24 hemiplegic patients completed patterned functional electrical stimulation (PFES) upon the afflicted arm and leg. The multichannel PFES program was mathematically derived from the EMG agonist/antagonist pattern recorded from each subject's unaffected limbs during a series of monitored, voluntary movements. The average improvement in volitional range of motion for the group's paralyzed limbs was 90% for the upper extremities and 69% for the lower extremities. For partially paralyzed limbs, there was an average increase in range of movement of 68% for the upper extremities and 26% for the lower extremities. These findings support the relearning-based, PFES open-loop theory which uses individualized therapeutic PFES-derived from EMG coordination patterns modeled from specific, ballistic limb movements to rehabilitate patients who have been immobilized after stroke.
References
1.
American Heart Association. (1990) Research factsDallas, TX: National Center.
2.
Bach-y-RitaP. (1981) Central nervous system lesions: Sprouting and unmasking in rehabilitationArchives of Physical Medicine and Rehabilitation, 62, 413–417.
3.
BentonL. A.BakerL. L.VowmanB. R.WatersR. L. (1981) Functional electrical stimulation—a practical clinical guideDowney, CA: Rancho Los Amigos Rehabilitation Engineering Center.
4.
GoldsteinM. (1990) The decade of the brain: Challenge and opportunities in stroke researchStroke, 21, 373–374.
5.
HenryF. M.LotterW.SmithL. E. (1962) Factorial structure of individual differences in limb speed, reaction and strengthResearch Quarterly, 33, 70–84.
6.
HenryF. M.RogersD. E. (1960) Increased response latency for complicated movements and a “memory drum” theory of neuromotor reactionResearch Quarterly, 31, 448–458.
7.
KelsoJ. A. S. (1979) Motor-sensory feedback formulations: Are we asking the right questions?Brain and Behavioral Sciences, 2, 72–73.
8.
KelsoJ. A. S.ScholzJ. (1985) Cooperative phenomena in biological motion In HakenH. (Ed.), Complex systems-operational approaches in neurobiology, physical systems and computersBerlin: Springer-Verlag. Pp. 124–129.
9.
KelsoJ. A. S.SouthardD. L.GoodmanD. (1979) On the structure of human inter-limb coordinationScience, 203, 1029–1031.
10.
KilmerW.KrollW.CongdonV. (1982) An EMG-level muscle model for fast arm movement to targetBiological Cybernetics, 44, 17–66.
11.
KuglerP. N.KelsoJ. A. S.TurneyM. T. (1982) On the control and coordination of naturally developing systems In KelsoJ. A. S.ClarkJ. E. (Eds.), Development of movement coordinationNew York: Wiley. Pp. 5–78.
12.
LagasséP. (1979) Prediction of maximum speed of human movement by two selected muscular coordination mechanisms and by maximum static strengthPerceptual and Motor Skills, 49, 151–161.
13.
LagasséP.BoucherJ.SamsonJ.JacquesL. (1979) Training effects of functional stimulation in weightliftingJournal of Human Movement Studies, 5, 61–67.
14.
LagasséP.KrollW.KilmerW. (1982) Functional electrical stimulation and the treatment of flaccid hemiparesis In ReidG.BryantT.OlneyS.SmithB.StevensonJ.WalmsleyR. (Eds.), Human locomotion IIKingston, Ontario: Canadian Society for Biomechanics. Pp. 42–43.
15.
LagasséP.RouillardC.NormandM.TremblayL. (1982) The effects of functional electrical stimulation training on the activation pattern of antagonist muscleJournal Slovenian Medical Society, 51, 189–190.
16.
LagasséP.RoyM. A. (1989) Functional electrical stimulation and the reduction of co-contraction in spastic biceps brachiClinical Rehabilitation, 3, 111–116.
17.
MeyerJ. S.ShawT. (1982) Diagnosis and management of stroke and TIAsMenlo Park, CA: Addison-Wesley.
18.
PetrofskyJ. S.PhillipsC. A. (1985) Closed-loop control of movement of skeletal muscleCRC Critical Reviews in Biomedical Engineering, 13, 35–96.
19.
SmithL. E. (1970a) Increased strength, reaction time and speed of limb movementPerceptual and Motor Skills, 30, 775–781.
20.
SmithL. E. (1970b) Speed of muscular contractionPerceptual and Motor Skills, 31, 171–176.
21.
SmithL. E. (1972) Relationships between individual differences in static strength, and strengths in actionJapanese Research Journal of Physical Education, 17, 97–103.
22.
TsukaharaN.MurakamiF. (1983) Axonal sprouting and recovery of function after brain damage In DesmedtJ. E. (Ed.), Motor control mechanisms in health and diseaseNew York: Raven. Pp. 1073–1084.
23.
VodovnikL.BajdT.KraljA.GracaninF.SrojnikP. (1981) Functional electrical stimulation for control of locomotor systemsCRC Critical Reviews in Biomedical Engineering, 9, 63–131.
24.
WoodworthR. S. (1899) The accuracy of voluntary movement. Psychological Review, Supplement 2.
25.
World Health Organization. (1971) Cerebrovascular diseases: Prevention, treatment and rehabilitation. Geneva: WHO. (Technical Report Series No. 469).
