The electrical constants of the motoneurone membrane

Modulation of Respiratory System by Limb Muscle Afferents in Intact and Injured Spinal Cord

Breathing constantly adapts to environmental, metabolic or behavioral changes by responding to different sensory information, including afferent feedback from muscles. Importantly, not just respiratory muscle feedback influences respiratory activity. Afferent sensory information from rhythmically moving limbs has also been shown to play an essential role in the breathing. The present review will discuss the neuronal mechanisms of respiratory modulation by activation of peripheral muscles that usually occurs during locomotion or exercise. An understanding of these mechanisms and finding the most effective approaches to regulate respiratory motor output by stimulation of limb muscles could be extremely beneficial for people with respiratory dysfunctions. Specific attention in the present review is given to the muscle stimulation to treat respiratory deficits following cervical spinal cord injury.

The beginning of intracellular recording in spinal neurons: facts, reflections, and speculations

Intracellular (IC) recording of action potentials in neurons of the vertebrate central nervous system (CNS) was first reported by John Eccles and two colleagues, Walter Brock and John Coombs, in Dunedin, NZL in 1951/1952 and by Walter Woodbury and Harry Patton in Seattle, WA, USA in 1952. Both groups studied spinal cord neurons of the adult cat. In this review, we discuss the precedents to their notable achievement and reflect and speculate on some of the scientific and personal nuances of their work and its immediate and later impact. We then briefly discuss early achievements in IC recording in the study of CNS neurobiology in other laboratories around the world, and some of the methods that led to enhancement of CNS IC-recording techniques. Our modern understanding of CNS neurophysiology directly emanates from the pioneering endeavors of the five who wrote the seminal 1951/1952 articles.

Motor unit types of cat triceps surae muscle

1. Motor units, defined as including a motoneurone (cell body, dendrites and axon) plus the muscle unit innervated, have been examined in the triceps surae motor pool of pentobarbital anaesthetized cats.2. The technique of intracellular stimulation and recording which was used permitted measurement of the axonal conduction velocity, post-spike hyperpolarization duration and input resistance of individual motoneurones, and the correlation of these properties with the characteristics of the twitch and tetanus responses of the muscle unit innervated by the cell elicited by direct intracellular stimulation.3. On the basis of muscle unit speed of contraction, motor units were divided into two groups: (a) fast twitch, or F, type with twitch time to peak (TwTp) less than or equal to 30 msec, and (b) slow twitch, or S, type with TwTp of 40 msec or greater. The twitch tensions (TwTen) produced by type F units were significantly larger (median value = 18 g) than the tensions generated by type S units (TwTen median value = 1.6 g). Type F muscle units had much higher tetanus fusion frequencies (median = 85 pulses/sec) than the S type (median 25 pulses/sec), and tended to have smaller tetanus to twitch tension ratios (Tet/Tw) (median = 2.6) than type S units (median = 5.4).4. The gastrocnemius heads contained a mixture of F and S types of muscle units, the proportions found being about 3 to 1 respectively. Units encountered in the soleus muscle were uniformly of type S. The characteristics of gastrocnemius and soleus type S motor units were not identical but appeared to represent quantitative differences in units of the same qualitative type.5. Motoneurones innervating type F muscle units had faster axonal conduction velocities, shorter post-spike hyperpolarizations and lower input resistances than those supplying type S units. However, no combination of motoneurone properties alone was sufficient to separate unambiguously types F and S motor units.

Stimulus feature selectivity in excitatory and inhibitory neurons in primary visual cortex

