The goals of the Translational neurobiology Laboratory are to understand the pathogenesis and cell death pathways in neurodegenerative disorders to reveal potential therapeutic targets for pharmaceutical intervention; to investigate endogenous survival pathways and try to induce these pathways to restore full function or replace lost neurons; and to identify biomarkers to mark disease function or replace lost neurons; and to identify biomarkers to mark disease progression and evaluate therapeutics. Our research projects focus on models of Huntington's disease and Parkinson's disease. We use a combination of cell biology and transgenic animal models of these diseases.

We are exploring whether anodal tDCS when administered in combination with spelling, naming, or working memory therapy can improve language performance of PPA and MCI participants at least in the short term more than behavioral therapy alone. We are also investigating whether and how tDCS alters the neuropeptide signature in participants with PPA and MCI. We use proton magnetic resonance spectroscopy (1H-MRS) to monitor neuropeptide concentrations at the areas of stimulation. We hypothesize that tDCS will stabilize the decline of specific neuropeptides, but only in those areas of the brain where tDCS effectively results in more efficient gains in language compared to language therapy alone (with sham tDCS). Study results may help optimize future intervention in individuals with PPA and MCI by providing treatment alternatives in a neurodegenerative condition with no proven effective treatment. A better understanding of the therapeutic and neuromodulatory effects of tDCS in PPA and MCI will offer insight into ways of impeding neurodegeneration that may improve quality of life for individuals with PPA and MCI and may provide insights into the mechanisms of this treatment for augmenting therapy for stroke as well.

The Tsion Abdi Lab performs clinical research on Scleroderma Bowel Disease and Inflammatory Bowel Disease.

URobotics is a research and education program that uses advanced technology to improve how urological diseases are diagnosed and treated. The URobotics lab’s main focus is creating robots that aid in real-time, image-guided interventions. This multidisciplinary team of urologists, radiologists and engineers has teamed up to revolutionize how surgeries are performed.

The Vaninder Dhillon Lab is currently researching 1) the role of voice outcomes in laryngeal dysplasia treated both in the operating room and clinic with the KTP laser; 2) Voice outcome pre and post thyroidectomy 3) Voice outcomes and technique in placement of Montgomery T tubes for subglottic and upper cervicotracheal stenosis.

The Singh Lab does basic and translational research on intestinal ion transport, cellular physiology, and membrane trafficking in diabetic disorders.

Vascular research led by Rafael Tamargo, M.D., the Walter E. Dandy Professor of Neurosurgery, explores treatment of aneurysms, arteriovenous malformations, cavernous malformations, and arteriovenous fistulas of the brain and spinal cord. Basic science research has focused on endothelial cell-leukocyte interactions (inflammation) after subarachnoid hemorrhage and identifying drugs that might inhibit this inflammatory response as well as the narrowing of blood vessels.

The Veit Stuphorn Laboratory studies the neurophysiological mechanisms that underlie decision making and self-control. We record the activity of single neurons in awake animals that are engaged in decision-making processes. This allows us to identify the types of signals that neurons in specific parts of the brain represent and the computations they carry out. We also study human subjects in the same tasks with the help of fMRI. These parallel experiments provide comparative information about decision processes in human and non-human primates.

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 Raman laboratory is within the Division of Cancer Imaging Research in the Department of Radiology and Radiological Science. The focus of the laboratory is bench-to-bed side cancer research. We integrate molecular and cellular biology, developmental biology, cancer biology, molecular imaging techniques to study cancer formation and progression. Many of the projects in the lab investigate dysregulated genes in cancer and the translatability of this information to a clinical setting. One such project is to functionally decipher the role of a RNA helicase gene, DDX3, in the biogenesis of multiple cancer types such as breast, lung, brain, sarcoma, colorectal and prostate. Additionally, using a rational drug design approach, a small molecule inhibitor of DDX3 (RK-33) was synthesized and its potential for clinical translation is being investigated.