Synchronous afferent discharge from a passive muscle of the cat: significance for interpreting spike-triggered averages

Modulation of human muscle spindle discharge by arterial pulsations--functional effects and consequences

Arterial pulsations are known to modulate muscle spindle firing; however, the physiological significance of such synchronised modulation has not been investigated. Unitary recordings were made from 75 human muscle spindle afferents innervating the pretibial muscles. The modulation of muscle spindle discharge by arterial pulsations was evaluated by R-wave triggered averaging and power spectral analysis. We describe various effects arterial pulsations may have on muscle spindle afferent discharge. Afferents could be "driven" by arterial pulsations, e.g., showing no other spontaneous activity than spikes generated with cardiac rhythmicity. Among afferents showing ongoing discharge that was not primarily related to cardiac rhythmicity we illustrate several mechanisms by which individual spikes may become phase-locked. However, in the majority of afferents the discharge rate was modulated by the pulse wave without spikes being phase locked. Then we assessed whether these influences changed in two physiological conditions in which a sustained increase in muscle sympathetic nerve activity was observed without activation of fusimotor neurones: a maximal inspiratory breath-hold, which causes a fall in systolic pressure, and acute muscle pain, which causes an increase in systolic pressure. The majority of primary muscle spindle afferents displayed pulse-wave modulation, but neither apnoea nor pain had any significant effect on the strength of this modulation, suggesting that the physiological noise injected by the arterial pulsations is robust and relatively insensitive to fluctuations in blood pressure. Within the afferent population there was a similar number of muscle spindles that were inhibited and that were excited by the arterial pulse wave, indicating that after signal integration at the population level, arterial pulsations of opposite polarity would cancel each other out. We speculate that with close-to-threshold stimuli the arterial pulsations may serve as an endogenous noise source that may synchronise the sporadic discharge within the afferent population and thus facilitate the detection of weak stimuli.

Effect of nonlinear summation of synaptic currents on the input-output properties of spinal motoneurons

A single spinal motoneuron receives tens of thousands of synapses. The neurotransmitters released by many of these synapses act on iontotropic receptors and alter the driving potential of neighboring synapses. This interaction introduces an intrinsic nonlinearity in motoneuron input-output properties where the response to two simultaneous inputs is less than the linear sum of the responses to each input alone. Our goal was to determine the impact of this nonlinearity on the current delivered to the soma during activation of predetermined numbers and distributions of excitatory and inhibitory synapses. To accomplish this goal we constructed compartmental models constrained by detailed measurements of the geometry of the dendritic trees of three feline motoneurons. The current "lost" as a result of local changes in driving potential was substantial and resulted in a highly nonlinear relationship between the number of active synapses and the current reaching the soma. Background synaptic activity consisting of a balanced activation of excitatory and inhibitory synapses further decreased the current delivered to the soma, but reduced the nonlinearity with respect to the total number of active excitatory synapses. Unexpectedly, simulations that mimicked experimental measures of nonlinear summation, activation of two sets of excitatory synapses, resulted in nearly linear summation. This result suggests that nonlinear summation can be difficult to detect, despite the substantial "loss" of current arising from nonlinear summation. The magnitude of this "loss" appears to limit motoneuron activity, based solely on activation of iontotropic receptors, to levels that are inadequate to generate functionally meaningful muscle forces.

Synchrony between neurons with similar muscle fields in monkey motor cortex

Synchronous firing of motor cortex cells exhibiting postspike facilitation (PSF) or suppression (PSS) of hand muscle EMG was examined to investigate the relationship between synchrony and output connectivity. Recordings were made in macaque monkeys performing a precision grip task. Synchronization was assessed with cross-correlation histograms of the activity from 144 pairs of simultaneously recorded neurons, while spike-triggered averages of EMG defined the muscle field for each cell. Cell pairs with similar muscle fields showed greater synchronization than pairs with nonoverlapping fields. Furthermore, cells with opposing effects in the same muscles exhibited negative synchronization. We conclude that synchrony in motor cortex engages networks of neurons directly controlling the same muscle set, while inhibitory connections exist between neuronal populations with opposing output effects.

