Axonal Membrane Potential Research Articles

Axonal Ionic Pathophysiology in Human Peripheral Neuropathy and Motor Neuron Disease

Testing the excitability of axons can provide insights into the ionic mechanisms underlying the pathophysiology of axonal dysfunction in human neuropathies and motor neuron diseases. Threshold tracking, which was developed in the 1990's, non-invasively measures a number of axonal excitability indices, which depend on membrane potential and on the Na+ and K+ conductances. This paper reviews recent advances in ionic-pathophysiological studies in human subjects in vivo. Membrane potential of human axons can be estimated, because most of the ion channels expressed on the axolemma are voltage-dependent, and patterns of changes in multiple excitability indices can suggest whether axons are depolarized or hyperpolarized. This has been clearly demonstrated in a single patient with acute hypokalemia (hyperpolarization) and patients with chronic renal failure (depolarization due to hyperkalemia). Muscle cramps/fasciculations arise from hyperexcitability of the motor axons. The enhanced excitability can result from altered ion channel function; an increase in persistent Na+ conductance, a decrease in accommodative K+ conductance, and focal membrane depolarization, all of which increase excitability, have been demonstrated in amyotrophic lateral sclerosis or other disorders affecting lower motor neurons. Patients with demyelinating neuropathy often complain of muscle fatigue. During voluntary contraction, the activation of the electrogenic Na+-K+ pump and resulting membrane hyperpolarization can cause activity-dependent conduction block when the safety factor for impulse transmission is critically reduced. Studies of ion-channel pathophysiology in human subjects have recently begun. Investigating ionic mechanisms is of clinical relevance, because once a specific ionic conductance is identified, blocking or activating it may provide a new therapeutic option for a variety of neuromuscular diseases.

Changes in the Axonal Membrane Potential and Ca2+ Concentration Associated with Peripheral Nerve Grafting after Spinal Cord Injury

We performed peripheral nerve allografting in rats with spinal cord injury, and measured motor function and axonal membrane potential as well as Ca(2+) concentration of the nerve grafting spinal cord area by using a behavior observation system and a confocal laser-scanning microscope, respectively. In our experiments, we produced a model of peripheral nerve grafting after spinal cord injury by peripheral nerve allografting (sciatic nerve) in rats with spinal cord injury (thoracic cord hemisection). The group with spinal cord injury that underwent peripheral nerve grafting showed improvement in motor function, a significant increase in the axonal action potential, and a slight increase in the Ca(2+) concentration compared with the group that did not undergo nerve grafting.

Aberrant Chloride Transport Contributes to Anoxic/Ischemic White Matter Injury

Rundown of ionic gradients is a central feature of white matter anoxic injury; however, little is known about the contribution of anions such as Cl-. We used the in vitro rat optic nerve to study the role of aberrant Cl- transport in anoxia/ischemia. After 30 min of anoxia (NaN3, 2 mm), axonal membrane potential (V(m)) decreased to 42 +/- 11% of control and to 73 +/- 11% in the presence of tetrodotoxin (TTX) (1 microm). TTX + 4,4'-diisothiocyanatostilbene-2,2' disulfonic acid disodium salt (500 microm), a broad spectrum anion transport blocker, abolished anoxic depolarization (95 +/- 8%). Inhibition of the K-Cl cotransporter (KCC) (furosemide 100 microm) together with TTX was also more effective than TTX alone (84 +/- 14%). The compound action potential (CAP) area recovered to 26 +/- 6% of control after 1 hr anoxia. KCC blockade (10 microm furosemide) improved outcome (40 +/- 4%), and TTX (100 nm) was even more effective (74 +/- 12%). In contrast, the Cl- channel blocker niflumic acid (50 microm) worsened injury (6 +/- 1%). Coapplication of TTX (100 nm) + furosemide (10 microm) was more effective than either agent alone (91 +/- 9%). Furosemide was also very effective at normalizing the shape of the CAPs. The KCC3a isoform was localized to astrocytes. KCC3 and weaker KCC3a was detected in myelin of larger axons. KCC2 was seen in oligodendrocytes and within axon cylinders. Cl- gradients contribute to resting optic nerve membrane potential, and transporter and channel-mediated Cl- fluxes during anoxia contribute to injury, possibly because of cellular volume changes and disruption of axo-glial integrity, leading to propagation failure and distortion of fiber conduction velocities.

The scorpion alpha-like toxin Lqh III specifically alters sodium channel inactivation in frog myelinated axons.

