Amplitude modulation of the soleus H reflex in the human during active and passive stepping movementsBrooke, J. D.; Cheng, J.; Misiaszek, J. E.; Lafferty, K.
doi: N/Apmid: 7714556
Abstract 1. It was hypothesized that passive movement of either the whole leg or its separate segments, in a manner mimicking human gait, leads to attenuation of the soleus H reflex. It was further hypothesized that this attenuation arises from presynaptic effects. Reflex amplitudes were observed in humans during natural bipedal and unipedal stepping on the spot, during passive stepping, during passive movement of the lower limb segments about the hip, knee, and ankle individually in a stepping fashion, and during passive movement with tonic contraction of the soleus muscle. 2. In natural stepping at a cadence of 54 steps/min, the reflex means were substantially depressed in the swing phase (P < 0.01). (Means, standing control 90.1%, unipedal 8.3%, bipedal 6.9%, of maximum M wave.) During the stance phase, reflex magnitudes were mildly and significantly elevated in four of six subjects, compared with standing controls (P < 0.05). 3. For passive stepping, subjects were dorsally tilted 20 and 90 degrees (lying supine) from the vertical position, to obtain quiet electromyograms (EMGs) in the postural muscles. Recorded during natural stepping, the right leg was manipulated to match the electrogoniometer traces of the three major joints. 4. At 20 degrees of tilt of the body, mean H reflexes were significantly lower, by 26.4%, compared with the supine position (P < 0.05). During passive stepping movement of the leg at 54 steps/min, the reflex was profoundly attenuated over the entire cycle (P < 0.01). The significantly attenuated reflexes during active stepping and during passive stepping movement of the whole leg were not significantly different at the point where the limb approached full flexion in the swing phase (P > 0.48). This was the case for measurements made at either body position, 20 degrees dorsal tilt or supine. 5. Passive flexion-extension, around either the hip or the knee, significantly inhibited the mean reflex magnitude close to full flexion, at either body position (P < 0.01). Such movement around the ankle resulted in significant inhibition of the reflex in two of the four subjects (P < 0.05). The numeric sum of the reflex depression arising from the flexion-extension of the individual joints was greater than that arising from movement of the whole limb. 6. With the ankle braced, the significant reflex attenuation remained when a tonic isometric contraction of the soleus muscle was introduced. This suggests premotoneuronal mechanisms for the inhibition.(ABSTRACT TRUNCATED AT 400 WORDS) Copyright © 1995 the American Physiological Society
Effects of superior temporal polysensory area lesions on eye movements in the macaque monkeyScalaidhe, S. P.; Albright, T. D.; Rodman, H. R.; Gross, C. G.
doi: N/Apmid: 7714555
Abstract 1. On the basis of its anatomic connections and single-unit properties, the superior temporal polysensory area (STP) would seem to be primarily involved in visuospatial functions. We have examined the effects of lesions of STP on saccadic eye movements, visual fixation, and smooth pursuit eye movements to directly test the hypothesis that STP is involved in visuospatial and visuomotor behavior. 2. Seven monkeys were trained to make saccades to targets 8, 15, and 22 degrees from a central fixation point along the horizontal meridian and 8 degrees from the central fixation point along the vertical meridian. One monkey was also trained to make saccades to auditory targets. The same monkeys were trained to foveate a stationary central fixation point and to follow it with a smooth pursuit eye movement when it began moving 5, 13, or 20 degrees/s. Four monkeys received unilateral STP lesions, one received a bilateral STP lesion, and as a control, two received unilateral inferior temporal cortex (IT) lesions. After testing, three of the animals with unilateral STP lesions received an additional STP lesion in the hemisphere contralateral to the first lesion. Similarly, one animal with a unilateral IT lesion received an additional IT lesion in the hemisphere contralateral to the first lesion. 3. All monkeys with complete removal of STP showed a significant increase in saccade latency to the most peripheral contralateral target, and most also had increased saccade latencies to the other contralateral targets. Saccades directed to targets along the vertical meridian or toward targets in the hemifield ipsilateral to the lesion were not impaired by removal of STP. By contrast, IT lesions did not impair the monkeys' ability to make saccadic eye movements to visual stimuli at any location, showing that saccades to visually guided targets are not impaired nonspecifically by damage to visual cortex. 4. The deficit in making eye movements after STP lesions was specific to saccade latency, with little effect on the accuracy of saccades to visual targets. 5. In the one monkey trained to make saccades to auditory targets, removal of STP did not impair saccades to auditory targets contralateral to its lesion, despite this monkey showing the largest increase in saccades latencies to visual targets. 6. There was complete recovery of saccade latency to the baseline level of performance on the saccade task after all STP lesions.(ABSTRACT TRUNCATED AT 400 WORDS) Copyright © 1995 the American Physiological Society
Impairments of reaching movements in patients without proprioception. II. Effects of visual information on accuracyGhez, C.; Gordon, J.; Ghilardi, M. F.