The influence of single VB thalamocortical impulses on barrel columns of rabbit somatosensory cortex

Extracellular recordings were obtained from single neurons in ventrobasal (VB) thalamus of awake rabbits while field potentials were recorded at various depths within topographically aligned and nonaligned barrel columns of somatosensory cortex (S1). Spike-triggered averages of cortical field potentials were obtained following action potentials in thalamic neurons. Action potentials in a VB neuron elicited a cortical response within layer 4 with three distinct components. 1) A biphasic, initially positive response (latency <1 ms) was interpreted to reflect activation of the VB axon terminals (the AxTP). This response was not affected by infusion of an alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)/kainate receptor antagonist within the barrel. In contrast, later components of the response were completely eliminated and were interpreted to reflect focal synaptic potentials. 2) A negative potential [focal synaptic negativity (FSN)] occurred at a mean latency of 1.65 ms and lasted approximately 4 ms. This response had a rapid rise time ( approximately 0.7 ms) and was interpreted to reflect monosynaptic excitation. 3) The third component was a positive potential (the FSP), with a slow rise time and a half-amplitude duration of approximately 30 ms. The FSP showed a weak reversal in superficial cortical layers and was interpreted to reflect di/polysynaptic inhibition. The amplitudes of the AxTP, the FSN, and the FSP reached a peak near layer 4 and were highly attenuated in both superficial and deep cortical layers. All components were attenuated or absent when the cortical electrode was missaligned from the thalamic electrode by a single cortical barrel. Deconvolution procedures revealed that the autocorrelogram of the presynaptic VB neuron had very little influence on either the amplitude or duration of the AxTP or the FSN, and only a minor influence (mean, 11%) on the amplitude of the FSP. We conclude that individual VB thalamic impulses entering a cortical barrel engage both monosynaptic excitatory and di/polysynaptic inhibitory mechanisms. Putative inhibitory interneurons of an S1 barrel receive a highly divergent/convergent monosynaptic input from the topographically aligned VB barreloid, and this results in sharp synchrony among these interneurons. We suggest that single-fiber access to disynaptic inhibition is facilitated by this sharp synchrony, and that the FSP reflects a consequent synchronous wave of feed-forward inhibition within the S1 barrel.

Sharp, local synchrony among putative feed-forward inhibitory interneurons of rabbit somatosensory cortex

Many suspected inhibitory interneurons (SINs) of primary somatosensory cortex (S1) receive a potent monosynaptic thalamic input (thalamocortical SINs, SINstc). It has been proposed that nearly all such SINstc of a S1 barrel column (BC) receive excitatory synaptic input from each member of a subpopulation of neurons within the topographically aligned ventrobasal (VB) thalamic barreloid. Such a divergent and convergent network leads to several testable predictions: sharply synchronous activity should occur between SINstc of a BC, sharp synchrony should not occur between SINstc of neighboring BCs, and sharp synchrony should not occur between SINs or other neurons of the same BC that do not receive potent monosynaptic thalamic input. These predictions were tested by cross-correlating the activity of SINstc of the same and neighboring BCs. Correlations among descending corticofugal neurons of layer 5 (CF-5 neurons, identified by antidromic activation) and other neurons that receive little or no monosynaptic VB input also were examined. SINs were identified by a high-frequency (>600 Hz) burst of three or more spikes elicited by VB stimulation and had action potentials of short duration. SINstc were further differentiated by short synaptic latencies to electrical stimulation of VB thalamus (<1.7 ms) and to peripheral stimulation (<7.5 ms). The above predictions were confirmed fully. 1) Sharp synchrony (+/-1 ms) was seen between all SINstc recorded within the same BC (a mean of 4.26% of the spikes of each SINtc were synchronized sharply with the spikes of the paired SINtc). Sharp synchrony was not dependent on peripheral stimulation, was not oscillatory, and survived general anesthesia. Sharp synchrony was superimposed on a broader synchrony, with a time course of tens of milliseconds. 2) Little or no sharp synchrony was seen when CF-5 neurons were paired with SINstc or other neurons of the same BC. 3) Little or no sharp synchrony was seen when SINstc were paired with other SINstc located in neighboring BCs. Intracellular recordings obtained from three SINs in the fully awake state supported the assertion that SINs are GABAergic interneurons. Each of these cells met our extracellular criteria for identification as a SIN, each had a spike of short duration (0.4-0.5 ms), and each responded to a depolarizing current pulse with a nonadapting train of action potentials. These results support the proposed network linking VB barreloid neurons with SINstc within the topographically aligned BC. We suggest that sharp synchrony among SINstc results in highly synchronous inhibitory postsynpatic potentials (IPSPs)in the target neurons of these cells and that these summated IPSPs may be especially effective when excitatory drive to target cells is weak and asynchronous.