Although several lines of evidence suggest that stimulus selectivity in somatosensory and visual cortices is critically dependent on unselective inhibition, particularly in the thalamorecipient layer 4, no comprehensive comparison of the responses of excitatory and inhibitory cells has been conducted. Here, we recorded intracellularly from a large population of regular spiking (RS; presumed excitatory) and fast spiking (FS; presumed inhibitory) cells in layers 2-6 of primary visual cortex. In layer 4, where selectivity for orientation and spatial frequency first emerges, we found no untuned FS cells. Instead, the tuning of the spike output of layer 4 FS cells was significantly but moderately broader than that of RS cells. However, the tuning of the underlying synaptic responses was not different, indicating that the difference in spike-output selectivity resulted from differences in the transformation of synaptic input into firing rate. Layer 4 FS cells exhibited significantly lower input resistance and faster time constants than layer 4 RS cells, leading to larger and faster membrane potential (V(m)) fluctuations. FS cell V(m) fluctuations were more broadly tuned than those of RS cells and matched spike-output tuning, suggesting that the broader spike tuning of these cells was driven by visually evoked synaptic noise. These differences were not observed outside of layer 4. Thus, cell type-specific differences in stimulus feature selectivity at the first level of cortical sensory processing may arise as a result of distinct biophysical properties that determine the dynamics of synaptic integration.

Beginning at the end: repetitive firing properties in the final common pathway

Since the early 20th century, it has been recognized that motoneurons must fire repetitive trains of action potentials to produce muscle contraction. In 1932, Sir John Eccles, together with Hebbel Hoff, found that action potential spike trains in motor axons were produced by "rhythmic centres", which were within the motoneurons themselves. Two decades later, Eccles attended a Cold Spring Harbor Symposium in NY, USA entitled "The Neuron". Two of the many notable presentations at this symposium were juxtaposed: one by Eccles from the University of Otago, Dunedin, NZL, and the other by J. Walter Woodbury and Harry Patton from the University of Washington, Seattle, USA. Both presentations included data obtained using sharp microelectrodes to study the intracellularly recorded potentials of cat motoneurons. In this review, I discuss some of the events leading up to and surrounding this jointly accomplished advance and proceed to discussion of subsequent studies over 5+ decades that have made use of intracellular recordings from motoneurons to study their repetitive firing behavior. This begins with early descriptions of primary and secondary range firing, and continues to the discovery of dendritic persistent inward currents and their relation to plateau potentials, synaptic amplification, and motoneuronal firing. Following a brief description of the possible mechanisms underlying spike frequency adaptation, I discuss the modulation of repetitive firing properties during various motor behaviors. It has become increasingly clear that the central nervous system has exquisite control of the repetitive firing of motoneurons. Eccles' work laid the foundation for the present-day study of these processes.

John Eccles’ pioneering role in understanding central synaptic transmission

This chapter deals with the central role that Sir John Eccles played in the elucidation of the mechanisms of synaptic transmission within the central nervous system during the three decades between the late 1930s and 1966. His seminal discoveries involved studies of synaptic input to spinal motoneurons using intracellular recording via glass micropipettes after their introduction in the late 1940s. After defending the hypothesis that electrical currents alone explained central synaptic events, his observations of reversal potentials and sensitivity to ion injections instantly converted Eccles to the idea that central synapses generate postsynaptic potentials, designated IPSPs and EPSPs, by liberating chemical transmitters. He and his collaborators used pharmacological manipulations of recurrent inhibition to support the idea that a given neuron liberates the same chemical transmitter substance at all of its synapses, which he called "Dale's Principle". His team worked out the mechanisms and spinal circuits underlying disynaptic and recurrent inhibition, as well as those of presynaptic inhibition. Not content with the view that central synapses were static entities, Eccles also made seminal observations on synaptic plasticity induced by alterations in use and disuse. Although his firmly held belief that the extensive dendritic trees of motoneurons were essentially irrelevant to synaptic events at the soma was later refuted by others in the mid-1960s, Eccles stands as a towering figure in the history of neuroscience. His prodigious energy and commanding intellect gave the field of central synaptic transmission the conceptual bases that have guided it for over 40 years.

