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Experimental Brain Research
Published in: Experimental Brain Research 2/2012

01-08-2012 | Research Article

Training-induced modifications of corticospinal reactivity in severely affected stroke survivors

Authors: Ruth N. Barker, Sandra G. Brauer, Benjamin K. Barry, Toby J. Gill, Richard G. Carson

Published in: Experimental Brain Research | Issue 2/2012

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Abstract

When permitted access to the appropriate forms of rehabilitation, many severely affected stroke survivors demonstrate a capacity for upper limb functional recovery well in excess of that formerly considered possible. Yet, the mechanisms through which improvements in arm function occur in such profoundly impaired individuals remain poorly understood. An exploratory study was undertaken to investigate the capacity for brain plasticity and functional adaptation, in response to 12-h training of reaching using the SMART Arm device, in a group of severely affected stroke survivors with chronic upper limb paresis. Twenty-eight stroke survivors were enroled. Eleven healthy adults provided normative data. To assess the integrity of ipsilateral and contralateral corticospinal pathways, transcranial magnetic stimulation was applied to evoke responses in triceps brachii during an elbow extension task. When present, contralateral motor-evoked potentials (MEPs) were delayed and reduced in amplitude compared to those obtained in healthy adults. Following training, contralateral responses were more prevalent and their average onset latency was reduced. There were no reliable changes in ipsilateral MEPs. Stroke survivors who exhibited contralateral MEPs prior to training achieved higher levels of arm function and exhibited greater improvements in performance than those who did not initially exhibit contralateral responses. Furthermore, decreases in the onset latency of contralateral MEPs were positively related to improvements in arm function. Our findings demonstrate that when severely impaired stroke survivors are provided with an appropriate rehabilitation modality, modifications of corticospinal reactivity occur in association with sustained improvements in upper limb function.
Literature
Barker RN, Brauer SG, Carson RG (2008) Training of reaching in stroke survivors with severe and chronic upper limb paresis using a novel nonrobotic device: a randomized clinical trial. Stroke 39:1800–1807PubMedCrossRef
Barreca S, Wolf SL, Fasoli S, Bohannon R (2003) Treatment interventions for the paretic upper limb of stroke survivors: a critical review. Neurorehabil Neural Repair 17:220–226PubMedCrossRef
Butefisch CM, Netz J, Wessling M, Seitz RJ, Homberg V (2003) Remote changes in cortical excitability after stroke. Brain 126:470–481PubMedCrossRef
Carr JH, Shepherd RB, Nordholm L, Lynne D (1985) Investigation of a new motor assessment scale for stroke patients. Phys Ther 65:175–180PubMed
Carroll TJ, Riek S, Carson RG (2001) Corticospinal responses to motor training revealed by transcranial magnetic stimulation. Exerc Sport Sci Rev 29:54–59PubMedCrossRef
Carroll TJ, Riek S, Carson RG (2002) The sites of neural adaptation induced by resistance training in humans. J Physiol 544:641–652PubMedCrossRef
Cauraugh JH, Summers JJ (2005) Neural plasticity and bilateral movements: a rehabilitation approach for chronic stroke. Prog Neurobiol 75:309–320PubMedCrossRef
Cauraugh JH, Kim SB, Summers JJ (2008) Chronic stroke longitudinal motor improvements: cumulative learning evidence found in the upper extremity. Cerebrovasc Dis 25:115–121PubMedCrossRef
Cramer SC (2004) Changes in motor system function and recovery from stroke. Restor Neurol Neurosci 22:231–238PubMed
Di Lazzaro V, Restuccia D, Oliviero A, Profice P, Ferrara L, Insola A, Mazzone P et al (1998) Effects of voluntary contraction on descending volleys evoked by transcranial stimulation in conscious humans. J Physiol 508:625–633PubMedCrossRef
Dum R, Strick P (1996) Spinal cord terminations of the medial wall motor areas in macaque monkeys. J Neurosci 16:6513–6525PubMed
Dum RP, Strick PL (2002) Motor areas in the frontal lobe of the primate. Physiol Behav 77:677–682PubMedCrossRef
Feydy A, Carlier R, Roby-Brami A, Bussel B, Cazalis F, Pierol L et al (2002) Longitudinal study of motor recovery after stroke: recruitment and focusing of brain activation. Stroke 33:1610–1617PubMedCrossRef
