Faculty

My research is on the early pregnancy origins of exposure-related risk to the long-term health of the child. My unique contribution to this question includes deep thinking and experimentation on the role of the human placenta.

Circuit dynamics underlying pathology and treatment of compulsive behaviors and anxiety disorders; Ongoing projects in the lab focus on identifying molecular changes and plasticity mechanisms related to compulsive behaviors, as well as exploring the molecular and circuit mechanisms of anxiety and the interplay between stress, anxiety, and the development of compulsive behaviors.

Our lab uses structural and functional MRI to study the brain changes associated with aging, and the disorders of aging   

The Ambrose laboratory studies antiretroviral therapeutics used for HIV-1 prevention and suppression, including the characterization of new drug targets against early steps of the virus life cycle, and the impact of drug resistance on HIV-1 transmission, prevention, persistence, and treatment.

Tissue Engineering and Regenerative Medicine, emphasis upon clinical application; cell:biomaterial interactions; epimorphic regeneration in mammals

Identify phosphorylations, dephosphorylations and acetylations that regulate ATM activity in vivo. 

Neurophysiology of sensory-motor coordination, brain-machine interfaces.          

Research focused on the interface between clinical informatics and bioinformatics with a particular focus on translational research resources, particularly tissue banking informatics.

Our laboratory studies the molecular mechanisms regulating genetic and acquired cardiomyopathies to identify novel methods to prevent heart failure and sudden death.

Interdisciplinary approach to explore how the signals from the eye are transformed into meaningful percepts by the brain 

We apply a multidisciplinary strategy to design and develop biologically and clinically inspired technologies that enable us to elucidate cellular and molecular mechanisms that govern tissue pathology or offer protection during lung and immune injury.

The mechanisms of cross-priming of antigens during immune responses to cancer, viruses and autoimmunity   

Demand adapted hematopoiesis in infection and inflammation.   

Dr. Borrero is a health services researcher with advanced clinical training in women’s health whose work strives to advance reproductive health equity.

Miguel Brieno-Enriquez's research interests include human meiosis analysis, endocrine disruptor effects on meiotic prophase I, transgenerational epigenetics, NEK1 kinase regulation of cohesin removal, and ovarian reserve protection in mammals.

Protein “quality control”, diseases associated with misfolded proteins, and drug treatments for these diseases 

Tumor microenvironment, Cancer stem cells, novel therapeutics for cancer 

Basic and translational investigations of the mechanisms and therapies of skin disease.

Development of targeted therapies for KRAS mutant NSCLC; Reactivation of OIS and apoptosis; Mechanisms of acquired resistance to targeted agents       

Computational drug discovery; My main research interests focus on modeling the physical interactions responsible for molecular recognition, and in the development of new technologies for structural prediction, their substrates and supramolecular assemblies.

In the Carvunis lab, we study the molecular mechanisms of change and innovation in evolution.   

The Catov research group utilizes large perinatal registries and cohort studies to evaluate the relationship between cardiovascular risk factors and preterm birth, as well as the postpartum characteristics of women who delivered preterm infants.

Osteoporosis treatment and the consequences of osteoporosis in both men and women.          

Basic science and translational research studying the molecular mechanisms of pulmonary vascular disease and pulmonary hypertension           

The study of human tumor viruses; 

Our lab researches viral oncogenesis, focusing on Merkel cell polyomavirus in skin cancer, Kaposi’s sarcoma-associated herpesvirus in AIDS-related malignancies, and the discovery of new human pathogens using advanced genomic technologies.

Dr. Chapman's research aims to understand the psychological processes behind decision-making to design interventions that promote healthy and prosocial behaviors like vaccination and blood donation.

Our lab wants to understand how neurons wire together to form the intricate yet adaptable neural circuits that support complex brain functions. We are particularly interested in how newborn neurons form synaptic connections, and how this determines whether a neuron will survive. To answer these questions, we use in vivo 2-photon microscopy to track the structure and function of individual neurons and synapses over time in the living brain, as well as molecular genetic tools, electrophysiology, optogenetics, and behavior.
 

