Journal of Neurophysiology

Binder, M. D.; Stuart, D. G.

doi: N/Apmid: 6445413

Abstract 1. The responses of deefferented Ia and spindle group II afferents to electrically activated twitch contractions of randomly selected motor units of the cat tibialis posterior muscle have been studied. Each afferent was paired with from 8 to 20 of the muscle's 60 motor units, and each afferent-motor unit interaction was recorded to two muscle lengths. 2. Cross-correlation histograms were compiled for each afferent-motor unit interaction studied as well as the average twitch tension produced by the motor unit. A numerical "coupling index" was computed for the histogram distributions to quantitate the extent of mechanical coupling between the receptor and the single motor units. 3. Qualitatively, no consistent differences were noted in the responses of Ia and spindle group II afferents to single motor-unit contractions. However, Ia afferents were responsive to a higher percentage of motor units with which they were tested (89%) and, on the average, displayed a significantly larger magnitude of response (mean coupling index, 0.72 +/- 0.04 SE) than the spindle group II afferents (66% of motor units; mean coupling index, 0.51 +/- 0.03). 4. The extent to which a motor-unit contraction altered the discharge pattern of a spindle afferent was not strictly related to the amount of force generated by the unit, nor to its contraction time. 5. Muscle length exerted a strong influence on both the qualitative and quantitative features of many of the motor unit-muscle receptor interactions. 6. These results suggest that the degree of "mechanical coupling" between a receptor and a motor unit is largely dependent on anatomical arrangements and reinforce the possibility that muscle receptors generate a "sensory partitioning" of the motor-unit population within a muscle. Copyright © 1980 the American Physiological Society

Yokota, T.; Nishikawa, N.

doi: N/Apmid: 7373354

Abstract 1. The medulla oblongata caudal to the obex was explored with glass capillary microelectrodes filled with fast green dye in urethan-chloralose-anesthetized cats. Concurrently, the trigeminal integument was mechanically stimulated. Two classes of units, which were activated by innocuous mechanical stimulation of the ipsilateral trigeminal integument, were identified. Both of them showed a somatotopic organization. 2. Units maximally activated by tactile stimulation of a small receptive field in the ipsilateral trigeminal integument were located in pars magnocellularis of the trigeminal subnucleus caudalis. Receptive field falling within, the mandibular distribution were found in the dorsomedial part of pars magnocellularis, maxillary fields occurred next, and ophthalmic fields were represented ventrolaterally. The rostrum (the mouth and nose) was represented just behind the obex, and the receptive field represented gradually shifted to the periphery of the face along the rostrocaudal axis, finally proceeding to dermatomes of cervical segments. At each transverse plane, tactile sensation of the most rostral segment of the represented integument projected onto the marginal zone of pars magnocellularis immediately adjacent to substantia gelatinosa, while the most peripheral segment projected onto the core of quasi-semicircular pars magnocellularis. The result is in contrast with the scheme proposed by previous investigators. 3. Within the lateral part of subnucleus reticularis dorsalis medullae oblongatae, which is ventromedially contiguous with pars magnocellularis, trigeminal units homologous with lamina V units in the spinal dorsal horn were identified. Typically, these units had a graded response in the center of the receptive field, but responded only to strong mechanical stimuli applied to the periphery of the receptive field. In the center of the receptive field, tactile stimulation of a small restricted area was effective, and the tactile receptive field showed a somatotopic organization. The mandibular distribution was represented dorsomedially, the maxillary distribution next to that, and the ophthalmic distribution laterally. Furthermore, a rostrocaudal differentiation similar to that observed with tactile units in pars magnocellularis was found. Hence, a double somatotopic representation of tactile sensation within the caudal medulla oblongata was indicated. Copyright © 1980 the American Physiological Society

Van Sluyters, R. C.; Levitt, F. B.

doi: N/Apmid: 7373353

Abstract 1. We have examined the relative roles of visual and nonvisual input to striate cortex cells in causing the breakdown of binocularity produced by brief periods of visual-axis misalignment in kittens. 2. In the first study, the binocularity of single neurons recorded from the striate cortex was assessed in kittens reared with either surgical or optical strabismus. Surgical strabismus was induced by performing a unilateral medial rectus tenotomy, and optical strabismus by means of goggles that held prisms of equal power before the two eyes with their bases oriented in opposite directions. The loss of functional binocular connections was of comparable severity in these two groups of kittens. Control kittens, reared wearing goggles containing prisms whose bases were oriented in the same direction, showed normal levels of binocularity. 3. In the second experiment, normal kittens were given a surgical strabismus at around 1 mo of age and kept in total darkness for 2 days, 2 wk, or 4 wk. Cortical binocularity was normal in these kittens. 4. Finally, a group of kittens was reared in the illuminated colony with a symmetric surgical strabismus (bilateral medial rectus tenotomy). These kittens suffered a severe loss in cortical binocularity that was comparable to that seen in control kittens reared with asymmetric (unilateral) strabismus. 5. We conclude that altered visual input caused by misregister of the images falling in the two eyes is necessary and almost certainly sufficient to cause breakdown of cortical binocularity in kittens exposed to brief periods of divergent strabismus and that, when strabismus is induced surgically, this loss of binocularity is not dependent on the symmetry of the surgical manipulation; we thus find no evidence for a special role of afferents from the extraocular muscles in producing this effect. Copyright © 1980 the American Physiological Society