Functional identities of thoracic respiratory interneurones in the cat

1. Spike-triggered averaging was used to reveal focal synaptic potentials (FSPs) in the thoracic ventral horn resulting from impulses in individual respiratory interneurones situated in the contralateral ventral horn of the same segment (T6 or T7) in anaesthetized paralysed cats. 2. FSPs were of two types, negative-going or positive-going, and were of the same sign at each of several sites for each unit. These two types were interpreted as indicating excitatory or inhibitory actions respectively. 3. The positive-going FSPs were almost all the result of activity in the most strongly modulated, phasic respiratory interneurones, whereas most of the negative-going ones were derived from neurones with a continuous tonic component in their firing patterns. 4. Positive-going FSPs (particularly those from inspiratory neurones) were generally found at more ventral sites in the ventral horn than negative-going ones. 5. It is suggested that an important role for the phasically active interneurones is to provide phasic inhibition, which is combined with largely tonic excitation to produce strong respiratory modulation in the activity of other neurones in the thoracic spinal cord, particularly in motoneurones. However, some groups of respiratory interneurones, such as a group of tonic inspiratory ones which are located more dorsally than the phasic inspiratory ones, may not receive such phasic inhibition.

Artifactual averaged 'twitch tension' waveforms resulting from synchronized activity: recording from feline diaphragmatic motor units

Averaging techniques have been used to measure contractile properties of spontaneously active motor units (MUs). This study examined the potential for artifactual results due to synchronization between the triggering, single-MU action potentials, and activity of other MUs within the muscle. A muscle strip was formed in situ from feline diaphragm. Single MUs were recorded from the strip and from the contralateral diaphragm. The diaphragm including the muscle strip continue to contract rhythmically in this preparation and a high-gain, AC-coupled recording of force was averaged using MUs recorded in either hemidiaphragm to trigger the averager. Twitch-tension waveforms occurred in 42 of 49 cases triggering from spikes of MUs contained within the strip and in 13 of 19 averages triggered from contralateral MUs. The waveforms generated using contralateral MUs as triggers could only arise from synchronization with MUs contained within the diaphragmatic strip. Although twitch waveforms that were generated from external and internal triggers could appear similar qualitatively, contraction times were significantly (P less than 0.05) longer for averages using contralateral MUs. This study demonstrates that synchronization of triggering events is a major source for error in determining mechanical properties of MUs.