Redox signaling & autophagy in neuroprotection and neurodegeneration; mitochondrial phosphoproteomics; genetic & toxin models of Parkinson's disease   

My research focuses on the ovarian cancer microenvironment, specifically targeting carcinoma-associated mesenchymal stem cells (CA-MSC) that support cancer survival, growth, and spread.

My group studies the way visual information is encoded in groups of neurons and used to guide behavior.     

Artificial lungs; hemodynamics, pulmonary drug delivery; liquid ventilation; right ventricular function, critical care medicine           

My group studies human memory and perception with neuroimaging, cognitive studies, and advanced analysis methods. We seek to understand how the human brain learns, remembers, and ultimately creates knowledge.

David Creswell studies stress, self-affirmation, mindfulness, and emotions, focusing on their neural mechanisms and impact on resilience and health.

Dr. Tracy Cui is William Kepler Whiteford Professor of Bioengineering at the University of Pittsburgh. Dr. Cui is the Director of the Neural Tissue/Electrode Interface and Neural Tissue Engineering Lab. She is also the Neural Engineering Track Coordinator for the Department of Bioengineering Graduate Committee.

Modeling of CNS infections using induced pluripote; Modeling schizophrenia using induced pluripotents; Development of three-dimensional neuronal platform.

Steroid hormone action in neural stem cells and cancer          

We are developing novel chemical tools to investigate biological processes in Chemical Biology, using a multidisciplinary approach that includes small molecule synthesis, medicinal chemistry, and protein engineering.

The metabolic regulation of T cell function, with a specific focus of those T cells that infiltrate the nutrient-poor tumor microenvironment. 

HSV gene expression in productive and persistent infections 

Research in the Dermody laboratory focuses on the molecular mechanisms of Mammalian Orthoreovirus (reovirus) and Chikungunya virus infections.

The central goal of my lab is to explore the structure-function properties and antimicrobial mechanisms of cationic amphipathic peptides to develop peptide-based therapeutics for drug-resistant infections and cancer.

Conducts research in the areas of pharmaceutical policy and mental health, and has particular expertise in the Affordable Care Act.       

Research in the Duncan lab focuses on liver development, homeostasis, and regeneration.     

Synthetic Morphogenesis of Human Tissues, Human Organoids, Epigenetic Engineering, Designer Tissues, Blood Development, Synthetic Biology, Systems Biology, Cellular Ecology

My lab is interested in developing mathematical models of biological regulatory processes that integrate specific knowledge about protein-protein interactions.     

We develop materials-based, engineering strategies to control the self-organization and assembly of various cell types into tissues using nanoscale fabrication and 3D bioprinting. Understanding of higher-order function in biological systems.   

We use multimodal imaging techniques—high-density EEG, TMS, MRI, and MRSI—in healthy and psychiatric populations to study the neurobiology and cognitive dysfunctions of major disorders like OCD, bipolar disorder, and schizophrenia.

Cognitive and educational neuroscience of reading, language, math, and learning.       

aging, metabolism, mitochondria ; For over twenty years, my research group has studied mitochondrial function, cellular metabolism, oxidative stress, and aging, gaining expertise in mitochondrial assays, molecular biology, mouse models, and physiological measurements.

Immunology and Pathogenesis of Tuberculosis.          

Forno’s overarching research interests are the epidemiology, genetic epidemiology, and genomics of asthma. He is particularly focused on the effects of obesity and adiposity on childhood asthma.

Kaposi’s sarcoma-associate herpesvirus (KSHV), AIDS-related malignancies, Cancer metabolism, Angiogenesis, Innate immunity, Microbiota, microRNAs, Genomics Epigenetics, RNA epigenetics, high-throughput screening (drug and genomic), systems biology

The current focus of Dr. Gelhaus' research is on the mechanism of these electrophilic fatty acids in asthma. Asthma is a complicated disease that much like cancer is comprised of numerous disease states and phenotypes.

Genetics of aging, reproduction, lipid metabolism, immunity, protein homeostasis, age-related disease biology   

Dr. Ghuman’s research focuses on how our brain turns what falls upon our eyes into the rich meaningful experience that we perceive in the world around us. Specifically, his lab studies the neural basis of the visual perception of objects, faces, words, and social and affective visual images in the real-world.

