Core & Sub-Concentration Areas
Neuromotor Control & Rehab Core Concentration
This core concentration area of study consists of two facets: neuromotor science and motor control. Neuromotor science refers to knowledge about brain anatomy, biology, and physiology in relation to movement and movement disorders. Relevant techniques for research might include brain imaging, transcranial magnetic stimulation, startle probes, peripheral nerve stimulation or electroencephalography each of which are available to the trainees. Motor control refers to knowledge about the principles of interaction between neural/physiological, biomechanical, behavioral and developmental systems underlying movement function and dysfunction that can inform rehabilitation assessments and interventions. Relevant techniques for research might include physiological and biomechanical analyses, adaptation and learning paradigms, and clinical tests of movement function. Students are expected to have a knowledge-base in both areas but the specific applications will depend on their research questions.
Applied Physiology Sub-Concentration
This area of research involves the study of basic biological processes in muscle physiology, metabolism and cardiovascular exercise using human and animal models. It will be a complementary area for those students who seek to investigate neuromotor rehabilitation in relation to peripheral muscle adaptation, to metabolic sequellae or to cardiovascular benefits from exercise and rehabilitation. All mentors in this area have a history of research relevant to rehabilitation/disability or aging. Trainees who wish to learn from this area will interact with trainees and resources from the Training Programs in Biology of Exercise and Aging and Muscle Biology located in the School of Medicine.
Rehabilitation Biomechanics Sub-Concentration
This complementary area of research involves the application of mechanical principles to biological systems. It is a natural complementary area for those who want to quantify movement and/or electromyographic signals in a rigorous way. These efforts lead to adeeper understanding of motor deficits as well as providing more precise measurements of rehabilitation outcomes. Opportunities to learn computational modeling are also available. After learning basic principles, trainees will have the opportunity to choose from a variety of motion analysis systems and task-specific experimental paradigms in six different biomechanically based laboratories that are actively undertaking neuromotor, aging and rehabilitation research.
This complementary area of research involves the study of the causes, treatments and prevention of disability using population-based data as well as data from smaller studies. Mentors in this area have expertise in biostatistics or in rehabilitation/disability and aging. This is a complementary area for those students who want to investigate neuromotor rehabilitation in relation to population-based/large data set research or in translational research taking laboratory rehabilitation methods into the community. Students will interact with trainees and resources from the Training Program in Epidemiology of Aging (Magaziner) located in the School of Medicine.
Rehabilitation Engineering Sub-Concentration
This is a complementary area that is rapidly developing and affords new opportunities to bring novel technologies and methods into Rehabilitation Science. In cooperation with the UM Pepper Center, VA Exercise & Robotics Center and the VA Robotics Cooperative studies that all support rehabilitation robotics this area of potential training involves relevant course work and interacting with engineers concerning the development of devices to augment both the evaluation and implementation of rehabilitative strategies targeting those with movement dysfunction. In addition, we have current collaborations with UMBC engineering and MIT as well as strong connections with UMCP, National Rehabilitation Hospital and Catholic University of America, Faculty, students and post-doctoral trainees are intimately involved in the development and testing of a variety of novel training devices employed in neuromotor rehabilitation research. Various robotic devices for the upper extremity are currently in use, ankle robotics are in the development and test phase, a bilateral upper arm training system designed and based on research by faculty is in production, and novel robotic devices for perturbation studies of balance and locomotion are being implemented and tested in funded research.