First name,Last name,Preferred title,Overview,Position,Department,Individual
Karuppiah,Chockalingam,Research Assistant Professor,,Research Assistant Professor,Microbial Pathogenesis and Immunology,https://scholars.library.tamu.edu/vivo/display/n015218cf
Zhilong,Yang,Associate Professor,"The overarching research goal of the Yang laboratory is to understand the mechanisms governing viral replication, with the rationale that the discoveries will expand the knowledge of both viruses and their hosts, and facilitate the development of novel strategies to combat viral and non-viral diseases. A parallel goal of Yang lab is to provide a highly supportive environment to train the next generations of scientists. The ongoing research focuses on how viruses interact with two cellular housekeeping processes: protein synthesis and metabolism using vaccinia virus as the research model. Vaccinia virus is the prototype poxvirus. Poxviruses significantly impact public health, with many presently causing morbidity and mortality in humans and many economically important animals, including deadly zoonotic pathogens (e.g., monkeypox virus). In addition, despite the eradication of smallpox, one of the most (if not the most) devastating diseases in human history, smallpox resurgence remains a serious biothreat. Poxviruses are also widely developed as veterinary and human vaccine vectors and as cancer treatment agents. Poxviruses provide numerous precious tools to understand many aspects of cell biology and dissect complex life processes, as their large DNA genomes encode hundreds of genes that engage many key nodes of cellular life. Yang's research integrates biochemical, molecular, and omics approaches. Taking advantage of their in-depth knowledge of the poxvirus replication and virus-host interactions, the Yang lab also develops vaccinia virus-based utilities and anti-virals.",Associate Professor,Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/n02daa01b
Vishal,Gohil,Associate Professor,"Despite the fundamental role of the mitochondrion in cellular energy production and its involvement in numerous human diseases, we still do not know the function of nearly 20% of the known mitochondrial proteins. My laboratory applies genomic, genetic, and biochemical tools to uncover the role of these uncharacterized proteins in the mitochondrial respiratory chain (MRC) biogenesis. MRC is the main site of cellular respiration and energy production and since the core components of the MRC are evolutionarily conserved, we reason that the assembly factors required to build the MRC should also be conserved. Therefore, we utilize multiple models systems, including yeast, zebrafish, and human cell lines, to determine the role of these conserved, uncharacterized mitochondrial proteins in bioenergetics, organismal development, and human disease pathogenesis.
Another poorly understood aspect of the mitochondrial energy metabolism is the role of phospholipids in maintaining the structural and functional integrity of the MRC. Although it is well known that the MRC is localized in the inner mitochondrial membrane, how the unique lipid milieu of the mitochondrial membrane influences the assembly and activity of the MRC is not fully understood. We have constructed yeast mutants with defined mitochondrial phospholipid compositions to systematically determine each lipid's role in MRC assembly and activity. Ultimately, defining the roles of mitochondrial proteins and phospholipids will allow us to develop better diagnostic and therapeutic options for human disorders resulting from mitochondrial dysfunction.",Faculty Affiliate||Assistant Professor,Energy Institute||Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n03100e49
Raymond,Carroll,Distinguished Professor,,Distinguished Professor,Statistics,https://scholars.library.tamu.edu/vivo/display/n032647a0
Gregory,Reeves,Associate Professor,,Associate Professor,Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n05d3cae9
Limei,Tian,Assistant Professor,,Assistant Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n05e20d80
Donald,Darensbourg,Distinguished Professor,"The fundamentally interesting and challenging chemistry associated with carbon dioxide, coupled with its high potential as a source of chemical carbon, provides adequate justification for comprehensive investigations in this area. In our research program we have attempted to establish a clearer mechanistic view of carbon-hydrogen, carbon-carbon, and carbon-oxygen bond forming processes resulting from carbon dioxide insertion into M-H, M-C, and M-O bonds.
Relevant to the latter process our research has addressed the utilization of carbon dioxide in the development of improved synthetic routes for the production of polycarbonates. The hazardous and expensive production process currently in place industrially for these materials involves the interfacial polycondensation of phosgene and diols, accentuates the need for these studies. Although we and others have made significant advances in the synthesis of these useful thermoplastics from carbon dioxide and epoxides much of the fundamental knowledge concerning the reaction kinetics of these processes is lacking, due in part to the practical challenges associated with sampling and analyzing systems at elevated temperatures and pressures. This information is needed for making this process applicable to the synthesis of a variety of copolymers possessing a range of properties and uses. Our studies are examining in detail the mechanistic aspects of metal catalyzed carbon dioxide/epoxide coupling reactions employing in situ spectroscopy methods. For this purpose Fourier-transform infrared attenuated total refluctance (FTIR/ATR) spectroscopy is being utilized. Other related investigations involve the development of structural and reactivity models for the industrially prevalent double metal cyanide catalysts(DMC) used in polyethers and polycarbonate synthesis from epoxides or CO2/epoxides, respectively.",Distinguished Professor||Faculty Affiliate,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/n06bf3bf8
Andy,Thomas,Assistant Professor,"Our primary research objective is to develop new methods by investigating and harnessing the reactivity of highly unstable intermediates. Essential to improving mechanistic understanding is the development of new strategies that allow us to monitor fleeting intermediates and manipulate their reactivity. To supplement our mechanism driven methodology development, we will develop a new rapid multiple injection NMR (RMI-NMR) system to monitor and control the reactivity of transient species. Representative areas of research interest include the development of new organic transformations; and the development of catalyst-transfer polymerization reactions.",Assistant Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n07836ca1
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
Carolyn,Cannon,Associate Professor,"Our goal is to develop novel, non-toxic antimicrobial formualtions with efficacy against gram-positive and gram-negative multi-drug resistant pathogens.",Associate Professor,Microbial Pathogenesis and Immunology,https://scholars.library.tamu.edu/vivo/display/n0b3870aa
Youjun,Deng,Associate Professor,"The research focus of soil clay mineralogy group is to reveal molecular mechanisms of 1) reactions of soil/ clay minerals with natural and synthetic organic, inorganic, and biological compounds with environmental and industrial importance, e.g., mycotoxins, emerging organic contaminants, organoclays, modification of clay minerals; and 2) soil/clay mineral transformation under various natural and anthropogenic conditions, e.g., agriculture, forest, desert, wetland, polar region, and Mars soils, at nuclear waste storage sites and repositories, mine tailing and dump sites. We are also adapting and developing advanced spectroscopic and microscopic methods and molecular modeling for soil/clay mineralogy studies.",Associate Professor,Soil and Crop Sciences,https://scholars.library.tamu.edu/vivo/display/n0c13cfe6
Ethan,Grossman,"Professor, Michel T. Halbouty Chair","My research focuses on global change and paleoclimates, stable isotope geochemistry, coastal environments past and present, hypoxia, isotope hydrology, past and present, biogeochemistry and geomicrobiology of aquifer systems.","Faculty Affiliate||Professor, Michel T. Halbouty Chair||Director",Geology and Geophysics||Stable Isotope Geosciences Facility||Energy Institute,https://scholars.library.tamu.edu/vivo/display/n0c709094
Carlos,Avila,Associate Professor,,Associate Professor||Associate Professor,Texas A&M AgriLife Research||Weslaco Research and Extension Center,https://scholars.library.tamu.edu/vivo/display/n0cb2ddef
Lawrence,Wolinsky,Dean,,Dean||Professor||Faculty Fellow,Periodontics||School of Dentistry||Center for Health Systems and Design,https://scholars.library.tamu.edu/vivo/display/n0d0247f9
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
Hamidreza,Samouei,Research Assistant Professor,,Faculty Affiliate||Research Assistant Professor,Energy Institute||Petroleum Engineering,https://scholars.library.tamu.edu/vivo/display/n0d5dd156
Bruce,Riley,Professor,"My lab studies inner ear development in zebrafish. A prominent feature of our research is to investigate how cell-cell signaling and downstream gene-interactions control development. One project in the lab focuses on how cell signaling regulates ectodermal patterning during gastrulation to establish the otic placode, the precursor of the inner ear. Our recent work shows that localized Fgf signaling is especially critical for inducing formation of the otic placode, and members of the Pax2/5/8 family of transcription factors are important mediators of Fgf signaling. During later stages of inner ear development, we are exploring how sensory hair cells and neurons are regulated. Our studies address how these cells initially form, how they are genetically maintained, and how they become specialized for hearing vs. balance. We are also investigating how zebrafish can replace dead and damaged hair cells, an ability that mammals have lost. The inability to regenerate hair cells explains why humans show progressive irreversible hearing loss as we age. It is hoped that activating or augmenting human homologs of genes shown to operate in zebrafish might help restore hearing and balance in humans.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n0dbb8253
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
Timothy,Devarenne,Associate Professor,"We study the biochemical and molecular mechanisms underlying the control of programmed cell death (PCD) in plants and how PCD is manipulated during plant-pathogen interactions. Specifically we study the interaction between tomato and Pseudomonas syringae pv. tomato (Pst) the causative agent of bacterial spot disease. Resistance to this disease is conferred by the host Pto serine/threonine protein kinase which recognizes Pst strains expressing the type III effector protein AvrPto.
PCD is induced during both resistant and susceptible plant-pathogen interactions. In the case of a resistant interaction, PCD induced by the plant, known as the hypersensitive response (HR), and acts to limit the spread of the pathogen. In susceptible plant-pathogen interactions plant PCD is induced by the pathogen after infection leading to death of the host. Studies have indicated that the genes controlling host PCD during the HR are the same genes that are manipulated by the pathogen during susceptible interactions. The difference lies in the timing of controlling the activity of these genes; HR PCD occurs within 12 hours of pathogen recognition while pathogen-induced PCD occurs several days after infection.
Many of these genes that control plant PCD are serine/threonine (S/T) protein kinase. We are interested in studying a specific class of S/T protein kinases that control PCD in plants called AGC kinases and how they are regulated in both resistant and susceptible plant-pathogen interactions. Additionally, when plants are not attacked by pathogens, PCD is a process that requires constant control so that cell death does not occur. We are looking at the signaling mechanisms and pathways employed to keep PCD under check in non-pathogen challenged plants.",Faculty Affiliate||Associate Professor,Energy Institute||Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n11411275
Jorge,Cruz-Reyes,Professor,"We combine approaches in molecular genetics, structural biology, biochemistry, proteomics, and bioinformatics to study the amazing RNA biology of trypanosome parasites. One research line is on an RNA editing process by uridine insertion and deletion that creates amino acid coding triplets in most mRNAs. Yet a single error in the U-changes yields a frame-shift. Trypanosomes split from other eukaryotic lineages over a hundred million years ago, yet this editing has analogies with RNAi, CRISPR/Cas9, mRNA splicing and other systems directed by small non-coding RNAs (ncRNAs).",Professor||Professor,Texas A&M AgriLife Research||Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n147e77ee
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
Anthony,Knap,Professor and Director,"Dr. Knap's primary research focuses include oceanography, organic geochemistry, environmental science, atmosphere/ocean interactions, oil pollution and dispersant use, and effects of contaminants on the marine environment. Global climate change is another area of interest, particularly climate instability, business/science interactions, renewable energy, marine derived bio-fuels, ocean genomics, ocean acidification. He was Founder and Principal Investigator of the NSF-funded Bermuda Atlantic Time-series Study (BATS) off Bermuda. He was also the Principal Investigator for 30 years of Hydrostation S, founded in 1954 and the longest continuous time-series in the Ocean, also funded by NSF. He most recently was appointed to the Gulf Research Board of the US National Academy of Sciences.","Professor||Faculty Affiliate||Director, Geochemical and Environmental Research Group||Faculty Fellow",Center for Health Systems and Design||Oceanography||Energy Institute||College of Geosciences,https://scholars.library.tamu.edu/vivo/display/n15ee86bc
Guoyao,Wu,Distinguished Professor,"Dr. Wu teaches graduate courses in protein metabolism and nutritional biochemistry. He conducts research in protein and amino acid metabolism at molecular, cellular, and whole body levels . The animal models used in his research include cattle, chicks, pigs, rats, sheep, fish, and shrimp. He has also conducted research on amino acid nutrition in humans.",Faculty Fellow||University Faculty Fellow||Distinguished Professor||Senior Faculty Fellow||Distinguished Professor,Veterinary Integrative Biosciences||Animal Science||Texas A&M AgriLife Research||Texas A&M AgriLife Research||Nutrition,https://scholars.library.tamu.edu/vivo/display/n169f9a74
Sarah,Bondos,Associate Professor,"My laboratory works in two research areas. First, we are combining biophysical and genetic approaches to understand how proteins use unstructured regions to sense cellular information and respond by adjusting their function. We developed methods to purify Ultrabithorax, a full-length, active Hox transcription factor, and have used this unique opportunity to investigate the role of intramolecular regulatory interactions in tissue-specific protein regulation. Second, we discovered methods to self-assemble Ultrabithorax into robust, extensible materials that are biocompatible and provide unique opportunities for functionalization. These materials are being developed for use as biosensors and to pattern and instruct vascularization in tissue engineering scaffolds.",,,https://scholars.library.tamu.edu/vivo/display/n18de9127
Stratos,Pistikopoulos,Professor,"The objective of my research programme is to develop fundamental theory and optimization based methodologies and computational tools that enable process engineers to analyze, design and evaluate process manufacturing systems which are economically attractive, energy efficient and environmentally benign, while at the same time exhibit good performance characteristics like flexibility, controllability, robustness, reliability and safety.",Director||Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n1aaac28f
Inna,Krieger,Research Assistant Professor,,Research Assistant Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n1b08b016
Sandun,Fernando,Professor,"Progression of chemical reactions often requires the presence of a substance called a catalyst that selectively accelerates the desired reaction(s) without itself being consumed. In this regard, enzyme catalysts are very selective towards specific reactions. However, their ability to tolerate a wide range of reaction conditions is poor. On the other hand, non-enzymatic catalysts (inorganic and organic) are robust and tolerant to a wide range of conditions, but they are not very selective. The long-term goal of my research program is to integrate (marry) desirable traits of both these catalysis systems in order to develop catalytic systems with novel functionalities.",Faculty Affiliate||Professor,Biological and Agricultural Engineering||Energy Institute,https://scholars.library.tamu.edu/vivo/display/n1b70c743
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
Tatyana,Igumenova,,"My laboratory is broadly interested in understanding the structural basis of signal transduction events that occur at the membrane surface. These events are mediated by signaling proteins that reversibly associate with membranes in response to binding second messengers, such as Ca2+ ions, diacylglycerol, and phosphoinositides. One of the key kinases regulating these signal transduction pathways is the Protein Kinase C (PKC) family. Aberrant levels of PKC expression or activity have been implicated in a large number of human diseases, such as cancer, cardiac failure, Alzheimer's disease, and diabetes. Despite the significance of PKC in signal transduction and human health, the structural and dynamical basis of its activation upon binding to lipid membranes remains elusive.",Associate Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n1c6e6632
Kayla,Bayless,Associate Professor,"My laboratory conducts research in two areas of molecular and cellular medicine: the mechanism through which primary human endothelial cells invade into 3D matrices, and communication between invading endothelial cells and their surrounding 3D collagen matrix.",Associate Professor,Cell Biology and Genetics,https://scholars.library.tamu.edu/vivo/display/n1dd3799c
Taylor,Ware,Associate Professor,,Associate Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n1f43628f
Peter,Knappett,Associate Professor,,Associate Professor,Geology and Geophysics,https://scholars.library.tamu.edu/vivo/display/n21dc06e7
Emile,Schweikert,Professor,"Our research explores the extreme limits of analytical chemistry: the characterization of atto to zeptomole quantities of molecules. The aim is to detect such amounts of analyte within nanometric surface volumes. The goal is chemical imaging of surfaces with exquisite spatial resolution. The first challenge is to conceive methods and instrumentation for the accurate identification of as little as a few thousand molecules. The second challenge is to convert a measurement into analytical information. A measurement by itself, even a spectacular one such as detection of a single atom or molecule, is not sufficient. Measurements must be related to the physico-chemical system sampled in terms of concentration and/or spatiotemporal localization.