Neural circuits in the basal ganglia involved in motor control and disease 

Pain continues to be a major health problem with tremendous financial, social and psychological costs. Conservative estimates put the cost of pain to the US economy well into the hundreds of billions of dollars per year as a result of associated medical expenses and lost wages with a significant minority of Americans suffering from persistent or recurrent pain syndromes throughout the most productive years of their lives. Just one pain syndrome, migraine headache, directly impacts 20% of the adult population. Yet, there remain few if any effective therapies devoid of serious side effects that are currently available to treat pain, particularly persistent or recurrent pain associated with syndromes.

The clinical features of a number of pain syndromes serve as the organizing focus of research in the Gold laboratory. These observations include the following: 1) many pain syndromes are unique to a particular part of the body such as the head in migraine, the temporomandibular joint in temporomandibular disorder (TMD), or the colon in inflammatory bowel disease (IBD); 2) many pain syndromes such as migraine, TMD and IBD occur with a greater prevalence, severity and/or duration in women than in men; 3) many pain syndromes are associated with changes in the excitability of primary afferent neurons; 4) there are time-dependent changes in the mechanisms underlying pain syndromes; and 5) the type of injury, (i.e., inflammation or nerve injury), are differentially sensitive to therapeutic interventions. These observations led to specific hypotheses that are tested in ongoing studies in the Gold laboratory. These include 1) characterizing the mechanisms underlying inflammation-induced changes in the evoked Ca2+ transients in sensory neurons, 2) characterizing the mechanisms underlying the initiation of migraine attacks, 3) characterizing the influence of estrogen on the excitability of spinal and trigeminal ganglion neurons, 4) characterizing the role of changes in inhibitory receptors, in particular GABA, in injury-induced increases in sensitivity, and 5) identification of ways to maximize the therapeutic utility of local anesthetics. The ultimate goal of these studies is to identify novel targets for the development of therapeutic interventions for the treatment of pain.

Neurophysiology of basal ganglia system related to psychiatric disorders.

Combining NMR spectroscopy w/Biophysics, Biochem&Chem to investigate cellular processes at the molecular & atomic levels in relation to human disease 

Our research focuses on vertebrate eye development, disease modeling and regeneration utilizing the zebrafish as a model system. 

Understand the causes of diseases with disruptions between the immune system and the microbiota, such as Crohn’s Disease and Environmental Enteropathy.          

The Hatfull lab in the Department of Biological Sciences at the University of Pittsburgh studies the molecular genetics of the mycobacteria and their mycobacteriophages. 

My lab addresses this question by examining microbial molecular mechanisms associated with disease. We study Streptococcus pneumoniae, a major human pathogen that causes over a million annual deaths in young children and the elderly, worldwide.

Studying signaling proteins and receptors of the TGF-beta family, deciphering the molecular adaptations that the signaling proteins, single-pass transmembrane receptors, downstream effectors, and multitude of extracellular and intracellular modulators.

My research involves the use of techniques from data science, machine learning, human-computer interaction,  and information visualization to increase the usability and utility of clinical, public health, and other biomedical data.

My lab investigates the cognitive and neurobiological bases of how human listeners use sound. This involves study of speech communication, auditory perception, attention, and learning.   

Identify renal progenitor cells, determine their role in patterning the embryonic kidney, and relate these events to kidney regeneration.           

The neural basis of flexible auditory perception and behavior; novel neurotechnologies for restoring hearing 

Multi-level translational studies of neurovascular and metabolic brain health with focus on aging and sex-specific differences.

We plan to employ our methods to edit epigenetic processes for cell fate reprograming as well as correcting aberrant gene expression in human diseases like obesity and cancer.

Prefrontal cortex; interneurons; Novel pharmacology; Alcohol use disorders & affective disorders

Her lab’s research is focused on developing noninvasive optical imaging methods for disease detection and/or treatment monitoring, with an emphasis on diffuse optical imaging.

Plasticity of neuronal circuits during development and in pathology, focusing on the central auditory system     

Signal Transduction.