The effects of 1-100 nM Lqh III, an alpha-like toxin isolated from the scorpion Leiurus quinquestriatus hebraeus, were assessed on the nodal membrane potential and ionic currents of single frog myelinated axons. In current-clamped axons, Lqh III increased the duration of action potentials without markedly affecting the peak amplitude and the resting membrane potential. The toxin was less effective when the resting membrane potential of axons was increasingly more positive. The Lqh III-induced increase in action potential duration was not due to the blockade of K(+) channels, since the toxin had no significant effect upon the K(+) current. In contrast, Lqh III inhibited the inactivation of a fraction of the Na(+) current, leading to a maintained late inward Na(+) current which represented about 45% of the peak Na(+) current, as observed during long-lasting depolarisations and in steady-state Na(+) current inactivation-voltage relationships when the pre-pulse potential was more positive than about -30mV. The activation kinetics of the late Na(+) current were well described by a single exponential whose time constant was 8.53+/-0.78 ms (n=3). Finally, Lqh III slowed the time-course of the remaining peak Na(+) current inactivation by altering initial amplitudes (to time zero of depolarisation) and time constants of its fast and slow phases. No significant additional effect was detected during the action of the toxin. In conclusion, we propose that, in frog myelinated axons, the effects of Lqh III are those typically attributed to classical scorpion alpha-toxins.

Multiple measures of axonal excitability: a new approach in clinical testing.

From measurements of nerve excitability and the changes in excitability produced by nerve impulses and conditioning currents, it is possible to infer information about the membrane potential and biophysical properties of peripheral axons. Such information cannot be obtained from conventional nerve conduction studies. This article describes a new method that enables several such measurements to be made on a motor nerve quickly and reproducibly, with minimal operator intervention. The protocol measures stimulus-response behavior using two stimulus durations (from which the distribution of strength-duration time constants can be estimated), threshold electrotonus to 100-ms polarizing currents, a current-threshold relationship (indicating inward and outward rectification), and the recovery of excitability following supramaximal activation. The method was tested on 30 healthy volunteers, stimulating the median nerve at the wrist and recording from the abductor pollicis brevis. The results were comparable with previously published normal data, but the recordings took less than 10 min. The convenience and brevity of the new method make it appropriate for routine clinical use.

The intrinsic electrophysiological characteristics of fly lobula plate tangential cells: III. Visual response properties.

In this last paper in a series (Borst and Haag, 1996; Haag et al., 1997) about the lobula plate tangential cells of the fly visual system (CH, HS, and VS cells), the visual response properties were examined using intracellular recordings and computer simulations. In response to visual motion stimuli, all cells responded mainly by a graded shift of their axonal membrane potential. While ipsilateral motion resulted in a graded membrane potential shift, contralateral motion led to distinct EPSPs. For HS cells, simultaneous extracellular recorded action potentials of a spiking interneuron, presumably the H2 cell, corresponded to the EPSPs in the HS cell in a one-to-one fashion. When HS cells were hyperpolarized during ipsilateral motion, they mainly produced action potentials, but when they were hyperpolarized during contralateral motion only a slight increase of EPSP amplitude, could be observed. Intracellular application of the sodium channel blocker QX 314 abolished action potentials of HS cells while having little effect on the graded membrane response to ipsilateral motion. HS and CH cells were also studied with respect to their spatial integration properties. For both cell types, their graded membrane response was found to increase less than linearly with the size of the ipsilateral motion pattern. However, while for HS cells various amounts of hyperpolarizing current injected during motion stimulation led to different saturation levels, this was not the case for CH cells. In response to a sinusoidal velocity modulation, CH cells followed pattern motion only up to 10 Hz modulation frequency, but HS cells still revealed significant membrane depolarizations up to about 40 Hz. In the computer simulations, the compartmental models of tangential cells, as derived in the previous papers, were linked to an array of local motion detectors. The model cells revealed the same basic response features as their natural counterparts. They showed a response saturation as a function of stimulus size. In CH-models, however, the saturation was less pronounced than in real CH-cells, indicating spatially nonuniform membrane resistances with higher values in the dendrite. As in the experiments, HS models responded to high-frequency velocity modulation with a higher amplitude than did CH models.

Graded, irreversible changes in crayfish giant axon as manifestations of lidocaine neurotoxicity in vitro.

High concentrations of lidocaine induce irreversible conduction block with little effect on resting membrane potential (Em). We assumed the mechanism of persistent neurologic deficit caused by local anesthetics may result from neural death, as represented by the loss of Em. We investigated the effects of lidocaine on Em and action potential (AP) in single crayfish giant axons in vitro. Axons were perfused with two doses of lidocaine for either 15 or 30 min, and they were continuously washed. No axons exposed to 80 mM lidocaine for 30 min showed recovery of AP and Em. Those exposed to 40 mM for 30 min and 80 mM for 15 min showed a return to baseline for Em, but no recovery of AP. Those exposed to 40 mM lidocaine for 15 min showed full recovery of Em and AP immediately after washing. The membrane depolarization was significantly greater during exposure to 80 mM lidocaine for 30 min than in other groups. We conclude that lidocaine has a direct neurotoxic effect on crayfish giant axons and that the generation of AP is more vulnerable than the maintenance of Em. The irreversibility of AP and Em is dose- and time-dependent. Highly concentrated lidocaine induced an irreversible conduction block and a complete loss of resting membrane potential in crayfish giant axons in vitro. Our results may represent a possible explanation for various grades of local anesthetic-induced neurotoxicity in clinical cases if the same toxicity occurs in mammalian nerves in vivo.