doi: N/Apmid: 7714578
Abstract 1. The aim of this study was to determine how vision of a cursor indicating hand position on a computer screen or vision of the limb itself improves the accuracy of reaching movements in patients deprived of limb proprioception due to large-fiber sensory neuropathy. In particular, we wished to ascertain the contribution of such information to improved planning rather than to feedback corrections. We analyzed spatial errors and hand trajectories of reaching movements made by subjects moving a hand-held cursor on a digitizing tablet while viewing targets displayed on a computer screen. The errors made when movements were performed without vision of their arm or of a screen cursor were compared with errors made when this information was available concurrently or prior to movement. 2. Both monitoring the screen cursor and seeing their limb in peripheral vision during movement improved the accuracy of the patients' movements. Improvements produced by seeing the cursor during movement are attributable simply to feedback corrections. However, because the target was not present in the actual workspace, improvements associated with vision of the limb must involve more complex corrective mechanisms. 3. Significant improvements in performance also occurred in trials without vision that were performed after viewing the limb at rest or during movements. In particular, prior vision of the limb in motion improved the ability of patients to vary the duration of movements in different directions so as to compensate for the inertial anisotropy of the limb. In addition, there were significant reductions in directional errors, path curvature, and late secondary movements. Comparable improvements in extent, direction, and curvature were produced when subjects could see the screen cursor during alternate movements to targets in different directions. 4. The effects of viewing the limb were transient and decayed during a period of minutes once vision of the limb was no longer available. 5. It is proposed that the improvements in performance produced after vision of the limb were mediated by the visual updating of internal models of the limb. Vision of the limb at rest may provide configuration information while vision of the limb in motion provides additional dynamic information. Vision of the cursor and the resulting ability to correct ongoing movements, however, is considered primarily to provide information about the dynamic properties of the limb and its response to neural commands. Copyright © 1995 the American Physiological Society
Topography of intensity tuning in cat primary auditory cortex: single-neuron versus multiple-neuron recordingsSutter, M. L.; Schreiner, C. E.
doi: N/Apmid: 7714564
Abstract 1. We studied the spatial distributions of amplitude tuning (monotonicity of rate-level functions) and response threshold of single neurons along the dorsoventral extent of cat primary auditory cortex (AI). To pool data across animals, we used the multiple-unit map of monotonicity as a frame of reference. Amplitude selectivity of multiple units is known to vary systematically along isofrequency contours, which run roughly in the dorsoventral direction. Clusters sharply tuned for intensity (i.e., "nonmonotonic" clusters) are located near the center of the contour. A second nonmonotonic region can be found several millimeters dorsal to the center. We used the locations of these two nonmonotonic regions as reference points to normalize data across animals. Additionally, to compare this study to sharpness of frequency tuning results, we also used multiple-unit bandwidth (BW) maps as references to pool data. 2. The multiple-unit amplitude-related topographies recorded in previous studies were confirmed. Pooled multiple-unit maps closely approximated the previously reported individual case maps when the multiple-unit monotonicity or the map of bandwidth (in octaves) of pure tones to which a cell responds 40 dB above minimum threshold were used as the pooling reference. When the map of bandwidth (in octaves) of pure tones to which a cell responds 10 dB above minimum threshold map was used as part of the measure, the pooled spatial pattern of multiple-unit activity was degraded. 3. Single neurons exhibited nonmonotonic rate-level functions more frequently than multiple units. Although common in single-neuron recordings (28%), strongly nonmonotonic recordings (firing rates reduced by > 50% at high intensities) were uncommon (8%) in multiple-unit recordings. Intermediately nonmonotonic neurons (firing rates reduced between 20% and 50% at high intensities) occurred with nearly equal probability in single-neuron (28%) and multiple-unit (26%) recordings. The remaining recordings for multiple units (66%) and single units (44%) were monotonic (firing rates within 20% of the maximum at the highest tested intensity). 4. In ventral AI (AIv), the topography of monotonicity for single units was qualitatively similar to multiple units, although single units were on average more intensity selective. In dorsal AI (AId) we consistently found a spatial gradient for sharpness of intensity tuning for multiple units; however, for pooled single units in Aid there was no clear topographic gradient. 5. Response (intensity) thresholds of single neurons were not uniformly distributed across the dorsoventral extent of AI.(ABSTRACT TRUNCATED AT 400 WORDS) Copyright © 1995 the American Physiological Society
Nonstationary properties of the saccadic system: new constraints on models of saccadic controlNichols, M. J.; Sparks, D. L.
