First name,Last name,Preferred title,Overview,Position,Department,Individual
Sathish,Dharani,Research Assistant Professor,,Research Assistant Professor,Pharmacy Practice,https://scholars.library.tamu.edu/vivo/display/n0373e83e
John,Gladysz,Distinguished Professor,"My research has traditionally been centered around organometallic chemistry, and from this core area branches into catalysis, organic synthesis, enantioselective reactions, stereochemistry, mechanism, and materials chemistry. About half of my group is involved with catalysis projects. Areas receiving emphasis include (a) structurally novel new families of highly enantioselective catalysts, (b) metal-containing ""organocatalysts"" and (c) recoverable catalysts, particularly those with ""ponytails"" of the formula (CH2)m(CF2)nF; these can be recycled via ""fluorous"" liquid or solid phases, such as Teflon. The other half of my group synthesizes organometallic building blocks for molecular devices. These include (a) molecular wires composed of metal endgroups and linear (sp) carbon chains, including stable species with C28 bridges, (b) analogs in which the charge-transmitting bridges are insulated by a pair of polymethylene or (CH2)n chains that adopt a double-helical conformation, (c) polygons and multistranded molecular wires based upon such building blocks, and (d) molecular gyroscopes and compasses consisting of a rotating MLn fragment and an external cage (stator) that insulates the rotator from neighboring molecules, exactly as with the commercial gyroscopes used for aircraft and space-station navigation.",Faculty Affiliate||Distinguished Professor,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/n05e5403e
Peter,Rentzepis,Professor,My research interest include lasers and their application to science and technology.,Faculty Affiliate||Professor,Energy Institute||Electrical and Computer Engineering,https://scholars.library.tamu.edu/vivo/display/n08418952
John,Jifon,Professor,"Dr. Jifon's research is focused on environmental stress physiology of plants -- the physiological, biochemical and molecular mechanisms and traits that confer tolerance to environmental stresses (especially to drought, radiation/temperature extremes, and nutrient imbalance). A key theme in his research is to use integrated measurements obtained at leaf, whole-plant, and stand levels to study factors that regulate photosynthetic efficiency, water/nutrient use efficiency, assimilate partitioning, yield and quality. The aim is to use the information gained in these studies to develop practical strategies to optimize productivity and quality by improving plant tolerance to environmental stresses.",Professor||Professor,Texas A&M AgriLife Research||Horticultural Sciences,https://scholars.library.tamu.edu/vivo/display/n0aa3912d
Francois,Gabbai,Professor,"Our research is concerned with the chemistry of both organic and organometallic polyfunctional Lewis acids. While an important component of our work deals with the synthesis of new examples of such polyfunctional Lewis acids, it is our ultimate intent to harness and utilize the cooperative effects occurring in such systems for the discovery of unusual structures, bonding modes, supramolecules and reactivities. Our research efforts present important ramifications in the domain of molecular recognition, supramolecular materials and catalysis.",Faculty Affiliate||Professor,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/n0d5d68bb
Ziyaur,Rahman,Associate Professor,"Over 17 years of research experience in the general areas of pharmaceutical sciences and drug delivery systems, with special expertise in the area of formulation design and process development. Research areas are: 1) formulation and process design of complex drug delivery systems (such as liposomes, nanoparticles, transdermal, implant, emulsions, microspheres, pediatric etc.); 2) improving drug product quality as well as process understanding through Quality by Design (QbD) approach and Process Analytical Technologies (PAT); 3) development of in vitro release performance tests for traditional (tablets, capsules, gels, emulsions) as well as complex drug delivery systems (microspheres, liposomes, nanoparticles, transdermal, implant, emulsions, ointments, creams, etc.); 4) evaluation of bio-equivalence of complex drug dosage forms; 5) design and evaluation of abuse deterrent formulations (ADF) for opioid analgesics, 6) 3-dimensional printing of various dosage forms for pharmaceutical application, 7) continuous manufacturing of pharmaceutical dosage forms and 8) univariate and multivariate models (chemometrics, mega-data analysis) development for various phases (polymorphs, amorphous, solvates, salt or base) quantification in the drug products. Other areas of intense research interest include protein and peptide delivery using polymeric materials in formulation design and risk analysis.",Associate Professor,Irma Lerma Rangel School of Pharmacy,https://scholars.library.tamu.edu/vivo/display/n0fc48989
Daniel,Jones,Associate Professor,,Associate Professor,Veterinary Physiology and Pharmacology,https://scholars.library.tamu.edu/vivo/display/n14141cf6
Hassan Said,Bazzi,Professor and Senior Associate Dean,"Dr. Bazzi's research interests focus on metathesis chemistry as a powerful tool in small molecule and polymer synthesis, in addition to polymer-supported catalysis, DNA-mimetic polymers, and fluorous analogs of ruthenium based catalysts.",Professor and Associate Dean for Research,Science (Qatar),https://scholars.library.tamu.edu/vivo/display/n14a81bfa
Friedhelm,Schroeder,Professor,Intracellular lipid transfer proteins; lipid metabolism; multiphoton imaging of intracellular lipid transport and targeting in living cells and tissues of gene targeted animals.,Professor,Veterinary Physiology and Pharmacology,https://scholars.library.tamu.edu/vivo/display/n157063e2
Jhenny,Galan,Instructional Assistant Professor,,Instructional Assistant Professor,Foundational Sciences,https://scholars.library.tamu.edu/vivo/display/n1ba6982c
Melissa,Grunlan,Professor,"Prof. Grunlan's research is focused on the development of polymeric biomaterials for medical devices having resistance to biological adhesion and for implantable scaffolds used in regenerative engineering. The unique properties of these biomaterials afford the opportunity to overcome barriers associated with treating various diseases and medical conditions. Specifically, her research has focused on materials for implanted glucose biosensor membranes [to extend sensor lifetime], hemodialysis catheters [to reduce clotting and infection rates], self-fitting tissue scaffolds [to heal bone defects due to injury, tumor resection or congenital birth defect] and cartilage resurfacing [as an alternative to total joint replacement].",Professor||Professor||Professor,Biomedical Engineering||Materials Science and Engineering||Chemistry,https://scholars.library.tamu.edu/vivo/display/n1bfcff20
David,Russell,Professor,"My research focuses on proteomics, lipidomics, biophysical chemistry and application and development of mass spectrometry, such as ""label-free"" nano-particle based biosensors and novel peptide/protein isolation and purification strategies. We are also investigating the structure(s) of model peptides in an effort to better describe folding/unfolding and structure of membrane and intrinsically disordered (IDP) proteins. Peptides take on very different 2?, 3? and 4? structure, which determine or influence bio-activity. In the presence of lipid vesicles peptides can exist as solution-phase species, ""absorbed"" on lipid bilayers or ""inserted"" (as a monomer or multimer) in lipid bilayers. By what mechanism do peptides interact with lipid membranes to affect these structural changes, how do peptide-lipid interactions promote self-assembly to form intermediates that eventually yield aggregates, i.e., amyloid fibrils, or how does metal ion coordination affect the structure of metalloproteins? Mass spectrometry-based experiments, hydrogen/deuterium (H/D) exchange, chemical 'foot-printing' and gas-phase (ion-molecule and ion-ion reaction chemistry) and solution-phase chemical modifications, have expanded our abilities to address such questions, and new instrumental approaches, esp. ion mobility spectrometry (IMS) combined with enhanced molecular dynamics simulations (MDS), have become standard tools for structural-mass spectrometry studies. Over the past several years we have either acquired or developed novel, next-generation IM-MS instruments that are redefining cutting-edge structural-mass spectrometry research as well as cutting-edge computational tools essential to carry out these studies. Our new laboratories in the Interdisciplinary Life Sciences Building (ILSB) provides exciting opportunities for collaborative, interdisciplinary research with chemical-biologists, biochemists and other chemists.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n280e03e6
