First name,Last name,Preferred title,Overview,Position,Department,Individual
Lucas,Timmins,Associate Professor,"Throughout my research career, I have been committed to applying engineering mechanics to address prevalent challenges in cardiovascular biology, physiology, and medicine. The broad scope of my research program is to understand the interactions between mechanics and cardiovascular disease, focusing on translating efforts and establishing disruptive technologies that advance patient management. I leverage my unique expertise in solid and fluid mechanics, across both the experimental and computational domains, to comprehensively characterize the mechanical stimuli vascular tissues are subjected to in the setting of health and disease. The two broad objectives of my research are 1) to advance the diagnosis, prognosis, and treatment of cardiovascular disease in the clinical setting and 2) to understand how mechanics drive the structure, function, and remodeling of vascular tissues.",Associate Professor||Associate Professor||Associate Professor,School of Engineering Medicine||Engineering Medicine||Biomedical Engineering,https://scholars.library.tamu.edu/vivo/display/n0fa92a82
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
Qian,Wang,Associate Professor,"Dr. Wang's earlier work focused on the comparative morphology of craniofacial skeletons of Mid Pleistocene hominin fossils. During his postdoctoral training, he was involved in a number of studies examining the internal structure of craniofacial bone and suture morphology and how it is related to skeletal growth, function and adaptation. His recent research focuses on the functional morphology and biomechanics of the craniofacial skeleton. He has incorporated a range of methods, including geometric morphometrics (e.g., 3D Euclidean Distance Matrix Analysis and Generalized Procrustes Analysis/GPA), experimental approaches (e.g., in vitro strain measurements and ultrasonic techniques), computer-aided modeling and biomechanical analysis ( e.g., Finite Element Analysis), as well as phenotypic analyses. He has worked intensively on the various primate skeletal collections and has developed protocols for data collection and analyses of museum skeletal collections. In addition, he is a member of a multi-institutional research team made up of anatomists and anthropologists who have specialized in various aspects of functional morphology in order to systematically reassess the reconstruction and biomechanical interpretation of the face of early human types, based on current morphological and phylogenetic evidence and advances in biomechanical methods.",Associate Professor,Biomedical Sciences,https://scholars.library.tamu.edu/vivo/display/n10bc652f
Raffaella,Righetti,Associate Professor,My research focuses on ultrasound methods for imaging the mechanical behavior of soft and hard tissues and multi-modal biomedical imaging processing and analysis methods.,Associate Professor,Electrical and Computer Engineering,https://scholars.library.tamu.edu/vivo/display/n2d847d81
Sherecce,Fields,Professor,"My research focuses on the trans-disease processes of cognitive and emotional dysregulation and how these factors affect health-risk behaviors in adolescents. Identifying trans-disease processes that contribute to the development or maintenance of multiple diagnostic categories -- that underlie both substance use and obesity -- can enhance the development of interventions that target the underlying process rather than specific symptoms of a single disorder. This not only provides a more efficient approach to treatment, it is particularly relevant to health disparities. I am especially interested in how these trans-disease processes interact with family, social, and psychological factors to increase engagement in health-related risk behaviors, and the development of appropriate prevention and intervention tools that can be used to improve health outcomes in youth. I conceptualize these processes in the context of physical and mental health disparities as they relate to stress, minority status (race/ethnicity, sexual orientation, gender) and socioeconomic factors (food insecurity).",Faculty Fellow||Professor||Associate Department Head||Faculty Affiliate||Associate Professor,Center for Health Systems and Design||Institute for Engineering Education and Innovation,https://scholars.library.tamu.edu/vivo/display/n9f216306
George,Perry,Associate Professor,,Associate Professor,Texas A&M AgriLife Research,https://scholars.library.tamu.edu/vivo/display/nacfdace6
Sarah,White-Springer,Dr,,Associate Professor||Associate Professor,Kinesiology and Sport Management||Animal Science,https://scholars.library.tamu.edu/vivo/display/nd387aff4
Zachary,Adelman,Professor,,Associate Professor,Entomology,https://scholars.library.tamu.edu/vivo/display/ndc81a8e5
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
Jerome,Menet,Associate Professor,"Most organisms from bacteria to humans exhibit 24-hours rhythms in their biochemistry, physiology and behavior. Best exemplified by the sleep/wake cycle, these rhythms are remarkably widespread and include in humans hormonal (e.g., melatonin, insulin, cortisol), metabolic (e.g., glucose, cholesterol), physiological and behavioral oscillations. In fact, most biological functions are rhythmic and are set to perform optimally at the most appropriate time of the day. For example, the human digestion process performs better during the day when we are supposed to eat.
These circadian rhythms are generated by ""molecular clocks"", which consist of a few ""clock genes"" interacting in feedback loops, and which drive the rhythmic expression of a large number of genes, i.e. ~10% of the transcriptome in any tissues. This wide impact of clock genes in regulating gene expression is underscored by the surprisingly large number of pathologies developed by clock-deficient mice. In addition to being arrhythmic, these mice indeed develop pathologies as diverse as mania-like behaviors, learning and memory defects, depression, drug addiction, insomnia, metabolic diseases, arthropathy, hematopoiesis defects and cancers.
Research in our lab aims at characterizing how circadian clocks and clock genes regulate gene expression to provide insights into how and why clock dysfuntion leads to a wide spectra of pathologies. To this end, we are using a wide-range of molecular and biochemical techniques to investigate the circadian clock function at the genome-wide level (e.g., next-generation sequencing). We are currently extending some of our recent results and focus on 1) how clock genes rhythmically regulate chromatin environment and 2) the mechanisms involved in rhythmic post-transcriptional regulation of gene expression.",Associate Professor,Biology,https://scholars.library.tamu.edu/vivo/display/nf680fb91