Our experimental procedure is based on the desorption of atomic and molecular species when a solid is bombarded with energetic massive projectiles such as, for example, C60+ or Au4004+ . Their impact causes abundant emission of neutral and ionized atoms, molecules and molecular fragments. The desorbed ions are detected by time-of-flight mass spectrometry. The experimental procedure is that of secondary ion mass spectrometry with two innovations: the massive nature of the projectile and the mode of bombardment which is in a sequence of individual massive cluster impacts each isolated in time and space. Multiple ions can be ejected from a single impact. Given the size of the projectile (<= 3 nm in diameter), the co-ejected ions must originate from molecules colocated within nanometric dimensions.
The new capabilities for detecting, localizing and tracking small numbers of molecules (10-18 to 10-21 moles) are tested on surfaces, membranes, and nano-objects selected for their relevance in catalysis, microelectronics, environmental and biomedical research.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n233d0627
Yassin,,Distinguished Professor,,Professor||Professor and Head||Faculty Affiliate,Mechanical Engineering||Energy Institute||Nuclear Engineering,https://scholars.library.tamu.edu/vivo/display/n24b7e601
Susie,Dai,Associate Professor,"My research group is interested in evaluating environmental hazard substances, their interactions with the environment and species, and biological systems that can degrade and detoxify the pollutants. We have established broad analytical platforms to survey a wide spectrum of natural or man-made toxic chemicals such as mycotoxins, microcystins, agricultural, and industrial chemicals.
We integrate electrocatalysis/photoelectrocatalytic processes and material engineering with biological systems for 1) chemical degradation and 2) energy storage. Meanwhile, our laboratory has built a modern analytical tool suite, which includes mass spectrometry-based platforms for monitoring and surveillance, hydrogen-deuterium exchange mass spectrometry for protein structure dynamics analysis, and gel free mass spectrometry-based proteomics analysis. We develop qualitative and quantitative methods for molecular characterizations, protein analysis and proteomics when working in different environmental systems.",Associate Professor,Plant Pathology and Microbiology,https://scholars.library.tamu.edu/vivo/display/n27690618
Satish,Bukkapatnam,Professor,"Dr. Bukkapatnam's research addresses the harnessing of high-resolution nonlinear dynamic information, particularly from wireless MEMS sensors, to improve the monitoring and prognostics of real-world systems, including ultraprecision and nanomanufacturing processes and machines, and cardiorespiratory processes. His research has led to 185 peer-reviewed publications (115 published/ accepted in journals and 70 in conference proceedings), 1 granted and five pending patents, and has been the basis for 17 Ph.D. dissertations. His research has received support from federal agencies including National Science Foundation, Department of Energy, and Department of Defense, and the private sector including General Motors, Ford, National Instruments, and the Central Rural Electric Cooperative.",Faculty Affiliate||Professor,Energy Institute||Industrial and Systems Engineering,https://scholars.library.tamu.edu/vivo/display/n277d780c
Muhammad,Zubairy,Professor,Prof. Zubairy's research interests include quantum optics and laser physics. He has been interested in quantum optical applications to quantum computing and quantum informatics. He has also been interested in quantum state measurement of the radiation field and sub-wavelength atom localization. His other interests include coherent atomic effects and quantum thermodynamics.,Professor,Physics and Astronomy,https://scholars.library.tamu.edu/vivo/display/n279be03a
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
Mariappan,Muthuchamy,Professor,"The main goal of our laboratory is to understand the molecular mechanisms of cardiac muscle dynamics in normal and diseased states. Particularly, our interests focus on the relationships between thin filament activation and crossbridge kinetics, and how the mechanotransduction signaling transmits to myofilament activation. We use multiple techniques, molecular, cellular, biochemistry, structural and biophysical, to obtain information on the fundamental regulatory mechanisms of cardiac muscle contraction.
Our lab group is also investigating the role of lymphatics in different tissue beds, including mesentery, skeletal muscle, and brain using various animal models.",Professor,Medical Physiology,https://scholars.library.tamu.edu/vivo/display/n2877399b
Peter,Santschi,Distinguished Professor,"Research interests include a broad range of topics in Marine and Environmental Chemistry, including the role of natural nanoparticles in the biogeochemical cycling of trace substances, tracer applications using radioactive and stable isotopes, relationships between trace element and natural organic matter biogeochemistry, and the importance of exopolymeric substances and hydroxamate siderophores for trace element binding and removal from natural waters. That involves learning from new techniques, approaches and concepts that are used in related fields and applying them to solve questions in biogeochemistry and environmental science. Current themes of research are: Trace element speciation and cycling. Tracer applications in natural water systems using stable and radioactive isotopes. Sediment-water and particle-water interactions, with emphasis on colloids. Natural organic matter geochemistry. Metal-organic matter binding. Mobility of radioactive and toxic trace contaminants in surface waters, sediments and ground water. Applications of atomic force microscopy, accelerator, thermal ionization, and gas chromatography mass spectrometry in marine and environmental chemistry and geochemistry.",Distinguished Professor,Marine Sciences,https://scholars.library.tamu.edu/vivo/display/n2b3d402d
Ying,Li,Professor,"The research in our laboratory focuses on advanced materials and processes for sustainable energy and clean environment. Our group is specialized in synthesis of nanomaterials and multifunctional materials, catalysis and photocatalysis, carbon capture and conversion, natural gas utilization, solar photochemical and thermochemical processes, rechargeable batteries, membrane technology (wastewater treatment, desalination, drinking water purification), and aerosol engineering. For example, we have designed multifunctional nanomaterials to catalytically convert CO2 and water to syngas under solar irradiation, which can be further processed to produce liquid fuels. We also perform advanced microscopic and spectroscopic studies to understand materials properties, interfaces and surface chemistry.",Faculty Affiliate||Professor,Mechanical Engineering||Energy Institute,https://scholars.library.tamu.edu/vivo/display/n2b854905
Mansour,Karkoub,Professor,"Dr. Mansour Karkoub's teaching and research interests include: Controls, Robotics, Mechatronics, Vibration Engineering, and Application of AI to mechanical engineering systems.",Professor,Mechanical Engineering (Qatar),https://scholars.library.tamu.edu/vivo/display/n2b912bf4
Luis,Cisneros-Zevallos,Professor,The mission of our research program at the Plant Bioactives & Bioprocessing Research Laboratory is to generate information that can benefit the agriculture and processing industry by adding value to crops through bioactive compound discovery and the design of appropriate methods to enhance their content in plants as well as extend their post-harvest shelf-life.,Professor,Horticultural Sciences,https://scholars.library.tamu.edu/vivo/display/n2e6bb4c1
Suresh,Pillai,Professor,"Dr. Pillai's research focuses on bacterial cell-to-cell signaling, the molecular ecology of pathogens in natural and man-made ecosystems and the use of novel technologies to concentrate, detect, and decontaminate pathogens. His research on molecular microbial ecology and cell-cell signaling is targeted at understanding the complex and hitherto poorly understood relationship between microbial communities and human behavior. His research is aimed at understanding the role that the GI tract-associated microbiome has on human behavior.",Professor,Poultry Science,https://scholars.library.tamu.edu/vivo/display/n3009b050
Mian,Riaz,Instructional Associate Professor,,Instructional Associate Professor,Nutrition,https://scholars.library.tamu.edu/vivo/display/n31bf6fee
Hongbin,Zhan,Holder of Endowed Dudley J. Hughes '51 Chair in Geology and Geophysics,"My teaching and research interests are primarily in fundamental processes of groundwater hydrology, flow and transport in geological formations, and their applications in water resources management and geological, environmental, and petroleum engineering. I am recently interested in unconventional subsurface flow and transport processes, with the studied media changing from permeable porous and fractured ones to much less permeable ones such as clay and shale, and the studied pore sizes also changing from millimeters to micro-meters or even nano-meters. I am interested in the following research:
1. Flow and solute transport in highly deformable low-permeability porous media
2. Interaction of aquifer with connected and disconnected rivers
3. Vapor flow and transport in the subsurface
4. Non-Darcian flow and its impact on anomalous transport
5. Coupled unsaturated-saturated flow and transport problems
6. Radial dispersion and push-and-pull tests
7. Flow and transport in sloping aquifers
8. Coupled aquifer-conduit-fracture flow and transport
9. Flow and transport in fracture-matrix systems
10. Vadose zone infiltration well",Faculty Affiliate||Endowed Ray C. Fish Professor||Holder of Endowed Dudley J. Hughes Chair in Geology and Geophysics,Geology and Geophysics||Energy Institute||College of Geosciences,https://scholars.library.tamu.edu/vivo/display/n31c29796
Suin,Yi,Assistant Professor,,Assistant Professor,Electrical and Computer Engineering,https://scholars.library.tamu.edu/vivo/display/n31d2155e
Pingwei,Li,Professor,"The research in my lab focuses on elucidating the structural basis of innate immune responses towards microbial nucleic acids. The cGAS/STING pathway plays a central role in innate immunity toward bacterial and viral DNA. cGAS is activated by dsDNA and catalyzes the synthesis of a cyclic dinucleotide cGAMP, which binds to the adaptor STING that mediates the recruitment and activation of protein kinase TBK1 and transcription factor IRF-3. Activated IRF-3 translocates to the nucleus and induces the expression of type I interferons (IFN), an important family of antiviral cytokine. To elucidate the mechanism of cGAS activation, we determined the structures of cGAS in isolation and in complex with DNA. The cGAS/DNA complex structure reveals that cGAS interacts with DNA through two binding sites. Enzyme assays and IFN-? reporter assays of cGAS mutants demonstrate that interactions at both DNA binding sites are essential for cGAS activation. To investigate how cGAMP activates STING, we determined the structures of STING in isolation and in complex with cGAMP. These structures reveal that STING forms a V-shaped dimer and binds cGAMP at the dimer interface. We have also determined the structures of TBK1 in complex with two inhibitors, which show that TBK1 exhibits an I?B kinase fold with distinct domain arrangement. To elucidate the mechanism of IRF-3 recruitment by STING, we determined the structure of a phosphorylated STING peptide bound to IRF-3. To understand how phosphorylation activates IRF-3, we solved the structure of an IRF-3 phosphomimetic mutant bound to CBP, which reveals how phosphorylation induces the dimerization and activation of IRF-3.",Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n31ebad17
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
M,Castell-Perez,Professor,"Characterization of food and biological materials, biomass pretreatments for bioenergy, food rheology, smart packaging systems, food safety technologies including irradiation and active packaging.",Professor||Professor,Biological and Agricultural Engineering||Nutrition,https://scholars.library.tamu.edu/vivo/display/n34204884
Antonietta,Quigg,Associate Vice President,"The lab's research is focused on phytoplankton as model organisms to address questions related to water, climate and energy. We use quantitative experimental approaches to elucidate the importance of biotic and abiotic factors influencing phytoplankton dynamics (community composition, physiology, ecology) in field and laboratory-settings. It is collaborative, multidisciplinary and international (see publications list). However, does not follow the 20th century paradigm of striving to be the best in a narrowly defined field. Rather, our research paradigm is to continuously generate new ideas and new collaborations and alliances, which is needed to do well in the 21st century. In this way, the research we perform in the lab is capacity building for a new generation, with whom I have a strong commitment.