Virender,Sharma,Professor,"My research focuses on (1) chemistry and application of ferrates, (2) formation, fate, and toxicity of silver and gold engineered and natural nanoparticles in aquatic environment, (3) applications of ferrites to destroy toxins and pollutants under solar light, and apply carbon-based materials to remediate contaminated water",Faculty Affiliate||Professor,Energy Institute||Environmental and Occupational Health,https://scholars.library.tamu.edu/vivo/display/n28508dfb
Jian,Feng,Professor and Assistant Dean,,Assistant Dean for Research and Professor,Biomedical Sciences,https://scholars.library.tamu.edu/vivo/display/n2b3403fd
Thomas,Taylor,Professor,"Dr. Taylor's primary research interests are in the utilization and mechanisms of food antimicrobials to inhibit bacterial foodborne pathogens. Natural food antimicrobials are diverse in their chemistry, spectrum of activity, sources, and applications within foods. Specifically, research is conducted to investigate and determine the manner by which food antimicrobials inhibit microbial pathogens. Additionally, research is conducted that seeks to overcome obstacles to the use of food antimicrobials in some product by the encapsulation of food antimicrobials. Dr. Taylor regularly interacts with faculty in the Departments of Horticultural Sciences, Nutrition and Food Science, Poultry Science, and even Chemical Engineering in the development and completion of research programming.",Professor,Animal Science,https://scholars.library.tamu.edu/vivo/display/n324ce79b
Lane,Baker,Professor,,Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n3b0176ae
Genhua,Niu,Professor,"Dr. Genhua Niu is a professor in Urban Agriculture at the Texas A&M AgriLife Research Center in Dallas. Her research focuses on the development of culture information and best management practices related to urban agriculture, which is the science of crop production in an urban setting using a variety of controlled environment agriculture (CEA) technologies in an urban setting. Prior to this position, Dr. Niu was a professor in urban landscape water conservation at Texas A&M AgriLife Research Center in El Paso. Up to October 2019, Dr. Niu has published 131 refereed journal papers, 18 book chapters, 49 proceedings papers, and 23 technical extension articles and edited 3 books. She is the author and editor for the Plant Factory - Indoor Vertical Farming book. She has received several awards from American Society for Horticultural Science, USDA-NIFA, and Texas A&M University.",Professor,Horticultural Sciences,https://scholars.library.tamu.edu/vivo/display/n3b8a47b0
Thomas,Meek,Professor,"Marketed drugs have been developed for representatives of all six classes of enzymes, and comprise essential therapies for the treatment of cancers, HIV/AIDS, hypercholesterolemia, and bacterial infections. The availability of known point mutations that are causative of human cancers , as well as the full genomic descriptions of many pathogens, such as parasitic protozoa and infectious bacteria, provides an emerging means to identify new or known enzymes that would constitute potential drug targets. Likewise, the availability of crystal structures of many of these enzymes or their analogues, provides a means to rationally design new inhibitors of enzyme drug targets via the use of molecular modelling and a full understanding of the chemical mechanism of the target enzymes, as an important adjuvant to inhibitor discovery via high-throughput screening.
Our laboratory will initially focus on the detailed study of the mechanisms of cysteine proteases such as cathepsin C, the isocitrate lyase of Mycobacterium tuberculosis, and human ATP-citrate lyase, by the use of pre-steady-state and steady-state kinetics, as well as by use of existing crystal structures of these enzymes, to inform the design of both covalent and other mechanism-based modes for the inactivation of these enzymes. We will design and synthesize candidate inhibitors, and test them against these and other enzyme targets, and determine their suitability as potential drug candidates.",Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n41081941
James,Batteas,Professor,"The research in our group is organized around three main projects: nanoscale materials and devices, biological surfaces and interfaces and nanotribology,
with the overarching goal of developing custom engineered surfaces and interfaces. This requires obtaining a fundamental (molecular level) understanding of the underlying chemistry and physics of the systems in question to afford rational approaches to test and develop new technologies. In much of our research we employ a range of scanned probe microscopies such as scanning tunneling microscopy (STM) and atomic force microscopy (AFM) to probe structure and to manipulate materials at the nanoscale.",Faculty Affiliate||Professor||Faculty Fellow||D. Wayne Goodman Professor of Chemistry,Center for Health Systems and Design||Energy Institute||Chemistry||Chemistry,https://scholars.library.tamu.edu/vivo/display/n413d1dff
Emily,Pentzer,Associate Professor,,Associate Professor,Materials Science and Engineering,https://scholars.library.tamu.edu/vivo/display/n430ead7e
Arthur,Laganowsky,Associate Professor,"A long-term research goal of our group is to determine the molecular basis behind protein-lipid interactions and how these interactions can modulate the structure and function of membrane proteins, including their interactions with signaling molecules. What determines the selectivity of membrane proteins towards lipids, and the coupling between lipid binding events and function remains a key knowledge gap in the field; one that if addressed will significantly advance our understanding of how lipids participate in both normal and pathophysiological processes of membrane proteins. Therefore, there is a critical need to expand our fundamental knowledge in this emerging field by applying and developing innovative approaches to elucidate how lipids modulate the structure function of membrane proteins. To this end, we are studying a number of ion channels, receptors and other types of membrane proteins.",Associate Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n542411e4
Jorge,Seminario,Professor,"Dr. Seminario's research covers several aspects of nanotechnology such as the analysis, design, and simulation of systems and materials of nanometer dimensions--especially those needed for development and systems for energy, nanosensors and nanoelectronics. Among his recent goals is the design of smaller, cleaner, more efficient and faster devices for energy production and storage as well as for detection of chemical, biological and nuclear agents. He has developed new scenarios for nanodevice architectures using a multiscale and multidisciplinary approach that progresses from the atomistic level to the final product, guided by first principles calculations.",Faculty Affiliate||Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n563c3880
Phanourios,Tamamis,Assistant Professor,,Associate Professor,Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n5673e0c8
Thomas,Marek,Senior Research Engineer,,Senior Research Engineer,Amarillo Research and Extension Center,https://scholars.library.tamu.edu/vivo/display/n58f5e117
Barbara,Miller,Associate Professor - Executive Director,,Associate Professor - Executive Director,Restorative Sciences,https://scholars.library.tamu.edu/vivo/display/n59dcef07
Narendra,Kumar,Associate Professor,"1. Obesity associated metabolic syndrome (MetS) is both a US and a worldwide epidemic and a major burden to healthcare system. Chronic low-grade inflammation (CLGI) is a well-established characteristic of the obese-human condition and though, the gastrointestinal (GI) mucosa is the first tissue that interacts with dietary components and luminal microbiota both of which are known to regulate obesity, the research on the role of GI-mucosa in obesity associated MetS is lacking. Findings from my lab support a key role of Janus kinase 3 (Jak3), a non-receptor tyrosine kinase, in intestinal and systemic CLGI associated obesity and diabetes in both an animal-model and in humans. Our publications, and unpublished data indicate that Jak3 regulates; colonic and systemic CLGI, and multiple symptoms of metabolic syndrome. Our goal is to determine the associated underlying mechanisms. Our current focus is on tissue-specific roles of Jak3 and associated signaling complexes in CLGI-onset as a precursor for; (a) obesity and diabetes, (b) Obesity and Alzheimer's disease, and (c) inflammatory bowel disease.
