Early botulinum toxin treatment for spastic pes equinovarus--a randomized double-blind placebo-controlled study.

BACKGROUND AND PURPOSE: Spastic pes equinovarus is a frequent pathological posture of the lower extremity. Botulinum toxin (BoNT/A) has been successfully applied to treat lower limb spasticity. However, the best time to initiate treatment remains unclear. A beneficial effect of an early treatment has been suggested in previous studies. METHODS: A single-centre double-blind randomized placebo-controlled trial was performed to investigate the efficacy of BoNT/A to reduce muscle hypertonicity at the ankle. Fifty-two patients with unilateral or bilateral spastic pes equinovarus with a modified Ashworth score (mAS) of at least 1+ after stroke, traumatic brain injury or hypoxic encephalopathy were allocated to receive either BoNT/A or placebo treatment. A second, open injection was optional at week 12. Patients received unilateral or bilateral injections with 230 or 460 U onabotulinumtoxinA, respectively. The course of the mAS was explored during the open study phase. RESULTS: Patients who had received BoNT/A treatment had lower mAS compared with placebo at week 12 (P < 0.01). During the open label phase, patients from the placebo group showed further deterioration of muscle tone despite starting from a similar baseline and receiving BoNT treatment. Spastic feet that had received BoNT/A in the first cycle had comparatively lower mAS scores over all follow-up data and at week 24 (P < 0.01). CONCLUSIONS: The study demonstrates a reduction of muscular hypertonicity in spastic pes equines with BoNT/A treatment given during the first 3 months after the lesion. Exploratory analyses of the course of muscular hypertonicity during the open phase favour earlier to later treatment.

Botulinum toxin B increases mouth opening in patients with spastic trismus.

BACKGROUND: Severe generalized spastic movement disorders of various aetiologies often involve the jaw muscles and lead to a spastic trismus with masseter muscle hypertonia. We report a placebo-controlled randomized study on patients with spastic trismus. METHODS: Eleven patients with masseter hypertonia because of stroke, hypoxic encephalopathy or traumatic brain injury were allocated to either botulinum toxin serotype B (BoNT/B) injections into the masseter muscles or placebo treatment. The dental gap, the amount of saliva, salivation scales, and a clinical goal attainment were evaluated. RESULTS: Three weeks after injection the BoNT/B group showed a significantly increased mouth opening compared with placebo treatment (P < 0.05). In addition to the muscle paralysing effect, a goal attainment scale demonstrated a clinical benefit for the BoNT/B group (P < 0.01). CONCLUSIONS: Botulinum toxin serotype B injections into the masseter muscles effectively reduce hypertonia and provide for better mouth opening, thereby contributing to a positive and desired clinical goal.

[Freezing of gait : phenomenology, pathophysiology, and therapeutic approaches]. / Freezing während des Gehens : Phänomen, Pathophysiologie, Therapie.

Freezing of gait (FOG) is a common disturbance in Parkinson's disease (PD) and other higher-level gait disorders. It appears most often during the later stages of PD but is seen also during the initial phases before oral substitution of levodopa has started. The disorder has its own pathophysiology and differs from bradykinesia. It can occur both on and off medication. It interferes with activities of daily life, reduces mobility, and is an important risk factor for falling. While patients with FOG during medication do not reliably respond to pharmacotherapy or deep brain stimulation, external cues have been demonstrated that influence FOG effectively. They are applied as auditory, visual, tactile, or mental cues. This article discusses available pharmacological and physiotherapeutic approaches to the treatment of FOG.

Inhibitory conditioning stimulus in transcranial magnetic stimulation reduces the number of excited spinal motor neurons.