Contribution of group III and IV muscle afferents to multisensorial spinal motor control in cats

The contribution of group III and IV muscle afferents to multisensorial segmental reflex pathways was investigated by testing for spatial facilitation between these afferents and non-nociceptive segmental afferents from skin, muscles and joints on postsynaptic potentials (PSPs) in alpha-motoneurones recorded in anaemically decapitated high spinal cats. Group III and IV muscle afferents were activated by intraarterial injection of potassium chloride (320 mM) or bradykinin triacetate (81 microM). Skin, joint and group I-II muscle afferents were stimulated by graded electrical stimulation of various nerves. Conditioning by stimulation of group III and IV muscle afferents spatially facilitated the transmission in segmental reflex pathways from low- to medium-threshold cutaneous and joint afferents as well as from lb and group II muscle afferents. Both excitatory and inhibitory pathways from these afferents were facilitated. Monosynaptic excitation and disynaptic antagonistic inhibition from group Ia afferents remained unaffected. It is concluded that the spatial facilitation observed between group III and IV muscle afferents and the other afferents indicate a convergence from group III and IV muscle afferents and the other afferents on common interneurones in segmental flexor reflex pathways. Under physiological conditions they thus contribute to the multisensorial feedback of the flexor reflex pathways. Pathophysiologically, the observed convergence may aggravate muscle weakness and atrophy of muscles induced by group III and IV muscle afferents.

Subsurface cisterns and their relationship to the neuronal plasma membrane

Subsurface cisterns (SSC's) are large, flattened, membrane-limited vesicles which are very closely apposed to the inner aspect of the plasma membranes of nerve cell bodies and the proximal parts of their processes. They occur in a variety of vertebrate and invertebrate neurons of both the peripheral and central nervous systems, but not in the surrounding supporting cells. SSC's are sheet-like in configuration, having a luminal depth which may be less than 100 A and a breadth which may be as much as several microns. They are separated from the plasmalemma by a light zone of ∼50 to 80 A which sometimes contains a faint intermediate line. Flattened, agranular cisterns resembling SSC's, but structurally distinct from both typical granular endoplasmic reticulum (ER) and from Golgi membranes, also occur deep in the cytoplasm of neurons. It is suggested that membranes which are closely apposed may interact, resulting in alterations in their respective properties. The patches of neuronal plasmalemma associated with subsurface cisterns may, therefore, have special properties because of this association, resulting in a non-uniform neuronal surface. The possible significance of SSC's in relation to neuronal electrophysiology and metabolism is discussed.

Investigations of the electrical properties of cardiac muscle fibres with the aid of intracellular double-barrelled electrodes

Current has been passed through the cell membrane of muscle fibres of the isolated rabbit right ventricle with the aid of intracellular double-barrelled microelectrodes. Two types of muscle fibres were distinguished which are called P and V fibres. The relation between the intensity of a hyperpolarising current applied during the rising phase and the maximum amplitude of the action potential was different in these fibres. For P fibres the relation was essentially linear over most of the range of currents used. For V fibres the change in maximum action potential amplitude was either negligible or did not appear until a certain value of hyperpolarising current was reached. This behaviour of V fibres can be understood if a drop in polarisation resistance occurs during the rising phase and is of such short duration that the polarisation resistance has returned to its resting value before the crest of the action potential is reached. P fibres have an estimated mean resting polarisation resistance of (106 ± 13) K ohms, and a rheobase current strength of (0.08 ± 0.02) µa. In V fibres the resting polarisation resistance was (47 ± 29) K ohms and the rheobase current strength (0.47 ± 0.28) µa.

Determinants of voltage attenuation in neocortical pyramidal neuron dendrites

How effectively synaptic and regenerative potentials propagate within neurons depends critically on the membrane properties and intracellular resistivity of the dendritic tree. These properties therefore are important determinants of neuronal function. Here we use simultaneous whole-cell patch-pipette recordings from the soma and apical dendrite of neocortical layer 5 pyramidal neurons to directly measure voltage attenuation in cortical neurons. When combined with morphologically realistic compartmental models of the same cells, the data suggest that the intracellular resistivity of neocortical pyramidal neurons is relatively low ( approximately 70 to 100 Omegacm), but that voltage attenuation is substantial because of nonuniformly distributed resting conductances present at a higher density in the distal apical dendrites. These conductances, which were largely blocked by bath application of CsCl (5 mM), significantly increased steady-state voltage attenuation and decreased EPSP integral and peak in a manner that depended on the location of the synapse. Together these findings suggest that nonuniformly distributed Cs-sensitive and -insensitive resting conductances generate a "leaky" apical dendrite, which differentially influences the integration of spatially segregated synaptic inputs.