2. Inflammatory bowel disease (IBD) that includes Crohn's disease and Ulcerative colitis is a chronic inflammatory condition of gastrointestinal tract. Annual death from these diseases are over 70,000.00, and the incidences of new cases have been rising over the years. Because the repairs of intestinal mucosa (Restitution) are compromised during IBD, the research focus of our lab is to dissect the roles of intestinal epithelial, intestinal immune cells and gut microbiota in mucosal restitution. Our lab was pioneered the functions of Jak3 in intestinal epithelial mucosa. We show that IL-2 (a cytokine produced during intestinal inflammation) promotes mucosal wound repair through Jak3 complexed with villin, ShcA, and ?-catenin. Studies are underway to define the tissue-specific Jak3-mediated signaling pathways that regulate CLGI as a precursor for the onset of IBD.",Associate Professor and Director of Graduate Studies||Associate Professor,Pharmaceutical Sciences||Pharmaceutical Sciences,https://scholars.library.tamu.edu/vivo/display/n5bcfc45e
Mahmoud,El-Halwagi,Professor,"Dr. El-Halwagi's research is in the area of process design, integration, and optimization. The focus is on the development of systematic and generally applicable methodologies and tools that can guide engineers in the design and operation of gas and fuels processing facilities.",Faculty Affiliate||Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n5c26539a
Jason,Gill,Associate Professor,"Dr. Gill's major research focus is the biology and application of the viruses of bacteria, called bacteriophages or simply phages. Phages are the most abundant organisms on Earth, and they are found ubiquitously in water, soil, and as part of the microbial flora of animals and plants. As natural predators of bacteria, phages are attractive agents for the control of pathogenic bacteria in humans, animals, and foods. The increasing prevalence of antibiotic resistance in pathogenic bacteria, and the desire to curtail use of antibiotics in animal agriculture, has sparked interest in the use of phages as antimicrobials. Research in Dr. Gill's lab encompasses phage genomics, basic phage biology and the applications of phages in real-world settings.",Associate Professor,Animal Science,https://scholars.library.tamu.edu/vivo/display/n6277ae7f
Lauren,Mcintosh,Assistant Research Scientist,,Assistant Research Scientist,Cyclotron Institute,https://scholars.library.tamu.edu/vivo/display/n647d2e02
Joshua,Wand,Professor and Department Head,"We are broadly interested in how the biophysical properties of proteins are manifested in their biological function. We are particularly engaged in trying to reveal the nature of internal protein motion and how this influences functions ranging from molecular recognition to allostery and catalysis. These basic ideas are being employed in a range of studies including protein engineering to optimize protein drugs, reverse micelle encapsulation to aid fragment-based drug discovery, understanding the regulation of Parkin, which is involved in mitophagy and early onset Parkinson's Disease, and the enzyme AKR1C3, which is central to resistant forms of prostate cancer.",Professor and Department Head,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n6caf5ddd
Weihsueh,Chiu,Professor,,Professor,Veterinary Physiology and Pharmacology,https://scholars.library.tamu.edu/vivo/display/n6e29f354
Marcetta,Darensbourg,Distinguished Professor,"Bio-inspired Catalysts for Hydrogen Production: The ultimate, home-run, goal of our work is to synthesize and develop a robust, highly active hydrogen-producing catalyst comprised of earth-abundant transition metals within a ligand environment that is inspired by the biological Figure 3hydrogenase (H2ase) enzyme active sites. Progress in precise structural modeling of the illusive ""rotated"" structure displayed in the as-isolated, mixed-valent FeIIFe state in the past decade has permitted in depth analysis of electronic structure by Mo ssbauer, EPR (ENDOR), and computational chemistry. New electrocatalysts for hydrogen production: The connection between the Fe(NO)2 unit and the Fe(CX)3 (X = O or N) unit found in hydrogenase enzyme active sites offers opportunity for design of new catalysts, one of which is shown. In this regard we explore the ability of N2S2 metal complexes to bind as metallodithiolate ligands to various metal acceptors. The properties of such complexes vary The connection of these to light harvesting molecules for dye sensitized, sacrificial electron donor, hydrogen production is also of interest. When Iron Meets Nitric Oxide: Good Chemistry, Intriguing Biology. The affinity of iron for diatomic molecules, O2, CO, N2, and NO, is central to the most important of life processes, including those of human physiology. Figure 6In this research area we target synthetic chemistry involving dinitrosyl iron complexes (DNICs) that serve as biomimetics of products of FeS cluster degradation by excesses of NO, or as derived from the chelatable iron pool (CIP) in cells. The electronic ambivalence of the DNIC unit is expressed in the ease with which it interconverts between oxidized and reduced forms, {Fe(NO)2}9 and {Fe(NO)2}10, respectively (Enemark/Feltham notation), and serves as impetus to explore analogous reactions known to involve the CuII/CuI redox couple. The accessory ligands which stabilize one redox level over the other, including N-heterocyclic carb",Distinguished Professor||Faculty Affiliate,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/n6f445741
Micah,Green,Professor,,Professor||Faculty Affiliate,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n7276eb81
Larry,Johnson,Professor,,Professor,Veterinary Integrative Biosciences,https://scholars.library.tamu.edu/vivo/display/n72de4d00
Kung-Hui (Bella),Chu,Professor,"Our research interests are in enhancing our understanding of microbial-mediated processes in natural and engineered systems, and in application and development of biotechnology to address various environmental challenges in water, soils, and energy. The Chu lab applies molecular biology, isotopic techniques, chemical analysis, and phage biology to study environmental and biological systems, with focuses on (i) microbial ecology, fate and transport, biodegradation of environmental pollutants such as emerging contaminants and persistent organic pollutants, (ii) production of biofuels and bioproducts from renewable resources, and (iii) detection, tracking, and quantification of microorganisms that play roles in water quality, bioremediation, carbon sequestration and nitrogen cycle in the environment. Other research areas include development and application of novel sorbents and catalysts (bio and non-bio) for removing and/or monitoring emerging environmental pollutants.",Faculty Affiliate||Professor,Civil Engineering||Energy Institute,https://scholars.library.tamu.edu/vivo/display/n7a373eec
Amir,Asadi,Assistant Professor,"My laboratory focuses on inventing new or modifying the current manufacturing methods to develop polymer composites with engineered microstructure and performance. Our research promotes new levels of performance, capability, cost reduction and efficiency in different sectors of industries such as automotive, aerospace, marine, biomedical, energy, and buildings.",Assistant Professor||Faculty Affiliate,Engineering Technology and Industrial Distribution||Energy Institute,https://scholars.library.tamu.edu/vivo/display/n827ea3aa
Christian,Hilty,Professor,"We are developing and applying Magnetic resonance techniques for the investigation of rapid processes and molecular dynamics. Hyperpolarization of nuclear spins yields unprecedented levels of signal, which enables us to acquire NMR spectra of reactions as they occur, in real time. Applications of these techniques include the fields of enzyme catalysis, reactions in organic chemistry, polymers, and more.
