The Frederick Sieber Lab studies the impact of sedation on geriatric surgical patients—especially those undergoing orthopaedic or pelvic procedures—with the goal of preventing postoperative delirium. We are using electroencephalography to investigate the effect of sedation depth during spinal anesthesia. We are also working to determine the effects of using propofol for sedation in elderly patients as well as the effects of robotics and surgical positioning on cerebral blood flow.

Dr. Fridman's research group invents and develops bioelectronics for Neuroengineering and Medical Instrumentation applications. We develop innovative medical technology and we also conduct the necessary biological studies to understand how the technology could be effective and safe for people. Our lab is currently focused on developing the ""Safe Direct Current Stimulation"" technology, or SDCS. Unlike the currently available commercial neural prosthetic devices, such as cochlear implants, pacemakers, or Parkinson's deep brain stimulators that can only excite neurons, SDCS can excite, inhibit, and even sensitize them to input. This new technology opens a door to a wide range of applications that we are currently exploring along with device development: e.g. peripheral nerve stimulation for suppressing neuropathic pain, vestibular nerve stimulation to correct balance disorders, vagal nerve stimulation to suppress an asthma attack, and a host of other neuroprosthetic applications. Medical Instrumentation MouthLab is a ""tricorder"" device that we invented here in the Machine Biointerface Lab. The device currently obtains all vital signs within 60s: Pulse rate, breathing rate, temperature, blood pressure, blood oxygen saturation, electrocardiogram, and FEV1 (lung function) measurement. Because the device is in the mouth, it has access to saliva and to breath and we are focused now on expanding its capability to obtaining measures of dehydration and biomarkers that could be indicative of a wide range of internal disorders ranging from stress to kidney failure and even lung cancer.

Our broad research goals are to identify and validate novel molecular therapeutic targets in hematopoietic malignancies. We are interested in the identification and pre-clinical development of novel targeted therapies, and, in particular, the “translational” step of this research by using correlative studies to incorporate these novel therapies into existing treatments. Our research is of particular interest to those who wish to be involved in directly translating the results of laboratory bench work into meaningful benefits for patients. Currently, we are actively involved in the pre-clinical and clinical development of small molecule kinase inhibitors targeting the FLT3 signaling pathway in acute myeloid leukemia. We are interested in 3 compounds in particular- AC220, a FLT3/KIT inhibitor; crenolanib,a selective FLT3 inhibitor with activity against resistant point mutations; and PLX3397, another inhibitor of KIT and FLT3. The active projects in the lab include: 1) Characterization of cytotoxic responses of different hematologic malignancies to FLT3 and KIT kinase inhibition; 2) Examination of the interaction of bone marrow stroma and stroma-derived cytokines on the efficacy of these inhibitors; 3) Examination of the differential effect of FLT3 inhibition versus combined FLT3/KIT inhibition on acute myeloid leukemia and bone marrow progenitor cells; and 4) Correlative laboratory studies using blood and marrow samples from patients treated with FLT3 inhibitors, with the aim of developing predictive models for clinical response.

Work in the Hsin-Chieh Yeh Lab focuses on clinical trials and cohort studies of diabetes, obesity and behavioral intervention, cancer and hypertension. Recent investigations have focused on novel risk factors and complications related to obesity and type 2 diabetes, particularly lung function, smoking and cancer. We recently co-led a randomized clinical trial of tailored dietary advice for consumption of dietary supplements to lower blood pressure and improve cardiovascular disease risk factors in hypertensive urban African Americans.

Research in the Raymond Koehler Lab explores cerebrovascular physiology and cerebral ischemic injury caused by stroke and cardiac arrest, using protein analysis, immunohistochemistry and histology. We also study ischemic preconditioning, neonatal hypoxic-ischemic encephalopathy and the mechanisms of abnormal cerebrovascular reactivity after ischemia. We 're examining ways to improve tissue oxygenation and seek to better understand the mechanisms that connect an increase in cerebral blood flow to neuronal activity.

Research in the Romsai Boonyasai Lab focuses on systems-based approaches for improving health care quality, including reducing harm during care transitions after hospital discharge and improving outcomes related to hypertension and other chronic diseases. We recently have focused on developing and evaluating practice-based tools for improving the accuracy of blood pressure measurement, overcoming clinical inertia to treatment, and engaging patients in self-management of their health.

The main research goals of my laboratory are: (1) to identify and study the biology of novel cancer selective targets whose enzymatic function can be exploited for therapeutic and diagnostic purposes; (2) to develop methods to target novel agents for activiation by these cancer selective targets while avoiding or minimizing systemic toxicity; (3) to develop novel agents for imaging cancer sites at earliest stages. To accomplish these objectives the lab has originally focused on the development of prodrugs or protoxins that are inactive when given systemically via the blood and only become activated by tumor or tissue specific proteases present within sites of tumor. Using this approach, we are developing therapies targeted for activation by the serine proteases prostate-specific antigen (PSA), human glandular kallikrein 2 (hK2) and fibroblast activation protein (FAP) as well as the membrane carboxypeptidase prostate-specific membrane antigen (PSMA). One such approach developed in the lab consists of a potent bacterial protoxin that we have reengineered to be selectively activated by PSA within the Prostate. This PSA-activated toxin is currently being tested clinically as treatment for men with recurrent prostate cancer following radiation therapy. In a related approach, a novel peptide-cytotoxin prodrug candidate that is activated by PSMA has been identified and is this prodrug candidate is now entering early phase clinical development. In addition, we have also identified a series of potent inhibitors of PSA that are now under study as drug targeting and imaging agents to be used in the treatment and detection of prostate cancer.

Work in the Sean Berenholtz Lab focuses on patient safety, ICU care, quality health care and evidence-based medicine. Two notable and successful projects include the National On The Cusp: Stop BSI project, which was implemented in 47 states with the goal of eliminating bloodstream infections, and the Agency for Healthcare Research and Quality (AHRQ)-funded Keystone ICU project, which improved communication and teamwork and reduced hospital-acquired infections in more than 100 ICUs in Michigan. One recent study focused on ventilator-associated pneumonia (VAP), one of the most common type of health care-associated infections in the ICU. Existing VAP prevention intervention bundles vary widely on the interventions, but our research team described a structured approach for developing a new VAP prevention bundle.

Current research in the Sean T. Prigge Lab explores the biochemical pathways found in the apicoplast, an essential organelle found in malaria parasites, using a combination of cell biology and genetic, biophysical and biochemical techniques. We are particularly focused on the pathways used for the biosynthesis and modification of fatty acids and associated enzyme cofactors, including pantothenate, lipoic acid, biotin and iron-sulfur clusters. We want to better understand how the cofactors are acquired and used, and whether they are essential for the growth of blood-stage malaria parasites.

Research in the Sean Agbor-Enoh Lab explores topics within the field of pulmonary medicine. Our team also participates in clinical trials that explore new techniques for diagnosing rejection following an organ transplant. One current study is seeking to develop a new blood test that may be used instead of biopsies to diagnose rejection after transplant.