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23 - Technology for recovery after stroke

Published online by Cambridge University Press:  05 August 2016

Neville Hogan
Affiliation:
Massachusetts Institute of Technology
Hermano I. Krebs
Affiliation:
77 Massachusetts Ave, Bldg 3-137, Cambridge, MA02139, USA
Brandon R. Rohrer
Affiliation:
Sandia National Laboratories
Susan E. Fasoli
Affiliation:
77 Massachusetts Ave, Bldg 3-147, Cambridge, MA02139, USA
Joel Stein
Affiliation:
Spaulding Rehabilitation Hospital
Bruce T. Volpe
Affiliation:
The Burke Medical Research Institute
Michael P. Barnes
Affiliation:
University of Newcastle upon Tyne
Bruce H. Dobkin
Affiliation:
University of California, Los Angeles
Julien Bogousslavsky
Affiliation:
Université de Lausanne, Switzerland
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Summary

Introduction

Stroke continues to be the leading cause of disability in the USA and elsewhere, despite the success of preventive strategies. In fact, recent studies have reported an increase in the incidence of stroke (Broderick et al., 1998; Muntner et al., 2002) with close to five million stroke survivors in the USA alone. This trend is likely to continue, driven by many factors, notably increasing life expectancy, aging of the “baby boom” generation, and improved medical treatment to increase stroke survivability. However, 90% of stroke survivors are left with significant impairment and require therapy.

While the number of patients is growing, pressure to contain and reduce the cost of healthcare has grown even faster, prompting a reduction of the time and resources available for post-stroke treatment. This generates a pressing need for new approaches to increase the effectiveness and efficiency of therapy, and one promising approach is to create innovative technology for rehabilitation. In principle, technology may be applied broadly across the entire spectrum of impairments that result fromstroke: cognitive, affective, sensory, andmotor. However,motor deficits persist chronically in about half of stroke survivors (Gresham et al., 1979) and the following will focus on new technology for sensory–motor rehabilitation, in particular on robotic and information technologies.

Rehabilitation robots

In general, there are two broad classes of rehabilitation robot: those directed at recovery, attempting to reduce impairment and restore function, and those directed at compensation for disability. The latter is the older and more mature application. An excellent example is the wheelchair-mounted robot developed in the Netherlands (Verburg et al., 1996). This is an elegant design that can fold unobtrusively when not in use and provides extended reach and limited manipulation to a seated patient.

Though both approaches arguably assist the patient, the term “assistive technology” is traditionally reserved for the direct use of technology to compensate for disability. More recently, attention has turned from such direct assistance to a more indirect role, helping clinicians to help patients recover. Though they present greater technical challenges (see below), robots to aid recovery have the potential for greater positive impact on patients' quality of life. They may be used throughout the process of recovery, beginning before a patient has regained voluntary movement, perhaps even at the bedside; in principle, they may minimize or eliminate the need for assistance.

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Recovery after Stroke , pp. 604 - 622
Publisher: Cambridge University Press
Print publication year: 2005

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