Erwin Kunesch

Invariant temporal characteristics of manipulative hand movements.

SummaryThe measurement of eight manipulative serial hand movements showed a clear distribution of their temporal characteristics into two distinct groups. When the hand was used as a sense organ during active touch the finger movements across objects were restricted to a slow performance range below 2 Hz. Recordings from single mechanoreceptive afferents and calculations of their receptor densities indicated that these movements have to be slow to match the temporal requirements of the sequential sampling process from the mechanoreceptor populations. In contrast, manual skills not associated with the collection of sensory information like handwriting, typing or pencil shading, were performed rapidly. Their frequencies were close to those of fastest possible tapping. Evidence is provided that the different frequency groups are associated with distinct sensory control processes. The low frequency group represents movements involving focal sensory control (Julesz 1984). The high frequency group is not performed open-loop but monitored by preattentive sensory processes. The results indicate a dual sensory control mode operating in separate frequency domains of movement.

Chapter 59 Paired associative stimulation

Paired associative stimulation (PAS) refers to a paradigm consisting of slow-rate repetitive low-frequency median nerve stimulation combined with transcranial magnetic stimulation (TMS) over the contralateral motor cortex. This protocol has been shown to induce plastic changes of excitability in the human motor cortex. Its principles of design were shaped after associative long-term potentiation (LTP) in experimental animals, a cellular mechanism likely to be relevant for learning and memory. PAS-induced changes of cortical excitability share a number of physiological properties with LTP. Of particular importance is the fact that the sign of PAS-induced changes of the size of amplitudes of the motor evoked potentials (MEPs) depends on the exact interval between the afferent and the magnetic pulse during the intervention. A number of observations suggest that PAS-induced excitability changes may have functional significance. PAS-induced plasticity may contribute to elucidating the pathogenesis of neurological disorders where neuroplasticity is thought to have a pathogenetic role. Finally, PAS-induced plasticity may itself have therapeutic potential.

Parallel and serial processing of haptic information in man: Effects of parietal lesions on sensorimotor hand function

Recent animal studies have shown that there is an evolutionary shift within the order of primates from parallel to serial processing of haptic information. In an attempt to determine whether there is also evidence of serial processing in humans 10 patients with parietal cortical lesions, three patients with subcortical lesions and one patient after hemispherectomy, were examined. Case-by-case and across subject analysis of lesion type, sensorimotor profile and electrophysiological findings showed that in unihemispheric lesions: (a) there is little impairment of thermesthesia, nociception and vibration sense: (b) two-point discrimination and integrity of the N20 somatosensory component are highly correlated; (c) a loss of the N20 component is accompanied by a severe impairment of stereognosis; (d) conversely, in more posterior lesions astereognosis can occur with an intact N20 component; and (e) if the lesion is in the right hemisphere there is frequently impairment of graphesthesia in both hands. These data are taken to indicate serial processing from SI (as evidenced by an intact N20 component) to posterior parietal cortex allowing progressive spatial and temporal integration. In graphesthesia our data suggest an integrative function of the right parietal cortex for both sides of the body. Other sensory qualities like vibration nociception and thermesthesia are apparently processed in a non-serial, probably parallel way involving both hemispheres. The effects of cerebral lesions in our series suggest parallel as well as serial processing of somesthetic information in man underlying the perception of different haptic features.

Residual sensorimotor functions in a patient after right-sided hemispherectomy

Sensorimotor functions were examined in a patient with left-sided infantile hemiparesis who underwent hemispherectomy (HS) on the right side at age 18 for intractable epilepsy. Pathological examination of the removed hemisphere showed a porencephalic cyst of the temporal lobe and of the frontoparietal operculum. On examination, the patient had hemianopia to the left and sensorimotor deficits only of the distal limbs contralateral to the HS. She walked with a barely perceptible limp. Axial and proximal movements were quasi normal, so that the patient could fully elevate both arms, flex and extend the forearm with nearly normal power and execute small, isolated precision movements of the arm around the shoulder joint. This astonishing proximal motor repertoire was mimicked on the somatosensory side where cutaneous sensation and kinesthesia were normal above the elbow and knee and contrasted the pronounced distal sensorimotor dysfunctions. Movement analysis by means of an optoelectronic two-camera position analysis system (Selspot II) showed normal flexion-extension synergies during gait, but abnormal synergic coupling between the shoulder and elbow joint during reaching and prehension. Distal movements were still possible but could only be performed as rigidly coupled movement synergies, such as closing and opening of the fist along with arm adduction/flexion or abduction/extension. She could engage these synergies for grasping and holding large objects. The performance of individual, fractionated finger movements was impossible. Involuntary mirror movements were elicited in both the affected and the normal arm, but with distinctly different phase relationships, indicating that different circuitries contribute to their generation. The case study reveals the existence of a bilaterally organized sensorimotor system that has the potential to provide quasi normal performance of the axial-proximal body parts on both sides. This raises the question why this potential cannot be better used in cases with only partial unilateral brain damage and persistent hemiplegia.