To enable the use of hyperpolarization in NMR, we develop new hardware and specially adapted NMR experiments, and investigate the dynamics of hyperpolarized spin systems.
Hand-in-hand with hyperpolarization, we use modern multi-dimensional NMR for the investigation of basic determinants of protein structure and function, including of membrane proteins.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n83f91df7
Allison,Rice-Ficht,Senior Associate Vice President for Research,"Studies in the our lab are currently focused on the use of unique biomaterials for controlled release of live and subunit vaccines. Our focus is currently directed to the production of vaccines against human Brucellosisand Q fever, but will be applied to the storage and delivery of other vaccines. A study of specific immune mechanisms and potentiation through controlled releases is underway. Another focus is the study of alpha crystalline structure and function. These unique proteins protect against thermal insult and modulate folding and activity of other proteins",Professor||Senior Associate Vice President for Research,Cell Biology and Genetics||Division of Research,https://scholars.library.tamu.edu/vivo/display/n84a56c5b
Antonio,Rene,Associate Professor,,Associate Professor,Environmental and Occupational Health,https://scholars.library.tamu.edu/vivo/display/n8911bceb
Hongcai,Zhou,Professor,"Research topics: Energy Storage for Transportation, Supramolecular Chemistry, Hydrogen and Methane Storage, Carbon Dioxide Capture, Clean-Energy-Related Separation, Metal-Organic Frameworks, Mesh-Adjustable Molecular Sieves, Mesoporous Materials, Biomimetic Synthesis.","Professor, Affiliated Faculty||Faculty Affiliate",Energy Institute||Materials Science and Engineering,https://scholars.library.tamu.edu/vivo/display/n8c5a2ac9
Qingwu,Xue,Professor,"Develop a competitive and extramurally funded research program in the area of crop water use, water use efficiency, and abiotic and biotic stress resistance in major field crops in the Texas High Plains. The overall goal of my research program is to provide selection tools for breeders and geneticists and management tools for agronomists and producers, through better understanding the physiological mechanisms of crop performance under stress conditions. The major research focuses include understanding physiological and molecular mechanisms of drought tolerance, identifying plant traits conferring to stress tolerance, understanding the interactions of abiotic and biotic stresses, evaluating and developing field phenotyping tools, and developing management strategies under stress conditions. Advise graduate student research.",Professor||Professor||Adjunct Professor,"Soil and Crop Sciences||Texas A&M AgriLife Research||West Texas A&M University - (Canyon, Texas, United States)",https://scholars.library.tamu.edu/vivo/display/n8c76b901
James,Sacchettini,Professor,"My lab uses X-ray crystallography to better understand the relationship between proteins and ligands. Tiny differences in the structure of a molecule can radically change the interaction between a protein and ligand and we are only begining to understand how many factors play a role in this interaction. By manipulating the individual components of a compound it is possible to create a chemical that binds to the protein better than the natural substrate, and prevent the natural reaction from occurring. This is the basis for rational drug design. Our efforts have lead us to collaborations with other labs and scientists in many disciplines as our approach to directed compound design has applications not only in basic research but also in pesticide development, health research and clinical research.",Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n90385563
Jack,Waas,Lecturer,,Lecturer,Chemistry,https://scholars.library.tamu.edu/vivo/display/n956db11d
Nimir,Elbashir,Professor,"Dr. Elbashir is a professor at Texas A&M University at Qatar and the Director of the Fuel Research Center of Texas A&M University; a major research center that involves 19 faculty members from both the Qatar and College Station campuses of Texas A&M University. His research activities is focused on design of reactors and catalysts for Gas-to-Liquid (GTL) technology, petrochemical conversions, and CO2 utilization. In addition, Dr. Elbashir is the Director of Texas A&M Qatar Fuel Characterization Lab, a research lab that is supporting major research activities in the advancements of synthetic fuels and chemicals obtained from natural gas in collaboration with GE(Oil& Gas); OryxGTL; and Shell and world leading academic institutions.",Faculty Affiliate||Professor||Chair of the ORYX GTL Gas-to-Liquid Technology Excellence Program||Director of Gas and Fuels Research Center||Professor,Texas A&M Engineering Experiment Station (TEES)||Texas A&M University at Qatar||Energy Institute||Chemical Engineering (Qatar)||Petroleum Engineering (Qatar),https://scholars.library.tamu.edu/vivo/display/n963c4ab2
Vincent,VanBuren,Assistant Professor,,Instructional Assistant Professor,School of Medicine,https://scholars.library.tamu.edu/vivo/display/n98068f16
Patrick,Louchouarn,Executive Assoc Vice President for Academic Affairs Tamug/Assoc Provost Tamu,,Executive Assoc Vice President for Academic Affairs Tamug/Assoc Provost Tamu,Marine Sciences,https://scholars.library.tamu.edu/vivo/display/n991473cf
Bhimanagouda,Patil,"Leonard Pike Inagural University Professor and Interim Head, Food Science and Technology","Dr. Bhimu Patil is internationally recognized for his expertise and research on 'foods for health' and his related educational programs. His systems-wide farm-to-table approaches include examining pre- and postharvest effects on bioactive compounds, isolating and characterizing these compounds from different fruits and vegetables, and understanding their roles in human health. Moreover, he has a strong working relationship with produce industry stakeholders. Dr. Patil has a distinguished record of achievements in education, including leading the development of three unique courses linking agriculture, human health, and sustainability. Texas A&M University has been a leader in this area, due in part to Dr. Patil's seminal contributions in these first-of-their-kind multidisciplinary courses. Dr. Patil's contributions to education are no less distinguished. He developed and taught three unique, innovative multi-state and multi-disciplinary courses, ""Phytochemicals in Fruits and Vegetables to Improve Human Health"", ""Science of Foods for Health"" and ""The Nexus of Food & Nutritional Security, Hunger, and Sustainability"".",Professor||Professor,Nutrition||Horticultural Sciences,https://scholars.library.tamu.edu/vivo/display/n9a0e203e
Jeetain,Mittal,Professor,Dr. Mittal's research focuses on biomolecular self-assembly processes with a specialization in protein phase separation and nanoparticle superlattice design.,Professor,Artie Mcferrin Department of Chemical En,https://scholars.library.tamu.edu/vivo/display/n9c511486
Xiaohua,Liu,Professor,"As a bioengineer, I have a broad background in biomedical science and engineering, with specific training and expertise in novel biomaterials design/fabrication, controlled protein release, and the use of stem cells for bone, dental and other tissues repair and regeneration. Some of the our current research projects include:
