscopy (OCM) technologies to perform “optical biopsy” and generate 3D in situ images of tissue morphology, function and pathological status in real-time without the need to remove and process specimens.

Zhou Lab »