Poor motor function is associated with reduced sensory processing after stroke

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• 作者：S. Floor Campfens (1) (2)
  Sarah B. Zandvliet (3)
  Carel G. M. Meskers (3)
  Alfred C. Schouten (1) (4)
  Michel J. A. M. van Putten (2)
  Herman van der Kooij (1) (4)
  
  1. Department of Biomechanical Engineering ; MIRA Institute of Biomedical Engineering and Technical Medicine ; University of Twente ; PO Box 217 ; 7500 AE ; Enschede ; The Netherlands
  2. Clinical Neurophysiology ; MIRA Institute of Biomedical Engineering and Technical Medicine ; University of Twente ; Enschede ; The Netherlands
  3. Department of聽Rehabilitation Medicine ; Leiden University Medical Center ; Leiden ; The Netherlands
  4. Department聽of Biomechanical Engineering ; Delft University of Technology ; Delft ; The Netherlands
  
• 关键词：Stroke ; Coherence ; Afferent pathways ; Motor control ; Joint position perturbation ; EEG
• 刊名：Experimental Brain Research
• 出版年：2015
• 出版时间：April 2015
• 年：2015
• 卷：233
• 期：4
• 页码：1339-1349
• 全文大小：2,045 KB
• 参考文献：1. Baker, SN (2007) Oscillatory interactions between sensorimotor cortex and the periphery. Curr Opin Neurobiol 17: pp. 649-655 CrossRef
  2. Bortel, R, Sovka, P (2007) Approximation of statistical distribution of magnitude squared coherence estimated with segment overlapping. Signal Process 87: pp. 1100-1117 CrossRef
  3. Campfens, SF, Schouten, AC, Putten, MJAM, Kooij, H (2013) Quantifying connectivity via efferent and afferent pathways in motor control using coherence measures and joint position perturbations. Exp Brain Res 228: pp. 141-153 CrossRef
  4. Campfens, SF, Kooij, H, Schouten, AC (2014) Face to phase: pitfalls in time delay estimation from coherency phase. J Comput Neurosci 37: pp. 1-8
  5. Connell, LA, Lincoln, NB, Radford, KA (2008) Somatosensory impairment after stroke: frequency of different deficits and their recovery. Clin Rehabil 22: pp. 758-767 CrossRef
  6. Conway, BA, Halliday, DM, Farmer, SF, Shahani, U, Maas, P, Weir, AI, Rosenberg, JR (1995) Synchronization between motor cortex and spinal motoneuronal pool during the performance of a maintained motor task in man. J Physiol 489: pp. 917-924 CrossRef
  7. Vos, M, Vos, DM, Ri猫s, S, Vanderperren, K, Vanrumste, B, Alario, FX, Huffel, S, Huffel, VS, Burle, B (2010) Removal of muscle artifacts from EEG recordings of spoken language production. Neuroinformatics 8: pp. 135-150 CrossRef
  8. Dobkin, BH (2005) Rehabilitation after stroke. N Engl J Med 352: pp. 1677-1684 CrossRef
  9. Dukelow, SP, Herter, TM, Moore, KD, Demers, MJ, Glasgow, JI, Bagg, SD, Norman, KE, Scott, SH (2010) Quantitative assessment of limb position sense following stroke. Neurorehabil Neural Repair 24: pp. 178-187 CrossRef
  10. Fries, P (2005) A mechanism for cognitive dynamics: neuronal communication through neuronal coherence. Trends Cogn Sci 9: pp. 474-480 CrossRef
  11. Fugl-Meyer, AR, J盲盲sk枚, L, Leyman, I, Olsson, S, Steglind, S (1975) The post-stroke hemiplegic patient. 1. A method for evaluation of physical performance. Scand J Rehabil Med 7: pp. 13-31
  12. Halliday, DM, Conway, BA, Farmer, SF, Rosenberg, JR (1998) Using electroencephalography to study functional coupling between cortical activity and electromyograms during voluntary contractions in humans. Neurosci Lett 241: pp. 5-8 CrossRef
  13. Herrmann, CS (2001) Human EEG responses to 1鈥?00聽Hz flicker: resonance phenomena in visual cortex and their potential correlation to cognitive phenomena. Exp Brain Res 137: pp. 346-353 CrossRef
  14. Kwakkel, G, Kollen, BJ, Grond, J, Prevo, AJH (2003) Probability of regaining dexterity in the flaccid upper limb: impact of severity of paresis and time since onset in acute stroke. Stroke 34: pp. 2181-6 CrossRef
  15. Kwakkel, G, Kollen, B, Lindeman, E (2004) Understanding the pattern of functional recovery after stroke: facts and theories. Restor Neurol Neurosci 22: pp. 281-299
  16. Lincoln, NB, Crow, JL, Jackson, JM, Waters, GR, Adams, SA, Hodgson, P (1991) The unreliability of sensory assessments. Clin Rehabil 5: pp. 273-282 CrossRef
  17. Mendez-Balbuena, I, Huethe, F, Schulte-M枚nting, J, Leonhart, R, Manjarrez, E, Kristeva, R (2011) Corticomuscular coherence reflects interindividual differences in the state of the corticomuscular network during low-level static and dynamic forces. Cereb Cortex 22: pp. 628-638 CrossRef
  18. Mima, T, Steger, J, Schulman, AE, Gerloff, C, Hallett, M (2000) Electroencephalographic measurement of motor cortex control of muscle activity in humans. Clin Neurophysiol 111: pp. 326-337 CrossRef