Fridman EA, Hanakawa T, Chung M, Hummel F, Leiguarda RC, Cohen LG (2004) Reorganization of the human ipsilesional premotor cortex after stroke. Brain 127:747–758PubMedCrossRef
Galea MP, Darian-Smith I (1994) Multiple corticospinal neuron populations in the macaque monkey are specified by their unique cortical origins, spinal terminations, and connections. Cereb Cortex 4:166–194PubMedCrossRef
Hallett M (2001) Plasticity of the human motor cortex and recovery from stroke. Brain Res Rev 36:169–174PubMedCrossRef
Harris-Love ML, Morton SM, Perez MA, Cohen LG (2011) Mechanisms of short-term training-induced reaching improvement in severely hemiparetic stroke patients: a TMS study. Neurorehabil Neural Repair 25:398–411PubMedCrossRef
Hendricks HT, Pasman JW, Merx JL, van Limbeek J, Zwarts MJ (2003) Analysis of recovery processes after stroke by means of transcranial magnetic stimulation. J Clin Neurophysiol 20:188–195PubMedCrossRef
Kaneko K, Kawai S, Fuchigami Y, Shiraishi G, Ito T (1996) Effect of stimulus intensity and voluntary contraction on corticospinal potentials following transcranial magnetic stimulation. J Neurol Sci 139:131–136PubMedCrossRef
Kischka U, Fajfr R, Fellenberg T, Hess CW (1993) Facilitation of motor evoked potentials from magnetic brain stimulation in man: a comparative study of different target muscles. J Clin Neurophysiol 10:505–512PubMedCrossRef
Koski L, Mernar TJ, Dobkin BH (2004) Immediate and long-term changes in corticomotor output in response to rehabilitation: correlation with functional improvements in chronic stroke. Neurorehabil Neural Repair 18:230–249PubMedCrossRef
Kwakkel G, Kollen BJ, Krebs HI (2008) Effects of robot-assisted therapy on upper limb recovery after stroke: a systematic review. Neurorehabil Neural Repair 22:111–121PubMed
Liepert J, Graef S, Uhde I, Leidner O, Weiller C (2000) Training-induced changes of motor cortex representations in stroke patients. Acta Neurol Scand 101:321–326PubMedCrossRef
Loewen SC, Anderson BA (1988) Reliability of the modified motor assessment scale and the barthel index. Phys Ther 68:1077–1081PubMed
Loewen SC, Anderson BA (1990) Predictors of stroke outcome using objective measurement scales. Stroke 21:78–81PubMedCrossRef
Luft AR, Waller S, Forrester LW, Smith GV, Whithall J, Macko RF et al (2004) Lesion location alters brain activation in chronically impaired stroke survivors. Neuroimage 21:924–935PubMedCrossRef
Mangold S, Schuster C, Keller T, Zimmermann-Schlatter A, Ettlin T (2009) Motor training of upper extremity with functional electrical stimulation in early stroke rehabilitation. Neurorehabil Neural Repair 23:184–190PubMed
Mazevet D, Meunier S, Pradat-Diehl P, Marchand-Pauvert V, Pierrot-Deseilligny E (2003) Changes in propriospinally mediated excitation of upper limb motoneurons in stroke patients. Brain 126:988–1000PubMedCrossRef
Mills KR, Nithi KA (1997) Corticomotor threshold to magnetic stimulation: normal values and repeatability. Muscle Nerve 20:570–576PubMedCrossRef
Murray EA, Coulter JD (1981) Organization of corticospinal neurons in the monkey. J Comp Neurol 195:339–365PubMedCrossRef
Oliviero A, Profice P, Tonali PA, Pilato F, Saturno E, Dileone M, Ranieri F et al (2006) Effects of aging on motor cortex excitability. Neurosci Res 55:74–77PubMedCrossRef
Page SJ, Maslyn S, Hermann VH, Wu A, Dunning K, Levine PG (2009) Activity-based electrical stimulation training in a stroke patient with minimal movement in the paretic upper extremity. Neurorehabil Neural Repair 23:595–599PubMedCrossRef
Pitcher JB, Ogston KM, Miles TS (2003) Age and sex differences in human motor cortex input-output characteristics. J Physiol 546:605–613PubMedCrossRef
Poole JL, Whitney SL (1988) Motor assessment scale for stroke patients: concurrent validity and interrater reliability. Arch Phys Med Rehabil 69:195–197PubMed
Richards LG, Stewart KC, Woodbury ML, Senesac C, Cauraugh JH (2008) Movement-dependent stroke recovery: a systematic review and meta-analysis of TMS and fMRI evidence. Neuropsychologia 46:3–11PubMedCrossRef
Rossini PM, Pauri F (2002) In: Pascual-Leone A, Davey NJ, Rothwell JC, Wassermann EM (eds) Central conduction time studies, pp 90–96. Handbook of Transcranial Magnetic Stimulation, London
Rossini PM, Barker AT, Berardelli A, Caramia MD, Caruso G, Cracco RQ, Dimitrijević MR et al (1994) Non-invasive electrical and magnetic stimulation of the brain, spinal cord and roots: basic principles and procedures for routine clinical application. Report of an IFCN committee. Electroenceph Clin Neurophysiol 91:79–92PubMedCrossRef