OBJECTIVE: To study the mechanisms of amplitude attenuation caused by a transcranial magnetic conditioning stimulus. Both conventional MEPs and the recently described triple stimulation technique (TST) were applied; the latter to improve the quantification of the response size decrease. METHODS: TST uses a peripheral collision method to eliminate the effects of desynchronization of the transcranial magnetic stimulation (TMS) induced spinal motor neuron discharges. The attenuation of motor evoked potentials (MEPs) and responses to TST was studied in 10 healthy volunteers using the conditioning-test paradigm with 2 ms interstimulus intervals. RESULTS: Conventional MEPs and responses to TST demonstrated a marked attenuation by the preceding conditioning stimulus in all subjects. The ratio of MEP to TST amplitudes was the same in conditioned and unconditioned responses. CONCLUSIONS: Our findings suggest that the transcranial conditioning stimulus does not change the degrees of desynchronization of spinal motor neuron discharges, but results in a reduced number of excited alpha motor neurons. This reduction can be estimated by both MEPs and TST.

Tremor analysis in two normal cohorts.

OBJECTIVE: Quantitative tremor analyses using almost identical methods were compared between two independent large normal cohorts, to separate robust measures that may readily be used diagnostically from more critical ones needing lab-specific normalization. METHODS: Hand accelerometry and surface EMG from forearm flexors and extensors were recorded with (500 and 1000 g) and without weight loading under postural conditions in 117 and 67 normal volunteers in two different specialty centers for movement disorders in Germany. RESULTS: Tremor amplitude (total power) and frequency fell within a similar range but differed significantly. A significant reduction of tremor frequency under 1000 g weight load (>1 Hz), and a lack of rhythmic EMG activity at the tremor frequency in around 85-90% of the recordings were robust findings in both centers. CONCLUSIONS: The differences in frequency and total power indicate that these measures critically depend on the details of the recording conditions being slightly different between the two centers. Thus each lab needs to establish its own normative data. We estimate that at least 25 normal subjects have to be recorded to obtain normal values. The reduction of tremor frequency under load and lacking tremor-related EMG activity were well reproducible allowing a differentiation of physiological from low amplitude pathological tremor. SIGNIFICANCE: This study provides a framework for more standardized tremor analyses in clinical neurophysiology.

Fast corticospinal system and motor performance in children: conduction proceeds skill.

Transcranial magnetic stimulation and motor performance tests were used to study the correlation between corticospinal maturation and actual motor performance in a group of young school children (n = 10, mean age = 7 years, age range = 6-9 years). The results were compared with normal adults (n = 10, mean age = 24 years, age range = 22-26 years). In children the central conduction time under the preinnervation condition of facilitation and the postexcitatory silent period was similar to that in adults. However, the central conduction time under relaxation, the latency jump (defined as the difference between the two preinnervation conditions), and the stimulus intensity were statistically different between children and adults (P < 0.01-0.001). Children did not reach the same level of performance as adults in any of the motor performance tasks (simple acoustic reaction time, tapping, ballistic movement, tracking, and diadochokinesis) (P < 0.05-0.01). The results indicate that at an early school age, children already possess mature fast corticospinal pathways able to access spinal motoneurons through the pyramidal tract. However, despite the partially adult-like level of neuronal maturation, young school children were not able to perform deliberate motor actions with the same proficiency as adults.

Transcranial magnetic stimulation in patients with Rett syndrome: preliminary results.

Transcranial magnetic stimulation was used to investigate Rett patients (n = 31, age 2-38 years). The results were compared to healthy control persons (n = 112, age 1 month-35 years). The peripheral conduction time showed no difference between the patients and control persons. The mean central conduction time, however, was shorter in the younger patients with Rett syndrome, and this is particularly evident in the youngest. This phenomenon could be interpreted as cortical and/or spinal hyperexcitability which occurs during the early stages of Rett syndrome.

Absence of transcallosal inhibition in adolescents with diplegic cerebral palsy.

The role of intracortical organization in the pathophysiology of cerebral palsy (CP) is not clear. We used transcranial magnetic stimulation to investigate the paradigm of transcallosal inhibition (TI) in a group of adolescent patients with diplegic CP (n = 4), hereditary spastic paraplegia (n = 2), and healthy control adolescents (n = 4). None of the patients with CP showed TI, whereas all other subjects had normal TI. These findings indicate a lack of inhibitory control of the motor cortex in CP.