Facilitation of individual gamma-motoneurones by the discharge of single slowly adapting type 1 mechanoreceptors in cats

1. Cross-correlation of the discharges of individual neurones has been used to investigate the influence of identified cutaneous afferents on gamma-motoneurones below the level of complete spinal section in decerebrated cats. Discharges of single, sural nerve afferents from the heel were recorded in the dorsal root ganglia. Discharges of gamma-motoneurones were recorded from cut filaments of the muscle nerve to gastrocnemius medialis of the same leg. gamma-Motoneurones had a background discharge in the absence of intentional stimulation. 2. Correlograms involving slowly adapting afferents were formed during steady application of a probe to the receptive field for repeated periods of 10 s. Afferent synchronization was minimized by rejecting any period of probe movement. Correlograms involving rapidly adapting afferents required continuous movement of the probe to sustain afferent discharge. 3. Statistically significant primary peaks in correlations were observed for twenty-one pairings of gamma-motoneurones with seventeen out of thirty-nine slowly adapting, type 1 (SA1) mechanoreceptors. Primary peaks had widths at half-maximum in the range of 2-7 ms. No such short duration peaks were seen for fourteen pairings of gamma-motoneurones with eleven slowly adapting type 2 (SA2) receptors or for thirty-five pairings with twenty-nine hair follicle (HF) afferents. Broad correlations with peaks extending over tens of milliseconds were seen for HF afferents and could be generated in correlograms for slowly adapting afferents by moving the probe. 4. The short duration peaks were delayed with respect to the SA1 afferent discharges. Subtraction of peripheral conduction times gave central delays for the increased probability of gamma-motoneurone firing ranging from 2.7 to 6.5 ms (mean = 4.0 ms). These values were not significantly different from the central delays of gamma-motoneurone excitation in response to electrical stimulation of the sural nerve at a strength 1.2 times threshold. 5. The increase in probability of gamma-motoneurone discharge given a single SA1 afferent discharge ranged from 0.005 to 0.156 with a mean value of 0.052. The rise time of the peak ranged from 1 to 4 ms with a mean value of 1.9 ms (n = 9). 6. The properties of the correlogram peaks were not related to the axon conduction velocity of either the SA1 afferent or gamma efferent neurones. 7. The SA1 afferents that facilitated gamma-motoneurone discharge had axon conduction velocities in the range 29-81 m/s and could not be distinguished from SA1 afferents lacking correlations.(ABSTRACT TRUNCATED AT 400 WORDS)

A comparison of homonymous and heteronymous connectivity in the spinal monosynaptic reflex arc of the cat

Multi-unit spike triggered averaging was used to determine functional connectivity between spindle afferent fibers from the medial gastrocnemius muscle and the motoneurons innervating the medial (homonymous connections) and the lateral gastrocnemius-soleus muscle (heteronymous connections). As many as 288 possible connections between 24 motoneurons and 12 afferent fibers were studied in single, acute experiments. The influences of morphological and topographical factors, as well as of motoneuron species on functional connectivity were analysed. The probability that a motoneuron would receive functional connections from a given population of afferent fibers was related to its size and its proximity to the spinal entry level of the afferent fibers. The faster the axonal conduction velocity of the motoneuron (i.e. the larger the motoneuron) and the closer its location to the entry zone of the afferent fibers, the higher was its probability of receiving functional connections. The greater the conduction velocity (i.e. diameter) of a stretch receptor afferent fiber, the higher was its probability of making functional connections with motoneurons. These relationships were qualitatively similar for homonymous and heteronymous connections. 58% (233/399) of the Ia and group II afferents (combined) had functional connections with homonymous motoneurons, 32% (75/234) with heteronymous motoneurons. However, homonymous and heteronymous motoneurons of similar sizes were equally likely to receive functional connections when located at the same craniocaudal level. Differences in the locations and mean sizes of homonymous and heteronymous motoneurons however, cannot account completely for the observed overall differences in homonymous and heteronymous connectivity.