doi: N/Apmid: 7714588
Abstract 1. We tested the predictions of two models of the saccadic burst generator by electrically stimulating sites in primate superior colliculus (SC) immediately following visually guided movements. 2. The amplitude and direction of stimulated saccades depend systematically on the amplitude and direction of preceding visually guided saccades, and that effect decays exponentially with a time constant of approximately 45 ms. The saccadic system, then, displays an amplitude-dependent non-stationarity that follows an exponential time course during the intersaccadic interval (ISI). 3. These results are consistent with a variant of the eye displacement model proposed by Jurgens et al. but not with Robinson's classic model of the burst generator. Moreover, since all models of saccadic control must predict either stationary or nonstationary behavior during the ISI, these results provide a powerful new constraint on those models. 4. Finally, the success of the displacement model in accounting for our data suggests a new explanation for the results of colliding saccade experiments. Copyright © 1995 the American Physiological Society
Presynaptic calcium-activated potassium channels and calcium channels at a crayfish neuromuscular junctionBlundon, J. A.; Wright, S. N.; Brodwick, M. S.; Bittner, G. D.
doi: N/Apmid: 7714563
Abstract 1. We used a two-microelectrode current clamp to investigate various characteristics of the Ca(2+)-activated K+ conductance gK(Ca) and Ca2+ conductance (gCa), and transmitter release in presynaptic terminals of excitatory neuromuscular junctions in the crayfish walking leg. 2. Voltage-activated Na+ conductances (gNa) and K+ conductances gK(v) were blocked with tetrodotoxin and 3,4-diaminopyridine, respectively. Under these conditions, presynaptic depolarization produced by a first (conditioning) pulse admitted Ca2+ into the presynaptic terminals and activated gK(Ca), which modulated the amplitude of the depolarization produced by a second (test) pulse. The relative amount of gK(Ca) measured at the test pulse increased with increased magnitude or duration of the conditioning pulse. 3. A brief hyperpolarization immediately after a conditioning pulse substantially reduced gK(Ca). 4. gK(Ca) activation was blocked by funnel web spider toxin (a Ca2+ channel blocker) or by injection of the presynaptic terminal region with a calcium chelator, bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid (BAPTA). Under current-clamp conditions, gK(Ca) was not blocked by charybdotoxin or iberiotoxin specific gK(Ca) blockers. 5. When gK(Ca) was blocked or reduced, the amplitude of the depolarizing afterpotential of action potentials was increased. When gK(v) was blocked or reduced, the duration of action potentials was increased. 6. Intracellular injection of BAPTA into the presynaptic terminal region eliminated evoked neurotransmitter release before test pulse modulation was affected, suggesting that the K(Ca) channel had a greater sensitivity (greater affinity or lower stoichiometry) for Ca2+ than did the transmitter release machinery. BAPTA reduced neurotransmitter release by 66-78%, but did not affect facilitation of neurotransmitter release. 7. When gNa, gK(v), and gK(Ca) were blocked, we detected a membrane depolarization produced by an increase in presynaptic gCa that was eliminated by 2 mM Cd2+ or 0 mM Ca2+. Copyright © 1995 the American Physiological Society
Activities of spinal neurons during brain stem-dependent fictive swimming in lampreyBuchanan, J. T.; Kasicki, S.
doi: N/Apmid: 7714592
Abstract 1. We made intracellular microelectrode recordings of membrane potential from spinal neurons during fictive swimming elicited by brief electrical shocks to the spinal cord in a brain stem-spinal cord preparation of the adult silver lamprey (Ichthyomyzon unicuspis). 2. We characterized membrane potential activities recorded during brain stem-dependent fictive swimming in five spinal cell types: myotomal motoneurons, lateral interneurons (inhibitory neurons with ipsilateral descending axons), CC interneurons (neurons with contralateral and caudal projecting axons), edge cells (intraspinal stretch receptors), and dorsal cells (primary mechanosensory neurons with cell bodies in the spinal cord). The membrane potential activities were compared with data from previous reports recorded during fictive swimming in the isolated spinal cord with fictive swimming induced by superfusion with D-glutamate. 3. Compared with the same cell types recorded during D-glutamate-induced fictive swimming in brain stem-dependent fictive swimming, the motoneurons and CC interneurons had significantly larger trough-to-peak amplitudes of membrane potential oscillations, whereas lateral interneurons were not significantly different in amplitude. The timings of the membrane potential oscillations and of cell spiking were not significantly different in the two preparations, with the exception that motoneurons in brain stem-dependent fictive swimming were significantly earlier by approximately 10% of a cycle. Edge cells had only weak or no oscillatory activities, and dorsal cells had no detectable input during brain stem-dependent fictive swimming. These findings are similar to those in D-glutamate-induced fictive swimming.(ABSTRACT TRUNCATED AT 250 WORDS) Copyright © 1995 the American Physiological Society
Functional neural regeneration in the feeding system of Aplysia: behavioral recovery correlated with changes in buccal motor outputScott, M. L.; Li, Y.; Kirk, M. D.