Determinants of voltage attenuation in neocortical pyramidal neuron dendrites

How effectively synaptic and regenerative potentials propagate within neurons depends critically on the membrane properties and intracellular resistivity of the dendritic tree. These properties therefore are important determinants of neuronal function. Here we use simultaneous whole-cell patch-pipette recordings from the soma and apical dendrite of neocortical layer 5 pyramidal neurons to directly measure voltage attenuation in cortical neurons. When combined with morphologically realistic compartmental models of the same cells, the data suggest that the intracellular resistivity of neocortical pyramidal neurons is relatively low ( approximately 70 to 100 Omegacm), but that voltage attenuation is substantial because of nonuniformly distributed resting conductances present at a higher density in the distal apical dendrites. These conductances, which were largely blocked by bath application of CsCl (5 mM), significantly increased steady-state voltage attenuation and decreased EPSP integral and peak in a manner that depended on the location of the synapse. Together these findings suggest that nonuniformly distributed Cs-sensitive and -insensitive resting conductances generate a "leaky" apical dendrite, which differentially influences the integration of spatially segregated synaptic inputs.

The Ferrier Lecture: The nature of central inhibition

I feel greatly honoured by the invitation to give the Ferrier Lecture. I attended the first Ferrier Lecture, given by Sherrington in 1929, and I learned from Sherrington to value and admire the pioneer contributions of David Ferrier to neurology. In choosing the subject of inhibition for my lecture I was prompted by the peculiar challenge that inhibition has presented to physiologists ever since it was first demonstrated by the Weber brothers in 1846 that stimulation of the vagus nerve could stop the heart and by Setchenov in 1863 that stimulation of areas in the brain could slow or prevent reflex responses of frog limbs. It was Sherrington who greatly extended and organized knowledge of inhibition in the central nervous system; first, by a series of remarkable investigations, and finally by a theoretical paper published by the Royal Society in 1925, in which excitation and inhibition were given equivalent status in the synaptic mechanisms controlling neuronal discharge. His interest in central inhibition continued to the end of his scientific life, and was the subject of his Nobel Lecture in 1932. I might mention that both my first scientific paper and my D.Phil. thesis were concerned with inhibition, and that I have continued to be more interested in the problem of synaptic inhibition than in any other aspect of neurophysiology. In recent years progress has been so rapid that our understanding of the nature of central inhibition is in several respects more complete than that of central excitation. This illumination has followed rather rapidly upon a long period of ingenious theorizing which is now only of historical interest

THE EXTRUSION OF SODIUM FROM CAT SPINAL MOTONEURONS

Sodium ions were injected into cat spinal motoneurons electrophoretically through an intracellular NaCl-filled microelectrode. Following an injection there were characteristic changes in the resting and spike potentials, the after-potential and the inhibitory postsynaptic potential, all of which recovered within about 7 min. The maximum rising slope of the spike recovered exponentially, suggesting the exponential decrease of the intracellular sodium concentration by the operation of the sodium pump in actively extruding excess sodium. The time course of the recovery of the maximum falling slope of the spike paralleled that of the rising slope, indicating a reciprocal change in the intracellular sodium and potassium concentrations. There was a good parallelism in the time courses of the recovery of the amplitude of the after-potential and the maximum falling slope of the spike, as would be expected from their postulated dependence on the same internal potassium concentration. The inhibitory postsynaptic potential recovered from its displacement in the depolarizing direction with the same time course as did the other potentials, which indicates parallel decreases of the intracellular sodium and chloride concentrations. From the exponential recovery curves obtained for these potentials, the rate constant of active sodium extrusion was estimated as 40 h -1 . The fast rate of sodium extrusion in cat motoneurons is related to the dynamic ionic balance in neurons of the central nervous system, and is explained by the geometry and by the membrane properties of motoneurons.