1. Development of novel biomimetic materials/scaffolds for dental and craniofacial tissue regeneration.
2. Development of controlled drug/growth factor delivery system
3. Development of bio-inspired platform to explore cell-material interactions in three-dimension (3D).",Associate Professor||Professor,School of Dentistry||Biomedical Sciences,https://scholars.library.tamu.edu/vivo/display/n9cd6704b
Kevin,Crosby,Professor,"Dr. Crosby's area of research is plant breeding and genetics of vegetable crops. He has worked on melon, pepper, tomato, onion and carrot. The main emphasis of his research has been the elucidation of genetic mechanisms for stress tolerance and enhanced nutritional quality. Dr. Crosby has discovered several novel traits and studied their inheritance in both melon and pepper. These range from root physiology and vigor to virus and insect resistance. His program also has developed a genetic linkage map of melon with DNA markers linked to several key traits. The development of thousands of novel families for genetic studies has also produced elite breeding lines for commercial seed companies and 9 cultivar releases. In addition, Dr. Crosby has developed unique, high antioxidant pepper lines with flavonoid and ascorbic acid levels more than 400% higher than commercial cultivars.",Professor,Horticultural Sciences,https://scholars.library.tamu.edu/vivo/display/n9db4acaa
Daniel,Singleton,Professor,"The central focus of the Singleton research group is the study of organic, organometallic, and bioorganic reaction mechanisms, and the key tool that we use in these studies is the determination o kinetic isotope effects (KIEs). In the mid-1990's, we developed a method for the high precision combinatorial determination of small KIEs at natural abundance by NMR. Its direct applicability to complex unlabeled reactants makes this methodology 1-2 orders of magnitude faster than studies requiring labeling. At the same time, it is much more versatile - our technique can look at a great number of reactions that would have been impractical or impossible to study by labeling or mass spectral methods, and the choice of reactants can be readily changed in response to each new experimental result. The simultaneous determination of a complete set of 13C, 2H, and 17O isotope effects possible with our methodology provides a much greater level of information than available from conventional methods. In addition, substantial evidence has accumulated supporting the reliable accuracy of our results.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/na0239851
Mohammad,Nutan,Associate Professor,,Associate Professor,Pharmaceutical Sciences,https://scholars.library.tamu.edu/vivo/display/na26fd78d
Frank,Raushel,Distinguished Professor,"Enzymes catalyze a remarkable variety of chemical reactions with extremely high rate enhancements and very selective substrate specificity. The research efforts in our laboratory are directed towards a more complete understanding of the fundamental principles involved in enzyme-catalyzed chemistry and the dependence on protein structure. The pursuit of this information will provide the framework for the rational and combinatorial redesign of these complex molecules in an effort to exploit and develop the properties of enzyme active sites for a variety of chemical, biological, and medicinal uses. The techniques that we are using to solve these problems include steady-state and stopped-flow kinetics, NMR and EPR spectroscopy, X-ray crystallography, and the synthesis of inhibitors and suicide substrates. We are also using recombinant DNA methods to construct new proteins with novel catalytic properties. These efforts are currently being directed to the reactions catalyzed by phosphotriesterase and enzymes involves in the degradation of lignin and the metabolism of novel carbohydrates from the human gut microbiome.
The phosphotriesterase enzyme catalyzes the hydrolysis of organophosphate insecticides and other toxic organophosphate nerve agents. We have discovered that the active site of this protein consists of a unique binuclear metal center for the activation of water. We are now investigating the structure and properties of this metal center as a model system for the evolution of enzyme structure and function. Toward this end we have mutated the active site of this enzyme in a research project to create novel enzymes with the ability to detect, destroy, and detoxify various chemical warfare agents such as sarin, soman, and VX. The Raushel laboratory is also engaged in a large scale research project that is focused on the development of novel strategies for the discovery of new enzymes.",Distinguished Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/na84f2fec
Michael,Benedik,Regents Professor,My laboratory studies basic biological problems using molecular genetic methods with simple microbial systems. Additionally we are developing novel microbial approaches for biotechnological applications.,Regents Professor,Biology,https://scholars.library.tamu.edu/vivo/display/nac9856e5
Lisa,Perez,Director for Advanced Computing Enablement,,Associate Director,Texas A&M High Performance Research Computing,https://scholars.library.tamu.edu/vivo/display/naf9f7163
Stephen,Safe,Distinguished Professor,The aryl hydrocarbon receptor (AhR) is a nuclear helix-loop-helix transcription factor which forms a ligand-induced nuclear heterodimer with the AhR nuclear translocator (Arnt) protein. Research in this laboratory is focused on the molecular mechanism of crosstalk between the AhR and estrogen receptor (ER) signaling pathways in which the AhR inhibits estrogen-induced gene expression. The antiestrogenic activities of some AhR agonists are also being developed as drugs for clinical treatment of breast and endometrial cancers in women. Research on estrogen-dependent gene expression in various cancer cell lines is focused on analysis of several gene promoters to determine the mechanisms of ERa and ERb action. This includes several genes that are activated through interactions of the ER with Sp1 protein and other DNA-bound transcription factors.,Distinguished Professor||Distinguished Professor||Syd Kyle Chair,School of Veterinary Medicine and Biomedical Sciences||Biochemistry and Biophysics||Veterinary Physiology and Pharmacology,https://scholars.library.tamu.edu/vivo/display/nb20fdbd9
Charles,Patrick,Professor of the Practice,"His current research within the Ideas to Innovation Engineering Education Excellence Laboratory focuses on enhancing undergraduate and graduate student learning, engagement and workforce development by transforming biomedical engineering education through scholarship and research of innovative teaching and learning practices and technologies.",Professor of the Practice,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/nb2ed7577
Ivan,Rusyn,Professor,"My laboratory has an active research portfolio funded by the National Institutes of Health and the US EPA with a focus on the mechanisms of action of environmental toxicants and the genetic determinants of the susceptibility to toxicant-induced injury. Through a combination of in vivo animal studies and experiments that utilize cellular and molecular models, we aim to better understand why certain chemicals cause cancer or organ damage in rodents and whether humans in general, or any susceptible sub-population in particular, are at risk from similar exposures.
