Kinematic analysis of movement imitation in apraxia

doi:10.1093/brain/119.5.1575

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Brain, Vol. 119, No. 5, 1575-1586, 1996
© 1996 Guarantors of Brain

research-article

Kinematic analysis of movement imitation in apraxia

J. Hermsdörfer¹^,, N. Mai², J. Spatt³, C. Marquardt¹, R. Veltkamp² and G. Goldenberg¹^,2

¹Clinical Neuropsychology Research Group, Department of Neuropsychology, City Hospital Bogenhausen ²Department of Neurology, Ludwig-Maximilians-Universität Munich, Germany ³Second Neurological Department, Neurological Hospital Rosenhügel, Vienna, Austria

Correspondence to: Dr Joachim Hermsdörfer, Entwicklungsgruppe Klinische Neuropsychologie, Städtisches Krankenhaus München-Bogenhausen, Dachauer Strasse 164, D-80992 München, Germany

Accuracy of the final position and kinematics of movement wereanalysed during the imitation of meaningless gestures in patientswith unilateral brain lesions who performed with the hand ipsilateralto the lesion and in control subjects. Controls imitated thegestures virtually without spatial errors. The kinematics oftheir movements was characterized by single-peaked and approximatelybell-shaped velocity profiles of the transport phase combinedwith no or only minor corrective movements in the final phase.Patients with right brain damage (RBD) performed as well ascontrol subjects with respect to both spatial accuracy of finalhand-positions and kinematic parameters of the movement trajectories.Patients with left brain damage (LBD) committed spatial parapraxiasand had a much higher frequency of kinematic abnormalities.However, there was no correlation between kinematic abnormalitiesand apraxic errors. There were kinematically abnormal movementswhich reached a correct final position as well as kinematicallynormal movements leading to apraxic errors. One possible explanationfor the combined occurrence of kinematic abnormalities and parapraxiasin LBD patients would be that they are independent sequels ofleft hemisphere lesions. An alternative account is that theassociations and dissociations result from an interaction betweenone common basic deficit and strategies to cope with this deficit.The basic deficit may concern the mental representation of thetarget position. The LBD patients may react to the absence ofan appropriate representation of the target by one of two alternativestrategies; they may switch to a strategy of slowed, on-linecontrolled movements to find the required final position, orthey may move their hand smoothly at normal speed to a roughlyspecified location without taking note of their deficiency.Depending on whether these strategies are successful or notthey would lead to the observed associations and dissociationsbetween kinematic abnormalities and spatial parapraxias.

ideomotor apraxia; motor control; left hemisphere damage; imitation of meaningless gestures; kinematic analysis

Received December 15, 1995. Revised February 28, 1996. Accepted June 14, 1996.

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