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Experimental Brain Research

, Volume 237, Issue 2, pp 327–333 | Cite as

Increased center of pressure trajectory of the finger during precision grip task in stroke patients

  • Junichi Kurihara
  • Bumsuk LeeEmail author
  • Daichi Hara
  • Naoto Noguchi
  • Tsuneo Yamazaki
Research Article
  • 84 Downloads

Abstract

The aim of this study was to assess the spatial stability of stroke patients while holding a freely movable object. Twenty-two acute stroke patients with mild hand impairment performed a grip and lift task using the thumb and index finger. The displacement of the center of pressure (COP) trajectory, the grip force (GF) and several clinical parameters were monitored. Although the GF was not different between paretic and nonparetic hands, the COP trajectory of the paretic index finger was increased. Moreover, the COP trajectories of the thumb and index finger in hemorrhagic patients were longer than those in ischemic patients. These discrepancies between kinetic parameters suggest that different aspects of grip force control may be considered in patients with mild stroke.

Keywords

Center of pressure Grip force Precision grasp Stroke 

References

  1. Alexander NB, Ashton-Miller JA, Giordani B, Guire K, Schultz AB (2005) Age differences in timed accurate stepping with increasing cognitive and visual demand: a walking trail making test. J Gerontol A Biol Sci Med Sci 60:1558–1562CrossRefGoogle Scholar
  2. Augurelle AS, Smith AM, Lejeune T, Thonnard JL (2003) Importance of cutaneous feedback in maintaining a secure grip during manipulation of hand-held objects. J Neurophysiol 89:665–671CrossRefGoogle Scholar
  3. Binder EF, Storandt M, Birge SJ (1999) The relation between psychometric test performance and physical performance in older adults. J Gerontol A Biol Sci Med Sci 54:M428–M432CrossRefGoogle Scholar
  4. Ble A, Volpato S, Zuliani G, Guralnik JM, Bandinelli S, Lauretani F, Bartali B, Maraldi C, Fellin R, Ferrucci L (2005) Executive function correlates with walking speed in older persons: the InCHIANTI study. J Am Geriatr Soc 53:410–415CrossRefGoogle Scholar
  5. Blennerhassett JM, Carey LM, Matyas TA (2006) Grip force regulation during pinch grip lifts under somatosensory guidance: comparison between people with stroke and healthy controls. Arch Phys Med Rehabil 87:418–429CrossRefGoogle Scholar
  6. Blennerhassett JM, Matyas TA, Carey LM (2007) Impaired discrimination of surface friction contributes to pinch grip deficit after stroke. Neurorehabil Neural Repair 21:263–272CrossRefGoogle Scholar
  7. Cole KJ (1991) Grasp force control in older adults. J Mot Behav 23:251–258CrossRefGoogle Scholar
  8. Cruz EG, Waldinger HC, Kamper DG (2005) Kinetic and kinematic workspaces of the index finger following stroke. Brain 128:1112–1121CrossRefGoogle Scholar
  9. Enders LR, Seo NJ (2015) Altered phalanx force direction during power grip following stroke. Exp Brain Res 233:1677–1688CrossRefGoogle Scholar
  10. Grichting B, Hediger V, Kaluzny P, Wiesendanger M (2000) Impaired proactive and reactive grip force control in chronic hemiparetic patients. Clin Neurophysiol 111:1661–1671CrossRefGoogle Scholar
  11. Hoonhorst MH, Nijland RH, Van den Berg JS, Emmelot CH, Kollen BJ, Kwakkel G (2015) How do fugl-meyer arm motor scores relate to dexterity according to the action research arm test at 6 months poststroke? Arch Phys Med Rehabil 96:1845–1849CrossRefGoogle Scholar
  12. Jenmalm P, Johansson RS (1997) Visual and somatosensory information about object shape control manipulative fingertip forces. J Neurosci 17:4486–4499CrossRefGoogle Scholar
  13. Johansson RS, Flanagan JR (2009) Coding and use of tactile signals from the fingertips in object manipulation tasks. Nat Rev Neurosci 10:345–359CrossRefGoogle Scholar