Mano, N.; Yamamoto, K.

doi: N/Apmid: 6768848

Abstract 1. Three rhesus monkeys were trained to perform a rapid (greater than 100 degrees/s) and a slow (less than 100 degrees/s) wrist movement guided by a visual cue. While the monkey performed wrist flexion or extension from a neutral position, Purkinje cell (P-cell) discharges were recorded from intermediate and lateral parts of lobules IV--VI of the cerebellum. 2. By the visually guided movement, we could control the direction of the wrist movement; the holding position at three different angles of the wrist joint: neutral, about 30 degrees flexed, and extended; and the velocity in four ranges: a) 10--30, b) 30--100, c) 100--300, and d) 300-650 degrees/s. 3. From 92 P-cells that significantly increased or decreased the discharge rate of simple spikes with task performance, we selected 45 P-cells ("response-locked" cells) as related to the wrist movement by statistical analyses of temporal correlation of P-cell activities to wrist movement. The direction of the frequency modulation (increase or decrease) was in a nonreciprocal fashion with oppositely directed wrist movements (flexion or extension) in 90% of the response-locked P-cells. The maintained frequencies at three holding positions did not significantly differ. 4. Nineteen P-cells changed their spike frequencies temporally locked to both rapid and slow wrist movements. By the discharge pattern in relation to the rapid and slow movements, these cells were classified into two groups. Discharge pattern in group I P-cells (n = 5) conformed very well to that of velocity, and a linear correlation between the instantaneous increase of the discharge rate and velocity was observed in analyses of individual trials. Group II cells showed increase (n = 9) or decrease (n = 5) of firing rate (20--50 spikes/s) larger than group I cells (less than 10 spikes/s) as long as the wrist was moving, even with very slow velocity (less than 30 degrees/s. The correlations between the increase of the discharge rate and the velocity in individual trials were less clear in group II than in group I cells. 5. The present study suggests the importance of the cerebellar cortex in controlling the slow limb movement as well as the rapid movement. The selected P-cells in this study also suggested that the velocity or some dynamic aspect related to the velocity of limb movement is the major information among the dissociated motion parameters coded by the simple-spike frequencies of the P-cells in the cerebellar hemisphere. Whether the latter suggestion represents an essential characteristic of all limb movement-related P-cells or reflects only a feature of a special subgroup among the movement-related cells should be clarified in future experiments. Copyright © 1980 the American Physiological Society

Rhoades, R. W.; Chalupa, L. M.

doi: N/Apmid: 7373351

Abstract 1. Monocular enucleation in infant hamsters results in a marked expansion of the normally very limited ipsilateral retinotectal projection (13). In 34 hamsters subjected to removal of one eye within 12 h of birth, the receptive-field characteristics of superior collicular neurons ipsilateral and contralateral to the remaining eye were investigated quantitatively and compared to those of normal animals. In six additional neonatal enucleates, the density of the expanded retinotectal projection was studied with the autoradiographic method and an attempt was made to relate the anatomical reorganization with the electrophysiological findings, 2. The response characteristics of visual cells in the colliculus contralateral to the remaining eye were not significantly different from those observed in normal animals. In the ipsilateral tectum, however, numerous changes were observed. Visual receptive fields were abnormally large. The incidence of directional selectivity was markedly reduced, as were the magnitudes of the discharges elicited by either flashed or moving stimuli. Fewer cells were activated by small flashed spots and most of the units that were responsive to such stimulation failed to exhibit the surround suppression typical for the majority of tectal neurons in normal hamsters. Most cells in the ipsilateral colliculus responded only to relatively low (less than 50 degrees/s) stimulus velocities and response decrements resulting from repeated stimulation also occurred much more readily for the neurons tested on this side. 3. The results of additional experiments in neonatal enucleates (n = 8), which were also subjected to acute bilateral removal of the visual cortex, demonstrated that such damage resulted in a marked reduction in the incidence of directional selectivity in the colliculus contralateral to the remaining eye but had no effect on the responses of cells innervated by the aberrant ipsilateral pathway. 4. A correlation between the relative density of the ipsilateral retinal projection at different points in the colliculus, as demonstrated by the autroradiography and the nature of the visual responses obtained in different portions of the structure, indicated that receptive-field size was negatively correlated with the density of the aberrant retinotectal projection and that absolute responsivity (number of impulses elicited by an optimal stimulus) was positively correlated with autoradiographic grain density. 5. These findings demonstrate that while the aberrant retinocollicular projection can, along with the other visual inputs to the tectum, result in the organization of normal response properties for a small number of tectal neurons, the majority of the visual cells innervated by this pathway have responses that are appreciably different from normal. Copyright © 1980 the American Physiological Society