EXCITABILITY CHANGES OF THE MAUTHNER CELL DURING COLLATERAL INHIBITION

Excitability changes during collateral inhibition of the goldfish Mauthner cell (M cell) were measured directly by stimulating the cell with current pulses applied through an intracellular electrode. Excitability was suppressed during the extrinsic hyperpolarizing potential (EHP) as well as during the collateral IPSP. The inhibitory effect of the EHP was shown to be comparable in intensity to the effect of the IPSP. Excitability changes in the M cell during collateral IPSP depended on changes in the membrane conductance as well as in the membrane potential. Some simple equations are advanced which describe the excitability change during the IPSP in terms of changes in membrane potential and conductance. It was also found that invasion of antidromic impulses into the M cell was suppressed during the EHP, but not during the collateral IPSP. Conductance increase during the IPSP did not interfere with the invasion of antidromic impulses.

Graded action potentials generated by differentiated human neuroblastoma cells

Stimulus-dependent impulses and resting membrane parameters of human SH-SY5Y neuroblastoma cells, induced to differentiate by retinoic acid, were investigated with tight-seal recording techniques. Mean resting potential was -53 mV, mean input resistance 2.1 G omega, mean capacitance 14 pF, and mean time constant 30 ms. Rectangular current steps induced clearly stimulus-dependent impulses, with stronger current steps causing impulses of larger amplitude. The degree of impulse variability differed significantly among different cells. The current thresholds for impulse generation ranged from 35 to 100 pA for 10 ms current steps. With longer current steps, thresholds below 10 pA were recorded. In response to 0.5-1 s long current steps, most cells generated only a single impulse, but a few cells generated two impulses. When two impulses were generated, the interval between the impulses decreased with increasing stimulus strength. Whole-cell currents were recorded under voltage-clamp conditions. Voltage-activated, tetrodotoxin-sensitive Na+ currents and 'delayed rectifier' K+ currents were recorded. The degree of impulse variability was correlated to the maximum Na+ current density. Cells with large Na+ currents showed little impulse variability, while a marked variability was recorded in cells with intermediate or small Na+ currents. Cells which generated more than one impulse in response to prolonged stimuli belonged to the group with large Na+ currents. Spontaneous impulse-currents were recorded from cell-attached membrane patches on intact cells. Also these impulses showed a large variability in amplitude: In each of five cells analysed, the peak-to-peak amplitude varied by a factor larger than 1.7.

Impulses and resting membrane properties of small cultured rat hippocampal neurons

1. The impulses and resting membrane parameters of small (soma diameter less than 10 microM) cultured hippocampal neurons from rat embryos were studied with the tight-seal whole-cell recording technique. 2. Mean resting potential was -47 mV, mean input resistance 3.3 G omega, mean capacitance 11 pF, and mean time constant 33 ms. 3. Rectangular suprathreshold current steps elicited regenerative potential responses. The amplitude and time course of the responses were clearly stimulus dependent: stronger current steps caused impulses of larger amplitude. 4. The current threshold was very low: rheobase current was less than 15 pA. 5. The potential response depended on the preceding holding potential, responses from more negative potentials showing sharper peaks than those from more positive potentials. 6. Spontaneous impulses with pre-potentials similar to synaptically induced events were recorded from several cells. The amplitude of the spontaneous impulses varied similarly to that of the stimulus-induced responses.

Graded action potentials in small cultured rat hippocampal neurons

The 'all-or-nothing' principle has been central to neurobiology since the beginning of this century. We here demonstrate that action potentials in small cultured neurons from the hippocampus of rat embryos clearly depend on stimulus strength and thus deviate from this principle. We also demonstrate that similar stimulus-dependent action potentials can be predicted from computations based on voltage-clamp measurements. The findings suggest that amplitude modulation of the action potential may be a principle for information processing in the mammalian nervous system.

Electrophysiology of adult rat facial motoneurones: the effects of serotonin (5-HT) in a novel in vitro brainstem slice

Studies of adult rat motoneurones using in vitro slice preparations are rare. We here describe a novel brainstem slice of the adult rat containing the facial motor nucleus (FMN). Data obtained for facial motoneurones (FM) by intracellular recording indicate that they display several passive and active properties seen in other rat cranial and spinal motoneurones. Bath application of serotonin (5-HT) evokes a reversible depolarization of FMs which is associated with an increase in input resistance due to a reduction in potassium permeability. This effect is unaffected by tetrodotoxin indicating a postsynaptic site of action.

