Dr. Borahay's lab focuses on understanding pathobiology, developing novel treatments, and carrying out high quality clinical trials for common gynecologic problems with a special focus on uterine fibroids. Our lab also investigates the causes and novel treatments for menstrual disorders such as heavy and irregular periods. In addition, Dr. Borahay’s team explores innovative approaches to minimally invasive gynecologic surgery, focusing on outpatient procedures with less pain and faster recovery times.

The Artemov lab is within the Division of Cancer Imaging Research in the Department of Radiology and Radiological Science. The lab focuses on 1) Use of advanced dynamic contrast enhanced-MRI and activated dual-contrast MRI to perform image-guided combination therapy of triple negative breast cancer and to assess therapeutic response. 2) Development of noninvasive MR markers of cell viability based on a dual-contrast technique that enables simultaneous tracking and monitoring of viability of transplanted stems cells in vivo. 3) Development of Tc-99m and Ga-68 angiogenic SPECT/PET tracers to image expression of VEGF receptors that are involved in tumor angiogenesis and can be important therapeutic targets. 4) Development of the concept of “click therapy” that combines advantages of multi-component targeting, bio-orthogonal conjugation and image guidance and preclinical validation in breast and prostate cancer models.

The Dong Laboratory has identified many genes specifically expressed in primary sensory neurons in dorsal root ganglia (DRG). Our lab uses multiple approaches, including molecular biology, mouse genetics, mouse behavior and electrophysiology, to study the function of these genes in pain and itch sensation. Other research in the lab examines the molecular mechanism of how skin mast cells sensitize sensory nerves under inflammatory states.

Research in the Donald MacGlashan Laboratory aims to understand the regulation of secretion from human basophils and mast cells—two cells thought to play key roles in allergic reactions and other diseases. The hallmark reaction in these cells is degranulation through cell-bound IgE. Our interests lie in the signaling mechanisms that control this dramatic cell response and the factors that regulate the degree of the reaction.

The Wang lab focuses on the signals that direct the differentiation of pluripotent stem cells, such as induced-pluripotent stem (iPS) cells, into hematopoietic and cardiovascular cells. Pluripotent stem cells hold great potential for regenerative medicine. Defining the molecular links between differentiation outcomes will provide important information for designing rational methods of stem cell manipulation.

We are interested in basic and translational studies looking at the effects of environmental exposures, including cigarette smoke and electronic cigarettes, on lung epithelial function. We are focused on mechanisms to reverse injury to promote lung health, primarily in the context of Chronic Obstructive Pulmonary Disease (COPD).

The mission and interest of the neuroengineering and Biomedical Instrumentation Lab is to develop novel instrumentation and technologies to study the brain at several levels--from single cell to the whole brain--with the goal of translating the work into practical research and clinical applications. Our personnel include diverse, independent-minded and entrepreneurial students, post docs, and research faculty who base their research on modern microfabrication, stem cell biology, electrophysiology, signal processing, image processing, and integrated circuit design technologies.

Research in the Kendall Moseley Lab is focused on the interplay between type 2 diabetes, aging and osteoporosis. We also study the function of bone stem cells in the regulation of bone remodeling.

Our research interest is crystalized into three main areas: 1. Type-1 diabetes - Our focus is on understanding how the Fas death pathway regulates the disease and how extracted information can be used to protect high risk individuals and those with new-onset disease. 2. Type 2 diabetes and Obesity - Our lab is studying the role of heparan sulfate proteoglycans (HSPG) in regulating body fat and glucose clearance. 3. Double negative ??T cells - Our studies suggest a critical role for these cells in protecting kidneys from Ischemia reperfusion injury (IRI). Our current focus is understanding their origin and physiological functions.

The Seydoux Lab studies the earliest stages of embryogenesis to understand how single-celled eggs develop into complex multicellular embryos. We focus on the choice between soma and germline, one of the first developmental decisions faced by embryos. Our goal is to identify and characterize the molecular mechanisms that activate embryonic development, polarize embryos, and distinguish between somatic and germline cells, using Caenorhabditis elegans as a model system. Our research program is divided into three areas: oocyte-to-embryo transition, embryonic polarity and soma-germline dichotomy.