The goal of this proposal is to attain support for a new Interdisciplinary Engineering Career Development Center in Movement and Rehabilitation Sciences created by a consortium of leading institutions in the field including Northwestern University, the Rehabilitation Institute of Chicago, University of California Irvine, University of North Carolina, Case Western Reserve University, Marquette University, Stanford University, and University of Delaware. The mission of the proposed program is to develop scholars with engineering and other quantitative backgrounds to become successful rehabilitation scientists in basic, translational and/or clinical research. This would be the only program of its kind to focus on engineering-trained investigators. The PIs believe that these individuals, who already possess strong quantitative, problem-solving, programming, signal analysis and mechatronics skills, are uniquely positioned to make a significant impact on the field of quantitative movement and rehabilitation sciences (MRS) and its translation to rehabilitative care. The proposed career development program seeks to provide scholars with: 1) In-depth understanding of rehabilitation patient-centered clinical problems;2) Career development opportunities and mentoring to broaden their MRS research and training;and 3) Mentoring in translational research to increase the impact of their work. The PIs will accomplish these goals by using a dual mentorship model with a senior engineering faculty member and a senior clinical rehabilitation faculty member. In addition, scholars will participate in sabbatical experiences where they can further their knowledge and research skills in rehabilitation and engineering laboratories. The participating institutions have a long and recognized history in the study of the neurobiology of movement behavior and dysfunction, rehabilitation robotics, sensory-motor neural machine interfaces, and musculoskeletal modeling and dysfunction. Extensive research is being performed in these areas, across the continuum, from basic animal and human studies focused on the control of movement and movement disorders, to the development of novel rehabilitation robotics interventions that address these movement disorders. This impressive array of established research programs will not only provide a fertile ground for the development of engineering scholars in the field of MRS, but will also foster the creation of new interdisciplinary and inter-institutional collaborations that will bring new discoveries to fruition. The PIs intend to supporta total of 4 scholars in year 1 of the career development program, and 8 scholars in subsequent years. The program will provide support for a total of two years for each scholar.

Public Health Relevance

As a result of wars, aging demographics, and the evolving needs of children with developmental and other disabilities, the number of individuals with movement disabilities continues to increase, revealing a dire need for developing more effective and efficient rehabilitation interventions. The proposed program will develop a new generation of movement and rehabilitation engineering scientists who can bridge the gap between the laboratory and the clinic. This program will have an impact on the future of rehabilitative care in the nation.

Agency
National Institute of Health (NIH)
Institute
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Type
Physician Scientist Award (Program) (PSA) (K12)
Project #
1K12HD073945-01
Application #
8384827
Study Section
Special Emphasis Panel (ZHD1-RRG-K (52))
Program Officer
Nitkin, Ralph M
Project Start
2012-09-01
Project End
2017-05-31
Budget Start
2012-09-01
Budget End
2013-05-31
Support Year
1
Fiscal Year
2012
Total Cost
$500,000
Indirect Cost
$37,037
Name
Northwestern University at Chicago
Department
Physical Medicine & Rehab
Type
Schools of Medicine
DUNS #
005436803
City
Chicago
State
IL
Country
United States
Zip Code
60611
Engdahl, Susannah M; Gates, Deanna H (2017) Reliability of upper limb and trunk joint angles in healthy adults during activities of daily living. Gait Posture 60:41-47
Park, S; Finley, J M (2017) Characterizing dynamic balance during adaptive locomotor learning. Conf Proc IEEE Eng Med Biol Soc 2017:50-53
Cowley, Jeffrey; Resnik, Linda; Wilken, Jason et al. (2017) Movement quality of conventional prostheses and the DEKA Arm during everyday tasks. Prosthet Orthot Int 41:33-40
Bigler, Rebecca L; Kamande, Joyce W; Dumitru, Raluca et al. (2017) Messenger RNAs localized to distal projections of human stem cell derived neurons. Sci Rep 7:611
Yandell, Matthew B; Quinlivan, Brendan T; Popov, Dmitry et al. (2017) Physical interface dynamics alter how robotic exosuits augment human movement: implications for optimizing wearable assistive devices. J Neuroeng Rehabil 14:40
Finley, James M; Bastian, Amy J (2017) Associations Between Foot Placement Asymmetries and Metabolic Cost of Transport in Hemiparetic Gait. Neurorehabil Neural Repair 31:168-177
Foltz, Mary H; Kage, Craig C; Johnson, Casey P et al. (2017) Noninvasive Assessment of Biochemical and Mechanical Properties of Lumbar Discs Through Quantitative Magnetic Resonance Imaging in Asymptomatic Volunteers. J Biomech Eng 139:
Jakubowski, Kristen L; Terman, Ada; Santana, Ricardo V C et al. (2017) Passive material properties of stroke-impaired plantarflexor and dorsiflexor muscles. Clin Biomech (Bristol, Avon) 49:48-55
Lawrence, Rebekah L; Ellingson, Arin M; Ludewig, Paula M (2017) Validation of single-plane fluoroscopy and 2D/3D shape-matching for quantifying shoulder complex kinematics. Med Eng Phys :
Choi, Hwan; Bjornson, Kristie; Fatone, Stefania et al. (2016) Using musculoskeletal modeling to evaluate the effect of ankle foot orthosis tuning on musculotendon dynamics: a case study. Disabil Rehabil Assist Technol 11:613-8

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