One of the greatest challenges facing the world today is ensuring an adequate supply and quality of water to meet rapidly increasing human needs whilst securing the continued health of our waterways. The goal of much of the lab's research is to understand and predict interactions between water systems, climate change, land use and ecosystem function and services in estuaries and coasts. We are working predominately in the Gulf of Mexico, Galveston Bay and other Texas bayous to address these concerns, but also have studies with colleagues in other regions of the world. A parallel goal is addressing emerging issues for the 21st century, including but not limited to, the fate and transport of engineered nanoparticles, oil pollutants and other man-made materials in the environment. Phytoplankton are directly and indirectly impacted by these pollutants, such that there is an increased potential for bioaccumulation and biomagnification to higher trophic levels. The potential phytoplankton protective and detoxifying mechanisms are also of interest.",Associate Vice President for Research and Graduate Studies||Professor||Professor,Texas A&M University at Galveston||Oceanography||Marine Biology,https://scholars.library.tamu.edu/vivo/display/n3641a7b1
Thomas,Ioerger,Professor - Term Appoint,"Dr. Ioerger's research interests are in the areas of Artificial Intelligence, Intelligent Agents, and Machine Learning. His work has covered diverse areas, from spatial reasoning, to simulating team-work, to modeling emotions. Currently, his primary focus is on designing multi-agent system architectures to simulate collaborative behavior and teamwork. He also applies AI and machine learning methods to various problems in the area of Bioinformatics, including the improvement of protein sequence alignments, molecular modeling, and X-ray crystallography. The latter research has lead to the development of an automated software system for protein model-building called TEXTAL, which is currently being used by crystallographers throughout the world.",Professor - Term Appoint,Computer Science and Engineering,https://scholars.library.tamu.edu/vivo/display/n36a51a43
Kathleen,Schwehr,nstructional Assistant Professor,,Instructional Assistant Professor,Foundational Sciences,https://scholars.library.tamu.edu/vivo/display/n37c9d4fe
Luis,Tedeschi,Professor,"Dr. Tedeschi conducts research on energy and nutrient requirements of grazing and feedlot animals, growth biology and bioenergetics, chemical composition and kinetics of fermentation of feeds, modeling and simulation of decision support systems, and evaluation of models (http://nutritionmodels.tamu.edu). He has collaborated with several researchers overseas to develop models for small ruminants (sheep and goats). He utilizes System Dynamics concepts applied to nutrition.",Associate Professor||Professor,Animal Science||Nutrition,https://scholars.library.tamu.edu/vivo/display/n387904d6
Arun,Srinivasa,Professor,"My research focuses on plasticity of metals and polymers; thermomechanics of dissipative processes, dislocation dynamics, Cosserat continua, design and dynamics of compliant mechanisms.",Professor||Faculty Affiliate,Mechanical Engineering||Institute for Engineering Education and Innovation,https://scholars.library.tamu.edu/vivo/display/n3b0f1d01
Luc,Berghman,Professor,"The hallmark of my research career is the development of novel antibodies and applying them toward the development of new immuno-biotechnological tools. My lab has developed an antibody discovery platform in chickens that goes from in silico sequence to epitope-specific chicken IgG (IgY) in less than 3 weeks based on in vivo CD40-targeted immunogen delivery.
Research projects include the study of the immune response in the chicken, especially the function of CD40-positive antigen presenting cells (such as the dendritic cells) in activating the humoral immune response and the development of chicken egg yolk antibodies, monoclonal antibodies and recombinant antibodies for diagnostic, prophylactic and therapeutic purposes. a Dr. Berghman was the recipient of the 2016 Zoetis Fundamental Science Award.",Professor||Professor,Poultry Science||Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/n3e016f20
Jianrong,Li,"Professor, Neurobiology and Neuroimmunology, Veterinary Integrative Biosciences","The central goal of our research is to understand how oligodendroglial development and function in the mammalian central nervous system is regulated in health and disease. Specifically, we are interested in molecular and cellular mechanisms involved in oligodendrocyte damage/dysfunction in white matter injuries such as multiple sclerosis and cerebral palsy and in aging-related neurodegenerative diseases such as Alzheimer's disease. Because in most CNS diseases, multiple cell types including neurons, glial cells and vascular cells are involved via complex interactions, we investigate, at the cellular and molecular level, the role of microglia and astrocytes in the process of oligodendrocyte development, differentiation and damage. We use a variety of methods including primary cell cultures and transgenic and knockout animals to elucidate cellular pathways mediating oligodendrocyte injury.
The second focus of our laboratory is to elucidate the signals that promote oligodendrocyte survival and regeneration/remyelination after injury, and to study cell-cell interactions that regulate remyelination. These studies should contribute significantly to our understanding of mechanisms of oligodendrocyte development and injury, and provide new clues for potential prevention and treatment of human white matter diseases.",Professor,Veterinary Integrative Biosciences,https://scholars.library.tamu.edu/vivo/display/n3ef91dcf
Robert,Chapkin,Distinguished Professor,"Research in the Chapkin lab focuses on dietary/microbial modulators related to the prevention of cancer and chronic inflammatory diseases.
Our central goal is to (1) understand cancer chemoprevention at a fundamental level, and (2) to test pharmaceutical agents in combination with dietary/microbial (countermeasures to the Western diet) to more effectively improve gut health and reduce systemic chronic inflammation. Since diet influences gut microbiota composition and metabolite production, to unravel the interrelationships among gut health and the structure of the gut microbial ecosystem, we are in the process of evaluating (using transgenic mouse, Drosophila models and humans) how the gut microbiome modulates intestinal cells, innate immune cells and tumors. As part of this endeavor, we are modeling at the molecular level the dynamic relationship between diet and gut microbe-derived metabolites which modulate chronic inflammation and the hierarchical cellular organization of the intestine, e.g., stem cell niche.",Distinguished Professor||Professor,Biochemistry and Biophysics||Nutrition,https://scholars.library.tamu.edu/vivo/display/n3fbb59f8
Thomas,Mcdonald,Professor,"My research focuses on environmental chemistry, petroleum geochemistry, and general organic chemistry.",Professor,Environmental and Occupational Health,https://scholars.library.tamu.edu/vivo/display/n407d0459
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
Dzmitry,Kurouski,Assistant Professor,"My laboratory is broadly interested in elucidation of structural organization of amyloid oligomers using Tip-Enhanced Raman Spectroscopy (TERS).
The ultimate objective of our studies is to unravel structural elements on surfaces of amyloid oligomers that are responsible for their toxicity and propensity to propagate into amyloid fibrils. These findings will help to guide pharmaceutical drug screening efforts towards finding selective blockaders of amyloid fibrillation at the stage where their aggregates are minimally toxic. Finally, resolving the structure of amyloid oligomers will give an inside how to cure Alzheimer's and Parkinson's diseases and dementia.",Assistant Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n43453d43
Kenneth,Ramos,Professor and Executive Director,,Professor of Medicine||Professor and Executive Director||Executive Committee||Associate Vice President for Research||Assistant Vice Chancellor for Health Services,The Texas A&M University System||Institute of Biosciences and Technology||Global Institute for Hispanic Health||School of Medicine||Health Science Center,https://scholars.library.tamu.edu/vivo/display/n47de353a
Hong,Liang,Professor,,Faculty Affiliate||Professor||Affiliated faculty,Mechanical Engineering||Energy Institute||Materials Science and Engineering,https://scholars.library.tamu.edu/vivo/display/n4923e41d
Tadhg,Begley,Distinguished Professor,"The Begley Group is interested in the mechanistic chemistry and enzymology of complex organic transformations, particularly those found on the vitamin biosynthetic pathways. We are currently working on the biosynthesis of thiamin, molybdopterin, pyridoxal phosphate and menaquinone. Our research involves a combination of molecular biology, protein biochemistry, organic synthesis and structural studies and provides a strong training for students interested in understanding the organic chemistry of living systems and in pursuing careers in biotechnology, drug design or academia.
Thiamin pyrophosphate plays a key role in the stabilization of the acyl carbanion synthon in carbohydrate and amino acid metabolism. The biosyntheses of the thiamin pyrimidine and thiazole are complex and are different from any of the characterized chemical or biochemical routes to these heterocycles. We are particularly interested in cellular physiology and the mechanistic enzymology of thiamin biosynthesis. As an example of one of the complex transformations on this pathway, the figure below shows the structure of the pyrimidine synthase catalyzing the complex rearrangement of aminoimidazole ribotide (left) to the thiamin pyrimidine (right).",Distinguished Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n498aa35b
Thomas,Kent,Professor,"Neurologist and clinician scientist with a basic, translational and clinical research program, focused mostly on stroke and other brain injuries. The laboratory utilizes a variety of cell free, tissue culture and in-vivo techniques to design and characterize a series of carbon nanomaterials that possess the ability to act as catalytic antioxidants as well as support key mitochondrial functions. This NIH-supported research is in collaboration with synthetic nano-chemists at Rice University (Tour Lab) and biochemists at University of Texas Health Science Center Houston (Tsai Lab). The group is testing a variety of engineered modifications of these versatile, non-toxic materials to address specific cell injury and death mechanisms including ferroptosis and interruption in electron transport and oxidative phosphorylation.
A major interest of ours is the role of diabetes in worsening outcome from stroke, a condition that affects minority and rural Texans disproportionally. With a range of research from molecular interactions to whole animal and clinical studies, the work in this lab is deeply translational, leveraging the group's clinical training and experience to insure that conclusions have direct relevance to the disease state, with the ultimate goal of facilitating the identification of new therapies for these major contributors to disability and mortality.",Professor,Institute of Biosciences and Technology,https://scholars.library.tamu.edu/vivo/display/n4acd1da6
Yinan,Wei,Professor,"We are interested in studying the interaction between microbes and host systems, in the context of antibiotic resistance, infection, and the innate immune response.",Professor,Pharmacy Practice,https://scholars.library.tamu.edu/vivo/display/n4bb89912
Tanmay,Lele,Professor,"Dr. Tanmay Lele's research is in the area of mechanobiology with a focus on cancer mechanobiology. His lab is interested in the molecular mechanisms by which cell generated mechanical forces and associated signaling pathways enable cell and tissue functions, and how these relationships become altered in cancer. Current research projects in the laboratory include quantitative measurements of nuclear forces, the effect of mechanical stresses on nuclear functions and gene expression, cellular adaptation to mechanical properties of the extracellular matrix, and the mechanics of cancer tissue development.
Lele is a scholar in cancer research at the Cancer Prevention and Research Institute of Texas.",Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n4c5b9ade
Thomas,Boutton,Professor,"Dr. Boutton is interested in the ecology of grassland and savanna ecosystems, particularly the impacts of land cover/land use changes on ecosystem processes (productivity, decomposition, biogeochemistry, hydrology). At present, most of his work is oriented towards understanding the influence of woody plant invasion into grasslands and savannas on biogeochemistry and soil biology. He is also interested in understanding ecosystem responses to global changes predicted for the future. The effects of climate, land use, and atmospheric composition on ecosystem structure and function are being investigated at time scales ranging from a few years (contemporary ecosystems) to thousands of years (paleo ecosystems), and spatial scales ranging from the soil aggregate to the landscape. Dr. Boutton also serves as Director of the Stable Isotope Biogeochemistry Laboratory, and teaches two graduate level courses (ESSM 600 - Principles of Ecosystem Science and Management, and ESSM 622 - Biogeochemistry of Terrestrial Ecosystems).",Regents Professor & Sid Kyle Endowed Chair,Ecology and Conservation Biology,https://scholars.library.tamu.edu/vivo/display/n50abe2cc
Aziz,Rahman,Associate Professor,,Faculty Affiliate||Associate Professor,Energy Institute||Petroleum Engineering,https://scholars.library.tamu.edu/vivo/display/n52fdba5b
Soon-Mi,Lim,Lecturer,,Associate Graduate Advisor||Instructional Assistant Professor,Chemistry||Chemistry,https://scholars.library.tamu.edu/vivo/display/n53c3c8a0
Rosana,Moreira,Professor,"My research topics include engineering aspects of foods and food processes; fundamental modeling: dehydration, frying, extrusion, food irradiation; process control techniques as applied to food processing systems: food extrusion processes, continuous fryers, and continuous flow grains dyers; deep-fat frying: modeling, oil absorption mechanisms, vacuum frying, acrylamide; impingement drying; food safety: food irradiation and biosensor technology.",Professor||Faculty Affiliate||Faculty Affiliate,Biological and Agricultural Engineering||Energy Institute||Institute for Engineering Education and Innovation,https://scholars.library.tamu.edu/vivo/display/n53d8a153
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
Phanourios,Tamamis,Assistant Professor,,Associate Professor,Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n5673e0c8
Susan,Woodard,Senior Lecturer - Faculty,"Product recovery and purification; assays in support of product quality; enzyme assays; immunological assays, HPLC. Transgenic plant extraction and protein recovery; biomass conversion. Biopharmaceutical and vaccine manufacturing and quality control testing. cGMP and GLP compliance.",Senior Lecturer,Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n573c6961
Sergio,Capareda,Professor,"Fluidized bed pyrolysis and gasification of biomass; biofuels and biopower production including biomass characterization; waste management, environmental air quality research, PM, GHG and RVOC emissions measurements; engine dynamometer testing; process design and development.",Professor||Faculty Affiliate,Biological and Agricultural Engineering||Energy Institute,https://scholars.library.tamu.edu/vivo/display/n5974e0e3
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
Thomas,Mcknight,Professor and Head,"My lab is currently investigating mechanisms that regulate telomerase activity in plants. We previously showed that the pattern of telomerase expression in plants is remarkably similar to the pattern seen in humans, despite fundamental differences in development between plants and animals. Telomerase is abundantly expressed in reproductive organs but is undetectable in most vegetative organs (Fitzgerald et al., 1996). Additionally, telomerase can be induced in leaves and other vegetative organs by exposure to exogenous auxin.