Effects of synchrony between primate corticomotoneuronal cells on post-spike facilitation of muscles and motor units

Cross-correlating the activity of neighboring motor cortex neurons recorded with independent electrodes in behaving monkeys has revealed synchronization peaks, largely due to common synaptic input. Corticomotoneuronal (CM) cells produced post-spike facilitation (PSF) of rectified forearm electromyograms (EMG); 15 cells synchronized with CM cells showed no PSF. Five pairs of CM cells with overlapping muscle fields exhibited similar synchrony peaks. The contribution of this synchrony to facilitation of common target muscles was assessed by two new methods: selective spike-triggered averaging and convolution. They showed that the PSF is composed predominantly of effects mediated by output of the triggering cell, but may include a broad, shallow component mediated by synchrony with other CM cells.

Segmental influence of slowly-adapting cutaneous mechanoreceptors on gamma motoneurones revealed by cross-correlation of unit discharges in the cat

Cross-correlations between the discharges of individual cutaneous afferents and gamma motoneurones have been constructed in the spinal, decerebrated cat. The discharges of single receptors in the sural nerve field from the heel were recorded in dorsal root ganglia. Background discharges of gamma motoneurones and the responses to heel stimulation were recorded from cut filaments of the muscle nerve to gastrocnemius medialis of the same leg. Slowly-adapting afferents were stimulated by steady application of a probe to the receptive field whereas rapidly-adapting afferents required continuous movement to sustain discharge of a receptor. Cross-correlation between the discharges of 17 out of 39 slowly-adapting, type-1 (SA1) mechanoreceptors and gamma motoneurones revealed sharp increases in probability of gamma motoneurone discharge that were delayed with respect to the afferent discharge. The peaks were of short duration with widths at half maximum in the range 2-7 ms and rise times of 1 to 4 ms. Deducting peripheral conduction times gave central delays of 3-6.5 ms for gamma motoneurone facilitation. These delays were comparable to those of gamma motoneurone excitation seen in response to electrical stimulation of the sural nerve at 1.5 to 4 times threshold. No short duration peaks were seen in correlograms between hair follicle (n = 29) or slowly-adapting type-2 (SA2) (n = 11) afferents and gamma motoneurones. It is concluded that a single impulse from a SA1 afferent from the hairy skin of the heel is able to facilitate the discharge of gamma motoneurones to the ipsilateral gastrocnemius muscle.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of chloralose-urethane anesthesia on single-axon reciprocal Ia IPSPs in the cat

Reciprocal Ia inhibitory postsynaptic potentials (IPSPs) generated by single afferents have been recorded with signal averaging in unanesthetized ischemic-decapitate cats for comparison with measurements previously obtained from preparations anesthetized with a mixture of chloralose and urethane. The results are similar to those which we obtained recently for single-axon recurrent IPSPs. Together, the studies show that chloralose-urethane anesthesia has a depressant effect on two widely studied circuits in the mammalian spinal cord.

Activation of ion channels in the frog end-plate by high concentrations of acetylcholine

1. The equilibrium relationship between acetylcholine (ACh) concentration and response (fraction of channels open), corrected for the effects of desensitization, has been estimated by single-ion-channel recording at the adult frog skeletal neuromuscular junction. At high ACh concentration channel openings occur in well-defined clusters separated by long desensitized intervals. The response, po, was estimated as the proportion of time for which a single channel was open during a cluster. 2. At negative membrane potential (-120 mV) po reached a maximum value of 0.9 at 100 microM-ACh and was half-maximum at 15 microM with a Hill slope of 1.6 at this point. At concentrations higher than 200 microM-ACh, po declined as a result of open-channel block by free ACh itself. 3. At positive membrane potentials (+100 mV) there was little channel block by ACh; po reached a maximum value of 0.41 at 500 microM-ACh, with half-maximum activation at 50 microM and Hill slope of 1.2 at this point. 4. Particular mechanisms for channel activation by ACh were fitted to the data by the method of least squares. Fits were fully determinate only if the two binding sites for ACh were assumed to be equivalent with no co-operativity in the ACh binding reactions. At negative potential the microscopic equilibrium constant for binding was K1 = K2 = 77 microM and the equilibrium constant for channel opening (opening/closing rates, beta/alpha) was 32. At positive potential the affinity was slightly higher, K = 32 microM, which confirms the view that the binding sites for ACh are outside the membrane electric field. The equilibrium constant for channel opening was reduced to 0.7 mainly as a result of the much shorter open lifetime (increased closing rate alpha) at positive potentials. 5. The data were also fitted well by very high values of beta/alpha together with a high degree of negative co-operativity or non-equivalence in ACh binding affinity (K2 much greater than K1). A good fit could also be obtained with moderate positive co-operativity combined with non-equivalence of the binding sites. 6. A mechanism that postulates a receptor with two independent gating subunits provided a poor fit to the data at negative potential. 7. The rate constants for channel opening and ACh dissociation were estimated by constraining the fitted parameters so that the burst length for channel opening was equal to its observed value at low concentrations of ACh.(ABSTRACT TRUNCATED AT 400 WORDS)

