Faculty

Currently, UW–Madison has more than 40 faculty members working in many disciplines engaged in stem cell research. The work ranges from basic science in important animal models such as nonhuman primates to studies of human embryonic, adult and cancer stem cells. The ultimate goals of this research are to help develop a full basic understanding of stem cells, their properties, how they work and how they might be applied to treat human disease.

Caroline Alexander: Oncology; Mouse models of breast cancer; understanding the changes of epithelial cell growth control that accompany pre-neoplasia and progression. Breast stem cells and their role in tumor initiation.
Lynn Allen-Hoffmann: Pathology and Laboratory Medicine; Tissue engineered models of human skin; dissecting the proximal tissue interactions important for AhR ligand toxicity in human stratified squamous epithelia. Differentiation of keratinocytes from human embryonic stem (ES) cells.
Alan D. Attie: Biochemistry; Diabetes, β-cells, liver, adipose tissue, muscle
David Beebe: Biomedical Engineering; Creating systems that allow precise control of the cellular microenvironment to both study and control stem cell fate. We work with both hES cells and mammary epithelial progenitor cells with collaborators T. Kamp and C. Alexander.
Anita Bhattacharyya: The Waisman Center; Nervous system, developmental disorders, basic stem cell science, drug discovery and testing
Emery Bresnick: Surgery; Molecular mechanisms controlling the differentiation of blood cells from hematopoietic stem cells (HSCs), including: (i) transcriptional mechanisms that control the synthesis of key regulators of HSCs, and (ii) how chromatin domains assemble and are regulated in stem cells vs. differentiated cells.
Wade Bushman: Pharmacology; Prostate development and prostate cancer
Gabriela G. Cezar: Animal Sciences, Human Oncology; Stem cells in drug discovery and toxicology, metabolomics of human embryonic stem cells
Qiang Chang: The Waisman Center; Neurodevelopmental diseases, Rett Syndrome and basic stem cell science
Alta Charo: Law School; Legal and policy issues in biomedical research. Committee Liaison for National Academy of Sciences, Ethics Guidelines for Embryonic Stem Cell Research. Member of the ethics standards working group of the California Institute for Regenerative Medicine.
Juan DePablo: Chemical and Biochemical Engineering; Preservation and long term storage of mammalian cells, with a particular emphasis on human ES cells. Molecular thermodynamics and statistical mechanics.
Karen M. Downs: Anatomy; Stem cell reservoir in the allantois and its role in building the umbilical vasculature and aligning it with the fetus and placenta
Ian Duncan: School of Veterinary Medicine; Strategies to myelinate or remyelinate the brain in animal models of human genetic or acquired myelin disorders. Human neural stem cells and their potential differentiation into the myelin producing cell of the CNS, the oligodendrocyte. Methods for promoting widespread dissemination or migration of cells upon transplantation.
Norman Fost: Medical History and Bioethics; As former Chair of the Health Sciences IRB and the University’s Bioethics Advisory Committee, Dr. Fost has played a central role in developing the conditions of approval for human ES cell research at UW–Madison, including an extensive review of the ethical, legal, regulatory and policy issues affecting stem cell research Dr. Fost has been a member of the AAAS Working Group on Stem Cell Research.
Michael K. Fritch: Pathology; Understanding early differentiation, especially mesoderm and neuroectoderm
David Gamm: Ophthalmology and Visual Sciences; Culture, differentiation, and transplantation of human retinal stem/progenitor cells and retinal pigment epithelial cells.
Ted Golos: Obstetrics and Gynecology; Use of nonhuman primate models, human clinical materials, and ES cells to examine questions of placental biology and maternal-fetal interactions.
Derek Hei: Waisman Clinical Biomanufacturing Facility; Developing cell and gene therapeutics for human clinical trials
Peiman Hematti: Medicine; Hematopoietic differentiation of human and non-human primate ES cells. Development of the rhesus macaque as a pre-clinical model for evaluation of novel gene and stem cell therapies. Hematopoietic stem cell expansion for transplantation.
Linda Hogle: Medical History and Bioethics; Social, ethical and legal/regulatory issues in emerging biomedical technologies. Analysis of emerging regulatory pathways for novel biological and combination products, and organizational and education concerns for future generations of interdisciplinary researchers.
Debra Hullet: Surgery; Understanding Chronic Allograft Injury/Chronic Kidney Disease, epithelial to mesenchymal transition, and vascular remodeling
Jeffrey A. Johnson: Division of Pharmaceutical Sciences; Basic stem cell science, transplantation of genetically engineering stem cells
Ron Kalil: Ophthalmology and Visual Sciences; Transplantation of embryonic neural progenitor cells for repairing traumatic brain injury. Neurogenesis in the adult brain.
Tim Kamp: Medicine; Mechanisms controlling differentiation of human ES cells into distinct types of cardiomyocytes and electrophysiological properties of ES cell-derived cardiomyocytes; stem cell-based therapies for myocardial repair and regeneration in cardiac disease models.