Gillette, R.; Gillette, M. U.; Davis, W. J.

doi: N/Apmid: 6246219

Abstract 1. The ventral white cells (VWC's) of the buccal ganglion of Pleurobranchaea, so named for their position and color, are a bilateral pair of neuron somata. Each sends a single axon out its contralateral stomatogastric nerve and has a dendritic field originating close to the soma. 2. The vwcs exhibit spontaneous episodes of prolonged depolarization (duration 1--4 min) accompanied by repetitive action-potential activity and separated by regular intervals of 3--30 min. Such prolonged burst episodes can be triggered by short pulses of depolarizing current. During the repetitive activity of the spontaneous bursts or that driven by imposed depolarization, the action potentials progressively broaden to 5--16 times their initial duration. 3. During spontaneous bursting or activity driven by imposed depolarization, the cyclic motor output of the feeding network is initiated or accelerated with a latency corresponding with the development of appreciable VWC spike broadening. When broadening of antidromic VWC spikes is suppressed by imposed hyperpolarization of the soma, the frequency of feeding cycles is significantly lower than when broadened spikes are allowed to develop. When trains of spikes are driven by depolarizing current, the motor output of the feeding network is not initiated until the VWC spikes have broadened to a repeatable "threshold" duration, regardless of the intensity of the depolarizing current. 4. The endogenous production of prolonged burst episodes, triggered by depolarizing current pulses, and progressive spike broadening can be demonstrated in the surgically isolated VWC soma. 5. The paired VWCs are strongly electrically coupled and display highly synchronous activity. They receive synaptic inputs from many previously identified interneurons of the feeding network and are thus reciprocally coupled within the network. 6. These results demonstrate that the capacity of this neuron to generate broadened action potentials during repetitive activity confers the ability to command coordinated motor-network output. The appropriate repetitive activity can be produced endogenously in the form of prolonged bursts of spikes. Copyright © 1980 the American Physiological Society

Byrne, J. H.

doi: N/Apmid: 6246217

Abstract 1. The release of ink in response to a noxious stimulus is a relatively stereotyped behavior produced by strong and long-lasting stimuli. The purpose of this series of papers is to determine the quantitative extent to which the known voltage- and time-dependent ionic conductance mechanisms and synaptic influences can account for the ink gland motor neurons' firing pattern and, thus, the features of the behavior. 2. Four voltage- and time-dependent ionic currents have been analyzed. These include a fast transiet Na+-mediated inward current, a slower Ca2+-mediated inward current, a fast transient K+-mediated outward current, and a slower delayed outward current also mediated by K+ ions. 3. The current-voltage (I-V) relationships, equilibrium potentials, and steady-state activation and inactivation characteristics appear qualitatively similar to comparable currents observed in other gastropod neurons. 4. The recovery from inactivation of the delayed outward current has two time constants, one comparable to the inactivation time constant and the other more than an order of magnitude larger. The fast transient K+ current also appears to have a similar slow recovery from inactivation. 5. The synaptic current contributing to the firing pattern of the ink motor cells is a complex function of time. Initially, the synaptic conductance is high and the equilibrium potential near 0 mV. But, with time there is a gradual decrease in synaptic conductance and shift in the equilibrium potential to more depolarized levels. Copyright © 1980 the American Physiological Society

Wood, H. L.; Glantz, R. M.