Schwerin S, Dewald JP, Haztl M, Jovanovich S, Nickeas M, MacKinnon C (2008) Ipsilateral versus contralateral cortical motor projections to a shoulder adductor in chronic hemiparetic stroke: implications for the expression of arm synergies. Exp Brain Res 185:509–519PubMedCrossRef
Seitz RJ, Schlaug G, Kleinschmidt A, Knorr U, Nebeling B, Wirrwar A, Steinmetz H et al (1994) Remote depressions of cerebral metabolism in hemiparetic stroke: topography and relation to motor and somatosensory functions. Hum Brain Mapp 1:81–100CrossRef
Shelton F, Reding MJ (2001) Effect of lesion location on upper limb motor recovery after stroke. Stroke 32:107–112PubMedCrossRef
Smith AE, Sale MV, Higgins RD, Wittert GA, Pitcher JB (2011) Male human motor cortex stimulus-response characteristics are not altered by aging. J Appl Physiol 110:206–212PubMedCrossRef
Sterr A, Shen S, Szameitat AJ, Herron KA (2010) The role of corticospinal tract damage in chronic motor recovery and neurorehabilitation: a pilot study. Neurorehabil Neural Repair 24:413–419PubMedCrossRef
Stinear C (2010) Prediction of recovery of motor function after stroke. Lancet Neurol 9:1228–1232PubMedCrossRef
Stinear CM, Barber PA, Smale PR, Coxon JP, Fleming MK, Byblow WD (2007) Functional potential in chronic stroke patients depends on corticospinal tract integrity. Brain 130:170–180PubMedCrossRef
Taub E, Miller NE, Novack TA, Cook EW, Flemming WC, Nepomuceno CS et al (1993) Technique to improve chronic motor deficit after stroke. Arch Phys Med Rehabil 74:347–354PubMed
Theilman GT, Dean CM, Gentile AM (2004) Rehabilitation of reaching after stroke: task-related training versus progressive resistance exercise. Arch Phys Med Rehabil 85:1613–1618CrossRef
Timmermans AA, Spooren AI, Kingma H, Seelen HA (2010) Influence of task-oriented training content on skilled arm-hand performance in stroke: a systematic review. Neurorehabil Neural Repair 24:858–870PubMedCrossRef
Traversa R, Cicinelli P, Bassi A, Rossini PM, Bernardi G (1997) Mapping of motor cortical reorganisation after stroke: a brain stimulation study with focal magnetic pulses. Stroke 28:110–117PubMedCrossRef
Traversa R, Cicinelli P, Pasqualetti P, Filippi M, Rossini PM (1998) Follow-up of interhemispheric differences of motor evoked potentials from the ‘affected’ and ‘unaffected’ hemispheres in human stroke. Brain Res 803:1–8PubMedCrossRef
Trompetto C, Assini A, Buccolieri A, Marchese R, Abbruzzese G (2000) Motor recovery following stroke: a transcranial magnetic stimulation study. Clin Neurophysiol 111:1860–1867PubMedCrossRef
Turton A (1998) Mechanisms for recovery of hand and arm function after stroke: a review of evidence from studies using non-invasive investigative techniques. Br J Occup Ther 61:359–364
Turton A, Wroe S, Trepte N, Fraser C, Lemon RN (1996) Contralateral and ipsilateral EMG responses to transcranial magnetic stimulation during recovery of arm and hand function after stroke. Electromyogr Mot Control Electroencephalogr Clin Neurophysiol 101:316–328CrossRef
van Kuijk AA, Pasman JW, Hendricks HT, Zwarts MJ, Geurts AC (2009) Predicting hand motor recovery in severe stroke: the role of motor evoked potentials in relation to early clinical assessment. Neurorehabil Neural Repair 23:45–51PubMed
von Giesen HJ, Roick H, Benecke R (1994). Inhibitory actions of motor cortex following unilateral brain lesions as studied by magnetic brain stimulation. Exp Brain Res 99:84–96
Ward NS, Brown MM, Thompson AJ, Frackowiak RSJ (2003) Neural correlates of outcome after stroke: a cross-sectional fMRI study. Brain 126:1430–1448PubMedCrossRef
Wassermann EM (2002) Variation in the response to transcranial magnetic brain stimulation in the general population. Clin Neurophysiol 113:1165–1171PubMedCrossRef
Winstein CJ, Rose DK, Tan SM, Lewthwaite R, Chui HC, Azen SP (2004) A randomised controlled comparison of upper-extremity rehabilitation strategies in acute stroke: a pilot of immediate and long term outcomes. Arch Phys Med Rehabil 85:620–628PubMedCrossRef
Metadata
Title
Training-induced modifications of corticospinal reactivity in severely affected stroke survivors
Authors
Ruth N. Barker
Sandra G. Brauer
Benjamin K. Barry
Toby J. Gill
Richard G. Carson
Publication date
01-08-2012
Publisher
Springer-Verlag
Published in
Experimental Brain Research / Issue 2/2012
Print ISSN: 0014-4819
Electronic ISSN: 1432-1106
DOI
https://doi.org/10.1007/s00221-012-3163-z

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