Chemical kinetic measurements of a mammalian acetylcholine receptor by a fast-reaction technique

In the presence of acetylcholine, the nicotinic acetylcholine receptor undergoes two rapid conformational changes: one in the 1-ms time region, leading to the formation of a transmembrane channel and signal transmission between cells, and the other in the 100-ms time region, leading to an inactive "desensitized" form with altered ligand-binding properties. To determine the properties of the receptor that are relevant for channel opening and signal transmission, we have developed a cell-flow technique that allows measurements to be made with cells prior to receptor desensitization. Here we illustrate the usefulness of the technique. A wide concentration range of both a ligand that controls the opening of receptor channels (carbamoylcholine) and a receptor inhibitor (procaine) was used to measure the dissociation constant of the receptor site controlling channel opening (2.4 X 10(-4) M), the channel-opening equilibrium constant (5.5), the inhibition constant for procaine (5.8 X 10(-5) M), and the rate coefficients for two desensitization processes of 5 s-1 and 0.2 s-1. The cell-flow technique illustrated here is of interest because, by rapid-reaction techniques, it extends the chemical kinetic approach from investigations of reactions in solutions to investigations of many different receptors that exist in membranes of central nervous system cells and whose properties are not well known.

Two types of acetylcholine receptor channels in developing Xenopus muscle cells in culture: further kinetic analyses

1. Further developmental changes in acetylcholine (ACh) receptor channel function were examined in Xenopus muscle cultures using the cell-attached patch-clamp technique. 2. Two types of acetylcholine (ACh) receptor channel events, low- and high-conductance channel events, were distinguished as reported earlier. Apparent open-time histograms for high-conductance channel events were well fitted by a single exponential but those for low-conductance channel events were sometimes fitted better by two exponentials. 3. In low-conductance channel events when the open-time histogram was well fitted by two exponentials, successive open times were correlated: an event with a long open time tended to be followed after a brief interval (less than 1 ms) by another long-duration event. A short-duration event was less frequently followed by an event within a short interval (1 ms) with a long-duration event. 4. Closed-time histograms for the interval between successive low-conductance channel events and between successive high-conductance channel events were both fitted by two exponentials. The fast time constant was 0.36 ms for the high-conductance channel event and 0.31 ms for the low-conductance channel event. There was an indication that a third and faster component was hidden in the first bin (0-200 microseconds) in the closed-time histogram of both types of channel events. 5. Defining a burst as successive openings separated by closures briefer than 1 ms, the number of gaps per burst was different for the two types of channel events. They were 0.16 for high- and 0.37 for low-conductance channel events. In both types of channels, neither the fast component in the closed-time histogram nor the number of gaps per burst changed with time in culture. 6. The apparent open time of both types of channels increased progressively as ACh concentration was increased, suggesting an increasing number of unresolved closures at higher concentrations. At 100 microM-ACh the apparent open time became shorter probably due to channel blockade by ACh molecules. Closed-time histograms were fitted by two exponentials. The time constant of the fast component remained similar to that at low concentration (0.2 microM) up to 20 microM, but the relative number of closures belonging to this component increased with ACh concentration. In contrast, the slow component shortened its time constant as ACh concentration increased and the relative frequency decreased. Again, there was an indication that another faster component existed in the closed-time histogram.(ABSTRACT TRUNCATED AT 400 WORDS)