Subthalamic nucleus stimulation in Parkinson's disease: correlation of active electrode contacts with intraoperative microrecordings.

BACKGROUND/AIMS: The most effective site for subthalamic nucleus (STN) stimulation has remained unclear. The position of active contacts relative to the dorsal margin of the STN was determined. METHODS: Electrodes (n = 49) were implanted following STN mapping by microrecording and microstimulation along five tracks (n = 25 patients). The stereotactic position of active contacts was determined and correlated with microrecordings using an algorithm for direct three-dimensional comparisons (n = 37). RESULTS: Most active contacts were detected within +/-1.0 mm from the dorsal margin of the STN as defined by microrecording (32.4%) or farther dorsal in the subthalamic area (37.8%), and only 29.7% were localized to the STN proper. This was consistent with the average stereotactic coordinates of the active contacts in these three groups. CONCLUSION: Our data suggest that the dorsal border area of the STN is the most effective target. Besides the dorsolateral STN (sensorimotor part) this may include projections from/to STN, the zona incerta, and pallidofugal projections in the fields of Forel.

Methylphenidate enhances both intracortical inhibition and facilitation in healthy adults.

Transcranial magnetic stimulation was used to investigate the effect of the psychostimulant drug methylphenidate (MPH) on motor cortex excitability in healthy adults (n = 12) in a placebo-controlled, crossover design study. MPH caused an enhancement of intracortical inhibition as well as intracortical facilitation. Enhancement of both of these TMS parameters was unexpected and suggests that MPH exerts its action on the motor cortex not only through the dopaminergic neurotransmitter system.

Absence of transcallosal inhibition following focal magnetic stimulation in preschool children.

Focal transcranial magnetic stimulation of the hand-associated motor cortex was used to study normal healthy preschool children (n = 7; mean age, 4.6 years) and adults (n = 7; mean age, 29.4 years) under the conditions of standardized tonic voluntary contraction of small hand muscles. Callosally mediated inhibitory as well as corticospinally mediated inhibitory and excitatory motor effects were investigated. Although children had no detectable transcallosal inhibition, their corticospinally mediated postexcitatory silent period was present (mean, 140.8 +/- 30.2 msec). It was significantly shorter than in adults (mean, 192.5 +/- 32.0 msec). The motor thresholds of the cortically elicited muscle responses, measured as the lowest stimulus intensity, were significantly higher in children (mean, 89 +/- 5%) than in adults (mean, 46 +/- 6%). The corticomuscular latency of transcranially elicited motor responses revealed no difference between children and adults. These observations may reflect maturation processes in the motor system. Maturation of at least some direct corticospinal fibers occurs early in life and is followed by that of intracortical excitatory and inhibitory connections. The maturation of functionally competent callosal connections appears to occur after the age of 5 years.

Low level of intracortical inhibition in children shown by transcranial magnetic stimulation.

Transcranial magnetic stimulation (TMS) is an established neurophysiological tool to evaluate the integrity and maturation of the corticospinal tract. TMS was used in this study to compare intracortical inhibition (ICI) in children, adolescents, and adults. The paired-pulse technique of TMS with interstimulus intervals of 2 ms was used to determine the ratio of conditioned (cMEP) and unconditioned amplitudes (ucMEP) that measures ICI. In experiment 1 (Exp 1) stimulus intensity was adapted to motor threshold (50 healthy subjects; 24 male, 26 female, median age 13.5 years, range 6.3 - 34 years) and in experiment 2 (Exp 2) stimulus intensity was adapted to the ucMEP (200 - 400 microV). Children (quotient of cMEP and ucMEP: Exp. 1: 0.71 +/- 0.41, Exp. 2: 0.82 +/- 0.25) had significantly less ICI compared to adults (Exp. 1: 0.21 +/- 0.19, mean +/- STD, Exp. 2: 0.35 +/- 0.22, in both experiments p < 0.001). Recently, ICI has been linked to the regulating function of GABAergic cortical interneurons on practice-dependent neuronal plasticity. Therefore, the lower ICI in children points to maturation processes that may have implications for the greater capacity of practice-dependent neuronal plasticity in children.

