David A. Brown
Affiliations: | Northwestern University, Evanston, IL |
Area:
neural control of locomotion, spinal reflexesGoogle:
"David Brown"Mean distance: 16.59 (cluster 22) | S | N | B | C | P |
Parents
Sign in to add mentor| Carl G. Kukulka | grad student | University of Iowa | |
| Felix E. Zajac | post-doc | Stanford |
Children
Sign in to add trainee| Jamie Burgess | grad student | Northwestern | |
| Jing Nong Liang | grad student | Northwestern | |
| Lynn Marie Rogers | grad student | Northwestern | |
| Laila Alibiglou | grad student | 2010 | Northwestern |
| Carmen E. Capo-Lugo | grad student | 2013 | Northwestern |
| Deanna D Rumble | grad student | 2017 | The University of Alabama and The University of Alabama at Birmingham |
| Sarah Graham | grad student | 2018 | The University of Alabama and The University of Alabama at Birmingham |
| Avantika Naidu | grad student | 2019 | The University of Alabama and The University of Alabama at Birmingham |
| Rebecca Hennessy | grad student | 2020 | The University of Alabama and The University of Alabama at Birmingham |
| Sheila Schindler-Ivens | post-doc | Northwestern |
BETA: Related publications
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Publications
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| Cao S, Ko M, Li CY, et al. (2023) Single-Belt Versus Split-Belt: Intelligent Treadmill Control via Microphase Gait Capture for Poststroke Rehabilitation. Ieee Transactions On Human-Machine Systems. 53: 1006-1016 |
| Alhirsan SM, Capó-Lugo CE, Hurt CP, et al. (2023) The Immediate Effects of Different Types of Augmented Feedback on Fast Walking Speed Performance and Intrinsic Motivation After Stroke. Archives of Rehabilitation Research and Clinical Translation. 5: 100265 |
| Alhirsan SM, Capó-Lugo CE, Brown DA. (2021) Effects of different types of augmented feedback on intrinsic motivation and walking speed performance in post-stroke: A study protocol. Contemporary Clinical Trials Communications. 24: 100863 |
| Hennessy RW, Rumble D, Christian M, et al. (2020) A Graded Exposure, Locomotion-Enabled Virtual Reality App During Walking and Reaching for Individuals With Chronic Low Back Pain: Cohort Gaming Design. Jmir Serious Games. 8: e17799 |
| Naidu A, Graham SA, Brown DA. (2019) Fore-aft resistance applied at the center of mass using a novel robotic interface proportionately increases propulsive force generation in healthy nonimpaired individuals walking at a constant speed. Journal of Neuroengineering and Rehabilitation. 16: 111 |
| Graham SA, Roth EJ, Brown DA. (2018) Walking and balance outcomes for stroke survivors: a randomized clinical trial comparing body-weight-supported treadmill training with versus without challenging mobility skills. Journal of Neuroengineering and Rehabilitation. 15: 92 |
| Graham SA, Hurt CP, Brown DA. (2018) Minimizing Postural Demands of Walking While Still Emphasizing Locomotor Force Generation for Nonimpaired Individuals. Ieee Transactions On Neural Systems and Rehabilitation Engineering : a Publication of the Ieee Engineering in Medicine and Biology Society. 26: 1003-1010 |
| Naidu A, Brown D, Roth E. (2018) A Challenge-Based Approach to Body Weight-Supported Treadmill Training Poststroke: Protocol for a Randomized Controlled Trial. Jmir Research Protocols. 7: e118 |
| Mullens CH, Brown DA. (2018) Visual feedback during pedaling allows individuals post-stroke to alter inappropriately prolonged paretic vastus medialis activity. Journal of Neurophysiology |
| Rumble DD, Hurt CP, Brown DA. (2018) Step-by-step variability of swing phase trajectory area during steady state walking at a range of speeds. Plos One. 13: e0191247 |