The degree of short-term synchrony between alpha- and gamma-motoneurones coactivated during the flexion reflex in the cat

Cross-correlation analysis of unitary neuronal discharges has been used to study the linkage between alpha- and gamma-motoneurones coactivated during the flexion reflex of the semitendinosus muscle in the decerebrated spinal cat. A flexion reflex was elicited by firm grip or squeeze of the ipsilateral heel, shank or foot. The stimulus excited the discharges of both alpha- and gamma-motoneurones and increased the frequency of discharge of those gamma-motoneurones that had shown a background discharge prior to intentional stimulation. Short-term synchrony was present between a high proportion of semitendinosus gamma-motoneurones both for background discharges (sixteen out of nineteen pairs) and during the flexion reflex (thirteen out of fifteen pairs). All nineteen pairs of alpha-motoneurones examined during the flexion reflex showed short-term synchrony of discharge. Few alpha-motoneurones displayed background discharges but synchrony was observed in the two instances studied. The degree of synchrony was measured as the ratio (kappa) of the total counts contributing to the peak of the correlogram over the number expected by chance alone. The ratio was higher when the average frequency of motoneurone discharge was low. Kappa was generally higher for alpha-motoneurone pairs than for gamma-motoneurone pairs. The higher degree of synchrony for alpha-motoneurones reflected their lower discharge rates. During the flexion reflex the degree of synchrony between gamma-motoneurones was greater than expected for that same discharge rate in the absence of intentional stimulation. Only twenty-seven out of forty pairings of an alpha- with a gamma-motoneurone showed a significant degree of synchrony of discharge. On average, the degree of synchrony for alpha/gamma pairs was lower than that for either alpha/alpha or gamma/gamma pairings at the equivalent discharge rate. The results support the conclusion that coactivation of alpha- and gamma-motoneurones during the flexion reflex occurs largely through independent sets of interneurones. The possibility is discussed that those alpha-motoneurones which showed short-term synchrony with gamma-motoneurones were skeleto-fusimotor (beta-motoneurones) in nature.

Fast events in single-channel currents activated by acetylcholine and its analogues at the frog muscle end-plate

The fine structure of ion-channel activations by junctional nicotinic receptors in adult frog muscle fibres has been investigated. The agonists used were acetylcholine (ACh), carbachol (CCh), suberyldicholine (SubCh) and decan-1,10-dicarboxylic acid dicholine ester (DecCh). Individual activations (bursts) were interrupted by short closed periods; the distribution of their durations showed a major fast component ('short gaps') and a minor slower component ('intermediate gaps'). The mean duration of both short and intermediate gaps was dependent on the nature of the agonist. For short gaps the mean durations (microseconds) were: ACh, 20; SubCh, 43; DecCh, 71; CCh, 13. The mean number of short gaps per burst were: ACh, 1.9; SubCh, 4.1; DecCh, 2.0. The mean number of short gaps per burst, and the mean number per unit open time, were dependent on the nature of the agonist, but showed little dependence on agonist concentration or membrane potential for ACh, SubCh and DecCh. The short gaps in CCh increased in frequency with agonist concentration and were mainly produced by channel blockages by CCh itself. Partially open channels (subconductance states) were clearly resolved rarely (0.4% of gaps within bursts) but regularly. Conductances of 18% (most commonly) and 71% of the main value were found. However, most short gaps were probably full closures. The distribution of burst lengths had two components. The faster component represented mainly isolated short openings that were much more common at low agonist concentrations. The slower component represented bursts of longer openings. Except at very low concentrations more than 85% of activations were of this type, which corresponds to the 'channel lifetime' found by noise analysis. The frequency of channel openings increased slightly with hyperpolarization. The short gaps during activations were little affected when (a) the [H+]o or [Ca2+]o were reduced to 1/10th of normal, (b) when extracellular Ca2+ was replaced by Mg2+, (c) when the [Cl-]i was raised or (d) when, in one experiment on an isolated inside-out patch, the normal intracellular constituents were replaced by KCl. Reduction of [Ca2+]O to 1/10 of normal increased the single-channel conductance by 50%, and considerably increased the number of intermediate gaps. No temporal asymmetry was detectable in the bursts of openings. Positive correlations were found between the lengths of successive apparent open times at low SubCh concentrations, but no correlations between burst lengths were detectable. The component of brief openings behaves, at low concentrations, as though it originates from openings of singly occupied channels.(ABSTRACT TRUNCATED AT 400 WORDS)