To isolate genes that regulate telomerase, we screened a large population of activation tagged lines of Arabidopsis thaliana, and found that several lines that ectopically express telomerase in leaves. The first line we characterized over-expressed a gene encoding a small zinc finger transcription factor we designated TELOMERASE ACTIVATOR 1 (Ren et al., 2004). This factor does not bind to the promoter for TERT, which encodes the catalytically active subunit of telomerase. Instead, it binds to and activates transcription of BT2, a gene encoding a component of a ubiquitin ligase (Ren et al., 2007). Our working model is that the BT2 ubiquitin ligase marks a telomerase repressor for destruction, thereby allowing expression of telomerase. Efforts in the lab are currently focused on identifying the presumed telomerase repressor protein and other proteins that interact with BT2.",Professor and Head,Biology,https://scholars.library.tamu.edu/vivo/display/n5c3b294a
Wenshe,Liu,Bovay Chair and Professor in Chemistry,"Our research interest is to design methods for the genetic incorporation of noncanonical amino acids into proteins in living cells and apply these methods in three major directions: deciphering functions of protein posttranslational modifications, small molecule sensing, and expanding chemical diversities of phage display libraries. To study protein posttranslational modifications, we have constructed methods for the site-specific installation of lysine acetylation and methylation in proteins and will apply them to study functional roles of these two modifications on p53, a tumor suppressor protein. We have also developed a strategy to site-specifically install two noncanonical amino acids into one protein in E. coli and are applying this approach to construct biosensors for small organic molecules and metal ions. Phage display is an efficient method to identify peptides for therapeutic interventions. However, a phage display peptide library has limited structure motifs and functional groups because only 20 natural amino acids can be used to generate a library. We plan to expand the chemical diversity of a phage display library by incorporating multiple noncanonical amino acids and chemically modifying them to extend functional diversities. Screening this unnatural phage display library against therapeutic targets such as c-Abl tyrosine kinase is expected to identify highly potent inhibitors.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n5d9506ea
Svetlana,Sukhishvili,Professor,"My research focuses on stimuli-responsive all-polymer and polymer nanocomposite assemblies for sensing, separation and biomedical applications; structure and dynamics of polyelectrolyte assemblies; materials with controllable optical, swelling and drug-release responses; remote manipulation of material shape; smart antibacterial materials; and surface modification for controlling wettability, adhesion and adsorption.",Professor,Materials Science and Engineering,https://scholars.library.tamu.edu/vivo/display/n616e513c
Kevin,Mcinnes,Professor,I am Professor of Soil and Environmental Physics and a licensed Professional Geoscientist. My research focuses on mass and energy transport in the soil-plant-atmosphere continuum.,Professor,Soil and Crop Sciences,https://scholars.library.tamu.edu/vivo/display/n64b6b31f
Chetan,Jinadatha,Clinical Associate Professor,,Clinical Associate Professor,Medical Education,https://scholars.library.tamu.edu/vivo/display/n65d0a1d7
Joseph,Kwon,Associate Professor and holder of the Kenneth R. Hall Career Development Professorship,,Associate Professor||Faculty Affiliate,Energy Institute||Artie Mcferrin Department of Chemical En,https://scholars.library.tamu.edu/vivo/display/n680c5a23
Mark,Barteau,Professor,"Mark A Barteau's research focuses on chemical reactions at solid surfaces and their applications in heterogeneous catalysis and energy processes. He has received numerous grants throughout his career from such prestigious institutions as the National Science Foundation (NSF), the U.S. Department of Energy, the U.S. Air Force Office of Scientific Research and NASA.",Faculty Affiliate||Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n6b60a83e
Ann,Kier,Professor Emerita,,Professor,Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/n6c0ad160
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
Ahmed,Abdala,Professor,"Professor Abdala research focuses on development of advanced materials for energy and environmental applications based on polymers and nanomaterials, including polymer nanocomposites, functionalized graphene materials, anticorrosion coatings, polymeric membranes for gas separation and water treatment, and nanohybirds of metal/metal oxides and 2D carbon nanomaterials for catalysis, adsorption, energy storage, and thermoelectric materials. In addition, Dr. Abdala has research interests in applications of polymers and surfactants for EOR.",Faculty Affiliate||Associate Professor,Energy Institute||Chemical Engineering (Qatar),https://scholars.library.tamu.edu/vivo/display/n6cdc74b2
Abraham,Clearfield,Distinguished Professor,"Our research interests are focused in solid state and materials chemistry and encompass a wide variety of projects. An important goal is the ability to design and synthesize new materials whose structure and properties can be predicted and controlled. Layered compounds are amenable to manipulation to produce new structures because of the weak forces between layers. We have learned how to separate the layers of several classes of compounds and are reconstituting them into novel materials. For example, we have prepared staged materials in which alternating layers are hydrophobic and hydrophilic.
The surfaces of our layered materials react with a variety of molecules to bond them to the surface. We are developing such materials for drug delivery, heterogeneous catalysis, and polymer-nanoparticle composites.
Single crystal X-ray diffraction has been the key tool in elucidating the structure of solids. For many compounds, single crystals are unavailable so that indirect methods need to be used. We pioneered the solution of crystal structures from X-ray powder data and have had considerable success. The methods need to be improved and extended to more complex systems such as poorly crystallized materials. Combined use of X-ray, neutron and synchrotron methods are in progress and extension to EXAFS and amorphous scattering techniques is contemplated.",Distinguished Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n6dc4bd81
Weihsueh,Chiu,Professor,,Professor,Veterinary Physiology and Pharmacology,https://scholars.library.tamu.edu/vivo/display/n6e29f354
Bill,Batchelor,Professor Emeritus,"My major research focus has been on developing and investigating innovative treatment methods for water, wastewater and hazardous wastes. These include chemical, physical and biological treatment methods for both organic and inorganic contaminants. Among the novel treatment processes we have developed are autotrophic denitrification with sulfur electron donors, inorganic oxide adsorbents for wastewater reuse, ultra-high lime and ultra-high lime with aluminum process for scalant removal in recycled water and zero-discharge desalination, the biostrip process for biological and physical treatment, degradative solidification/stabilization, chromium stabilization in the vadose zone, sulfur and iron-based reactive adsorbents, and advanced reduction processes. This research incorporates both experimental and modeling activities and is integrated with graduate and undergraduate education.",Professor Emeritus||Professor Emeritus,Civil Engineering||Vernon Research and Extension Center,https://scholars.library.tamu.edu/vivo/display/n6ebab0fa
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
Junjie,Zhang,Associate Professor,"The living cell contains a collection of molecular machines to grow and function. These machines include the ribosomes, the chaperons, the proteasomes and other enzymes. Malfunction of these machines, if occurred in human, are related to many diseases. Understanding their three-dimensional (3D) structures is essential to understand how these machines work in the cell and eventually to treat those related diseases.
Here we use an experimental technique called cryo-electron microscopy (cryo-EM) to image these cellular machines in their native environment at liquid nitrogen temperatures. We then use image processing and graphics techniques to visualize their 3D structures, answering the questions such as how they assemble and how they interact with each other.
In addition, we develop computational modeling tools to interpret and animate these obtained 3D structures to further describe their movements and dynamics.",Associate Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n701e163f
Robert,Burghardt,Professor,"Research in the laboratory is focused on investigating mechanisms by which a variety of biological response modifiers ranging from mechanical signals, hormones and growth factors to environmental chemicals alter cellular signaling pathways and cellular homeostasis.","Professor||Director, Image Analysis Laboratory",School of Veterinary Medicine and Biomedical Sciences||Veterinary Integrative Biosciences,https://scholars.library.tamu.edu/vivo/display/n70a3d026
Yubin,Zhou,Professor & Presidential Impact Fellow,"We are a synthetic biology and bioengineering lab focused on developing technologies that enable remote and programmable control of protein activity, cell signaling and designer cells. We pioneer chemical and synthetic biology approaches to address challenges in health and disease. We are particularly interested in (i) illuminating novel regulatory mechanisms of signal transduction that remain unresolved in Ca2+ signaling and inter-organelle communications; (ii) pioneering widely-applicable molecular tools for precise control of cellular events, (epi)genome engineering, and gene transcription; and (iii) developing innovative theranostic devices, programmable biologics and intelligent cell-based therapies (CAR-T) for cancer and neurodegeneration intervention. The tight integration among mechanistic studies, biomedical engineering, and translational sciences is a hallmark of my research. See highlights in: ""Let there be light"" (Scientia); ""Optogenetics sparks new research tool"" (NIH Biomedical Beat)",,,https://scholars.library.tamu.edu/vivo/display/n70ef0d4e
Keyan,Zhu Salzman,Professor,"Over millions of years of co-evolution with insects, plants have developed various defense machineries that can be activated in response to insect herbivory. Insects, in turn, have developed a variety of strategies to evade these plant defense mechanisms. An improved understanding of this complex plant defense and insect counter-defense relationship will facilitate development of better strategies to improve host plant defense. Currently, we are using Arabidopsis to study plant defense signal transduction pathways against insect pests. Meanwhile, since effectiveness of plant defense is also determined by the insect response, my laboratory is also investigating how insects adapt to the challenge of plant defense molecules, as well as to human imposed management strategies, and is working to identify new insect vulnerable systems.",Professor,Entomology,https://scholars.library.tamu.edu/vivo/display/n716ece47
Ashfaq,Bengali,Professor,Dr. Bengali's research is focused on the photochemistry of transition metal containing organometallic complexes. A variety of infrared techniques including step-scan and rapid-scan FTIR are employed to investigate the reactivity of photochemically generated transient complexes from the nanosecond to longer timescales.,Professor of Chemistry,Science (Qatar),https://scholars.library.tamu.edu/vivo/display/n71911659
Margaret,Glasner,Associate Professor,"Evolution is the organizing principle of biology and provides the cornerstone of our approach to understand the relationships between protein structure and function. We combine bioinformatics, biochemistry, and genetics to address fundamental questions about protein evolution, such as: What structural and mechanistic features of enzymes increase their capacity to evolve new functions? How do new metabolic pathways evolve? Are there multiple evolutionary pathways to evolve new enzyme activities?
Our primary focus is on how catalytic promiscuity serves as the raw material for evolving new enzyme activities. Catalytic promiscuity is the ability to catalyze different chemical reactions using the same active site. Many enzymes in one branch of the protein family we are studying are catalytically promiscuous, and this activity has been incorporated into new metabolic pathways more than once. Comparing the sequences and structures of these proteins will identify characteristics that permitted them to evolve the second activity.
Our goal is to use results from our research to identify fundamental evolutionary principles that can can help decipher protein structure-function relationships, predict protein functions, and improve protein engineering methods.",Associate Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n721200c3
Frances,Ligler,Professor,,Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n74321a1f
Elizabeth,Pishko,Lecturer,,Lecturer,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n75e85328
Raymundo,Arroyave,Professor,"Dr. Arroyave obtained his BS degrees in Mechanical and Electrical Engineering from the Instituto Tecnol?gico y de Estudios Superiores de Monterrey (M?xico) in 1996. He got his MS in Materials Science and Engineering in 2000 and his PhD in Materials Science in 2004 from MIT. After a postdoc at Penn State, he joined the Department of Mechanical Engineering at Texas A&M University in 2006. He is currently a Professor in the Department of Materials Science and Engineering and holds courtesy appointments in the Departments of Mechanical Engineering and Industrial and Systems Engineering
Dr. Arroyave's area of expertise is in the field of computational materials science, with emphasis in computational thermodynamics and kinetics of materials. He and his group use different techniques across multiple scales to predict and understand the behavior of inorganic materials (metallic alloys and ceramics). The techniques range from ab initio methods, classical molecular dynamics, computational thermodynamics as well as phase-field simulations. Dr. Arroyave's group recent focus has been on simulation and data-enabled materials discovery and design in a wide range of contexts, including Additive Manufacturing.
Dr. Arroyave has been co-author of more than 250 publications in peer-reviewed journals, 20 conference proceedings as well as close to 120 conference papers and >130 invited talks in the US and abroad. He is the recipient of several awards, including NSF CAREER Award (2010), TMS Early Career Faculty Fellow (2012, Honorable Mention), TMS Brimacombe Medal (2019), ASM Fellow (2020), Acta Materialia Silver Medal (2023). He has been named Texas A&M Presidential Impact Fellow (2017) and Texas A&M University System Chancellor EDGES Fellow (2019). He currently holds the Segers Family Dean's Excellence Professorship.