Synaptic potentials of chinchilla lateral superior olivary neurons

Neurons in the lateral superior olive (LSO) were characterized in vivo, by extracellular and intracellular recordings. Principal neurons of the LSO are excited by ipsilateral auditory stimuli and exhibit binaural inhibition, as observed in extracellular recordings. In subsequent intracellular recordings, ipsilateral acoustic stimuli evoked robust excitatory postsynaptic potentials (epsps), while contralateral stimuli evoked large inhibitory postsynaptic potentials (ipsps). The contralaterally evoked ipsps were reversed when the cell was polarized below resting membrane potential and when current was injected into neurons recorded with chloride-filled electrodes. The ipsp is probably a reflection of contralaterally evoked release of glycine acting through glycinergic receptors on the somata and proximal dendrites of these neurons. The properties of the epsps are consistent with data suggesting that ipsilaterally evoked excitation may be mediated by an excitatory amino acid-like substance acting through quisqualate or kainate receptors at dendritic locations.

Passive electrical properties of spontaneously active neurons in the nucleus reticularis gigantocellularis of the cat

We evaluated in chloralose-urethane anesthetized cats the passive electrical properties of 25 spontaneously active neurons in the nucleus reticularis gigantocellularis (NRGC) of the medulla oblongata. Compared to other mammalian brain regions, these reticular cells in general possessed higher input resistance, shorter membrane time constant and first equalizing time constant, and longer somatodendritic electrotonic length factor. It is discussed that, by providing a synaptic machinery for quick and sensitive response to afferent inputs and an efficacious interplay between temporal and spatial summation, these electrical membrane properties may account for the spontaneous and irregular discharge pattern characteristic of the NRGC neurons.

Electronic characteristics and membrane properties of neurons in the inferior mesenteric ganglion in guinea-pig

Intracellular recordings were made from neurons (n = 75) in the inferior mesenteric ganglion (IMG) in guinea-pig to study the electronic characteristics and membrane properties of IMG cells which receive an excitatory, cholinergic input from mechanoreceptors in the gastrointestinal tract. An excitatory, cholinergic innervation from the periphery served as an index to identify the sympathetic neurons involved in the reflex inhibition of muscle tone when the gut is distended. Functionally identified neurons in the IMG were categorized into 4 subclasses (I, II, III and IV). Subclasses I and II comprised neurons which fired phasically (rapidly adapting), with the neurons in subclass II showing a voltage relaxation in the electronic potentials elicited by depolarizing current-clamps. Subclasses III and IV comprised neurons which fired tonically (slow adapting), with the neurons in subclass III also showing relaxation of electronic potentials. Active and passive membrane properties were determined for neurons in each of the 4 subclasses of IMG cells. Measured values for the charging time-constant, the threshold current and the voltage threshold for firing (as well as calculated values for the input capacitance, specific membrane resistance, total surface area, cell diameter and cell space-constant) distinguished the neurons classed as phasic-firing from the neurons classed as tonic-firing. There were no statistical differences between the membrane properties of subclass I and II phasic neurons, or the membrane properties of subclass III and IV tonic neurons, to explain why the neurons in subclasses II and III showed a relaxation in electrotonic potentials during current-clamp. In the light of recent voltage-clamp data on the IMG cells the actions of time conductances for potassium ions are discussed to account for the variations in the electrotonic behavior of these IMG cells.