W. John Kao: Ophthalmology & Visual Sciences; Center For Neuroscience; Biofunctionalized extracellular matrix mimetics, host cell - material interaction
Judith Kimble: Biochemistry; Stem cell controls in the nematode Caenorhabditis elegans. Molecular mechanisms by which the stem cell niche regulates the balance between stem cells and differentiation, and investigation of whether mechanisms regulating stem cells in C. elegans are conserved in humans.
John Kuo: Neurosurgery; Understanding molecular mechanisms of tumorigenesis via brain tumor stem cells and associated in vitro and in vivo tumor models; developing novel diagnostic and therapeutic strategies for benign and malignant brain tumors.
Youngsook Lee: Anatomy; Molecular mechanisms controlling normal cardiovascular differentiation and development. We take both in vivo and in vitro approaches; 1) To identify novel factors that are critical for normal cardiovascular development, we generate knock out mice to analyze the phenotype. 2) Using human ES cells, we examine molecular pathways to enhance cardiomyocyte generation.
Gary Lyons: Anatomy; ES cells and cardiac myocyte differentiation in vivo and in vitro. Genetic approaches to unraveling the complex molecular mechanisms involved in normal heart and vascular development that go awry in congenital heart disease. We also culture mouse, rhesus and human ES cells to produce purified cultures of cardiac myocytes.
Christopher Murphy: Department of Surgical Sciences, School of Veterinary Medicine; Understanding wound healing, organ preservation, biophysical cueing and modulation of cell behavior, engineering of the wound bed, stem cell cryopreservation and differentiation, and biophysical cues.
William Murphy: Biomedical Engineering; Delivery of developmental signals to influence stem cell activity. Development of biomaterials for tissue regeneration (tissue engineering). Novel approaches to drug delivery and gene therapy. Creation of novel materials using bioinspired approaches.
Jon Odorico: Surgery; Developing novel stem cell-based strategies for treating diabetes; stem cell biology and differentiation; pancreas and islet cell transplantation.
Brenda M. Ogle: Biomedical Engineering (primary); Material Science Program (affiliate); Understanding tissue engineering of cardiac muscle and blood vessels
Sean Palecek: Chemical and Biological Engineering; Effects of stresses on growth and differentiation of human ES cells. Improving viability of human ES cells during cryopreservation. We collaborate with Lynn Allen-Hoffmann’s group to study human ES cell differentiation into keratinocytes with the long term goal of generating skin product.
Amish N. Raval: Medicine/Cardiovascular Medicine Division; Innovative interventional image guidance modalities and therapeutic delivery systems to treat cardiovascular disease
Vijay Setaluri: Dermatology; Understanding skin and melanoma tumor stem cells
Aimen Shaaban: Surgery; Fetal stem cell transplantation. Study of the homing, engraftment and differentiation of pre-natally transplanted embryonic stem cell-derived hematopoietic stem cells. Examination of the mechanisms of long-term immunologic tolerance to pre-natally transplanted stem cells.
Igor Slukvin: Pathology and Laboratory Medicine; Differentiation of human ES cells into hematopoietic progenitors and mature blood cells in order to understand molecular mechanisms of early hematopoietic differentiation and to provide a novel source of cells for bone marrow transplantation, transfusion and cancer immunotherapy.
Rob Streiffer: Medical History and Bioethics (SMPH); Philosophy (L & S); Affiliate Appointments in Agricultural and Applied Economics (CALS); Medical Sciences (SVM); The Nelson Institute for Environmental Studies; Ethical and policy issues arising from modern biotechnology
Clive Svendsen: Waisman Center; Neurobiology and neural stem cells, including (i) the molecular mechanisms underlying new neuron production from neural stem cells (ii) the use of human neural stem cells to model neurological diseases and (iii) the transplantation of genetically modified neural stem cells in models of human neurological disease including Parkinson’s and ALS.
Ei Terasawa: Pediatrics/Primate Center; Cell replacement therapy and studying whether embryonic stem cells that are transformed into dopamine neurons can be used as a tool for treatment of Parkinson’s disease.
James Thomson: Genome Center; Understanding how human embryonic stem (ES) cells choose between self-renewal, death, and differentiation to specific lineages. Differentiation of human ES cells to early embryonic lineages.
Ray Vanderby: Orthopedics and Rehabilitation, Biomedical Engineering; Skeletal system tissue healing, tissue regeneration of ligament, tendon, and cartilage
Nathan Welham: Surgery, Clinical Sciences Center; Tissue engineering of extracellular matrix, contribution of mesenchymal stem cells and fibrocytes to wound repair.
Su-Chun Zhang: Waisman Center; Neural lineage differentiation of ES cells. Use of ES cells as a tool to understand early human neural development. Investigating the potential of stem cell derivatives in animal models of neurological conditions.
Jing Zheng: Obstetrics and Gynecology; Cellular and molecular mechanisms that control vasculogenesis and angiogenesis, ultimately regulating vascular growth and blood flow

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