The detection of monosynaptic connexions from inspiratory bulbospinal neurones to inspiratory motoneurones in the cat

Simultaneous recordings were made of the discharges of inspiratory bulbospinal neurones and phrenic or external intercostal alpha-motoneurones in the anaesthetized cat. The connexions between these neurones were studied by the construction of cross-correlation histograms from their discharges. Peaks observed in the cross-correlation histograms were divided into three groups on the basis of their time courses: narrow, medium-width and high-frequency oscillations (h.f.o.). Narrow peaks were defined as having half-widths less than 1.1 ms and medium-width peaks as having half-widths greater than this, while h.f.o. was characterized by periodic waves in the range 60-120 Hz. H.f.o. peaks were interpreted as being derived from the well known periodic synchronization of medullary inspiratory neurones in this frequency range. The time courses and latencies of the medium-width peaks could be quantitatively explained by a simple model representing excitation of the motoneurones by bulbospinal neurones whose discharges showed synchronization within +/- 1 ms of the reference spike, together with temporal dispersion in bulbospinal axons having a distribution of conduction velocities given by the measurements of this study. Such an explanation was essential for some of the medium-width peaks, whose latencies were short compared to the conduction times to the spinal cord for their own axons, but for other medium-width peaks oligosynaptic excitation of the motoneurones from the identified bulbospinal neurones was another possible explanation. The narrow peaks were of appropriate durations for monosynaptic connexions and were all at appropriate latencies (0.6-2.4 ms after the calculated arrival time of the bulbospinal impulse in the segment concerned). It is concluded from the observations of narrow peaks that monosynaptic excitation exists between inspiratory bulbospinal neurones and both phrenic and external intercostal motoneurones. However, because of the existence of presynaptic synchronization, as shown by the presence of the medium-width peaks, such a conclusion is predicated upon being able to discriminate against such an effect. The model showed that this restriction applies just as much to the measurements of excitatory post-synaptic potentials (e.p.s.p.s) by spike-triggered averaging as it does to cross-correlation measurements. We suggest that the discrimination against presynaptic synchronization here was possible only because the long conduction distance created temporal dispersion in the synchronized presynaptic impulses.

Detection of synchrony in the discharge of a population of neurons. I. Development of a synchronization index

A test for synchronization among the spike trains of muscle afferents or motor units is described which utilizes averages of neurograms and rectified neurograms. Synchronization is quantified by the increase of a synchronization index Is above a theoretical value for asynchrony. The dependence of the Is on signal amplitude and certain experimental conditions and a method of estimating confidence limits for the test are presented.

Detection of synchrony in the discharge of a population of neurons. II. Implementation and sensitivity of a synchronization index

This report describes the use of a synchronization index (Is; Hamm et al., 1985a) and its sensitivity to various forms and degrees of synchrony between spike trains. The dependence of the Is on signal-to-noise ratio, the number of synchronized spike trains and their degree of synchrony is shown in analog and digital simulations. These simulations and a comparison with peristimulus time histograms under conditions of induced synchrony reveal that the Is is a sensitive measure of synchronization in a population of spike trains.