A psychophysical study of the mechanisms of sensory recovery following nerve injury in humans

doi:10.1093/brain/117.1.149

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Brain, Vol. 117, No. 1, 149-167, 1994
© 1994 Oxford University Press

research-article

A psychophysical study of the mechanisms of sensory recovery following nerve injury in humans

Robert W. Van Boven¹^,2^, and Kenneth O. Johnson¹

¹The Philip Bard Laboratories of Neurophysiology, Departments of Neuroscience Baltimore, USA ²The Philip Bard Laboratories of Neurophysiology, Departments of Surgery, The Johns Hopkins University School of Medicine Baltimore, USA

Correspondence to: Correspondence to: Dr Robert W. Van Boven, University of Missouri—Kansas City School of Medicine, 2411 Holmes, Kansas City, MO 64108, USA

Twenty-four subjects were studied before and up to 1 year aftersurgery that produced injury to a major sensory branch of thetrigeminal nerve. We employed a battery of 11 psychophysicaltests, in which the neural mechanisms underlying performanceare understood, to study the basis of recovery following nerveinjury. Immediately after nerve injury, sensation was profoundlyimpaired in all subjects. In the following weeks and months,the recovery of performance proceeded in an orderly fashion.Although the rates of recovery varied between subjects, theorder of recovery between tasks did not. The recovery ratesfell into three distinct categories. Recovery in one task, brush-strokedirectional discrimination, was most rapid. Two weeks afternerve injury, 52% of subjects could discriminate brush-strokedirection; by 3 months only one subject could not perform thistask. The second category comprised recovery rates for painthresholds for noxious heat, cold and mechanical stimuli, andto preinjury performance in tasks assessing touch and vibrationdetection, two-point discrimination, cooling detection and subjectivemagnitude estimation of mechanical force. The third, slowestgroup included recovery rates for warming detection and gratingorientation discrimination. Early recovery to preinjury performancelevels in the brush-stroke direction and one-point versus two-pointdiscrimination tasks was correlated with later recovery to nearnormal performance in the grating orientation task. The gratingorientation task was unique in providing a measure that correspondedconsistently with the subjects' reports of sensory deficits.Our psychophysical findings are consistent with neurophysiologicaldata showing that the major primary afferent fibre classes reinnervatethe skin at a similar rate. A hypothesis that accounts for thepsychophysical findings in this study is that differences inrecovery rates between tasks is determined largely by theirrelative dependencies on functional innervation density. Alternativehypotheses are considered.

nerve regeneration; psychophysics; touch; nerve injury; somatosensory; human

Received January 26, 1993. Revised September 30, 1993. Accepted October 21, 1993.

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