doi: N/Apmid: 7714581
Abstract 1. We tested for functional neural regeneration in the feeding system of Aplysia after bilateral transections or crushes of the cerebral-buccal connectives (CBCs) with the use of behavioral analyses and electrophysiological recordings. 2. Both types of lesion selectively abolished rhythmic consummatory behavior, dramatically increasing bite latency and interbite interval, and decreasing bite magnitude. Appetitive feeding behavior was not affected. 3. About 2 wk after CBC crush, bite latency, bite magnitude, and interbite interval began to recover, as rhythmic biting reappeared; complete recovery of rhythmic biting occurred within 60 days. Rhythmic biting never recovered after transection of the CBCs. 4. The recovery of rhythmic biting was correlated with changes in buccal motor output, which were assessed with the use of in vivo recordings from buccal nerve 4 in freely moving Aplysia. Initially, some bursting in nerve 4 occurred without overt bites; with full recovery of biting, a 1:1 correspondence between bursts in nerve 4 and overt bites returned. 5. CBC lesions caused a functional separation between biting and swallowing; at early times postlesion, subjects displayed apparently normal rhythmic swallowing even though rhythmic biting had been eliminated. However, there was a disruption of the 1:1 correspondence between nerve 4 bursts and swallows, which persisted until consummatory feeding fully recovered. 6. Transection of the CBCs in animals that had fully recovered from a previous CBC crush again abolished rhythmic biting, suggesting that the recovery of consummatory feeding behavior was due to functional neural regeneration of cerebral-buccal connections. Copyright © 1995 the American Physiological Society
Neurons in monkey parietal area LIP are tuned for eye-movement parameters in three-dimensional spaceGnadt, J. W.; Mays, L. E.
doi: N/Apmid: 7714572
Abstract 1. A functional class of neurons in area LIP on the lateral bank of the intraparietal sulcus were shown previously (Gnadt and Andersen 1988) to be related to the metrics of saccadic eye movements. In this study, we tested LIP neurons at different depths with respect to the plane of fixation. 2. Sixty-one neurons were identified for their increased activity before saccadic eye movements. While holding the location of the target constant at the center of the frontoparallel (saccadic) response field, the neurons were tested systematically during eye movements to target positions proximal (near) to the plane of fixation, at the plane of fixation, and distal (far) to the plane of fixation. By necessity, the movements of these targets required a combination of saccadic and vergence movements. 3. Seventy-two percent of the neurons were found to change their activity as a function of target depth relative to the plane of fixation. The neurons had broad tuning curves for depth. Some cells preferred "near" target positions, some preferred "far" positions, and others responded best in the frontoparallel plane of fixation. 4. The location of a neuron's response field in the frontoparallel plane remained constant regardless of target depth. However, the magnitude of the neuron's response increased when the target was positioned at the preferred depth and it decreased for targets positioned at nonpreferred depths. This indicated that the neurons always were related to the same frontoparallel coordinates, but responded more vigorously when the target was positioned at its preferred depth. 5. The visual display apparatus allowed independent presentation of two stimulus cues for depth: binocular disparity and accommodative demand whereas other cues were held constant. For many neurons, either cue was sufficient to tune the activity in depth, though most neurons responded best for the geometrically appropriate combination of the two cues. 6. Comparison of the binocular tuning for depth with the individual monocular responses showed that the tuning for depth was not produced by simple linear combination of two monocular response fields. 7. We tested a subset of the neurons in a double-movement task that dissociated the retinal coordinates of the visual stimuli from the eye-movement coordinates of the second movement. These tests confirmed earlier findings that this functional class of neurons are active when the eye-movement coordinates matched the neurons' response field. It was not necessary for a visual stimulus to fall within the neurons' response field for them to become active.(ABSTRACT TRUNCATED AT 400 WORDS) Copyright © 1995 the American Physiological Society