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PLOS ONE 2013

Integration of Sensory Force Feedback Is Disturbed in CRPS-Related Dystonia

DOI: 10.1371/journal.pone.0060293

Winfred Mugge, Frans C. T. van der Helm, Alfred C. Schouten

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Abstract:

Complex regional pain syndrome (CRPS) is characterized by pain and disturbed blood flow, temperature regulation and motor control. Approximately 25% of cases develop fixed dystonia. The origin of this movement disorder is poorly understood, although recent insights suggest involvement of disturbed force feedback. Assessment of sensorimotor integration may provide insight into the pathophysiology of fixed dystonia. Sensory weighting is the process of integrating and weighting sensory feedback channels in the central nervous system to improve the state estimate. It was hypothesized that patients with CRPS-related dystonia bias sensory weighting of force and position toward position due to the unreliability of force feedback. The current study provides experimental evidence for dysfunctional sensory integration in fixed dystonia, showing that CRPS-patients with fixed dystonia weight force and position feedback differently than controls do. The study shows reduced force feedback weights in CRPS-patients with fixed dystonia, making it the first to demonstrate disturbed integration of force feedback in fixed dystonia, an important step towards understanding the pathophysiology of fixed dystonia.

References

[1]	K？rding KP, Ku SP, Wolpert DM (2004) Bayesian integration in force estimation. J Neurophysiol 92(5): 3161–5.
[2]	K？rding KP, Wolpert DM (2006) Bayesian decision theory in sensorimotor control. Trends Cogn Sci 10(7): 319–26.
[3]	Ernst MO, Bülthoff HH (2004) Merging the senses into a robust percept. Trends Cogn Sci 8(4): 162–9.
[4]	Yuille A, Bülthoff HH (1996) Bayesian decision theory and psychophysics. In Perception as Bayesian Inference (Knill, D. and Richards, W., eds), pp. 123–161, Cambridge University Press.
[5]	Mahboobin A, Loughlin PJ, Redfern MS, Sparto PJ (2005) Sensory re-weighting in human postural control during moving-scene perturbations. Exp Brain Res 167: 260–267.
[6]	Van der Kooij H, Jacobs R, Koopman B, Van der Helm F (2001) An adaptive model of sensory integration in a dynamic environment applied to human stance control. Biol Cyb 84: 103–115.
[7]	Zupan LH, Merfeld DM, Darlot C (2002) Using sensory weighting to model the influence of canal, otolith and visual cues on spatial orientation and eye movements. Biol Cyb 86(3): 209–230.
[8]	Peterka RJ, Loughlin PJ (2004) Dynamic regulation of sensorimotor integration in human postural control. J Neurophysiol 91(1): 410–23.
[9]	Mugge W, Schuurmans J, Schouten AC, Van der Helm FC (2009) Sensory weighting of force and position feedback in human motor control tasks. J Neurosci 29(17): 5476–82.
[10]	Schwartzman RJ, Kerrigan J (1990) The movement disorder of reflex sympathetic dystrophy. Neurology 40: 57–61.
[11]	Veldman PH, Reynen HM, Arntz IE, Goris RJ (1993) Signs and symptoms of reflex sympathetic dystrophy: prospective study of 829 patients. Lancet 342: 1012–1016.
[12]	Allen G, Galer BS, Schwartz L (1999) Epidemiology of complex regional pain syndrome: a chart retrospective review of 134 patients. Pain 9: 539–544.
[13]	Merskey H, Bogduk N (1994) Relatively generalized syndromes. In: Merskey H, Bogduk N, editors. Classification of chronic pain. Description of chronic pain syndromes and definitions of pain terms. Seattle: IASP Press: 40-3.
[14]	Van Hilten JJ, Geraedts EJ, Marinus J (2007) Peripheral trauma and movement disorders. Parkinsonism Relat Disord 13 Suppl 3: S395–S399.
[15]	Abbruzzese G, Berardelli A (2003) Sensorimotor integration in movement disorders. Movement Disord 18(3): 231–40.
[16]	Tinazzi M, Rosso T, Fiaschi A (2003) Role of the somatosensory system in primary dystonia. Movement Disord 18(6): 605–22.
[17]	Nowak DA, Hermsd？rfer J (2006) Objective evaluation of manual performance deficits in neurological movement disorders. Brain Res Rev 51(1): 108–24.
[18]	Mugge W, Munts AG, Schouten AC, Van der Helm FC (2012) Modeling movement disorders – CRPS-related dystonia explained by abnormal proprioceptive reflexes. J Biomech 45(1): 90–8.
[19]	Munts AG, Mugge W, Meurs TS, Schouten AC, Marinus J, et al. (2011) Fixed dystonia in complex regional pain syndrome: A descriptive and computational modeling approach. BMC Neurol 11: 53.
[20]	Chu WT, Sanger TD (2009) Force variability during isometric biceps contraction in children with secondary dystonia due to cerebral palsy. Mov Disord 24: 1299–305.
[21]	Prodoehl J, Corcos DM, Vaillancourt DE (2006) Effects of focal hand dystonia on visually guided and internally guided force control. J Neurol Neurosurg Psychiatry 77(8): 909–14.
[22]	Prodoehl J, MacKinnon CD, Comella CL, Corcos DM (2006) Rate of force production and relaxation is impaired in patients with focal hand dystonia. Parkinsonism Relat Disord 12(6): 363–71.
[23]	Hermsd？rfer J, Hagl E, Nowak DA (2004) Deficits of anticipatory grip force control after damage to peripheral and central sensorimotor systems. Hum Mov Sci 23: 627–646.
[24]	Nowak DA, Hermsd？rfer J (2005) Grip force behavior during object manipulation in neurological disorders: toward an objective evaluation of manual performance deficits. Mov Disord 20: 11–25.
[25]	Odergren T, Iwasaki N, Borg J, Forssberg H (1996) Impaired sensory–motor integration during grasping in writer's cramp. Brain 119: 569–583.
[26]	Serrien DJ, Burgunder JM, Wiesendanger M (2000) Disturbed sensorimotor processing during control of precision grip in patients with writer's cramp. Mov Disord 15: , 965–972.
[27]	Nowak DA, Rosenkranz K, Topka H, Rothwell JC (2005) Disturbances of grip force behavior in focal hand dystonia: evidence for a generalized impairment of sensory–motor integration. J Neurol, Neurosurg Psychiatry 76: 953–959.
[28]	Schenk T, Mai N (2001) Is writer's cramp caused by a deficit of sensorimotor integration. Exp Brain Res 136, 321–330.
[29]	Johansson RS (1996) Sensory control of dexterous manipulation in humans. In: Wing, A.M., Haggard, P., Flanagan, J.R. (Eds.), Hand and Brain. San Diego, Academic Press, pp. 381–414.
[30]	Johansson RS, Westling G (1984) Roles of glabrous skin receptors and sensorimotor memory in automatic control of precision grip when lifting rougher and more slippery objects. Exp Brain Res 56: 550–564.
[31]	Helbig HB, Ernst MO (2008) Visual-haptic cue weighting is independent of modality-specific attention. J Vis 8(1): 21.1–16.

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