He is an Associate Editor of Materials Letters, Integrating Materials and Manufacturing Innovation (IMMI) and the Journal of Phase Equilibria and Diffusion. He is involved in ASM and TMS, having served as Chair of the ASM Alloy Phase Diagram Committee, Chair of the TMS Functional Materials Division as well as member of the Board of Directors of TMS. He has chaired or co-chaired more than 20 symposia and has been the lead organizer and co-organizer of several international conferences.",Faculty Affiliate||Professor||Professor||Professor||Faculty Affiliate,Mechanical Engineering||Energy Institute||Materials Science and Engineering||Industrial and Systems Engineering||Institute for Engineering Education and Innovation,https://scholars.library.tamu.edu/vivo/display/n763870af
William,Pinchak,Professor,,Professor||Professor,Ecology and Conservation Biology||Vernon Research and Extension Center,https://scholars.library.tamu.edu/vivo/display/n76e6ff4b
Duncan,Maitland,Professor,,Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n77b950c0
Terry,Thomas,Professor,"My interests are evolutionarily broad and include animals, plants and fungi. A major focus of the lab is the genomic analysis of gene expression programs during plant gene expression programs, particularly during embryogenesis and seed development, and the underlying regulatory mechanisms required for the initiation and maintenance of these programs. This work has illustrated the combinatorial interactions of cis and trans -acting factors that result in specific gene regulatory events. We are also using genomics tools to study the interaction of the rice blast fungus, Magnaporthe grisea , with plant hosts; the circadian control of gene expression; and the development of the vertebrate retina. An additional focal area is the utilization of molecular and cellular approaches for crop improvement. As part of these research activities, we have developed or adapted high throughput genomics approaches to accelerate the gene discovery process and subsequent analysis of gene expression and function.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n79201ac5
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
Roderick,Dashwood,University Distinguished Professor,"Research integrates multiomic, genetic, epigenetic and immune approaches for precision oncology. Epigenetic readers, writers and erasers that reversibly regulate immune players in the antigen presentation pathway are of current mechanistic interest. Molecular and cell-based assays are combined with preclinical models coupled to polypectomy. Clinical specimens and organoids from patients undergoing colectomy provide for human translation. Supported by the NCI, NINDS/NIA, and the John S. Dunn Foundation.",John S. Dunn Chair in Disease Prevention||Distinguished Professor||Director,Institute of Biosciences and Technology||Center for Epigenetics and Disease Prevention||School of Medicine,https://scholars.library.tamu.edu/vivo/display/n7a63dbe7
Gerard,Cote,Professor,,Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n7bbfddf5
Karen,Wooley,Distinguished Professor,"Our research activities combine organic syntheses, polymerization strategies and polymer modification reactions in creative ways to afford unique macromolecular structures, which have been designed as functional nanostructures, polymer systems having unique macromolecular architectures, and/or degradable polymers. The emphasis is upon the incorporation of functions and functionalities into selective regions of polymer frameworks. In some cases, the function is added at the small molecule, monomer, stage, prior to polymerization, whereas, in other cases, chemical modifications are performed upon polymers or at the nanostructure level; each requires a strategic balance of chemical reactivity and the ultimate composition and structure.",Distinguished Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n7d5d2fbd
Arul,Jayaraman,Professor,,Professor,Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n7deb8230
Jingjing,Qiu,Associate Professor,,Associate Professor,Mechanical Engineering,https://scholars.library.tamu.edu/vivo/display/n80c41e6b
David,Peterson,Professor and Associate Department Head,"We are interested in the molecular mechanisms of transcriptional regulation in mammalian cells. Many of our experiments have focused on the transcription of the proviral genome of the retrovirus mouse mammary tumor virus, which is subject to both positive and negative control. A number of cellular proteins that are important for viral transcription have been identified, and we would like to define the precise roles of these proteins in establishing correct levels of viral gene expression. We are also exploring some specific questions related to the general mechanism of transcription initiation by RNA polymerase II and the biochemical details of transcriptional regulation. In particular, we are developing assays to directly assess effects of transcriptional regulatory proteins on discrete steps in the initiation process, including transcription complex assembly, separation of the two strands of template DNA at the initiation site, and promoter clearance by the polymerase as it begins RNA synthesis.",Professor and Associate Department Head,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n8186cf95
Walter,Den,TEES Researcher at TAMU-San Antonio,,"Professor, Department of Mathematical, Physical and Engineering Sciences||TEES Researcher at TAMU-San Antonio||Director, Institute for Water Resources Science and Technology","Texas A&M University – San Antonio - (San Antonio, Txas, United States)||Texas A&M University – San Antonio - (San Antonio, Texas, United States)||Texas A&M University – San Antonio - (San Antonio, Txas, United States)||Texas A&M University – San Antonio - (San Antonio, Texas, United States)||TEES Regional Divisions",https://scholars.library.tamu.edu/vivo/display/n822ff81a
Stephen,Talcott,Professor and Associate Department Head,"Dr. Talcott's research is focused on phytochemicals in fruits and vegetables, antioxidant stability and assessment, postharvest retention, beverage processing and value-added products. Intake of compounds such as phenolic acids, flavonoids, anthocyanins, procyanidins, carotenoids, tocopherols and ascorbic acid are suggested to have an inverse association with the risk of certain cancers and diseases. These compounds are investigated as antioxidants, enzyme inhibitors, and bioactive agents and changes in their concentration and activity are investigated following postharvest handling and processing. Current investigations include phytochemical identification, quantification and stability in tropical and subtropical fruits and vegetables including acai, mango, guava, passion fruit, grapes. As well as peanuts, strawberries, bell peppers and food-grade botanicals.",Professor and Associate Department Head,Nutrition,https://scholars.library.tamu.edu/vivo/display/n8247cf18
Arum,Han,Professor,"His research interests are in solving grand challenge problems in the broad areas of health and energy through the use of micro/nano systems technologies. His work in these areas has focused on the development of in vivo like in vitro systems through microfluidic lab-on-a-chip technologies (e.g., organ-on-a-chip & microphysiological systems, developmental neurobiology models of the central nervous system, blood-brain-barrier-on-a-chip, gastrointestinal tract-on-a-chip, high throughput live cell arrays), development of high throughput single-cell physio-chemical analysis platforms, and development of microbial systems as biorefineries for bioelectricity and biofuel production while simultaneously utilizing wastewater.
He has co-authored more than 80 peer-reviewed publications and has received funding from the Bill and Melinda Gates Foundation, National Institutes of Health (NIH), National Science Foundation (NSF), Defense Threat Reduction Agency (DTRA), United States Department of Agriculture (USDA), U.S. Army Corp of Engineers, Qatar National Research Foundation (QNRF), and several other international sponsors and private companies. He currently serves as the editorial board member of the journal PLoS ONE and as an associate editor for the journal Biomedical Microdevices.",Professor||Faculty Affiliate,Energy Institute||Electrical and Computer Engineering,https://scholars.library.tamu.edu/vivo/display/n8289e950
David,Barondeau,Associate Professor,Our group conducts research on Fe-S cluster biogenesis.,Associate Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n83588e44
Gordon,Carstens,Professor,"In addition to teaching animal nutrition courses, Dr. Carstens conducts research on energy metabolism and growth and development in ruminants. Specific research areas include the regulation of growth and composition of carcass and mammary tissues by nutritional control and the use of externally administered (exogenous) growth regulators. Recent research has focused on methods to increase the ability of newborn calves to produce heat and fight off cold stress and the influence of genetic and nutritional components on this ability.",Professor,Animal Science,https://scholars.library.tamu.edu/vivo/display/n839e23fe
Peter,Davies,Professor,,Interim Department Head||Professor and Director,Center for Translational Cancer Research||Translational Medical Sciences,https://scholars.library.tamu.edu/vivo/display/n83f40a4a
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
Rosemary,Walzem,Professor,"Dr. Walzem's core research focus within the laboratory is directed towards understanding how the structure of triglyceride-rich lipoproteins influences their ability to carry out specific nutrient delivery tasks. Her studies include identification of mechanisms and regulatory processes that control the assembly of trigylceride-rich lipoproteins in issues, structural studies of lipoproteins themselves and physiological studies to determine substrate properties and metabolic fates of different types of lipoproteins. Diet can significantly alter lipoprotein physiology through multiple mechanisms, and studies of diet effects provides a significant sub-theme to the research program. A variety of species are used to address specific questions, however, avian and human lipoprotein metabolism as it relates to egg production and atherogenesis, respectively, are emphasized.",Professor,Poultry Science,https://scholars.library.tamu.edu/vivo/display/n85cd191f
Sherzod,Madrahimov,Assistant Professor,"Sherzod Madrahimov is an Assistant Professor who teaches organic chemistry courses. Dr. Madrahimov's research focuses on catalysis in particular studying the mechanisms of transition metal catalyzed reactions and the heterogenization of well-defined, molecular, homogeneous catalysts.",Assistant Professor of Chemistry,Science (Qatar),https://scholars.library.tamu.edu/vivo/display/n89c64dc8
Simon,North,Professor and Head,"Our research involves trying to understand chemical reactivity on a microscopic quantum-state resolved level. We focus on isolated molecules in the gas-phase to develop a detailed description of the factors which influence the rates, energy disposal, and final products in a reaction. In order to address these issues we use lasers to carefully control the preparation of excited molecules and to probe all the properties of the reaction products. chemical reactivity on a microscopic quantum-state resolved level. Our specific interests include understanding atmospheric photochemistry, the tropospheric oxidation of biogenic hydrocarbons, and laser diagnostic development for flow field characterization. The laboratory contains equipment to perform state-of-the-art experiments in chemical dynamics and kinetics and is associated with several interdisciplinary University Research Centers. Our photochemistry experiments combine molecular beam and state-resolved ionization techniques with position-sensitive ion imaging to determine the identity and energy content of photochemical products in the absence of secondary collisions. Studies focus on the photodissociation of jet-cooled radicals of atmospheric relevance and preliminary results have already stimulated collaboration with several theoretical groups. The experiments provide a stringent test for modern theory and allow assessment of the impact that the photochemistry has on atmospheric modeling.",Professor and Head,Chemistry,https://scholars.library.tamu.edu/vivo/display/n8c54a7a4
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
Sumana,Datta,Assistant Provost,"We are currently investigating how organismal level cues regulate the onset of stem cell division during development. Our primary system is the neuroblasts in the brain of the fruit fly, Drosophila melanogaster. The trol gene of Drosophila encodes the fly homolog of the mammalian heparan sulfate glycoprotein, Perlecan. Perlecan is found in mice, humans, and C. elegans, and is widely known as a co-receptor for the growth factor FGF. We have shown that Trol, the Drosophila Perlecan homolog, is required for signaling by FGF. Furthermore, we have demonstrated that Trol is also a likely candidate for the Hedgehog co-receptor. Hedgehogs are peptide growth factors which are conserved in mammals and require heparan sulfate glycoproteins for their movement and long-range signaling; however, until now the identity of the protein core was unknown. Our studies demonstrate genetic interactions between trol and hedgehog or patched mutations (patched is the Hedgehog receptor). Further studies reveal that both FGF and Hedgehog signaling activate stem cell division. Current projects involve determining how Trol stimulates FGF and Hedgehog signaling through genetic, molecular, and biochemical analyses.",Assistant Provost,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n8ce436a7
Jingbo,Liu,Faculty Affiliate,"All Solid State Lithium-metal Batteries
Fuel Cells - Solid Oxide Fuel Cell, Microbial Fuel Cells and PEM (proton exchange membrane) Fuel Cells
Decentralized Hydrogen production and HFCV
NH3 Production
Water purification using cermet (ceramic and metal) membrane, and colloid and surface chemistry",Faculty Affiliate,Energy Institute,https://scholars.library.tamu.edu/vivo/display/n8dc7dbba
Charles,Kenerley,Professor,The long-term goal of my research program is to understand the interactions of Trichoderma species with pathogenic fungi as well as plant hosts to promote crop protection.,Professor,Plant Pathology and Microbiology,https://scholars.library.tamu.edu/vivo/display/n8f925111
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
Hamed,Ali,Assistant Professor,"I am an Assistant Professor of Pharmaceutical Sciences at Texas A&M Rangel College of Pharmacy (RCOP). I obtained my Ph.D. at Okayama University, Japan, in 2007. Since that, I have acquired ample experience in drug discovery research.Several years of experience in designing, synthesizing, and biological screening of selective tyrosine kinase inhibitors (TKIs) and for targeting the aggressive HER2-resistant breast cancer by selective allosteric and orthosteric kinase inhibitors. Conducting a successful scholarly activity to attract substantial extramural/intramural funding support worth $3.2 Million (as a PI, CO-I, and Consultant) in the United States and the Middle East. Mentoring many undergraduate, graduate, and Pharm-D students exposing them to meritorious research opportunities. Publishing more than 60 peer-reviewed articles and serving as Ad hoc grants/journals reviewer for several national and international institutions. I have served as an ad hoc reviewer for many scientific journals, an active member of several scientific associations, and a Chair of the Admission Committee at RCOP. Moreover, I have extensive experience in teaching Medicinal Chemistry and Drug Design for more than 25 years. During my teaching capacities, I received an excellent evaluation from Pharmacy students to get the honor of ""Teacher of the Year"" in 2017 and ""Teaching Team of the Year"" from 2013 to 2017 at RCOP.",Assistant Professor,Pharmaceutical Sciences,https://scholars.library.tamu.edu/vivo/display/n92575b4f
Yossef,Elabd,Professor,,Professor||Faculty Affiliate,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n94839ce3
Robin,Young,Professor,"The Fuchs-Young laboratory studies the basic mechanisms of breast carcinogenesis, including the interaction (cross-talk) between the estrogen receptor alpha (ERa), IGF-1 and p53 signaling cascades. Our research utilizes a variety of unique in vivo and in vitro models, including transgenic and humanized mice. An underlying theme of our research is the discovery of bio-physiological determinants of disparities in breast cancer incidence and outcome. Another project focuses on the interdependent regulation of ER and p53, and the role of racially disproportionate p53 polymorphisms in mediating breast cancer development and progression. A new project in the laboratory project is focused on investigating the impact of exposure to metabolic syndrome during different stages of development on metabolic function and mammary cancer risk. This line of research was initiated, in part, due to the obesity epidemic in the US, and the increasing prevalence of obesity in younger children. Initial results show that manipulation of gestational, lactational and post-weaning diet can have very significant effects on susceptibility to mammary carcinogenesis.",Professor||Professor,Cell Biology and Genetics||Institute of Biosciences and Technology,https://scholars.library.tamu.edu/vivo/display/n948adb5d
Timothy,Phillips,Professor,food safety; molecular toxicology; elucidation of fundamental chemical mechanisms of toxic action/interaction of food-borne carcinogens; mutagens; and developmental toxicants; and development of methods to detect and detoxify foodborne and environmental toxins.,Professor,Veterinary Integrative Biosciences,https://scholars.library.tamu.edu/vivo/display/n94eef946
Shankararaman,Chellam,Professor,"Our research covers a wide spectrum of topics related to the transport, characterization, and removal of environmental colloids. We collaborate synergistically with microbiologists, chemical engineers, mathematicians, medical doctors, geologists, and other environmental engineers and scientists. In particular, we investigate two seemingly disparate topics; water purification (treatment of drinking water, industrial and municipal wastewater including hydraulic fracturing water, etc.) and tropospheric aerosols.",Professor,Civil Engineering,https://scholars.library.tamu.edu/vivo/display/n94ff0cee
Andreea,Trache,Associate Professor,"The research in my laboratory focuses on the study of cellular responses to mechano-chemical stresses from a biophysical perspective. Biophysics research represents an applied field of science at the interface of physics, biology, engineering, and medicine. Our lab uses live vascular cells as a model system because endothelial and smooth muscle cells reside 'in vivo' in a mechanically active environment that is continuously changing. Using real-time imaging of live cells is the only way to directly monitor cellular responses to mechano-chemical stimulation. Moreover, single-cell imaging experiments allow discrete measurements of transient microscopic events that may be masked by a macroscopic average behavior, and will aid in understanding such behavior.",Associate Professor,Medical Physiology,https://scholars.library.tamu.edu/vivo/display/n955af1bf
Jack,Waas,Lecturer,,Lecturer,Chemistry,https://scholars.library.tamu.edu/vivo/display/n956db11d
Ahmed,Abdel-Wahab,Professor,"Dr. Abdel-Wahab's primary focus is on chemical, electrochemical, and physical processes associated with treatment of water and wastewater, carbon dioxide conversion, and green hydrogen production from water splitting. This research has attracted significant external funding totaling more than $12M as the lead principal investigator and more than $6M as co-investigator. Abdel-Wahab's research has led to publication of more than 130 peer-reviewed articles in leading research journals, 9 book chapters, and more than 80 refereed conference publications/presentations. He is an editorial board member of the Journal of Water Process Engineering (Elsevier) and an associate editor of Emergent Materials Journal (Springer).","Technical Director, QWE||Faculty Affiliate||Professor||Professor",Civil Engineering||Texas A&M University at Qatar||Energy Institute||Chemical Engineering (Qatar),https://scholars.library.tamu.edu/vivo/display/n96a2a261
Wonmuk,Hwang,Associate Professor,,Associate Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n96f41d07
Terje,Raudsepp,Professor,"Comparative genomics and molecular cytogenetics of animals, birds and other vertebrates organization, function and evolution of sex chromosomes; equine genomics - genomics of genetic diseases and disorders of sexual development and reproduction; alpaca and camelid genomics.",Professor,Veterinary Integrative Biosciences,https://scholars.library.tamu.edu/vivo/display/n970d3a82
Vladislav,Yakovlev,Professor,,Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n97d166af
Larry,Suva,Professor and Head,"The development, control and diseases of the musculoskeletal system have been my scholarly interests for the past 35+ years. Understanding how the musculoskeletal system adapts and progresses throughout life is the basis of my expertise. My research focus has been the skeletal consequences of disease, such as breast cancer bone metastasis and multiple myeloma, fracture healing, osteoporosis, and most recently rare bone diseases. Current research efforts include a focus on utilizing in vivo models (murine and large animals) to discover regulatory pathways fundamental to bone physiology and the development of rare bone disease preclinical model(s) that may provide novel insight into future therapeutic directions. A critical aspect of my academic philosophy is an open door policy and the importance of one-on-one interactions. We must strive to provide training and exposure for our students as they prepare for careers both in and out of academic medicine and research. I emphatically believe that these teaching and mentoring experiences have shaped my scientific career and have helped mold my teaching and mentoring philosophy of placing the best professional, academic, social and personal development of faculty, students and staff above all else.",Professor and Head,Veterinary Physiology and Pharmacology,https://scholars.library.tamu.edu/vivo/display/n98338eea
Julie,Howe,Associate Professor,The main focus of my research program is to better understand the impact of soil management practices on the fate and transformations of nutrients and carbon in the soil and water. My goal is improve nutrient cycling and carbon storage in soils through better land management that is economically viable and environmentally responsible. Understanding transformations of nutrients and carbon in an agroecosystem is an important aspect of the research goal.,Associate Professor,Soil and Crop Sciences,https://scholars.library.tamu.edu/vivo/display/n990ca0e2
Hung-Jue,Sue,Professor,"To direct and conduct research on high performance functional materials for nanotechnology, biotechnology and micro-/nano-electronics packaging applications; surface damage phenomena of polymers; structure-property relationship in polymers, blends, polyolefin films, fiber-reinforced composites, adhesives and nanocomposites; strengthening & toughening of polymers; utilization of processing tools to enhance physical & mechanical properties of polymers.",Director||Faculty Affiliate||Professor,Energy Institute||Materials Science and Engineering||Polymer Technology Center,https://scholars.library.tamu.edu/vivo/display/n99a23a7c
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
Coran,Watanabe,Associate Professor,"Our research group is actively characterizing the biosynthetic genes of this pathway, which involves a variety of techniques and strategies including: cloning and overexpression of genes, disruption/knockout of genes, enzymology, as well as chemical synthesis/isotopic labeling studies. Functional characterization of the genes of the pathway will not only shed light on the mechanism of azabicycle formation but will also pave the way for genetic engineering of the pathway and the development of new therapeutic methodologies.
