Biomedical Engineering Reference
In-Depth Information
Dovat, L., Lambercy, O., Ruffieux, Y., Chapuis, D., Gassert, R., Bleuler, H., Teo, C. and
Burdet, E. (2006). A haptic knob for rehabilitation of stroke patients, in
2006 IEEE/RSJ
International Conference on Intelligent Robots and Systems
, pp. 977-982.
Fugl-Meyer, A. R., Jaask o, L., Leyman, I., Olsson, S. and Steglind, S. (1975). The post-
stroke hemiplegic patient. 1. a method for evaluation of physical performance,
Scand. J.
Rehabil. Med.
7
, 1, pp. 13-31.
Gowland, C., Stratford, P., Ward, M., Moreland, J., Torresin, W., Van Hullenaar, S., Sanford,
J., Barreca, S., Vanspall, B. and Plews, N. (1993). Measuring physical impairment and
disability with the Chedoke-Mcmaster stroke assessment,
Stroke
24
, pp. 58-63.
Henderson, A., Korner-Bitensky, N. and Levin, M. (2007). Virtual reality in stroke rehabilita-
tion: A systematic review of its effectiveness for upper limb motor recovery.
Top Stroke
Rehabil.
14(2)
, pp. 52-61.
Hesse, S., Schulte-Tigges, G., Konrad, M., Bardeleben, A. and Werner, C. (2003). Robot-
assisted arm trainer for the passive and active practive of bilateral forearm and wrist
movements in hemiparetic subjects,
Arch. Phys. Med. Rehabil.
84
, pp. 915-920.
Hogan, N., Krebs, H., Rohrer, B., Palazzolo, J., Dipietro, L., Fasoli, S., Stein, J., Hughes, R.,
Frontera, W., Lynch, R. and Volpe, B. (2006). Motions or muscles? Some behavioral
factors underlying robotic assistance of motor recovery,
Journal of Rehabilitation Research
and Development
45
, pp. 605-618.
Holden, M. (2005). Virtual environment for motor rehabilitation: Review,
Cyber Psychology
and Behavior
8(3)
, pp. 187-211.
Hunter, S. and Crome, P. (2002). Hand function and stroke,
Reviews in Clinical Gerontology
12
, pp. 68-81.
Johnson, M. (2006). Recent trends in robot-assisted therapy environments to improve real-
life functional performance after stroke,
Journal of Neuro-engineering and Rehabilitation
3
,
pp. 29-34.
Kamper, D., Fischer, H., Cruz, E. and Rymer, W. (2006). Weakness is the primary contributor
to finger impairment in chronic stroke,
Arch. Phys. Med. Rehabil.
87
, pp. 1262-1269.
Kawasaki,H.,Ito,S.,Ishigure,Y.,Nishimoto,Y.,Aoki,T.,Mouri,T.,Sakaeda,H.andAbe,
M. (2007). Development of a hand motion assist robot for rehabilitation therapy by
patient self-motion control,
Proc. of the IEEE Int. Conf. on Robotic Rehabilitation (ICORR)
,
pp. 234-240.
Krakauer, J. (2006). Motor learning: its relevance to stroke recovery and neurorehabilitation,
Current Opinion in Neurology
19
, pp. 84-90.
Krebs, H. I., Mernoff, S., Fasoli, S. E., Hughes, R., Stein, J. and Hogan, N. (2008). A
comparison of functional and impairment-based robotic training in severe to moderate
chronic stroke: A pilot study,
NeuroRehabilitation
23
, 1, pp. 81-7.
Krebs, H. I., Volpe, B. T., Williams, D., Celestino, J., Charles, S. K., Lynch, D. and Hogan,
N. (2007). Robot-aided neurorehabilitation: A robot for wrist rehabilitation,
IEEE
Transactions on Neural Systems and Rehabilitation Engineering
15(3)
, pp. 327-335.
Kwakkel, G., Kollen, B. J. and Krebs, H. I. (2008). Effects of robot-assisted therapy on upper
limb recovery after stroke: a systematic review,
Neurorehabil Neural Repair
22
, 2, pp.
111-21, doi:10.1177/1545968307305457.
Lambercy, O., Dovat, L., Gassert, R., Burdet, E., Teo, C. and Milner, T. (2007). A haptic knob
for rehabilitation of hand function,
IEEE Transactions on Neural Systems and Rehabilitation
Engineering
15
, 3, pp. 356-366.
Lambercy, O., Dovat, L., Johnson, V., Salman, B., Wong, S., Gassert, R., Milner, T., Teo, C. and
Burdet, E. (2007b). Development of a robot-assisted rehabilitation therapy to train hand
function for activities of daily living,
Proc. of the IEEE Int. Conf. on Robotic Rehabilitation
(ICORR)
, pp. 678-682.