Altered force release control in Parkinson's disease

Isometric force tracking and force aiming modified by visual feed-back was investigated in Parkinsonian (PD) and control subjects. Production and maintenance of isometric force, production and release of isotonic force, and maximum force were tested. Statistical analysis revealed that the PD patients could perform most force tasks in a similar manner to that of control subjects. However, PD patients had difficulties in sustaining target force over a 30-s period and in performing rapid alternating movements. The major finding in PD patients was an inability to precisely release a target force. Overall these data suggest that the release of a produced force is a sensitive motor control parameter in Parkinsons disease.

The Pattern of Motor Deficits in Relation to the Site of Stroke Lesions

Thirty-two patients with hemispheric stroke lesions of distinct cortical functional zones (premotor, precentral, parietal) or of striatocapsular or striatothalamic subcortical territories were scored at the acute and chronic stage for the following sensorimotor arm-hand functions: force, praxis, motor attention, sensation and dexterity. The selection criterion was that in spite of the wide variation of lesion sites all patients had hemiparesis as the presenting clinical sign. Analysis of the scores showed that most patients showed apraxia, motor neglect or disturbed sensation in addition to hemiparesis. The distribution and severity of these deficits varied, so that different lesion groups showed different patterns. The actual functional impairment of arm-hand function was determined by the combined effect of these different sensorimotor dysfunctions.

Facilitation of somatosensory evoked potentials by exploratory finger movements

Modification of somatosensory processing depending on the behavioral setting was studied. Active alternating movements of the fingers, passive tactile stimuli to the hand, and active exploration of objects were performed during recording of somatosensory evoked potentials (SEPs). SEPs were elicited by compound electrical median nerve stimulation and electrical stimulation at detection threshold of cutaneous median nerve fascicles identified by microneurography. Electrical stimulation was not time-locked to the studied condition.In comparison with SEPs at rest there was attenuation of early cortical potentials up to 25 ms post-trigger in all nonresting conditions. In stimulation of the compound median nerve as well as of isolated cutaneous fascicles of a hand actively exploring an object there was an additional increased negativity, peaking at 28 ms. This facilitory effect was independent of attentional focusing and was absent during exploration using the ipsilateral, non-electrically stimulated hand. In patients with parietal lesions the facilitatory effect was diminished on the affected side. Spline interpolated brain maps at this latency based on 32channel recordings in healthy volunteers showed a shift of local contralateral positive maximum from frontal to parietal during exploration, indicating enhancement of a tangential dipole. It is suggested that in conditions involving close sensorimotor interaction such as exploratory hand movements there is preactivation of a cortical area which is located in the central sulcus and receives cutaneous somatosensory inputs.

Somatosensory evoked potentials (SEPs) elicited by magnetic nerve stimulation

Magnetic stimulation of peripheral nerves at distal and proximal sites of the upper and lower extremities and at the midlumbar level were used to elicit cortical somatosensory evoked potentials. Evidence is provided that peripheral nerve trunks, rather than distal receptor afferents, are the anatomical structures stimulated by the electromagnetic fields. Magnetic stimulation of peripheral nerves is considered to be useful for an evaluation of the integrity of proximal nerves, nerve roots and central conduction along sensory pathways. In contrast to electrical nerve stimulation, magnetic stimulation is painless and can be applied to proximal nerves and plexus. By means of proximal nerve stimulation central sensory conduction can be tested even in patients with peripheral nerve lesions or polyneuropathy.

Early-onset multisystem degeneration with central motor, autonomic and optic nerve disturbances: unusual Riley–Day syndrome or new clinical entity?

We report a 21-year-old woman presenting with a slowly progressive tetraparesis, optic nerve atrophy on both sides, and autonomic disturbances since early childhood. The patient has been carefully followed up for 5 years with clinical and ancillary investigations. The results and the time course strongly suggest an underlying degenerative syndrome affecting parts of three major systems: autonomic, motor and visual. Some symptoms resemble familial dysautonomia (FD, Riley-Day syndrome), however, hallmarks of FD, such as absence of fungiform papillae of the tongue, abnormal reaction on intradermal histamine injection, absent tendon reflexes, are missing, and central motor disturbances have not been described in FD. We consider this syndrome a slowly progressive multisystemic degeneration with two unusual hitherto unreported features: the combination of affected systems (autonomic and motor systems, optic nerves), and the early onset.

Somatosensory evoked potentials modified by laser-induced lesions of the rat cortex.

The effect of focal application of laser energy on the modification of somatosensory evoked potentials (SEPs) was studied in sensory cortical fields of the rat. This article describes the methodological set-up for recording of SEPs and for determining location and size of the laser-induced lesion. The results show that both the size of the lesion of the somatosensory cortex, and the suppression and time of recovery of cortical SEPs varied depending on the laser energy dose. It remains to be analyzed by further experiments if the recovery of SEPs is due to a transient dysfunction of the somatosensory cortex or if it reflects cortical plasticity.