We have also been investigating the biosynthesis and cellular effects of cycloterpenals and their derivatives. Cycloretinal (all-trans retinal dimer), a representative member of this family of natural products is attributed to causing age-related macular degeneration (AMD). AMD is the leading cause of blindness in adults over the age of 50 that can lead to the loss of central vision. One of the most common early characteristic features of AMD (the dry form) is the accumulation of yellow deposits in the eye called drusen. A more severe form of the disease, the wet form, is characterized by neovascularization (abnormal blood vessel formation). Our research group aims to study the role of beta-lactoglobulin in cycloretinal synthesis in the eye as an environmental (dietary), non-genetic contributor of AMD. This involves tracking BLG in the eye, monitoring the formation of cycloretinal, and elucidating the mechanism of cycloretinal formation. Research strategies include: chemical synthesis, enzymology, fluorescence/confocal microscopy, PET imaging, dual modality OCT/fluorescence lifetime imaging.",Associate Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n9a83891f
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
Hung-Jen,Wu,Associate Professor,"Dr. Wu uses nanostructured materials and analytical tools to develop diagnostic techniques for medical applications. His laboratory recently focuses on understanding the influences of multivalency and cell membrane environment on pathogen-host cell recognition. The applications of his techniques include, infectious diseases screening, exploring cell membrane function, and targeted drug delivery.",Associate Professor,Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/n9cbcca3e
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
Roland,Kaunas,Associate Professor,"Dr. Roland Kaunas' laboratory focuses on the engineering of micro-tissues containing mesenchymal stem cells as vehicles for regenerating musculoskeletal tissues and as cell-based models for studying bone tumor biology. This work employs sophisticated microfluidic platforms, custom bioreactors, and novel scaffolding strategies involving composites of natural and synthetic polymers.
Kaunas' group also studies how mechanical stresses and strains, such as tensile stretch and fluid shear stress, regulate cell function in vascular tissues including arteries, capillaries and lymphatics. This work involves integration of experiments and theory to elucidate the roles of intracellular contractility, applied forces and scaffold material properties on cell architecture and transduction of mechanical stimuli into intracellular signals leading to changes in cell behavior.",Associate Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n9eb05d66
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
Marlan,Scully,Distinguished Professor,,Distinguished Professor||Faculty Affiliate,Physics and Astronomy||Energy Institute,https://scholars.library.tamu.edu/vivo/display/na2a37577
Patrick,Stover,Vice Chancellor and Dean,,Professor||Vice Chancellor and Dean,College of Agriculture and Life Sciences||Nutrition,https://scholars.library.tamu.edu/vivo/display/na2e4838e
Aravind,Krishnamoorthy,Assistant Professor,,Assistant Professor,Mechanical Engineering,https://scholars.library.tamu.edu/vivo/display/na6b7b2f5
Gregory,Reinhart,Professor and Head,"Our laboratory is interested in the mechanisms by which enzymes are regulated in the cell. In particular, we are interested in allosteric regulation of enzyme activity. Consequently, we are interested in understanding the nature of the conformational change in proteins that can be effected by the binding of ligands, and specifically how these changes alter the catalytic behavior of enzymes subject to allosteric regulation. We endeavor to investigate properties that are complementary to those determined by x-ray crystallography in order to develop a comprehensive picture of the structure-function relationships involved in the regulatory phenomenon. For example, we are interested in how the dynamics of protein structure might dictate the nature of an allosteric effect. Techniques and approaches that we use in the laboratory include analysis of enzyme kinetics; analysis of the thermodynamics of enzyme-ligand interactions; time-resolved and steady-state fluorescence spectroscopy; analysis of the effects of temperature and hydrostatic pressure (up to 4 kbar) on enzyme properties, site-specific mutagenesis, isothermal titration calorimetry, and molecular graphics.",Professor and Head,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/na6e2a0db
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
M. Katherine,Banks,President,,President||Distinguished Professor,Civil Engineering||Office of the President,https://scholars.library.tamu.edu/vivo/display/na92cc165
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
Yang,Shen,Associate Professor,"My main motivation is to unravel molecular mechanisms and to modulate emergent behavior of biomolecular networks with the development and application of computational tools (including molecular modeling, network simulation, optimization, machine learning, graph theory, and systems and control theory). To that end, I aim at an iterative process that models and experiments can feed each other.",Faculty Affiliate||Associate||Assistant Professor,Energy Institute||Electrical and Computer Engineering||Aggie STEM,https://scholars.library.tamu.edu/vivo/display/naee36a69
Lisa,Perez,Director for Advanced Computing Enablement,,Associate Director,Texas A&M High Performance Research Computing,https://scholars.library.tamu.edu/vivo/display/naf9f7163
Kranthi,Mandadi,Associate Professor,"World-wide, pathogens, insects and abiotic stresses cause major losses to agricultural production and productivity. Our lab employs integrated approaches for basic and translational studies of crop stress responses in model and crops. We are using the latest genomics, genetics, and bioinformatics tools to study plant stress responses to diverse plant biotic and abiotic stress conditions, as well as enhance their stress tolerance using biotechnology and breeding tools.",Associate Professor||Associate Professor,Plant Pathology and Microbiology||Texas A&M AgriLife Research,https://scholars.library.tamu.edu/vivo/display/nb05fab89
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
Gregg,Wells,Associate Professor,"The general theme of the research in my laboratory is the role of protein structure in disease, particularly in neurological disease. One area of study is the structure and function of the superfamily of neurotransmitter-gated ion channels that includes nicotinic acetylcholine, serotonin 5HT3, glycine, and GABAA receptors. Members of this superfamily are involved in drug addiction and alcoholism, neurodegenerative diseases such as Alzheimer disease and Parkinson disease, genetic forms of epilepsy, and neuropsychiatric disorders such as schizophrenia and depression. We are developing new approaches to elucidating the molecular structures of these ion channels from animals and bacteria. Cyclic nucleotide gated channels (CNGCs) are a second area of study. We are interpreting their electrophysiological properties in terms of structure and thermodynamics. Hearing is a third area of study. We are using computational models of calcium and potassium ion channels and mechanotransduction to explain electrophysiological function of cochlear hair cells. Fourth, analysis of genomes and tissue-specific transcriptomes of electrogenic animals (e.g., electric fish) is expected reveal new aspects of lifecycles of ion channels. Explaining neurological diseases in terms of protein structure is a theme linking our neuroscience research with neuropathology, my medical specialty.",Associate Professor,Cell Biology and Genetics,https://scholars.library.tamu.edu/vivo/display/nb25f91ff
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
Mustafa,Akbulut,Associate Professor,"The Akbulut Lab is involved in research in various areas of nanotechnology, surface and interface science, with a special focus on the areas of drug delivery, biomedical interfaces, tribology, surface and intermolecular forces, colloidal stabilization, and crystallization.",Associate Professor||Faculty Affiliate||Associate Professor,Energy Institute||Chemical Engineering||Materials Science and Engineering,https://scholars.library.tamu.edu/vivo/display/nb5e5f93d
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
Warren,Zimmer,Scott Exter Professor,"Our research interests are directed towards understanding the complex mechanisms which regulate the expression of specific gene sequences in development. We have focused our studies upon the factors that influence the smooth muscle component of the developing gastrointestinal (G.I.) tract. It has been shown that smooth muscle cells are predominantly derived from mesodermal precursor cells, however the factors regulating the selection of the smooth muscle myogenic pathway is not well defined.",Scott Exter Professor,Medical Physiology,https://scholars.library.tamu.edu/vivo/display/nb6da0749
Joseph,Awika,Professor,"Dr. Awika's broad interest is in developing technologies that maximize the ability of food to protect humans against chronic disease. His research focuses on the chemistry behind the behavior and properties of specific micro (polyphenols) and macro (starch and proteins) food constituents derived from grains. The interactions of the starch and proteins with the polyphenols, and how these interactions affect the rheological and biologically relevant properties of the molecules are of interest. How the structure of the polyphenols can be used to predict and manipulate their chemical behavior and function in food systems, as well as predict their interactions relevant inflammatory response in biological models is a major area of focus.
Dr. Awika's research involves multidisciplinary and international collaborations with geneticists, nutritional biochemists, agronomists, plant breeders, among others, from around the world.",Professor||Professor,Soil and Crop Sciences||Nutrition,https://scholars.library.tamu.edu/vivo/display/nb760602b
Renyi,Zhang,University Distinguished Professor,"Our research has covered a wide variety of areas in atmospheric chemistry and physics and, in particular, the impacts of global air pollution on human health, ecosystems, and climate.",University Distinguished Professor,Atmospheric Sciences,https://scholars.library.tamu.edu/vivo/display/nb7e95563
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
Duane,Kraemer,Senior Professor - Term Appointment,,Senior Professor - Term Appointment,Veterinary Physiology and Pharmacology,https://scholars.library.tamu.edu/vivo/display/nb976606f
Rhonda,Miller,Professor,,Professor,Animal Science,https://scholars.library.tamu.edu/vivo/display/nb97c5e3d
Roula,Mouneimne,Research Professor,"For the past 24 years my research focused on: 1- The development of methods in the fluorescence microscopy field that achieve data acquisition and analysis in real time, quantitative analysis, and mathematical modeling of cellular signaling. 2- The development of novel technological tools to decipher molecular and physiological events in cells and immunological tissues under normal toxin exposure and disease conditions.",Research Professor,Veterinary Integrative Biosciences,https://scholars.library.tamu.edu/vivo/display/nbb6c8c2a
Paul,Derry,Assistant Professor,,Assistant Professor,Institute of Biosciences and Technology,https://scholars.library.tamu.edu/vivo/display/nbc3878a6
Carl,Tong,Associate Professor,"Cardiovascular disease remains as the number one cause of mortality. About 50% of heart failure patients will perish in five years. At age 40, lifetime risk of developing heart failure is one in five. Diastolic dysfunction heart failure prevalence has increased to 50% of all heart failure. In this context, My research is dedicated to elucidating underlying mechanisms and translating discoveries to new treatments.",Associate Professor,Medical Physiology,https://scholars.library.tamu.edu/vivo/display/nbf050ef5
Leslie,Cizmas,Instructional Assistant Professor,"My research focuses on the occurrence and toxicity of drinking water contaminants, health effects of complex mixtures, and chemical exposure assessment in underserved communities.",Assistant Professor,Environmental and Occupational Health,https://scholars.library.tamu.edu/vivo/display/nbfad6806
Clint,Magill,Professor,"The use of molecular probes is allowing us to gain new insights into fungal plant pathogens and to host responses to potential pathogens. We are currently developing real-time PCR primers for two downy mildews that are considered to be a threat to maize production if introduced into the US. We are also developing PCR-based tags genes for resistance to headsmut, anthracnose, downy mildew and grain mold in sorghum. These molecular tags will be useful for breeding cultivars with more durable resistance and for cloning specific resistance genes. We have also used PCR to clone segments of the cotton and sorghum equivalents of genes that function in known host defense pathways. These clones are being used to compare the rate and timing of induction of each gene in resistant and susceptible lines following inoculation with a pathogen. Genome wide association studies are being used to identify genes associated with disease response (susceptible or resistant) to several pathogens in sorghum.",Professor,Plant Pathology and Microbiology,https://scholars.library.tamu.edu/vivo/display/nc127cd28
Raghavan,Srinivasan,Professor,"R. Srinivasan, Ph.D. is a professor at Texas A&M University and director of the Spatial Sciences Laboratory at Texas A&M. He has become known and respected throughout the world for his developmental work with spatial sciences and computer-based modeling, especially the Soil and Water Assessment Tool or SWAT model. His research and its applications have contributed to long-lasting changes in natural resource assessments and development of management system options, currently being used in more than 90 countries.",Resident Director||Professor||Professor||Professor,Biological and Agricultural Engineering||Ecology and Conservation Biology||Temple Research and Extension Center||Temple Research and Extension Center,https://scholars.library.tamu.edu/vivo/display/nc1342d14
Dai,Lu,Associate Professor,"The Lu laboratory is a medicinal chemistry laboratory working in the interface of organic chemistry and pharmaceutical sciences. The lab is engaged in the discovery of potential therapeutics for the treatment of cancer, neurodegenerative diseases and various disorders associated with the endocannabinoid system such as pain, drug-addiction and obesity. The current research projects in the Lu lab include the synthesis of water-soluble analogs of natural products such as taxanes and cannabinoids; the synthesis of various pharmacologically important cannabinoid ligands including agonists, inverse agonists, and allosteric modulators; the synthesis of novel protein kinase inhibitors to regulate the Abelson kinases (ABLs) and cyclin dependent kinases (CDKs). The Lu lab is also interested in the preparation and fabrication of multi-drug-loaded nanoparticles to tackle the deadly pancreatic cancer. These research projects have been funded by National Institute of Health and the State of Texas. Dr. Lu's contributions in medicinal chemistry include the discovery of the first type of intrinsically fluorescent ligands for the G-protein-coupled receptor CB1 and CB2, the discovery of one of the first two selective agonists for the CB2 cannabinoid receptor, the discovery of water-soluble cannabinoids, the discovery of a novel class of protein kinase inhibitors, and the discovery of a clinical drug candidate Buagafuran.",Associate Professor,Pharmaceutical Sciences,https://scholars.library.tamu.edu/vivo/display/nc1a05f94
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
Nicholas,Sears,Instructional Assistant Professor,,Instructional Assistant Professor,College of Engineering,https://scholars.library.tamu.edu/vivo/display/nc6e4970a
Osvaldo,Gutierrez Santacruz,Associate Professor,,,,https://scholars.library.tamu.edu/vivo/display/nc719ab3d
Xin,Yan,Assistant Professor,"At the Yan lab, we seek to develop and apply novel mass spectrometric methodologies in disease diagnosis, reaction monitoring, and development of new synthetic methods. In particular, we are motivated by the possibility of enabling new technology for next-generation approaches to precision medicine, and sustainable synthesis.