  19. Mima, T, Matsuoka, T, Hallett, M (2001) Information flow from the sensorimotor cortex to muscle in humans. Clin Neurophysiol 112: pp. 122-126 CrossRef
  20. Nijland, RHM, Wegen, EEH, Kwakkel, G (2010) Presence of finger extension and shoulder abduction within 72聽hours after stroke predicts functional recovery: early prediction of functional outcome after stroke: the EPOS cohort study. Stroke 41: pp. 745-750 CrossRef
  21. Oostenveld, R, Praamstra, P (2001) The five percent electrode system for high-resolution EEG and ERP measurements. Clin Neurophysiol 112: pp. 713-719 CrossRef
  22. Oostenveld, R, Fries, P, Maris, E, Schoffelen, JM (2011) FieldTrip: Open source software for advanced analysis of MEG, EEG, and invasive electrophysiological data. Comput Intell Neurosci 2011: pp. 156869 CrossRef
  23. Pohja, M, Salenius, S (2003) Modulation of cortex-muscle oscillatory interaction by ischaemia-induced deafferentation. Neuroreport 14: pp. 321-324 CrossRef
  24. Riddle, CN, Baker, SN (2005) Manipulation of peripheral neural feedback loops alters human corticomuscular coherence. J Physiol 566: pp. 625-639 CrossRef
  25. Schabrun, SM, Hillier, S (2009) Evidence for the retraining of sensation after stroke: a systematic review. Clin Rehabil 23: pp. 27-39 CrossRef
  26. Scott, SH (2004) Optimal feedback control and the neural basis of volitional motor control. Nat Rev Neurosci 5: pp. 532-546 CrossRef
  27. Serrien, DJ, Strens, LHA, Cassidy, MJ, Thompson, AJ, Brown, P (2004) Functional significance of the ipsilateral hemisphere during movement of the affected hand after stroke. Exp Neurol 190: pp. 425-432 CrossRef
  28. Severens, M, Nienhuis, B, Desain, P, Duysens, J (2012) Feasibility of measuring event related desynchronization with electroencephalography during walking. Annu Int Conf IEEE Eng Med Biol Soc 2012: pp. 2764-2767
  29. Stolk-Hornsveld, F, Crow, JL, Hendriks, EP, Baan, R (2006) The Erasmus MC modifications to the (revised) Nottingham Sensory Assessment: a reliable somatosensory assessment measure for patients with intracranial disorders. Clin Rehabil 20: pp. 160-172 CrossRef
  30. Ushiyama, J, Suzuki, T, Masakado, Y, Hase, K, Kimura, A, Liu, M, Ushiba, J (2011) Between-subject variance in the magnitude of corticomuscular coherence during tonic isometric contraction of the tibialis anterior muscle in healthy young adults. J Neurophysiol 106: pp. 1379-88 CrossRef
  31. Varela, F, Lachaux, JP, Rodriguez, E, Martinerie, J (2001) The brainweb: phase synchronization and large-scale integration. Nat Rev Neurosci 2: pp. 229-239 CrossRef
  32. Ward, NS (2003) Neural correlates of outcome after stroke: a cross-sectional fMRI study. Brain 126: pp. 1430-1448 CrossRef
  33. Williams, ER, Soteropoulos, DS, Baker, SN (2009) Coherence between motor cortical activity and peripheral discontinuities during slow finger movements. J Neurophysiol 102: pp. 1296-1309 CrossRef
  34. Witham, CL, Riddle, CN, Baker, MR, Baker, SN (2011) Contributions of descending and ascending pathways to corticomuscular coherence in humans. J Physiol 589: pp. 3789-3800 CrossRef
  
• 刊物类别：Biomedical and Life Sciences
• 刊物主题：Biomedicine
  Neurosciences
  Neurology
  
• 出版者：Springer Berlin / Heidelberg
• ISSN：1432-1106

文摘

The possibility to regain motor function after stroke depends on the intactness of motor and sensory pathways. In this study, we evaluated afferent sensory pathway information transfer and processing after stroke with the coherence between cortical activity and a position perturbation (position-cortical coherence, PCC). Eleven subacute stroke survivors participated in this study. Subjects performed a motor task with the affected and non-affected arm while continuous wrist position perturbations were applied. Cortical activity was measured using EEG. PCC was calculated between position perturbation and EEG at the contralateral and ipsilateral sensorimotor area. The presence of PCC was quantified as the number of frequencies where PCC is larger than zero across the sensorimotor area. All subjects showed significant contralateral PCC in affected and non-affected wrist tasks. Subjects with poor motor function had a reduced presence of contralateral PCC compared with subjects with good motor function in the affected wrist tasks. Amplitude of significant PCC did not differ between subjects with good and poor motor function. Our results show that poor motor function is associated with reduced sensory pathway information transfer and processing in subacute stroke subjects. Position-cortical coherence may provide additional insight into mechanisms of recovery of motor function after stroke.