The role of the Akt kinase in NF-kB and T cell activation. 

Role of TIM proteins in T cell activation.     

To understand how skin resident immune cells (e.g. dendritic cells, T cells) interact with specific pathogens

My research interests are in nano-optics and nano-electronics: materials & devices; hierarchical integration of nanoscale structures into systems for multifunctional operations.

Develop and translate multi-modal ultrasound imaging technologies that are based on a fundamental understanding of how sound and light interact with soft tissues, and are capable of assessing their mechanical, compositional, and biological characteristics. 

Cellular, structural and molecular studies of epithelial ion channels       

Our laboratory is interested in identifying new molecular pathways in epithelial biology in the pathogenesis of tissue remodeling in chronic obstructive lung disease (COPD) and pulmonary fibrosis to improve therapeutic options for patients. Our lab specifically studies the role of adenine nucleotide translocase (a canonical mitochondrial ADP/ATP transporter) in the airway and alveolar epithelium of the lung in the context of cigarette smoking-related lung disease and lung fibrosis. We want to better understand how in health and disease ANT regulates epithelial function through cell metabolism and cellular senescence, as well as, airway epithelial homeostasis through surface hydration and the action of tiny motile cilia in the airway. We utilize a repertoire of relevant murine models of injury, molecular genetic approaches, in vitro biochemical assays, and human bio-samples to examine epithelial cell homeostasis in the lung.

Our research focuses on deciphering mechanisms involved in lung repair and regeneration, with the aim to identify novel therapeutic targets relevant for age-related chronic lung diseases, such as idiopathic pulmonary fibrosis (IPF) and chronic obstructive pulmonary disease (COPD). Our translational research program focuses on the comprehensive characterization of primary lung epithelial (stem) cells from experimental models and human tissue samples from patients with chronic lung disease. we aim to identify and investigate target signaling pathways that impact cellular mechanisms we identified the developmental WNT signaling pathway as a potent contributor to impaired lung repair and epithelial cell reprogramming, which is amenable to therapy and have further characterized features of epithelial cell reprogramming, such as cellular senescence. We further pioneered and apply patient-derived 3D Lung Tissue Cultures that allow to further validate and test potential novel drugs in an individualized fashion.

Our research is on whether and to what extent mammalian hearts can regenerate themselves, and to develop regenerative therapies for heart failure.       

Innate and adaptive immune response to transplanted organs and the mechanisms of transplantation tolerance. 

Molecular profiling (genomic, transcriptomic, proteomic) of women’s cancers, mouse modeling, and predictive biomarkers for targeted therapy       

Functional architecture of the prefrontal cortex and schizophrenia.          

Our lab is focused on the host protective immune responses to M. tuberculosis, a major factor in outcome of infection.   

Drug Delivery, Biomimetics, Immunotherapeutics, Tissue Engineering, Biomaterials, Synthetic Systems          

Our research objectives are focused on elucidating the genetic causes and developmental mechanisms of human congenital heart disease (CHD).

Brain basis of cognitive maturation through adolescence to adulthood.   

Neural network control of cardiac arrhythmias and myocardial function; Neuromodulation for treating sudden cardiac death; Studying perioperative healthcare delivery; Role of perioperative interventions in altering clinical outcomes and mortality     

Cortical control of vision and eye movements in populations of neurons

Neural coordination of oculomotor plans

Influence of eye movements on vision and behavior

We are interested in the molecular mechanisms of psychiatric disorders with a particular focus on the role of the circadian clock in these disorders 

Human immunology: Innate and adaptive immune responses to latent viruses and to allo-antigens after organ transplantation 

Dr. Miljkovic's research focuses on the epidemiology of obesity, ectopic fat deposition, body composition, and associated metabolic disorders. In particular, Dr. Miljkovic studies skeletal muscle, changes in skeletal muscle and whole body composition with aging, their determinants, and associated metabolic disorders, with a special focus on high-risk minority, international, and elderly populations.

Pelvic Floor Disorders, Prolapse Meshes; To date, Dr. Moalli’s research has mainly focused on 1) the development of novel biomaterials for use in pelvic reconstructive surgeries; 2) defining and reducing maternal birth injury; and 3) vaginal biofabrication.

