vendex and Torticollis

To investigate deficiencies in mechanisms of sensorimotor processing and reflexive-voluntary interactions leading to the impaired head position control in primary cervical dystonia.. Thirteen patients and 23 healthy controls were subjected to transient, low amplitude, low velocity head-on-trunk, trunk-under-head and whole-body rotations in the horizontal plane. With the instruction not to resist the imposed displacements, resistance to horizontal neck deflections was evaluated.. Patients exhibited a torque offset (bias) in the direction of torticollis before stimulus application. While controls reduced and occasionally eliminated completely the initial resistance to head-to-trunk rotations, torque in patients increased throughout displacements. Change of resistance relative to baseline in patients was, however, symmetrical, i.e. independent of torticollis direction. Spontaneous torque fluctuations were significantly larger in patients. Strong correlations existed among these abnormal findings.. Patients' ability to manipulate normal postural reactions to head-trunk rotations is impaired. The deficit is bilateral and correlates with the degree of abnormal posture. The present study extends previous work on reflexive-voluntary interactions and provides evidence that malfunctioning proprioceptive feedback may contribute to the pathophysiology of cervical dystonia.

Topics: Adult; Attention; Female; Head; Humans; Male; Middle Aged; Neck; Postural Balance; Proprioception; Reflex; Rotation; Sensation Disorders; Space Perception; Torque; Torticollis; Young Adult

We hypothesised that, since anomalous neck proprioceptive input can produce perturbing effects on posture, neck muscle fatigue could alter body balance control through a mechanism connected to fatigue-induced afferent inflow. Eighteen normal subjects underwent fatiguing contractions of head extensor muscles. Sway during quiet stance was recorded by a dynamometric platform, both prior to and after fatigue and recovery, with eyes open and eyes closed. After each trial, subjects were asked to rate their postural control. Fatigue was induced by having subjects stand upright and exert a force corresponding to about 35% of maximal voluntary effort against a device exerting a head-flexor torque. The first fatiguing period lasted 5 min (F1). After a 5-min recovery period (R1), a second period of fatiguing contraction (F2) and a second period of recovery (R2) followed. Surface EMG activity from dorsal neck muscles was recorded during the contractions and quiet stance trials. EMG median frequency progressively decreased and EMG amplitude progressively increased during fatiguing contractions, demonstrating that muscle fatigue occurred. After F1, subjects swayed to a larger extent compared with control conditions, recovering after R1. Similar findings were obtained after F2 and after R2. Although such behaviour was detectable under both visual conditions, the effects of fatigue reached significance only without vision. Subjective scores of postural control diminished when sway increased, but diminished more, for equal body sway, after fatigue and recovery. Contractions of the same duration, but not inducing EMG signs of fatigue, had much less influence on body sway or subjective scoring. We argue that neck muscle fatigue affects mechanisms of postural control by producing abnormal sensory input to the CNS and a lasting sense of instability. Vision is able to overcome the disturbing effects connected with neck muscle fatigue.

Topics: Adult; Analysis of Variance; Electromyography; Eye; Female; Humans; Male; Middle Aged; Muscle Contraction; Muscle Fatigue; Neck Muscles; Physical Endurance; Posture; Time Factors; Torque; Torticollis; Weight-Bearing

Vestibular and neck proprioceptive signals are known to be used in judging the locations of objects in space and relative to the body. Given that these signals are asymmetric in patients with spasmodic torticollis, one would expect such patients to have abnormal spatial perception. We tested this idea by measuring patients' perception of visual straight ahead (VSA) under various conditions: with the body in its primary position, i.e. with the head and trunk as closely aligned as possible, and after well defined passive rotations of the head and/or trunk. In the primary body position, patients' VSA direction showed considerable variations which were similar, however, to those of normal subjects; it was independent of torticollis direction, of the head torque it produced, and of the weak spontaneous nystagmus recorded in seven of the 10 patients. After whole-body rotations, i.e. where head and trunk underwent the same motion, the VSA was shifted in both patients and normal subjects, and in both groups the shift was symmetrical after rotations to the right or left. After motions where the trunk rotated under the stationary head (neck proprioceptive stimulation) or the head on the stationary trunk (combined vestibular and neck stimulus), the VSAs of normal subjects coincided rather well with their head midsagittal planes, whereas the VSAs of patients were shifted considerably towards the trunk, again in a symmetrical way. We suggest two mechanisms to explain the findings in patients: (i) a central compensation which restores symmetry of the afferent inflow in the patients (unlike the motor efference); (ii) shifting of the reference for the VSA from the head towards the trunk, because the trunk is a more reliable egocentric reference than the head in the patients. Our findings do not support the assumption that asymmetries in afferent inflow are responsible for the asymmetry of motor output in spasmodic torticollis.

Topics: Adult; Eye Movements; Head; Humans; Middle Aged; Orientation; Posture; Psychophysics; Reference Values; Torque; Torticollis