The main focus of our inter-disciplinary research is on improving the linkages between exposures and adverse health effects Specifically, we develop innovative experimental methods and computational tools which enable analysis of data across multiple dimensions including SNPs, -omic endpoints, multiple chemicals and traditional toxicity phenotypes.","Professor, Veterinary Physiology and Pharmacology",School of Veterinary Medicine and Biomedical Sciences,https://scholars.library.tamu.edu/vivo/display/nb3daa5ce
Indra,Reddy,Dean,,Executive Committee||Professor and Founding Dean||Faculty Fellow,Center for Health Systems and Design||Global Institute for Hispanic Health||Irma Lerma Rangel School of Pharmacy,https://scholars.library.tamu.edu/vivo/display/nb62b9d15
Qingsheng,Wang,Associate Professor,"Our research is highly multidisciplinary in the process safety area with the intent to resolve the most critical safety problem in the industries, which is to prevent and mitigate hazardous phenomena including fire, explosion, and toxic release. The research is ranging from a molecular level, macroscale, plant level to an enterprise level. Topics include QSPR modeling, flame retardant, fire suppression, CFD modeling, pipeline corrosion, risk analysis, and leak detection. The research aims to bring perspectives of chemical engineering, chemistry, and fire protection engineering to energy industries and hence yield systematic solutions to process safety issues.",Associate Professor||Faculty Affiliate,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/nb67cfe14
Poorya,Jalali,"Clinical Associate Professor, Endodontics",,,,https://scholars.library.tamu.edu/vivo/display/nb6fc0a56
Siegfried,Musser,Professor,"The primary focus of my laboratory is to decipher how proteins partition into different sub-compartments of the cell. Cellular membranes serve to compartmentalize biochemical reactions to specific microenvironments. Proteins cross these membranes via a diverse array of protein translocation systems, or translocons. My laboratory has investigated the detailed molecular function of three different protein transport machineries, the human nuclear pore complex (NPC) and the bacterial Sec and Tat general secretion machineries. We are a biophysics lab and our primary tools for deciphering molecular mechanisms and dynamics are super-resolution imaging and single molecule particle tracking approaches. Our aim is to develop detailed, molecular-scale, mechanistic models of protein transport processes. We recently demonstrated 3D imaging of cargo transport through nuclear pores on the millisecond timescale with 5-15 nm precision in all three dimensions. This will be a major tool going forward for multiple projects.
In 2018, we began a new project on membrane-less organelles, which are micrometer-scale cellular structures known as biomolecular condensates (BMCs) that contain high concentrations of intrinsically disordered proteins and RNA. These BMCs are generally agreed to arise from liquid-liquid phase separation (LLPS), which is the spontaneous partitioning into dense and dilute phases due to favorable interactions between the separating molecules. The high density of aggregation prone proteins in BMCs is thought to lead to the cellular inclusions found in patients with multiple neurological diseases including amyotrophic lateral sclerosis (ALS), frontotemporal dementia (FTD) and Parkinson's and Alzheimer's diseases. We are using super-resolution and single molecule methods to probe the structural and dynamic heterogeneity of condensates formed from the fused in sarcoma (FUS) protein to identify the conditions that lead to solidification of liquid condensates (phase maturation).",Professor,Cell Biology and Genetics,https://scholars.library.tamu.edu/vivo/display/nb824aefa
Perla,Balbuena,Professor,,University Distinguished Professor||Faculty Affiliate||Professor,Energy Institute||Chemical Engineering||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/nb82a0bc7
Terry,Wade,Deputy Director,,Research Scientist,College of Geosciences,https://scholars.library.tamu.edu/vivo/display/nba3197b7
Rachel,Smith,Assistant Professor,,Assistant Professor,,https://scholars.library.tamu.edu/vivo/display/nbe30d9b5
Kevin,Burgess,Professor,"We use novel strategies Exploring Key Orientations (EKO) that feature datamining to compare simulated preferred conformers of chemotypes we design with key features at protein-protein interfaces. Many chemotype candidates can be screened against one PPI, or one chemotype can be screened against all the PPI interfaces in the PDB. Virtual hit chemotypes are prepared in my lab, then tested against protein-protein interactions of biomedicinal interest using an array of biophysical and cellular assays.
We also design small molecules to target cell surface receptors that are selectively overexpressed in cancer cells. Much or our work has been focused on the TrkC receptor that is particularly important to metastatic breast cancer and melanoma. Going forwards we are interested in expanding the targets to include cell surface receptors that are overexpressed when cancer cells undergo aberrant epithelial to mesenchymal transitions (EMT) to produce circulating tumor cells and cancer stem cells. Much of this work involves design and synthesis of the small molecules for this targeting.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/nc4a5cad4
Robin,Autenrieth,Professor and Head,"My research is focused on microbial systems for the degradation of target compounds (hormones, crude oil, petroleum products, explosives, chemical warfare agents, chlorinated agents, among a few others) contaminating soils and waters. Physical and chemical processes are coupled to the microbial activity to understand the controlling parameters for optimization of performance. With an interest in improving the link between contaminant concentrations and human exposures for predicting the potential for adverse health effects, my students and I have been working on methods to improve the risk assessment of select compounds.",Department Head||A.P. and Florence Wiley Professor III,Civil Engineering||Civil Engineering,https://scholars.library.tamu.edu/vivo/display/nca139916
Shiqing,Xu,Assistant Professor,"Our research aims to develop innovative synthetic methodologies and therapeutic approaches, and apply them to solving pressing problems of biological and medical importance. New synthetic methodologies and strategies (e.g. non-traditional disconnections and C-H functionalization) have great impacts on the discovery of transformational medicines by enabling the rapid and efficient synthesis of novel, diverse, and complex biologically active molecules. New therapeutic approaches (e.g. targeted covalent inhibition and targeted protein degradation) provide new opportunities to address traditionally ""undruggable"" disease targets.
We anticipate that the combination of the efforts in the development of novel synthetic methodologies and therapeutic approaches will advance drug discovery in diseases of unmet need, and achieve the research goal of identifying small-molecule probes and drug candidates that specifically remove/inhibit disease-causing proteins in cells and animal models and ultimately impact human health. Representative research directions include:
1. COVID-19 drug discovery via small-molecule-induced targeted protein inhibition and degradation
2. Late-stage functionalization of drugs and peptides & its applications in drug discovery
3. Organoboron chemistry and its medical applications",Assistant Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/ncd983c6e
Vytas,Bankaitis,Professor,"My laboratory is interested in the regulatory interfaces between novel lipid-mediated signal transduction pathways and important cellular functions. The focus of our work is the phosphatidylinositol/ phosphatidylcholine transfer proteins (PITPs), a ubiquitous but enigmatic class of proteins. Ongoing projects in the laboratory derive from a multidisciplinary approach that encompasses biochemical characterization of novel members of the metazoan PITP family, and the application of genetic, molecular and biophysical approaches to detailed structural and functional analyses of PITPs.",E.L. Wehner-Welch Foundation Chair||Professor||Professor,Cell Biology and Genetics||Biochemistry and Biophysics||Chemistry,https://scholars.library.tamu.edu/vivo/display/ncff8dc21
Xingmao,Ma,Associate Professor,,Associate Professor,Civil Engineering,https://scholars.library.tamu.edu/vivo/display/nd2874fb7
Xiaofeng,Qian,Associate Professor,"My research focuses on: Materials Theory, Discovery, and Design for Energy Applications and Device Design Aided by HighThroughput Computing; Two-Dimensional Materials and Their Coupled Multi-Physical Properties and Novel Device Concepts; Electronic, Thermal, Ionic, and Excitonic Transport in Nanostructured Materials; First-Principles Methodology Development towards Efficient and Accurate Prediction of Ground-state and Excited-state Properties of Materials; and Multiscale Materials Modeling of Complex Physical and Chemical Processes.",Faculty Affiliate||Associate Professor||Assistant Professor,Energy Institute||Materials Science and Engineering||Materials Science and Engineering,https://scholars.library.tamu.edu/vivo/display/nd67bf9a1
Kim,Dunbar,Distinguished Professor,"Research in the Dunbar group spans topics in synthetic, structural and physical inorganic and bioinorganic chemistry. The use of a range of tools including spectroscopy, X-ray crystallography, magnetometry, electron microscopy, mass spectrometry and electrochemistry reflect the breadth of problems under investigation.",Distinguished Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/ndd473437
Sherry,Yennello,Professor and Director,"Research is centered around utilizing the newly available ability to produce beams of nuclei removed from the valley of stability to investigate nuclear reaction mechanisms. The experiments study the collisional dynamics of heavy-ion reactions and the thermodynamics of the resultant hot nuclear system.
