Kansas City Faculty Research

KCU's esteemed faculty conducts research in a variety of fields from molecular and cellular biology to infectious diseases and biomechanics. Each faculty member has years of experience in research and is available for partnerships and student mentorship.

A. Baki AgbasA. Baki Agbas, MSc, PhD
Professor of Biosciences

Research Interests: Biomarkers for Neurodegenerative Diseases

Dr. Agbas is working on the development of novel blood-based biomarkers for neurodegenerative diseases such as Alzheimer’s disease and ALS. He recently published new research suggesting a blood platelet screening with a specific antibody has the potential to be a useful tool in diagnosis Alzheimer's disease. He is also assessing the oxaloacetic acid (OAA) treatment for ALS model mouse as part of explorative study for developing treatment for human ALS. 

In addition, Dr. Agbas is exploring the mitochondrial respiration profile in Alzheimer’s disease and ALS as a potential biomarker and Zinc biology in neurodegenerative diseases. He also is exploring a novel mechanism of motor neuron death in a genetic form of ALS in dogs termed canine degenerative myelopathy (DM). This research is continuing in collaboration with University of Missouri-Columbia researchers.


Doug Bittel, PhDDoug Bittel, MSc, PhD
Professor of Biosciences

Research interests:  Alternative splicing (AS) of mRNA plays an important role in vertebrate development and pathogenesis. However, the mechanisms that regulate AS are poorly understood. Our studies of gene processing in heart tissue from babies with congenital heart defects suggest that scaRNAs may contribute to their heart defect. Our observations, using human cell cultures clearly show that altering the expression level of small cajal body-associated noncoding RNAs (scaRNAs) alters mRNA splicing. Furthermore, using zebrafish and quail embryos, we have shown that altering scaRNA expression levels in the embryo alters mRNA splicing and embryonic development. We hypothesize that scaRNAs play an important role in regulating development and when they are dysregulated, they contribute to developmental pathology. This is a new paradigm in developmental regulation; therefore, it is critical that we develop a better understanding of the role that scaRNAs play in alternative splicing of mRNA and development.      

We are also collaborating with a biotech company, Likarda, in developing a stem cell-based cure for Type 1 diabetes. In phase 1, Likarda is inducing pluripotent stem cells to differentiate into insulin-producing cells. They will transplant these cells into companion animals. Our role is to evaluate multiple biomarkers as the cells differentiate to ensure that the process is proceeding as expected. Their business model is to do clinical trials in companion animals to demonstrate proof of concept prior to adapting the process for human application.


Eugene Konorev, MD, PhDEugene Konorev, MD, PhD
Associate Professor of Pharmacology

Research Interests: Angiogenesis and Cardiovascular Complications of Anticancer Therapy

Utilizing animal models and cell culture, Dr. Konorev’s research is focused on the prevention of cardiac remodeling and progression of heart failure resulting from cancer chemotherapeutics. His team has made important contributions to the field of angiogenesis or the process of formation of new vascular networks in postnatal tissues. He has identified targets for the antiangiogenic effect of doxorubicin and therapeutics to alleviate the antiangiogenic effects.


Ehab Sarsour, MSc, PhDEhab Sarsour, MSc, PhD
Assistant Professor of Cellular and Molecular Biology

Research Interest: Aging and age-associated diseases including cancer

Dr. Sarsour's research interests focus on the molecular mechanisms that regulate the proliferative properties of normal and cancer cells. Dr. Sarsour proposed that two separate, but interdependent pathways could regulate cellular longevity in normal cells: a redox-sensitive checkpoint regulating the transition from quiescence to proliferation also known as chronological life span followed by telomeric attrition controlling the “mitotic clock” known as replicative life span. My research has shown that the antioxidant enzyme manganese superoxide dismutase protects quiescent normal human fibroblast regenerative capacity (chronological life span) by regulating mitochondrial reactive oxygen species and protecting mitochondrial integrity from age-associated abnormalities. Dr. Sarsour's work has evolved into examining the molecular mechanisms associated with oxidative stress and metabolic alteration during cellular aging and its effects on cancer progression. The scope of his current and future work is to understand how cellular redox status, reactive oxygen species, and lipid metabolism regulate cellular aging in human tissue and their effect on the microenvironment of diseased tissue, with the goal of enhancing the human health life span. Dr. Sarsour is also working on different translational research strategies that relate to manipulating the cancer microenvironment to enhance chemo and radiotherapies to achieve a better outcome for cancer patients.


