Dose has emerged as a key factor promoting functional recovery after stroke. Currently, a lack of data on the dose-response relationship impedes progress in the field of stroke rehabilitation. The goal of the proposed project is to define the range of doses of movement practice that produce the greatest improvements in outcomes in people with chronic stroke. Borrowing from animal models of stroke, dose in humans can be quantified by the number of repetitions of task-specific practice. Our central hypothesis is that there exists a range of doses for people with stroke, below which, there is minimal benefit, and above which, further practice does not result in further benefit. The range of beneficial doses is likely to vary based on the severity of motor deficits and the presence of non-motor deficits in other domains. Using a randomized, parallel dose-response design, we will evaluate the benefits of four different doses of task-specific upper extremity training with matched schedules of 1 hr sessions, 4 sessions/wk for 8 wks, in 100 people with chronic stroke. Total repetition doses to be evaluated (3200, 6400, 9600, &individualized-maximum) are based on our preliminary data. The individualized-maximum group may extend their sessions beyond 8 wks until meeting defined stop criteria. Our primary aim will test whether larger total doses result in better outcomes than smaller total doses. Benefits of the four doses will be evaluated at the impairment, activity, and participation levels, since understanding the dose-response relationship at all levels of measurement is critical for advancing rehabilitation research. We hypothesize that improvements will be greatest in the 9600 and individualized-maximum, followed by the 6400, and then the 3200 repetition dose groups. Our secondary aim is to characterize the dose-response relationship of upper extremity task-specific practice. With data from multiple assessment points, individual curve modeling will be used to estimate dose ranges, below which, there is minimal benefit, and above which, further practice does not result in further benefit. Furthermore, we will determine how various factors modify the dose estimates. We hypothesize that the severity of motor deficits will be the primary modifier of the dose- response relationship, with larger doses needed for those with more mild motor deficits. We further expect that needed doses will be larger for those with depression and hemispatial neglect. Our team is well-positioned to investigate the critical issue of dose because of our expertise in stroke rehabilitation research and measurement, our understanding of the challenges of clinical practice and clinical research, and our ready access to this patient population. Expected outcomes from this project are empirically-driven estimates indicating the dose of movement practice required to drive maximal improvements and how these estimates can be individually modified for people undergoing stroke rehabilitation. Our estimates will immediately impact rehabilitation research and clinical practice. The importance of this project transcends stroke rehabilitation;our primary results will be of high value to many other rehabilitation populations also impeded by the lack of knowledge regarding dose-response relationships.
Dose has emerged as a key factor promoting functional recovery after stroke. Currently, a lack of data on the dose-response relationship impedes progress in the field of stroke rehabilitation. This project will result in empirically-driven estimates indicating the dose of movement practice required to drive maximal improvements and how these estimates can be individually modified for people undergoing stroke rehabilitation. Our estimates will immediately impact translational and rehabilitation research as well as clinical practice.
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|Lang, Catherine E; Waddell, Kimberly J; Klaesner, Joseph W et al. (2017) A Method for Quantifying Upper Limb Performance in Daily Life Using Accelerometers. J Vis Exp :|
|Basso, D Michele; Lang, Catherine E (2017) Consideration of Dose and Timing When Applying Interventions After Stroke and Spinal Cord Injury. J Neurol Phys Ther 41 Suppl 3 Supp:S24-S31|
|Lang, Catherine E; Strube, Michael J; Bland, Marghuretta D et al. (2016) Dose response of task-specific upper limb training in people at least 6 months poststroke: A phase II, single-blind, randomized, controlled trial. Ann Neurol 80:342-54|
|Reinkensmeyer, David J; Burdet, Etienne; Casadio, Maura et al. (2016) Computational neurorehabilitation: modeling plasticity and learning to predict recovery. J Neuroeng Rehabil 13:42|
|Doman, Caitlin A; Waddell, Kimberly J; Bailey, Ryan R et al. (2016) Changes in Upper-Extremity Functional Capacity and Daily Performance During Outpatient Occupational Therapy for People With Stroke. Am J Occup Ther 70:7003290040p1-7003290040p11|
|Grattan, Emily S; Lang, Catherine E; Birkenmeier, Rebecca et al. (2016) Examining the Feasibility, Tolerability, and Preliminary Efficacy of Repetitive Task-Specific Practice for People With Unilateral Spatial Neglect. Am J Occup Ther 70:7004290020p1-8|
|Lohse, Keith R; Schaefer, Sydney Y; Raikes, Adam C et al. (2016) Asking New Questions with Old Data: The Centralized Open-Access Rehabilitation Database for Stroke. Front Neurol 7:153|
|Lohse, Keith; Bland, Marghuretta D; Lang, Catherine E (2016) Quantifying Change During Outpatient Stroke Rehabilitation: A Retrospective Regression Analysis. Arch Phys Med Rehabil 97:1423-1430.e1|
|Waddell, Kimberly J; Birkenmeier, Rebecca L; Bland, Marghuretta D et al. (2016) An exploratory analysis of the self-reported goals of individuals with chronic upper-extremity paresis following stroke. Disabil Rehabil 38:853-7|
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