Electrical activity of rat ocular motoneurons recorded in vitro

The electrophysiological properties of rat oculomotor neurons were studied in an in vitro slice preparation. Motoneurons were identified by their antidromic response to third nerve rootlet stimulation, and by their orthodromic responses to medial longitudinal fasciculus and reticular stimulations. Passive membrane properties showed the existence of an inward rectification mechanism in all the recorded motoneurons. The action potential is comprised of several distinct components. The fast initial spike, composed of an initial segment spike and a somatodendritic spike, is followed by a delayed depolarization, an afterhyperpolarization and a late afterdepolarization. The afterhyperpolarization has a maximum duration of 55 ms. The late afterdepolarization is a voltage-dependent mechanism that produces an oscillatory behavior in depolarized cells. Two types of motoneurons were distinguished on the basis of their response to long-lasting depolarizing current pulses. The intensity-frequency curves show the existence of a primary and secondary range of discharge and the study of the interspike intervals points to specific properties of the conductance underlying the afterhyperpolarization. It is concluded that large, stellate motoneurons of the brainstem maintained in vitro retain specific electrophysiological properties, comparable to those described in vivo and which differentiate the ocular motoneurons from spinal motoneurons.

Characterization of hindlimb motoneuron membrane properties in acute and chronic spinal cats

The purpose of this study was to determine if changes in hindlimb motoneuron membrane electrical properties occur 4-6 months after spinal transection in the adult animal. Eight acute and nine chronic animals were spinalized at T12. Intracellular recordings from motoneurons innervating the triceps surae were performed. Membrane electrical properties, including resting potential, action potential peak amplitude, afterhyperpolarization duration, rheobasic current, input resistance and axonal conduction velocity were measured. There were no statistical differences found between group means or frequency distributions in the membrane properties of motoneurons assessed from acute and chronic spinal animals. Thus, alteration of motoneuron membrane properties does not appear to be a major contributing factor to the hyperexcitable hindlimb reflex activity demonstrated by chronic spinal animals.

Cannabidiol-caused depression of spinal motoneuron responses in cats

Intracellular recording techniques were used on spinal motoneurons in the cat in order to define the synaptic pharmacology of cannabidiol (CBD). The cannabinoid produces only depression of electrophysiological responses of the motoneurons: For instance, the drug decreases the amplitude of excitatory postsynaptic potentials (EPSPs); this reduction does not appear to be the result of a change in the afferent input. In addition, CBD raises the firing threshold and decreases the amplitude of motoneuron action potentials; the effects on action potentials are related to changes in postsynaptic membrane conductances, probably involving at least sodium conductance. The spinal motoneuron effects provide potential electrophysiological mechanisms for CBD's central depressant actions.

Functional organization of the spinal reflex pathways from forelimb afferents to hindlimb motoneurones in the cat. II. Conditions of the interneuronal connections

The interneuronal conditions of the descending pathways from forelimb afferents to hindlimb motoneurones were investigated by testing spatial interactions in these pathways and between these pathways and segmental lumbar reflex pathways. In high spinal unanaesthetized cats hindlimb motoneurones were intracellularly recorded and spatial interactions were tested between effects evoked by stimulation of pairs of ipsi- and contralateral forelimb nerves or pairs of a forelimb and an ipsilateral hindlimb nerve. The excitatory and late inhibitory pathways from forelimb afferents projecting to most of the hindlimb motoneurone pools, showed an interactive pattern which was distinctly different to the fast inhibitory pathway projecting specifically from ipsilateral forelimb afferents to flexor digitorum and hallucis longus (FDHL) motoneurones. Stimulation of homonymous or heteronymous pairs of two forelimb nerves of both sides evoked generally a distinct spatial facilitation of the excitatory and late inhibitory effects, while the specific early IPSPs to FDHL motoneurones were not facilitated. Paired stimulation of two forelimb nerves of one side only produced spatial facilitation of EPSPs or late IPSPs if low strength stimuli were used, using higher strength which induced larger effects, generally caused occlusion instead. In case of large IPSPs this may be due to the vicinity to the equilibrium potential. Except for an inhibition of cutaneous reflex pathways, the spatial interaction of the excitatory and late inhibitory pathways onto segmental lumbar reflex pathways was weak and variable. The fast inhibitory pathway to FDHL motoneurones showed a partial spatial facilitatory interaction with lumbar reflex pathways from cutaneous and group II muscle afferents. The second IPSP wave evoked by this pathway was inhibited by antidromic stimulation of the ventral root L7S1 and of the alpha-efferents of the antagonistic peroneal nerve. From the results conclusions are drawn on the interneuronal organization of the descending pathways from forelimb afferents to hindlimb motoneurones.