The study of human tumor viruses; Our laboratory used pioneering genomic techniques to discover two different cancer viruses (Kaposi sarcoma herpesvirus and Merkel cell polyomavirus) that are responsible for four different cancers.       

Pathogenicity of Intestinal Microbes in Milk Fed and Formula Fed Premature Infants - See more >>

HIV-associated lung disease; HIV-associated emphysema; Role of Pneumocystis in COPD   

My research interests are in cardiovascular monitoring including novel sensors and algorithms and incorporating physiology.

We have been investigating and comparing signal transduction, rate of cell proliferation, and cell communication in normal and cancerous tissues.

Matthew Neal's research interests include co-leading the NIH-sponsored ACTIV-4 program, trauma-induced coagulopathy, clinical outcomes in trauma and hemorrhagic shock, and outcomes research in acute care and emergency general surgery.

To understand the cellular and molecular basis of liver injury, regeneration, and cholestatic liver disease     

Cardiovascular Disease Epidemiology;Subclinical atherosclerosis: Associations with aging, disability & frailty;Sarcopenia & disability

Hormone response and treatment resistance in breast and ovarian cancer, including the analysis of aberrant genetic and epigenetic changes           

Spermatogonial stem cells (SSCs) and male germ lineage development

Our group extracts biological insights and disease mechanisms from multiomics data including single-cell and spatially resolved data.

The O’Sullivan lab at the Hillman Cancer Center conducts research into proteins that alter the structural and epigenetic functions of human telomeres.

Molecular mechanisms underlying various neurological disorders using human genetic approaches as well as research on animal and cell culture models

NADPH oxidase (Nox) & reactive oxygen species in signaling, vascular dysfunction and cardiopulmonary disease; Nox drug therapy development   

What features do the genes and the genomes of vocal learning species have in common relative to those without the ability?          

Identification of neural correlates that underlie the symptoms of specific abnormalities in emotion processing in people with mood disorders     

Research in Dr. Rizzo’s lab focuses on investigating the mechanisms that drive divergence from healthy aging towards inception and progression of Alzheimer’s disease, in order to identify novel pathways and targets that may enable the discovery of new therapeutic agents to treat and prevent disease. Dr. Rizzo is a behavior pharmacologist by training and holds a BS in Animal Sciences from Rutgers University and a PhD in Neuroscience from University College London.

He is interested in the use of observational data analysis for causal inference, as well as in the measurement and inclusion of patient preferences into treatment decisions and the use of electronic health records for research. 

Vascular development, hereditary hemorrhagic telangiectasia, zebrafish, BMP signaling, mechanotransduction.

Brain adaptation, neuroepidemiological approaches to the causes, biomarkers and consequences of brain aging, advanced data reduction analyses

Understanding the functional organization of spinal microcircuits using molecular genetic, electrophysiological, optogenetic & behavioral approaches   

Research focuses on investigating neuron-glia communication in the normal hearing and in the hearing impaired 

Dr. Sabik is a health economist & health services researcher focused on investigating the role of state & federal policies in affecting healthcare access, utilization, & health outcomes among low-income populations, with a particular focus on cancer care.   

We develop materials-based, engineering strategies to control the self-organization and assembly of various cell types into tissues using nanoscale fabrication and 3D bioprinting. Understanding of higher-order function in biological systems.

Dr. Sachdev-Ost's research examines how the nuclear protein HMGB1 is released from ischemic muscle, finding that its absence hinders recovery and that inflammasomes and platelets may affect its local availability.

Neural mechanisms underlying complex sound perception in health and disease.   

Our lab focuses on molecular mechanisms underlying placental development and its function in supporting fetal growth and maternal-fetal communication   

We use interdisciplinary approaches to understand how the nervous system regulates homeostasis and disease, including pain syndromes, cancer, and immune responses.

I work in the general area of computational biology, with emphasis on computational genetics and the modeling and simulation of biological systems     

Our work is focused on neural circuits that mediate two neurological conditions: pain and Parkinson’s disease. We are also developing novel therapies to treat these conditions.   