Our research interests span a range of topics, including i) metabolomics in brain research: we couple dual imaging modality (mass spectrometry imaging and fluorescence imaging) with liquid chromatography mass spectrometry to discover biomarkers and elucidate their biological mechanism in brain aging and brain cancer research. ii) point-of-care diagnostics: we are interested in the development of ambient ionization for fast analysis of enzymatic biomarkers, as well as the design and development of the interface to mini-mass spectrometer (mini-MS) for point-of-care diagnosis. iii) microdroplet reaction: mass spectrometry is universally considered as an analytical tool, however, its new feature was discovered: its use as a unique tool in synthesis. The uniqueness represents in its capabilities of dramatical acceleration of organic reactions and the driving of reactions that cannot occur in bulk. We aim to develop microdroplet reactors for acceleration, explore new reactivity, and study fundamentals of microdroplet acceleration. iv) reaction mechanistic study: reaction mechanisms play an essential role in the study of organic chemistry. We aim to develop new online mass spectrometric reaction monitoring system to explore unknown reaction mechanism, capture short-lived intermediates, study kinetics of fast reactions, and control process of active pharmaceutical ingredient (API) synthesis. The central theme of all the topics above is about droplet chemistry.
This lab is a highly interdisciplinary research group. It provides students the opportunity to obtain hands-on experience in analytical, biological and synthetic chemistry.",Assistant Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/nc863cc6e
Ian,Murray,Instructional Associate Professor,,Instructional Associate Professor,Medical Physiology,https://scholars.library.tamu.edu/vivo/display/nc97a73f1
Zhilei,Chen,Associate Professor,"The Chen Medicinal Protein Lab aims to accelerate the discovery, development and clinical translation of protein therapeutics through innovative protein engineering research. We believe that better medicine enables a higher quality of living, and protein engineers are charged to create the better medicine for today and tomorrow. We are particularly interested in the creation and engineering of affordable protein therapeutics to prevent and treat infectious diseases and cancer.",Associate Professor,Microbial Pathogenesis and Immunology,https://scholars.library.tamu.edu/vivo/display/nc9a6c3ae
Paul,Lindahl,Professor,"One of our two current research areas involves iron metabolism in mitochondria. The iron imported into these organelles is assembled into iron-sulfur clusters and heme prosthetic groups. Some of these centers are exported into the cytosol, while others are installed into mitochondrial apo-proteins. All of these processes are regulated in healthy cells, but various genetic mutations giving rise to diseases can cause iron to accumulate (e.g. Friedreich's ataxia) or become depleted (e.g. Sideroblastic anemia). We have developed a biophysical approach involving Mossbauer, electron paramagnetic resonance, and electronic absorption spectroscopy, to study the entire iron content of intact mitochondria in healthy and genetically altered cells. This Systems Biology approach allows us to characterize the ""iron-ome"" of mitochondria at an unprecedented level of detail. We are also using analytical tools (e.g. liquid chromatography) to identify complexes that are involved in ""trafficking"" iron into and out of the organelle.
Our other research area involves mathematical modeling of cellular self-replication on the mechanistic biochemical level. We collaborate on this multidisciplinary NSF-sponsored project with a mathematician at the University of Houston (Professor Jeffrey Morgan). We have developed a modeling framework that facilitates such modeling efforts, and have designed a number of very simple and symbolic in silico cells that exhibit self-replicative behavior. Our minimal in silico cell model includes just 5 components and 5 reactions. A second generation model includes a more realistic mechanism of mitotic regulation. One novel aspect of our approach is that cellular concentration dynamics impact (and are impacted by) cellular geometry. By minimizing membrane bending energies, we are now calculating cell geometry during growth and division. Our results suggest that the ""pinching"" observed in real cells is enforced by cytoskeletal structures.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/nc9ce621b
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
Jonathan,Sczepanski,Assistant Professor,"Our primary research goals are to develop and apply novel tools for studying DNA damage in the context of chromatin and to explore new avenues for RNA-based therapeutics and diagnostics. By combining expertise in chemical biology, molecular biology, and molecular evolution, our lab addresses challenges associated with studying and targeting noncoding RNAs from a unique perspective. In addition, we utilize modern chemical biology techniques to develop designer chromatin systems for studying DNA damage. We are seeking motivated individuals who wish to gain experience in chemical biology, molecular biology, and in vitro evolution techniques.",Assistant Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/ncc157d6e
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
Jae,Cho,Assistant Professor,"Our research interests lie in the interface between biology and other areas of science (chemistry and physics). NMR is our primary tool for structural and biophysical analysis. We also extensively use other techniques including Circular Dichroism and Fluorescence spectroscopy, and Isothermal calorimetry. These biophysical analyses are corroborated by sophisticated engineering and tuning of target proteins using semi-synthetic chemical biology techniques, in addition to traditional molecular biology methods.",Assistant Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/ncfe16216
Xingmao,Ma,Associate Professor,,Associate Professor,Civil Engineering,https://scholars.library.tamu.edu/vivo/display/nd2874fb7
Akhilesh,Gaharwar,Professor,"Dr. Akhilesh K. Gaharwar is a professor in the Department of Biomedical Engineering at Texas A&M University. He received his Ph.D. in Biomedical Engineering from Purdue University in 2011 and completed his postdoctoral training from Massachusetts Institute of Technology (MIT) and Harvard University. The goal of his lab is to understand the cell-nanomaterials interactions and to develop nanoengineered strategies for modulating stem cell behavior for repair and regeneration of damaged tissue. In particular, his lab is leveraging principles from materials science, stem cell biology, additive biomanufacturing and high throughput genomics to design nanoengineered biomaterials, with wide-ranging applications in the field of regenerative medicine. His lab has developed approaches to direct stem cells differentiation by modulating the biophysical and biochemical characteristics of nanoengineered biomaterials.",Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/nd2c66835
Mark,Holtzapple,Professor,"Our group is dedicated to the research and development of the sustainable and renewable technologies which, when implemented on a commercial scale, will impact future fuel, chemical, food, and water production.",Faculty Affiliate||Professor,Energy Institute||Chemical Engineering,https://scholars.library.tamu.edu/vivo/display/nd303ef41
Fen,Wang,Professor,"The laboratory focuses on understanding the molecular basis of cell signaling, and how aberrant cell signaling leads to birth defects and causes cancers. Using in vitro cell culture systems and in vivo mouse models, we study how the fibroblast growth factor (FGF) activates its receptor (FF) tyrosine kinase, and how the activated FF transmits the signals to downstream targets and regulates proliferation, differentiation, homeostasis, and function of the cells, as well as in organogenesis and development, including prostate and cardiovascular system development. The laboratory also employs molecular biology, cell biology, and mouse genetic technologies to study how aberrant FGF signals promote tumor initiation, progression, and metastasis. In addition, how environmental factors contribute to tumorigenesis and congenital birth defects by modulating FGF signal intensity and specificity is also under the scope of our research interests.",Professor,Institute of Biosciences and Technology,https://scholars.library.tamu.edu/vivo/display/nd5ef47ba
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
Terry,Gentry,Professor,"My research focuses on the development and use of molecular technologies to enhance the detection and remediation of environmental contamination. This includes the detection and identification of microbial pathogens from animal, human, and natural sources and also the characterization of microbial populations and communities contributing to applied remediation processes such as the bioremediation of organic and metal contaminants.",Professor,Soil and Crop Sciences,https://scholars.library.tamu.edu/vivo/display/nd695d1d9
Mehrdad,Ehsani,Professor,"I conduct research in the areas of sustainable power and energy systems, power electronics, motor drives, electric and hybrid vehicles, Superconductive Magnetic Storage (SMES), aerospace power systems, specialized power systems, control systems, energy storage systems, High Voltage Direct Current (HVDC) Power Transmission, applications of microcomputers to power control, pulsed power systems, and high voltage engineering and electrical failures and hazards.",Professor||Faculty Affiliate,Energy Institute||Electrical and Computer Engineering,https://scholars.library.tamu.edu/vivo/display/nd6df91de
Yun,Huang,Associate Professor,"Dr. Huang is currently an Assistant Professor at the Center for Epigenetics and Disease Prevention, Institute of Biosciences & Technology, Texas A&M University. Her long-term goal is to elucidate the molecular basis of epigenetic changes in the human genome and to develop novel therapies by targeting aberrant DNA methylation and demethylation associated with human diseases, including cancer, immunoinflammatory and cardiovascular diseases.
Dr. Huang's laboratory is focused on elucidating the physiological and pathophysiological functions of TET2 protein and its 5-methylcytosine oxidation products (5hmC, 5fC and 5caC) in cancer and development (Nature Genet 2014; Trends in Genetics 2014).",Associate Professor,Institute of Biosciences and Technology,https://scholars.library.tamu.edu/vivo/display/nd7ed0926
Karl,Kaiser,Assistant Professor,,Assistant Professor,Marine Sciences,https://scholars.library.tamu.edu/vivo/display/nd9c9c762
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
Matt,Pharr,Associate Professor,"My current areas of interest include mechanics of materials for energy storage and conversion, deformation and fracture of soft materials, mechanics of flexible/wearable electronics, coupled electro-chemo-mechanics, and mass transport in materials.",Associate Professor||Faculty Affiliate,Mechanical Engineering||Energy Institute,https://scholars.library.tamu.edu/vivo/display/ne059f41f
Michael,Manson,Professor,"Bacteria have a limited behavioral repertoire. Their most conspicuous behavior is chemotaxis - the pursuit of molecules that are favorable to acquire and the avoidance of chemicals that are best to avoid. The simplicity of bacterial motility and chemotaxis and the amenability of the model species Escherichia coli to genetic, biochemical and physiological manipulation have facilitated rapid advances in understanding the molecular mechanisms of biological energy conversion and signal transduction.
Our laboratory studies the inputs and outputs of chemotaxis. Ligands interact with the periplasmic receptor domain of a chemotactic signal transducer that spans the cell membrane. This interaction is converted into an intracellular signal that is communicated to the flagella. Molecules can be sensed either by binding directly to a receptor or by first interacting with a periplasmic binding protein, which then interacts with a receptor.",Professor||Professor,Biology||Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/ne190242a
Lei,Fang,Associate Professor,"The multi-disciplinary research programs in the Fang Group will focus on the bottom-up synthesis and processing of novel organic polymer materials -- namely, ladder and coplanar polymers, as well as microporous polymer networks -- for the applications on electronics and energy conversion/storage. Our thrust will be to gain profound understanding on the structure-property relationship of these materials at both the molecular and the macroscopic levels by employing the toolboxes of synthetic chemistry and device engineering. With this knowledge, we aim to establish a series of synthetically feasible, high performing, processable organic carbon-based material systems for field effect transistors, light emitting diodes, solar cells, supercapacitors, and batteries, and to be at the forefront in the enhancement of their efficiencies.",Faculty Affiliate||Associate Professor||Associate Professor,Energy Institute||Materials Science and Engineering||Chemistry,https://scholars.library.tamu.edu/vivo/display/ne3bd8752
Susanne,Talcott,Professor,"Dr. Susanne Talcott's research revolves around botanical compounds (polyphenols, terpenoids and alkaloids) and the impact of their metabolites on inflammation, cognitive function, and intestinal health. She primarily focuses on conducting human clinical studies to understand the pharmacokinetics and pharmacodynamics of these compounds.