Development of the corticospinal system and hand motor function: central conduction times and motor performance tests.

Maturation of the corticospinal (CS) tract and hand motor function provide paradigms for central nervous system development. In this study, involving 112 participants (aged from 0.2 to 30 years), we evaluated central motor conduction times (CMCT) obtained with transcranial magnetic stimulation (TMS) during preinnervation conditions of facilitation and relaxation. Auditory reaction time, velocity of a ballistic movement of the arm, finger tapping, diadochokinesis, and fine motor visuomanual tracking were also examined. The maturation profiles for every parameter were calculated. CMCTs for the different preinnervation conditions reached adult values at different times and this could be explained by maturation of excitability at the cortical and spinal level. A stable phase for CMCTs and reaction time was reached during childhood. Parameters which measured motor speed and skill indicated that the development of these continued into adulthood. The maturation of the fast CS tract seems to be completed before the acquisition of the related motor performance has been accomplished. In conclusion, we could demonstrate that data from several neurophysiological methods can be combined and used to study the maturation of the function of the nervous system. This approach could allow appraisal of pathological conditions that show parallels with omissions or lack of developmental progress.

Deep brain stimulation of the subthalamic nucleus in Parkinson's disease: evaluation of active electrode contacts.

BACKGROUND: The subthalamic nucleus is the preferred target for deep brain stimulation in patients with advanced Parkinson's disease. The site of permanent stimulation is the subject of ongoing debate, as stimulation both within and adjacent to the subthalamic nucleus may be effective. OBJECTIVE: To assess the position of active electrode contacts in relation to the dorsal margin of the subthalamic nucleus as determined by intraoperative microrecordings and magnetic resonance imaging (MRI). METHODS: In 25 patients suffering from severe levodopa sensitive parkinsonism, deep brain stimulating electrodes (n = 49) were implanted following mapping of the subthalamic nucleus by microrecording and microstimulation along five parallel tracks. Postoperative stereotactic radiography and fusion of pre- and postoperative MRI studies were used to determine the stereotactic position relative to the midcommissural point of the most effective electrode contacts selected for permanent stimulation (n = 49). Intraoperative microrecordings were analysed retrospectively to define the dorsal margin of the subthalamic nucleus. In cases where the dorsal margin could be defined in at least three microrecording tracks (n = 37) it was correlated with the position of the active contact using an algorithm developed for direct three dimensional comparisons. RESULTS: Stimulation of the subthalamic nucleus resulted in marked improvement in levodopa sensitive parkinsonian symptoms and levodopa induced dyskinesias, with significant improvement in UPDRS III scores. In several instances, projection of the electrode artefacts onto the T2 weighted MRI visualised subthalamic nucleus of individual patients suggested that the electrodes had passed through the subthalamic nucleus. When the actual position of active electrode contacts (n = 35) was correlated with the dorsal margin of the subthalamic nucleus as defined neurophysiologically, most contacts were located either in proximity (+/- 1.0 mm) to the dorsal border of the subthalamic nucleus (32.4%) or further dorsal within the subthalamic region (37.8%). The other active contacts (29.7%) were detected within the dorsal (sensorimotor) subthalamic nucleus. The average position of all active contacts (n = 49) was 12.8 mm (+/- 1.0) lateral, 1.9 mm (+/- 1.4) posterior, and 1.6 mm (+/- 2.1) ventral to the midcommissural point. CONCLUSIONS: Subthalamic nucleus stimulation appears to be most effective in the border area between the upper subthalamic nucleus (sensorimotor part) and the subthalamic area containing the zona incerta, fields of Forel, and subthalamic nucleus projections.