Robert White, PhDRobert White, PhD
Dean of the College of Biosciences, Professor of Molecular Biology and Medical Genetics

Research Interest: Development of Therapy for Duchenne Muscular Dystrophy (DMD)

Duchenne Muscular Dystrophy (DMD)

Dr. White's lab has been developing a novel therapy to treat Duchenne Muscular Dystrophy (DMD), a lethal muscle degeneration disease commonly found in boys for which there is no cure and is caused by the lack of a muscle protein called dystrophin. Expression of a protein from the eye (retinal dystrophin) in DMD model mice by a transgene cures the mice of their disease which includes severe muscle degeneration accompanied by loss of limb movement and early death. Dr. White's next goal is to move from the lab bench to the bedside of patients. He and his team are identifying the promoter of the retinal dystrophin as a first step in identifying drugs which will induce its expression in muscle. The genetic machinery to make eye dystrophin in muscle is present in many DMD patients but is not used because it is not retinal tissue. Their long-range goal is to find drug(s) that induce expression of eye dystrophin from its promoter in muscle as a cure for DMD.

Hematological Diseases Project 1

Iron overloading is a debilitating disease that can occur in a genetic disease (Hereditary Hemochromatosis) or in blood transfusion-dependent diseases such as beta-thalassemia and sickle cell disease. Iron overloading can lead to heart, kidney and pancreatic disease which presents as severe morbidity. The treatment for this disease is using iron-chelating drugs for which patient compliance is low. Hemochromatosis patients are treated by bloodletting as this is the only method by which treatment can remove iron from the body. Dr. White's lab has a mouse mutant that excretes 100x more iron in urine and, when mated to hemochromatosis model mice, can prevent iron overloading. His study is to identify the mechanism and pharmaceutical targets to induce this urinary iron excretion to treat patients with iron overload.

Hematological Diseases Project 2

In a second project, Dr. White's lab is in the process of identifying a novel erythroid transcription factor to treat anemia and potentially identify a novel treatment for leukemia. This work derives from the study of an interesting mouse mutant (call Xpna: x-linked pre and neonatal anemia) which lacks the most important erythroid transcription factor called GATA1. The mice with a GATA1 mutation are born anemia but unexpectedly receiver from their anemia. The hypothesis being tested is that there is a compensatory erythroid transcription factor that replaces GATA1 in these mice and also has the likely characteristic that it can prevent leukemia as well.


Barth Wright, PhDBarth Wright, PhD
Associate Professor of Anatomy

Research Interests: Comparative Anatomy and Behavior

Dr. Wright's research examines the various interactions among human and non-human primate food mechanics behavior and morphological and physiological adaptations, particularly craniofacial. These tools and techniques include, but are not limited to, detailed in-field observations of feeding in field tests of food mechanical properties combined with laboratory measures of force transduction using high fidelity 3D imaging and force measurement. His research incorporates a range of tools and techniques, the use of which can prove beneficial to evolutionary biologists and clinicians.


Asma Zaidi, PhDAsma Zaidi, PhD
Professor of Biochemistry

Research Interests: Neurobiology of Brain Aging and Neurodegenerative Disorders

Teaching Expertise: Basic and Clinical Biochemistry, Molecular and Cell Biology

Dr. Zaidi’s research interests are focused on investigating the mechanisms underlying neuronal cell death in brain aging and in neurodegenerative disorders. Her work has shown that disruption of calcium homeostasis is the final common pathway leading to the death of neurons in the central nervous system. She focuses on a calcium transporter called the plasma membrane Ca2+-ATPase (PMCA). The PMCA is responsible for pumping calcium out of neurons to maintain a 10,000-fold gradient that exists across the plasma membrane and is critical for optimal functioning of neurons. Her research showed for the first time that the activity and protein levels of PMCA are progressively reduced in the brain with increasing age. She has also shown that this protein is extremely sensitive to oxidative stress and undergoes inactivation, aggregation and proteolysis when exposed to reactive oxygen species of physiological relevance. 

Dr. Zaidi’s recent work has identified that the PMCA plays an important role in the selective degeneration of dopaminergic neurons in Parkinson’s Disease (PD). Utilizing human brain post-mortem tissue animal model as well as a cell culture model of PD, she showed that endogenous levels of PMCA are lower in the substantia nigra of the brain compared to other regions. Additionally, PMCA activity is significantly reduced when exposed to PD mimetics. Currently, she is developing novel strategies to increase the expression of the PMCA, which may serve as a translational target for therapeutic intervention in PD. Several antioxidant flavonoid compounds including resveratrol, curcumin, fisetin and edaravone are emerging as promising targets.