  14. Johansson RS, Westling G, Bäckström A, Flanagan JR (2001) hand eye coordination in object manipulation. J Neurosci 21:6917–6932CrossRefGoogle Scholar
  15. Kamper DG, Rymer WZ (2001) Impairment of voluntary control of finger motion following stroke: role of inappropriate muscle coactivation. Muscle Nerve 24:673–681CrossRefGoogle Scholar
  16. Kelly PJ, Furie KL, Shafqat S, Rallis N, Chang Y, Stein J (2003) Functional recovery following rehabilitation after hemorrhagic and ischemic stroke. Arch Phys Med Rehabil 84:968–972CrossRefGoogle Scholar
  17. Kinoshita and Francis (1996) A comparison of prehension force control in young and elderly individuals. Eur J Appl Physiol Occup Physiol 74:450–460CrossRefGoogle Scholar
  18. Lang CE, Schieber MH (2009) Stroke. In: Nowak DA, Hermsdörfer J (eds) Sensorimotor control of grasping, 1st edn. Cambridge University, Cambridge, pp 296–310CrossRefGoogle Scholar
  19. Marquardt TL, Li ZM (2013) Quantifying digit force vector coordination during precision pinch. J Mech Med Biol 13:1350047CrossRefGoogle Scholar
  20. Mathiowetz V, Weber K, Kashman N, Volland G (1985) Adult norms for the Nine Hole Peg Test of finger dexterity. Occup Ther J Res 5:24–38CrossRefGoogle Scholar
  21. McDonnell MN, Hillier SL, Ridding MC, Miles TS (2006) Impairments in precision grip correlate with functional measures in adult hemiplegia. Clin Neurophysiol 117:1474–1480CrossRefGoogle Scholar
  22. Michaelsen SM, Jacobs S, Roby-Brami A, Levin MF (2004) Compensation for distal impairments of grasping in adults with hemiparesis. Exp Brain Res 157:162–173CrossRefGoogle Scholar
  23. Nowak DA, Hermsdörfer J (2005) Grip force behavior during object manipulation in neurological disorders: toward an objective evaluation of manual performance deficits. Mov Disord 20:11–25CrossRefGoogle Scholar
  24. Palmieri RM, Ingersoll CD, Stone MB, Krause BA (2002) Center-of-pressure parameters used in the assessment of postural control. J Sport Rehabil 11:51–66CrossRefGoogle Scholar
  25. Parikh PJ, Cole KJ (2012) Handling objects in old age: forces and moments acting on the object. J Appl Physiol 112:1095–1104CrossRefGoogle Scholar
  26. Quaney BM, Perera S, Maletsky R, Luchies CW, Nudo RJ (2005) Impaired grip force modulation in he ipsilesional hand after unilateral middle cerebral artery stroke. Neurorehabil Neural Repair 19:338–349CrossRefGoogle Scholar
  27. Seo NJ, Rymer WZ, Kamper DG (2010) Altered digit force direction during pinch grip following stroke. Exp Brain Res 202:891–901CrossRefGoogle Scholar
  28. Tamez E, Myerson J, Morris L, White DA, Baum C, Connor LT (2011) Assessing executive abilities following acute stroke with the trail making test and digit span. Behav Neurol 24:177–185CrossRefGoogle Scholar
  29. Towles JD, Kamper DG, Rymer WZ (2010) Lack of hypertonia in thumb muscles after stroke. J Neurophysiol 104:2139–2146CrossRefGoogle Scholar
  30. Wei JW, Heeley EL, Wang JG, Huang Y, Wong LK, Li Z, Heritier S, Arima H, Anderson CS (2010) ChinaQUEST Investigators. Comparison of recovery patterns and prognostic indicators for ischemic and hemorrhagic stroke in China: the ChinaQUEST (QUality Evaluation of Stroke Care and Treatment) Registry study. Stroke 41:1877–1883CrossRefGoogle Scholar
  31. Westling G, Johansson RS (1984) Factors influencing the force control during precision grip. Exp Brain Res 53:277–284CrossRefGoogle Scholar
  32. Yamada T, Taki T, Yamada M, Funahashi Y, Yamamoto H (2011) Static stability analysis of spatial grasps including contact surface geometry. Adv Robot 25:447–472CrossRefGoogle Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  1. 1.Division of Rehabilitation ServiceGeriatrics Research Institute and HospitalMaebashiJapan
  2. 2.Gunma University Graduate School of Health SciencesMaebashiJapan
  3. 3.Department of RehabilitationMaebashi Red Cross HospitalMaebashiJapan

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