My lab is interested in the establishment of long term B cell immunity and in pathogenesis of systemic autoimmune diseases and graft vs host disease   

Neurophysiology of visual perception and cognition, computational neuroscience, cortical circuitry, neural population coding   

Non-receptor protein-tyrosine kinase structure, regulation and signal transduction in cancer, AIDS, and embryonic stem cell biology

Biomarker discovery, beneficial effects of mechanical loading, & implementation in targeted exercise therapies for musculoskeletal conditions     

We have pioneered research in a historically understudied area of ophthalmology, the ocular microbiome and its effect(s) on ocular disease. Normally a highly contentious topic in ophthalmology, the ocular microbiome does, indeed, tune local immunity to prevent fungal and bacterial infection.

Mechanisms of white blood cell differentiation & its inhibition in leukemias; Mechanisms of stem cell differentiation & growth control           

Our studies will be a direct outgrowth of this work, where we will focus on the molecular, cellular, and in vivo contribution of somatic hemoglobins and CytB5Rs as it pertains to vascular physiology and disease.

Our work is focused on the relationship between biomolecular condensates, cytoplasmic crowding, cell fluid volume and size control, and kidney tubule function in health and disease

Loss and altered plasticity of auditory cortex synapses in schizophrenia; mediators of vulnerability to psychosis in Alzheimer disease.          

Psychosocial issues in organ and tissue donation and transplantation. 

Our research interest is development of novel molecular and metabolic imaging strategies for early detection and risk stratification of cardiovascular and pulmonary diseases using high-resolution SPECT and PET.

Dr. Tejero's research focuses on heme proteins, aiming to characterize nitrite reactions with hemoglobin and myoglobin, understand the cytoprotective roles of neuroglobin and cytoglobin, and develop heme-based antidotes for carbon monoxide poisoning.

We use molecular, biochemical, and cellular approaches to study the pathogenesis of Alzheimer’s disease.          

Regulation of the immune response; role of dendritic cells and T cells in tolerance induction; mechanism of action of novel immune suppressants           

Dennis Trumble uses multiscale computational models of the beating heart to develop implantable devices for cardiac assist purposes.

Zebrafish Heart Development and Regeneration; Research in Dr. Tsang’s lab has focused on the role of Fibroblast Growth Factor (FGF) signaling in zebrafish development. Another area of research in Dr. Tsang’s lab is using zebrafish as a model for human congenital heart disease and in understanding the early events that establish left-right patterning.

Basal ganglia-cortical dysfunction in Parkinson's disease and therapeutic mechanisms of deep brain stimulation          

Understanding and controlling the cytokine networks that direct immune responses responsible for both protective and pathological immunity. 

Repair of DNA damage in nuclear and mitochondrial genomes; 2) Structure and function of nucleotide excision repair proteins. 

Extracellular Matrix Remodeling, Tissue Engineering, Biomechanics, Computational Modeling

My research focuses on neural, vascular and metabolic imaging of normal brain function in vivo with extensions to neurological pathologies, especially Alzheimer’s disease. I use an array of computational and optical methodologies.

The inhibitory mechanisms, including inhibitory receptors & regulatory T cells, that limit anti-tumor immunity in cancer patients. 

Dr. Villanueva's research focuses on the development of medical diagnostic and therapeutic strategies based on ultrasound and ultrasound contrast agents (gas-filled microspheres, or microbubbles).

Computer-aided diagnosis and patient-specific prediction, genomic and precision medicine, clinical decision support, research data warehouse

My research focuses on mitochondrial energy metabolism, branched chain amino acid metabolism, inborn errors of metabolism, and development of novel therapies for inborn errors of metabolism.

Cardiovascular engineering with projects that address medical device biocompatibility and design, tissue engineering, and imaging.     

Wang’s research focuses on understanding how the immune system behaves within the microenvironment of a tumor in head and neck cancer and B cell lymphoma. She also studies how changes in the DNA of B cells alter how the body produces antibodies that are used to fight pathogens and cancer cells. Her research will shed light on how cancer cells evade detection by the immune system, findings that will help develop new immunotherapies and improve existing treatments.