doi: N/Apmid: 7373355

Abstract 1. The visual responses and synaptic interactions of a small population of crayfish interneurons are described. 2. The discharge of optic nerve sustaining fibers (tonic on-cells) appears in the brain prior to the onset of the light-evoked discharge of any of the higher order, descending visual interneurons. Direct depolarization of impaled sustaining fibers elicits impulse responses in a large number of descending interneurons. These results indicate that the sustaining fibers provide the visual input to higher order interneurons. 3. Four classes of descending interneurons can be distinguished. All arise in the brain and have axons in the circumesophageal connectives. The response forms vary from tonic to phasic. Two classes of tonic cells are distinguished by response latency and two classes of phasic neurons are distinguished by the rate of response adaptation. The phasic neurons exhibit the most rapid habituation, the largest receptive fields, and the most potent nonvisual inputs. 4. Synaptic interactions are studied by cross-correlation of impulse trains and direct observation of synaptic potentials. About 84% of the cells examined reveal evidence of functional connections to other descending visual interneurons. 5. Cross-correlograms derived from impulses of parallel interneurons exhibit a mean time lage to peak of 6.6 +/- 2.8 ms (SD). The measured delay from EPSP onset to spike onset is 6.0 +/- 4.0 ms. Thus a substantial proportion of the correlogram's time lag to peak is associated with postsynaptic integration time. 6. Direct depolarization of impaled tonic on-cells elicits impulse activity at a fixed delay in other descending interneurons. 7. Synaptic potentials in descending visual interneurons are correlated 1:1 with axon spikes of other descending interneurons. 8. A third of the 80 interactions examined were reciprocal and many cells were implicated in multiple interactions. 9. The results suggest that the descending visual interneurons are organized in a complex network, which can cordinate the discharge of various subpopulations of the ensemble. It is proposed that the coordination of impulses in parallel interneurons may be a mechanism for coding and information transfer in the crayfish nervous system. Copyright © 1980 the American Physiological Society

Tritt, S. H.; Byrne, J. H.

doi: N/Apmid: 6246216

Abstract 1. Using combined morphological and electrophysiological techniques, we have identified motor neurons in the right pleural ganglion of Aplysia californica that contribute to the release of opaline from the opaline gland. 2. Three pleural ganglion neurons were found to meet the requirements for identification as opaline gland motor neurons by a) sending processes in nerve P5, which innervates the gland; b) producing contractions of the gland in the absence of central synaptic activity; and c) producing excitatory junctional potentials (EJPs) in cells making up the opaline gland itself. The neurons can be reliably located and have been designated PLR1, PLR2, and PLR3. 3. When gland contraction is measured by the change in luminal pressure, the gland response is a graded function of low-frequency spike activity in the motor neurons. 4. Presumptive EJPs recorded from opaline gland cells are reversibly decreased in size by high extracellular Mg2+ and reversibly increased in size by raising the concentration of extracellular Ca2+. These results suggest that the presumptive EJPs are chemically mediated. The presumptive EJPs show facilitation and posttetanic potentiation. 5. The identified opaline motor neurons may constitute a significant portion of the motor input to the opaline gland via nerve P5 since hyperpolarization of the cells prevents the opaline gland response elicited by right connective stimulation in vitro. 6. We have compared the properties of the opaline motor neurons with the previously identified properties of the ink motor neurons (6--9, 19). Like the ink motor neurons, the opaline motor neurons have high resting potentials, are electrically coupled, and have no spontaneous spike activity. They also receive a slow and long-lasting evoked depolarizing synaptic input, which appears to be mediated by a decreased conductance mechanism. The firing pattern of the opaline motor neurons produced by synaptic input shows the same delayed bursting pattern previously described for the ink motor neurons. 7. The biophysical properties and synaptic input to the ink motor neurons have been shown to affect the features of inking behavior (4, 6--9, 19). The opaline motor neurons share some of these biophysical characteristics and mediate a defensive behavior similar to ink release. Further comparisons of these behaviors and their underlying neural circuits may provide a better understanding of the extent to which cellular biophysical properties and patterns of synaptic input influence the features of the behaviors that individual neurons mediate. Copyright © 1980 the American Physiological Society

Chan, R. Y.; Naka, K.

doi: N/Apmid: 7373359

Abstract 1. Temporal dynamics of receptive-field components were identified by use of circular stimuli whose diameter was modulated in white-noise fashion. 2. A thin ring of light evoked a complex response from the horizontal-cell soma but not from its axon. 3. All bipolar cells had a biphasic receptive field whose incremental sensitivities were comparable for the field's center and surround. 4. Type-N cells had a biphasic field whose two components were segregated both in time and space. 5. Type-C cells showed nonlinearities, which did not depend on the types of light inputs and which were intrinsic to the cell. 6. Ganglion cells could be classified roughly into two classes: small- and large-field cells. Their main nonlinearity was rectification. 7. Our studies on the catfish retna have shown that the distal cells are essentially linear in time and space and can be identified functionally by any type of input. The proximal cells, however, have a complex functional repertoire whose identification poses considerable difficulty. Copyright © 1980 the American Physiological Society