Recently, the impact of bioactive metabolites produced by the gut microbiota on intestinal and cognitive health through the gut-brain axis has been of great interest.
Dr. Susanne Talcott is working on federally funded projects (USDA, NIH) and collaborates with the dietary supplement and functional food industry on health-related product claims that are supported by unbiased scientific evidence and comply with FDA- and FTC-regulations.",Professor||Professor,Food Science and Technology||Nutrition,https://scholars.library.tamu.edu/vivo/display/ne4324c37
Robert,Taylor,Research Professor,,Research Professor,Veterinary Integrative Biosciences,https://scholars.library.tamu.edu/vivo/display/ne49b235c
Alejandro,Castillo,Associate Professor,"Dr. Castillo's research interests include the development of control measures for minimizing and reducing pathogens in fresh and fresh-cut food products, the bacterial reduction on beef and pork products and fresh produce by sanitizing rinses and the use of electron beam irradiation for food safety purposes. He has published numerous articles in peer-reviewed journals, has authored or co-authored six book chapters and has published two books as editor. He teaches the graduate course in Microbiology of Foods and co-teaches the HACCP stacked course.",Associate Professor||Associate Professor,Animal Science||Nutrition,https://scholars.library.tamu.edu/vivo/display/ne6e976cb
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
Chao,Tian,Associate Professor - Term Appoint,,Associate Professor - Term Appoint,Electrical and Computer Engineering,https://scholars.library.tamu.edu/vivo/display/ne78dd90b
Michael,McShane,Professor and Department Head,,Professor,Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/ne7c17cfc
Hays,Rye,Associate Professor,"A fundamental principle of biology is the use of chemical energy in the form of ATP to assemble, disassemble and alter macromolecular structure. Specialized control proteins known as molecular chaperones are often responsible for this activity and have been recognized in recent years to be essential for regulating many aspects of cellular biology. Using a variety of biophysical and biochemical techniques, the Rye lab focuses on three fundamental cellular processes that require molecular chaperones: (1) protein folding (2) protein disaggregation and (3) vesicle trafficking. In each of these cases, large quantities ATP are burned, resulting in molecular organization in the case of protein folding, and molecular disassembly and remodeling in the case of protein disaggregation and vesicle trafficking. We are interested in understanding the detailed biophysical mechanisms that underpin these events. Why are these processes so energetically expensive? Are there any similarities in how the energy is used between these very different molecular processes? Are there general principles of energy transduction in biology that can be gleaned by comparing these examples with other molecular machines, such as cytoskeletal motors? Understanding how molecular chaperones control protein and membrane organization will provide key insights into not only basic cell biology, but will also illuminate aspects of many diseases that spring from aberrant protein and membrane dynamics.",Associate Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/ne7fb85e1
Jeffrey,Cirillo,Professor,"Our laboratory is interested in the pathogenesis of bacterial lung infections particularly tuberculosis and Legionnaires' disease. We are examining the virulence mechanisms of bacteria using cellular, molecular and genetic techniques. Our primary research goal is to obtain a better understanding of the roles of the pathogen and host in disease. These studies should contribute to our understanding of host-pathogen interactions at the molecular and cellular level that can be used for prevention, treatment and diagnosis. We hope that through a better understanding of the mechanisms by which these organisms cause disease we can prevent some, if not all, of these infections in the future.",Professor||Director,Microbial Pathogenesis and Immunology||Center for Airborne Pathogen Research and Tuberculosis Imaging,https://scholars.library.tamu.edu/vivo/display/ne8bc1122
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
Wayne,Versaw,Professor,"Compartmentalization of metabolic pathways and other cellular functions is a hallmark of eukaryotic cells. This feature is extreme in plants due to the presence of organelles not found in most other eukaryotes - plastids. Plastids are a diverse group of interrelated organelles that perform a wide range of metabolic functions including photosynthesis, nitrogen and sulfur assimilation and the synthesis of amino acids, starch and fatty acids. These functions are coordinated with metabolic processes in the cytosol through dynamic exchange of metabolites and ions across the plastid inner envelope membrane.
My lab is studying phosphate (Pi) transport processes that link the metabolic pathways in the plastid and cytosol. The concentrations of Pi in the cytosol and plastid stroma influence photosynthesis and the partitioning and storage of fixed carbon. Transporters involved in the movement of Pi across the plastid inner membrane include members of the pPT, PHT2 and PHT4 families. We are using genetics, cell biology, biochemistry and molecular physiology to investigate the function and physiological roles of these transporters. Recent findings suggest that some members of the PHT4 family are targeted to chloroplasts, whereas others function in heterotrophic plastids and one resides in the Golgi apparatus.
Other projects in the lab include the genetic and biochemical characterization of Pi transport processes in the filamentous fungus Neurospora crassa. Mutants with altered phosphate uptake properties have been isolated, and these have led to the identification of Pi transporter genes, as well as genes with putative regulatory functions.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/nea6b0d01
Ryland,Young,Professor,"Most bacterial viruses (phages) cause lysis of their host cell to release the progeny virions. Large phages elaborate an enzyme (""endolysin"") to degrade the cell wall and also a small membrane protein (""holin""). The holin accumulates in the membrane and then, at a precisely scheduled time, suddenly forms a hole to allow release of endolysin through the cytoplasmic membrane to gain access to the wall. We use molecular genetics and biochemistry to study how this small protein is able to act as a molecular ""clock"" and punch holes in membranes. Small phages make single proteins which cause host lysis in a different way. This strategy is to target the host cell wall synthesis machinery; that is, the virus makes a ""protein antibiotic"" that causes lysis in the same way as antibiotics like penicillin by inhibiting an enzyme in the multi-step pathway of murein biosynthesis. Thus, when the infected cell tries to divide, it blows up, or lyses, because it can't make the new cell wall between the daughter cells. Remarkably, each of three different, small phages blocks a different step in the pathway. These small lysis proteins are models for a completely new class of antibacterial antibiotics. Also, the E. coli SlyD protein is required for this mode of lysis in one case. SlyD is a member of an ubiquitous family of proteins related to human ""immunophilins,"" the targets of immune-suppression drugs. We study SlyD to learn about the role of this class of proteins in biology.",Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/nea775348
Jeffrey,Bullard,Professor,,Professor,Civil Engineering,https://scholars.library.tamu.edu/vivo/display/neb4aaa75
Itza,Mendoza-Sanchez,Assistant Professor,"My research background is in mathematical and experimental models for studying transport, transformation and persistence of contaminants in the environment. I have focused my research in three principal areas: organics trapped and sorbed in soils as a source zone of groundwater contamination, physical and biological factors that control bioremediation of contaminated plumes in groundwater, and water balance modeling to quantify ground water - surface water interactions. Currently, I am working with emerging contaminants, specifically evaluating the persistence of heavy-metals in mining environments and predicting antibiotics transport in soils.",Assistant Professor,Environmental and Occupational Health,https://scholars.library.tamu.edu/vivo/display/nee608e2d
Stephen,Smith,Professor,"Dr. Smith teaches meat science, nutrition and physiological nutrition courses. He also conducts research on the growth and development of adipose tissue, particularly in the bovine species. He has investigated the limitation of cattle to marble and has used his background in molecular biology to investigate lipid metabolism in the bovine muscle.",Professor||Professor,Animal Science||Nutrition,https://scholars.library.tamu.edu/vivo/display/nee8e5966
Gerardo,Gold Bouchot,Professor,,Professor,Oceanography,https://scholars.library.tamu.edu/vivo/display/nefdcdfb5
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
John,Mullet,Professor,"Functional genomics, bioinformatics, and DNA chip technology are fundamentally changing research on biological systems. Knowledge of complete genome sequences and high resolution genome technology provide an extraordinary opportunity to understand complex biological processes and to relate detailed understanding of protein structure and biochemical mechanism to the function of whole organisms and biological systems in nature.
Our research team is helping to build genome maps and DNA diagnostic microarrays/chips for analysis of global gene expression and biodiversity. This new technology is being used to explore the molecular basis of several fundamental plant responses: (1) light responsive genetic systems that help protect plants from damage by high intensity UV/blue light; (2) genetic systems that allow plants to adapt to the environment; (3) genes and signal transduction pathways that help protect plants from insects and disease; and (4) genes that regulate plant development (flowering time, fertility restoration, chloroplast development/number).",Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/nf1c81fcb
Ed,Brothers,Professor,"Ed Brothers is an associate professor and the Science Program Chair whose research interests center on developing a practical quantum chemistry. To this end his work is primarily developing new and fast methods in density functional theory, as well as applying methods like this to molecular reaction barriers and solid band gaps.",Program Chair and Professor of Chemistry,Science (Qatar),https://scholars.library.tamu.edu/vivo/display/nf206a705
Paul,Hardin,Distinguished Professor,"A diverse array of organisms including prokaryotic and eukaryotic microbes, plants, and animals display daily rhythms in physiology, metabolism and/or behavior. These rhythms are not passively driven by environmental cycles of light and temperature, but are actively controlled by endogenous circadian clocks that are set by environmental cycles, keep time in the absence of environmental cues, and activate overt physiological, metabolic and behavioral rhythms at the appropriate time of day. This remarkable conservation of circadian clock function through evolution suggests that maintaining synchrony with the environment is of fundamental importance. Our understanding of the circadian clock is particularly important for human health and well-being. The clearest examples of circadian clock dysfunction are those that result in abnormal sleep-wake cycles, but clock disturbances are also associated with other ailments including epilepsy, cerebrovascular disease, depression, and seasonal affective disorder. The realization that disorders of the sleep-wake cycle such as Familial Advanced Sleep Phase Syndrome can result from alterations in clock gene function underscores the clinical importance of understanding the molecular organization of the circadian system.
Work in my laboratory focuses on defining the molecular mechanisms that drive circadian clock function in the fruit fly, Drosophila melanogaster. We previously found that the core timekeeping mechanism is based on core and interlocked transcriptional feedback loops. Our studies currently focus on (1) defining post-translational regulatory mechanisms that operate in the core loop to set the 24 hour period, (2) determining whether interlocked loops are important for circadian timekeeping and/or output, (3) understanding how circadian oscillator cells are determined during development, and (4) defining mechanisms that control rhythms in olfactory and gustatory physiology and behavior.",Distinguished Professor,Biology,https://scholars.library.tamu.edu/vivo/display/nf27056c4
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
Alexei,Sokolov,Professor,"Sokolov's research belongs to the broader field of atomic, molecular and optical physics. In particular, his work on molecular coherence, wherein an ensemble of molecules vibrate in unison, enabled remote detection of pathogens in real time. This achievement evolved from foundational work on maximal coherence preparation and usage, i. e. on tailoring light pulses to make a number of molecules vibrate in unison and then utilizing these coherent vibrations to control light. Sokolov's current research interests center around applications of molecular coherence to quantum optics, ultrafast laser science and technology, including generation of sub-cycle optical pulses with prescribed temporal shape and studies of ultrafast atomic, molecular, and nuclear processes, as well as applications of quantum coherence in biological, medical and industrial settings.",Professor,Physics and Astronomy,https://scholars.library.tamu.edu/vivo/display/nf872dbd9
David,Powers,Professor,"Catalysis lies at the heart of many unmet chemical challenges. Research efforts in our group focus on development of new catalytic chemistry to impact both chemical synthesis as well as chemical storage of solar energy. Projects span organic, organometallic, and inorganic chemistries and rely on the tools of modern synthetic chemistry and spectroscopy, as well as advanced characterization techniques supported at synchrotron X-ray sources. Representative research interests include: shape-selective catalysis, solar energy storage in organic solar-thermal flow batteries, and aerobic oxidation chemistry for C-H functionalization reactions. We are seeking students who wish to gain expertise in synthetic chemistry and reaction mechanism elucidation.",Professor||Faculty Affiliate,Energy Institute||Chemistry,https://scholars.library.tamu.edu/vivo/display/nfa6c8878
Ananya,Tiwari,ACES Faculty Fellow and Assistant Professor,"1) Dr. Tiwari broadly investigates how sense of belonging is shaped and influenced by identities, social structures, and experiences among marginalized communities. She further looks at issues related to measurement of social and emotional attributes cross-culturally.
2) The second strand of her research seeks to understand how programs and policies can enhance belonging for marginalized communities where she engages in policy-level analysis and program development. Additionally, she conducts process and impact assessments as part of evaluation using frameworks of culturally responsive evaluation and assessment (CREA).
Her emerging research interests are Artificial Intelligence in teaching and learning and belonging. She uses a mixed methods approach.",Aces Assistant Professor,Educational Psychology,https://scholars.library.tamu.edu/vivo/display/nfa8d259d
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
Darwin,Prockop,Professor,,Professor,Cell Biology and Genetics,https://scholars.library.tamu.edu/vivo/display/nfcfd0990
Magnus,Hook,Professor,"The primary interest of our laboratory is to try to understand the structural function of the extracellular matrix. Of particular interest is the study of the molecular mechanisms of microbial adhesion to host tissue. This process, which is believed to represent a critical initial step in the development of infections, involves specific cell-surface proteins that recognize and bind with a high affinity to components in the host tissue. Our goal is to decipher these events at a molecular level and, based on structural analysis of the interacting components, design new strategies to prevent and treat infections.",Regents & Distinguished Professor and Director,Center for Infectious and Inflammatory Diseases,https://scholars.library.tamu.edu/vivo/display/nfd8d37d6
Phillip,Kramer,Professor and Director,,Professor and Director,Biomedical Sciences,https://scholars.library.tamu.edu/vivo/display/nffafc708
Vijay,Singh,Distinguished Professor,"Surface-water Hydrology, Groundwater Hydrology, Hydraulics, Irrigation Engineering, Environmental Quality and Water Resources. Principal research topics have encompassed: 1. Watershed modeling, 2. Erosion and Sediment Transport in Upland Watersheds, 3. Streamflow Forecasting, 4. Dam Break Analysis, 5. Entropy-Based Modeling, 6. Network Design, 7. Groundwater Modeling, and 8. Hydrologic Impacts of Climate Change.",Professor,Biological and Agricultural Engineering,https://scholars.library.tamu.edu/vivo/display/nffd83e14