The overarching goal of this training program is to develop burgeoning scientists into future leaders in translational rehabilitation research who are specifically equipped to test and disseminate novel rehabilitative strategies that will alleviate functional impairment and compromised life quality in the face of chronic disease management. This goal will be met by taking advantage of an exceptionally rich institutional environment that offers myriad resources and a complementary and collaborative team of basic and clinical research mentors committed to training and career development. Predoctoral and postdoctoral trainees will benefit from two years of interdisciplinary training that carefully meld three core levels of scientific inquiry: i) cellular and molecular pathobiology of disease; ii) rehabilitation science and exercise physiology; and iii) rehabilitation medicine (i.e. clinical trials). Training ill occur in one of two areas of concentrated strength: 1) Neuromusculo- skeletal and Movement Disorders; or 2) Cardiopulmonary and Metabolic Diseases. Cross-cutting themes with training opportunities include cancer and aging. Predoctoral trainees will be selected from a highly competitive and diverse national pool of students admitted to either the Graduate Biomedical Sciences program or Rehabilitation Science program. Nationally recruited postdoctoral trainees will gain invaluable clinical and translational research training and career development via structured programs and courses sponsored by the Office of Postdoctoral Education and the Center for Clinical and Translational Science. Each trainee's primary mentor and Translational Mentoring Team will be drawn from expert program faculty in the Schools of Medicine (physiology, physical medicine & rehabilitation, neurology, cell biology, pathology, genetics, cardiology, geriatrics), Health Professions (physical therapy, occupational therapy, and nutrition sciences), Public Health (epidemiology), and Arts & Sciences (psychology). Together the trainee, mentor, and Translational Mentoring Team will craft an individual development plan, which will be approved and monitored semi-annually by the Executive Committee. The plan will include required and elective didactic courses, laboratory and clinical research, journal clubs, seminars, scientific presentations locally and at national meetings, and training in the responsible conduct of research. Learning to conduct and publish high-impact research will be a primary focus of the training program. Postdoctoral trainees will also profit from courses on grant writing and laboratory management. The program will grow from mentoring two predoctoral and two postdoctoral trainees in the first year to four of each annually, and will take advantage of well-established best practices for successful recruitment of underrepresented minorities and individuals with disabilities. As a top 25 NIH-funded academic medical center with over 80 state-of-the-art scientific core facilities and 25 University-wide, interdisciplinary reseach centers, the University of Alabama at Birmingham is remarkably well-positioned to cultivate truly translational scientists equipped to drive the field of rehabilitation medicine with cutting edge research.
The main goal of this training program is to develop highly competitive junior scientists into future leaders in rehabilitation research. This goal will be met by taking advantage of a rich academic environment that offers numerous resources and a complementary and collaborative team of basic and clinical research mentors committed to training and career development. The program will teach both predoctoral and postdoctoral trainees how to conduct, and the importance of, integrative research that spans from understanding disease at the cellular level to improving clinical rehabilitation practices.
|Warren, Jonathan L; Bulur, Sule; Ovalle, Fernando et al. (2017) Effects of acute hyperinsulinemia on skeletal muscle mitochondrial function, reactive oxygen species production, and metabolism in premenopausal women. Metabolism 77:1-12|
|Warren, Jonathan L; Gower, Barbara A; Hunter, Gary R et al. (2017) Associations of Mitochondrial Fatty Acid Oxidation with Body Fat in Premenopausal Women. J Nutr Metab 2017:7832057|
|Ford, Kristin J; Joop, Allen; Memon, Raima A et al. (2017) Pedestrian safety in patients with Parkinson's disease: A case-control study. Mov Disord 32:1748-1755|
|Stec, Michael J; Thalacker-Mercer, Anna; Mayhew, David L et al. (2017) Randomized, four-arm, dose-response clinical trial to optimize resistance exercise training for older adults with age-related muscle atrophy. Exp Gerontol 99:98-109|
|Hurt, Christopher P; Bamman, Marcas; Naidu, Avantika et al. (2017) Comparison of Resistance-Based Walking Cardiorespiratory Test to The Bruce Protocol. J Strength Cond Res :|
|McGinnis, Graham R; Tang, Yawen; Brewer, Rachel A et al. (2017) Genetic disruption of the cardiomyocyte circadian clock differentially influences insulin-mediated processes in the heart. J Mol Cell Cardiol 110:80-95|
|Kelly, Neil A; Wood, Kimberly H; Allendorfer, Jane B et al. (2017) High-Intensity Exercise Acutely Increases Substantia Nigra and Prefrontal Brain Activity in Parkinson's Disease. Med Sci Monit 23:6064-6071|
|Koentges, Christoph; Pepin, Mark E; Müsse, Carolyn et al. (2017) Gene expression analysis to identify mechanisms underlying heart failure susceptibility in mice and humans. Basic Res Cardiol 113:8|
|Loyd, Christine; Liu, Yanping; Kim, Teayoun et al. (2017) LDB1 Regulates Energy Homeostasis During Diet-Induced Obesity. Endocrinology 158:1289-1297|
|Brahma, Manoja K; Pepin, Mark E; Wende, Adam R (2017) My Sweetheart Is Broken: Role of Glucose in Diabetic Cardiomyopathy. Diabetes Metab J 41:1-9|
Showing the most recent 10 out of 23 publications