His research is focused on androgen action in prostate cancer and benign prostatic hyperplasia.  The Wang lab is actively pursuing following research directions: (a) the roles of androgen-responsive genes in prostate carcinogenesis, particularly the mechanisms of tumor suppression by ELL-associated factor 2 (EAF2), which is encoded by up-regulated androgen-responsive gene U19, (b) improvement of intermittent androgen deprivation therapy of prostate cancer based on differential action of testosterone and dihydrotestosterone (DHT), (c) the mechanisms regulating androgen receptor (AR) intracellular trafficking, level and activity, and (d) developing novel small molecule inhibitors targeting AR signaling for the treatment of prostate cancer that are resistant to current anti-androgens

I use machine learning and brain imaging to study the brain representations underlying language comprehension and other high-level functions.

Focuses on asthma phenotypes and the molecular mechanisms, particularly in the airway epithelium that control them 

the cell entry, immunity, and pathogenesis of human metapneumovirus (HMPV)

The Laboratory for Research on Arm Function and Therapy (RAFT) studies upper extremity motor function in healthy and disease states and particularly focuses on methods to improve recovery of motor function after stroke, using non-invasive brain activity-recording and stimulation techniques, robots, and wearables.

MuSIC 4 MIND: Multi-Systems Imaging Characterization for Mitochondrial Involvement in Neurological Diseases:

Leveraging novel systems imaging to uncover molecular mechanisms underlying epilepsy, traumatic brain injury, fetal alcohol syndrome, in utero exposure, congenital heart disease, mitochondrial disorders, childhood-onset epileptic encephalopathy and developmental origin of adult-onset diseases.  

Dr. Xia’s research addresses clinically relevant questions: (1) how does multiple sclerosis start and how to prevent this chronic neurological disease, (2) what contributes to individual variation among people with multiple sclerosis and how to bring precision medicine to multiple sclerosis. He leads an interdisciplinary research team to harness multi-dimensional, longitudinal, patient-derived data and deploy integrative quantitative science approaches. The long-term goal of his research program is to gain insights into the underlying disease and translates these findings into the clinical arena to improve individualized risk prediction, prevention, and management in multiple sclerosis and other related disorders.

My lab currently focuses on Epithelial-to-Mesenchymal Transiton (EMT). EMT is defined as the conversion of epithelial cells to mesenchymal cells, characterized by loss of cell-cell adhesion and increased cell motility.          

My lab focuses on developing targeted therapies that target beta cell mass and function in the pathogenesis of diabetes. Currently funded projects include 1) the role of the circadian clock in beta cell metabolic flexibility, 2) Interventions and mechanisms addressing the role of circadian clock disruptions in diabetes, atherovascular, and Alzheimer's' diseases 3) the role of Tead1 and the Hippo pathway in the transcriptional regulation of quiescence and proliferation of beta cells. We are also interested in how these pathways affect obesity, adipose biology, and cardiac biology.

Our goal is to establish how neural circuits lead to these action selection decisions. The vital ability to make appropriate actions requires the coordination of motor, reward, and cognitive brain systems.

Hassane Zarour's research focuses on identifying MHC class II tumor epitopes from cancer-germline antigens in melanomas, analyzing CD4+ T cell responses, and studying immune responses in melanoma patients receiving peptide- and protein-based vaccines with CpG oligonucleotides.

We are employing a quantitative approach using microfluidics, systems biology modeling and in vivo systems to investigate how microenvironmental signals (paracrine, hypoxia, mechanical forces and ECM composition) impact cell growth, migration and therapeutic response in the context of cancer (ovarian and breast) and remodeling tissues

The phase transition process of liquid-liquid de-mixing organizes proteins and RNAs into liquid compartments in cells. We study how this process promotes cellular functions in healthy cells and how mis-regulation of it leads to cancer.

Our lab is an interdisciplinary research group that combines diverse bioengineering and chemical approaches to develop novel techniques for interrogation of biological and pathological processes in cells and tissues.

Dr. Zhu’s lab is currently investigating the regulation as well as the physiological/pathological functions of the 12h-clock, taking a combination of computational, biochemical, genetic, cellular, imaging and genomic approaches.