Emission of fragments prior to equilibrium allows us to learn about cluster formation by studying the dynamics involved in the collision of two composite groups of nucleons. Projectile fragmentation reactions allow determination of the final state of the excited nuclear system thus enabling a reconstruction of the thermodynamics of fragmentation.
Much of our work is conducted at the Cyclotron Institute using the K500 superconducting cyclotron. Beams of radioactive ions can currently be separated in the recoil spectrometer, MARS. Complementary experiments with stable beams are also performed utilizing a 4-pi neutron detector for event characterization and selection.",Professor and Director,Chemistry,https://scholars.library.tamu.edu/vivo/display/ne2dd81c6
Janet,Bluemel,Professor,"Major research interests in my group include (1) immobilized catalysts, (2) the surface chemistry of oxide materials and (3) solid-state NMR spectroscopy.
Immobilized catalysts (1) allow the advantages of heterogeneous catalysts to be combined with those of homogeneous catalysts. In particular, surface-immobilized homogeneous catalysts are easy to recycle, and can be highly active and selective. Furthermore they are amenable to systematic design. We find the most interesting results when heterobimetallic systems, such as the Sonogashira Pd/Cu catalyst for the coupling of aryl halides and terminal alkynes, are involved. Effective immobilization requires a thorough understanding of the surface chemistry of the oxide support materials (2). Therefore, we investigate not only the reactivity of metal complexes and linkers, but also their mobility on the surfaces.
The most powerful analytical tool for investigating amorphous materials is solid-state NMR spectroscopy (3). We optimized this method especially for surface-bound species, enabling us to study reactions on surfaces, or analyze the nature of our anchored linkers and catalysts.
These different research areas provide my students with a strong multidisciplinary background, spanning from synthetic chemistry, through materials sciences and catalysis, to surface analytical methods including solid-state NMR spectroscopy. Our expertise in these fields has led to many industrial contacts and collaborations.",Faculty Affiliate||Professor,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/ne3b7e44f
Victor,Ugaz,Professor,"I am the world's smallest plumber--my research involves manipulating fluid flow in tiny channels the size of a human hair. Harnessing microfluidic phenomena makes it possible to build pocket-sized systems that can perform sophisticated chemical and biochemical tests outside the confines of a conventional lab. But achieving precise control over the flow of liquids at these small size scales is extremely challenging. Therefore, we are working to understand fundamental transport phenomena in microfluidic systems, and how they can be exploited to enable innovative applications including:
Fast and inexpensive diagnosis of infection and disease.
Sensitive screening for early detection of cancer.
Biodegradable sponges for easy cleanup of oil spills.
Spontaneous organization of chemical building blocks to form long-chain molecules--a key unanswered question in the origin of life.",Professor,Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/ne76e71aa
Albert,Mulenga,"Professor and Interim head, Veterinary Pathobiology","For generations ticks and tick borne diseases have had significant impact of animal health and livestock productivity around the world. In public health the effect of ticks and tick borne diseases is also tremendous. Since the 1980s when the causative agent of Lyme disease was described, numerous human tick borne diseases have been reported. In absence of effective vaccines against major tick borne diseases, prevention of animal and human tick borne disease infections relies on the use chemicals (acaricides) to kill ticks. Although acaricide based tick control methods are effective in the short-term, they do not offer a permanent solution because of serious limitations such as ticks developing resistance and contamination of the environment and the food chain. Immunization of animals against is a validated alternative tick control method. The attraction is that tick vaccines will be effective against both acaricide resistant and susceptible tick populations. The major limiting factor is the availability of effective tick vaccine targets. The tick cannot cause damage to host or transmit disease agents without successful feeding. Thus, our plan is to understand molecular mechanisms of how ticks accomplish feeding. In this way we will find targets that will be used for development of effective tick vaccines. We are currently studying the feeding physiology of the blacklegged tick (Ixodes scapularis) and the Lone Star tick (Amblyomma americanum). According to the US Centers for Disease Control, these two medically important tick species transmit a combined nine of the 14 human tick borne disease agents in the United States. Major work is on discovery and characterization of proteins that the Lone Star and the Blacklegged tick into animals every 24h through out feeding. The area of particular emphasis is to understanding roles of serine protease inhibitors (serpins) the blacklegged tick and the Lone Star tick inject into animals during feeding. We have identified serpins",Professor and associate head||Professor & Interim Head,School of Veterinary Medicine and Biomedical Sciences||Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/ne8f0c620
Michael,Hall,Professor,"Our group applies ""state-of-the-art"" theoretical techniques to chemical problems of current interest to practicing inorganic, organometallic, and biological chemists. We also develop new algorithms that are especially suited to electronic structure problems in large transition metal molecules.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/ne91c0625
David,Bergbreiter,Professor,"Our group explores new chemistry related to catalysis and polymer functionalization using the tools and precepts of synthetic organic chemistry to prepare functional oligomers or polymers that in turn are used to either effect catalysis in a greener, more environmentally benign way or to more efficiently functionalize polymers. Often this involves creatively combining the physiochemical properties of a polymer with the reactivity of a low molecular weight compound to form new materials with new functions. These green chemistry projects involve undamental research both in synthesis and catalysis but has practical aspects because of its relevance to practical problems.
A common theme in our catalysis studies is exploring how soluble polymers can facilitate homogeneous catalysis. Homogeneous catalysts are ubiquitously used to prepare polymers, chemical intermediates, basic chemicals and pharmaceuticals. Such catalysts often use expensive or precious metals or expensive ligands or are used at relatively high catalyst loadings. The products often contain traces of these catalysts or ligands - traces that are undesirable for esthetic reasons or because of the potential toxicity of these impurities. Both the cost of these catalysts of these issues require catalyst/product separation - separations that often are inefficient and lead to chemical waste. These processes also use volatile organic solvents - solvents that have to be recovered and separated. Projects underway in our lab explore how soluble polymers can address each of these problems. Examples of past schemes that achieve this goal in a general way as highlighted in the Figure below.
We also use functional polymers to modify existing polymers. Ongoing projects involve molecular design of additives that can more efficiently modify polymers' physical properties. We also use functional polymers in covalent layer-by-layer assembly to surface polymers' surface chemistry.",Faculty Affiliate||Professor,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/nf01e95dd
Kate,Creevy,Professor,"Dr. Creevy is a board-certified small animal veterinary internist, with a primary research interest in longevity, healthspan, morbidity and mortality within and among dog breeds as well as secondary research interests in infectious disease, and pedagogical theory in science education. In 2007, she established a productive collaboration with Dr. Daniel Promislow, combining her expertise in veterinary research and clinical practice with his expertise in genetics, aging and statistical analysis. Initially, their work was focused on the analysis of existing veterinary medical datasets. With the addition of Dr. Matt Kaeberlein, in 2014, the trio founded the Dog Aging Project and began to create a community of dog owners interested in becoming involved in this citizen-science project. The Dog Aging Project's current longitudinal study ambitious undertaking is the largest prospective study of companion dogs ever performed, enrolling 10,000 dogs across the nation who will be followed for ten years.",Professor,Small Animal Clinical Sciences,https://scholars.library.tamu.edu/vivo/display/nf40f2eea
Bruce,Herbert,Professor,"My research explores the role of open access and open science practices on the translation of agricultural research into societal impact, the ethical evaluation of academic research, advancing open education, and programs that support the sustainability of rural communities.
Previously, I served as the Director of the Office of Scholarly Communications in the Sterling C. Evans library At Texas A&M University. As Director, I was responsible for strengthening the Library's efforts in scholarly communications and open access through engagement and collaboration with the faculty across campus at Texas A&M University. In addition, we developed library services that support interdisciplinary research teams and enhance research translation and the societal impact of Texas A&M's research.
My earlier scientific research explored questions concerning biogeochemical processes that mediate the interactions between human society and ecosystems, including the fate and bioavailability of contaminants, natural and human perturbations of nutrient and organic carbon, and human impacts on ecosystem functioning.
In addition, I actively pursued research that characterized human understanding of complex earth systems; the professional development of future faculty and teachers; and the design of tertiary educational programs that promote learning for all students, develop synergy between educational and research activities, and address major societal issues. I have served as the Associate Director of Geosciences in the NSF-supported Information Technology in Science (ITS) Center for Learning and Teaching at Texas A&M University, the principal investigator of the NSF Teacher Professional Continuum program entitled Professional Learning Community Model for Alternative Pathways in Teaching Science and Mathematics, PLC-MAP, and co-PI of the NSF-sponsored CIRTL Network - Shaping, Connecting, and Supporting the Future National STEM Faculty.",Member||Professor||Assistant Director,"Center for Systematic Reviews and Research Syntheses||Agricultural Leadership, Education, and Communications||Engineering Education Research Taskforce",https://scholars.library.tamu.edu/vivo/display/nf489b17d
Zivko,Nikolov,Professor and Associate Department Head,"Nikolov's Bioseparations Lab conducts transformative research in bioprocess engineering aimed at the development of novel and cost-effective strategies for extraction and purification of recombinant and native biomolecules. Bioseparations Lab leverages scientific and engineering expertise of lab members to find solutions for a variety of bioprocessing and separations challenges that currently face plant and algal biotechnology. To guide early process development and identify constraints posed by biological system and final product lab members use process simulation. Past and current research projects directed by Dr. Nikolov include industrial protein products derived from rice, sugarcane, tobacco, Lemna minor, and microalgae.",Faculty Affiliate||Professor and Associate Department Head,Biological and Agricultural Engineering||Energy Institute,https://scholars.library.tamu.edu/vivo/display/nf84893f5
Daniel,Leskovar,Agrilife Center Director,"Dr. Leskovar's vegetable physiology program focuses on understanding plant morphological and physiological adaptation mechanisms to environmental stresses, and development of integrated sustainable vegetable cropping systems. His research emphasis is on: 1) seed-transplant production and physiology to increase plant survival and enhance stand establishment; 2) plant hormones to modulate seedling growth; 3) root/shoot developmental responses to water conservation strategies and irrigation technologies; 4) impact of cropping systems on antioxidants and sensory attributes of vegetable crops; and 5) genotype selection for drought resistance, high yield, quality, and phytochemical content. Dr. Leskovar's program involves international cooperators.",Agrilife Center Director||Professor||Professor,Dallas Research and Extension Center||Uvalde Research and Extension Center||Horticultural Sciences,https://scholars.library.tamu.edu/vivo/display/nfa1a6351
Hatice,Ceylan Koydemir,Assistant Professor,,Assistant Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/nfa4d71de
Sreeram,Vaddiraju,Associate Professor,"Development of novel vapor phase techniques for the synthesis of organic and inorganic nanostructures and the development and implementation of novel in-situ and ex-situ schemes for the large-scale integration of these nanostructures into energy conversion devices (e.g., solar cells, thermoelectric devices).",Faculty Affiliate||Associate Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/nfbff4e43
Mansoor,Khan,Professor and Vice Dean,"Dr. Mansoor A. Khan serves as a professor and Vice Dean of the Texas A&M University Rangel College of Pharmacy at College Station, Texas. Prior to joining Texas A&M in 2015, he served as the Director of Product Quality Research and a Senior Biomedical Research Scientist (SBRS) at CDER in US Food and Drug Administration for over eleven years. In FDA, he led the research and review teams to promote manufacturing science, and served as a founding member of the FDA Emerging Technology Team. Dr. Khan received his Ph.D. degree in industrial pharmacy form St. Johns University in NY. He has published over 335 peer-reviewed manuscripts in pharmaceutical formulations and manufacturing sciences, and delivered over 300 presentations world-wide. Dr. Khan's research, currently supported by the NIH and FDA, spans drug delivery and formulations, and he has received over ten million dollars in funding as a principal investigator.
Dr. Khan has held leadership positions at the AAPS including elected chair of formulations design and development (FDD) section. He serves on the editorial board of Pharmaceutical Technology, International Journal of Pharmaceutics, AAPSPharmsciTech, and the Drug Delivery and Translational Research. He has received about 20 FDA/CDER review, research, and exemplary achievement awards, outstanding alumni award at St. Johns University College of Pharmacy, Excellence Award in Texas A&M University. He received the 2012 AAPS Research Achievement Award in Formulations Design and Development. He is also an AAPS and AAiPS Fellow. Dr. Khan served as FDA representative to the World Health Organization (WHO), United States Pharmacopoeia (USP), European Medicine Agency (EMA), DARPA, NIH, National Institute of Pharmaceutical Technology and Education (NIPTE), and International Pharmaceutical Federation (FIP). He is also a member of the European Union Academy of Sciences.",Regents Professor and Presidential Impact Fellow,Center for Microencapsulation and Drug Delivery,https://scholars.library.tamu.edu/vivo/display/nfc5f1cd6
Ioannis,Economou,"Senior Associate Dean for Academic Affairs and Graduate Studies, Texas A&M at Qatar","Dr. Economou's research focuses on the design, development, validation and application of state-of-the art models for the prediction of structure and physical properties of complex chemical systems that are of interest to oil & gas and chemical industry, to the protection of natural environment, and to the society, at large.",Faculty Affiliate||Associate Dean,Energy Institute||Chemical Engineering (Qatar),https://scholars.library.tamu.edu/vivo/display/nfc6fc907