Graded, Irreversible Changes in Crayfish Giant Axon as Manifestations of Lidocaine Neurotoxicity In Vitro

High concentrations of lidocaine induce irreversible conduction block with little effect on resting membrane potential (Em).We assumed the mechanism of persistent neurologic deficit caused by local anesthetics may result from neural death, as represented by the loss of Em. We investigated the effects of lidocaine on Em and action potential (AP) in single crayfish giant axons in vitro. Axons were perfused with two doses of lidocaine for either 15 or 30 min, and they were continuously washed. No axons exposed to 80 mM lidocaine for 30 min showed recovery of AP and Em. Those exposed to 40 mM for 30 min and 80 mM for 15 min showed a return to baseline for Em, but no recovery of AP. Those exposed to 40 mM lidocaine for 15 min showed full recovery of Em and AP immediately after washing. The membrane depolarization was significantly greater during exposure to 80 mM lidocaine for 30 min than in other groups. We conclude that lidocaine has a direct neurotoxic effect on crayfish giant axons and that the generation of AP is more vulnerable than the maintenance of Em. The irreversibility of AP and Em is dose- and time-dependent. Implications: Highly concentrated lidocaine induced an irreversible conduction block and a complete loss of resting membrane potential in crayfish giant axons in vitro. Our results may represent a possible explanation for various grades of local anesthetic-induced neurotoxicity in clinical cases if the same toxicity occurs in mammalian nerves in vivo. (Anesth Analg 1998;86:569-73)

Ion transport and membrane potential in CNS myelinated axons. II. Effects of metabolic inhibition.

Compound resting membrane potential was recorded by the grease gap technique (37 degrees C) during glycolytic inhibition and chemical anoxia in myelinated axons of rat optic nerve. The average potential recorded under control conditions (no inhibitors) was -47 +/- 3 (SD) mV and was stable for 2-3 h. Zero glucose (replacement with sucrose) depolarized the nerve in a monotonic fashion to 55 +/- 10% of control after 60 min. In contrast, glycolytic inhibition with deoxyglucose (10 mM, glucose omitted) or iodoacetate (1 mM) evoked a characteristic voltage trajectory consisting of four distinct phases. A distinct early hyperpolarizing response (phase 1) was followed by a rapid depolarization (phase 2). Phase 2 was interrupted by a second late hyperpolarizing response (phase 3), which led to an abrupt reduction in the rate of potential change, causing nerves to then depolarize gradually (phase 4) to 75 +/- 9% and 55 +/- 6% of control after 60 min, in deoxyglucose and iodoacetate, respectively. Pyruvate (10 mM) completely prevented iodoacetate-induced depolarization. Effects of glycolytic inhibitors were delayed by 20-30 min, possibly due to continued, temporary oxidative phosphorylation using alternate substrates through the tricarboxylic acid cycle. Chemical anoxia (CN- 2 mM) immediately depolarized nerves, and phase 1 was never observed. However a small inflection in the voltage trajectory was typical after approximately 10 min. This was followed by a slow depolarization to 34 +/- 4% of control resting potential after 60 min of CN-. Addition of ouabain (1 mM) to CN--treated nerves caused an additional depolarization, indicating a minor glycolytic contribution to the Na+-K+-ATPase, which is fueled preferentially by ATP derived from oxidative phosphorylation. Phases 1 and 3 during iodoacetate exposure were diminished under nominally zero Ca2+ conditions and abolished with the addition of the Ca2+ chelator ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA; 5 mM). Tetraethylammonium chloride (20 mM) also reduced phase 1 and eliminated phase 3. The inflection observed with CN- was eliminated during exposure to zero-Ca2+/EGTA. A Ca2+-activated K+ conductance may be responsible for the observed hyperpolarizing inflections. Block of Na+ channels with tetrodotoxin (TTX; 1 microM) or replacement of Na+ with the impermeant cation choline significantly reduced depolarization during glycolytic inhibition with iodoacetate or chemical anoxia. The potential-sparing effects of TTX were less than those of choline-substituted perfusate, suggesting additional, TTX-insensitive Na+ influx pathways in metabolically compromised axons. The local anesthetics, procaine (1 mM) and QX-314 (300 microM), had similar effects to TTX. Taken together, the rate and extent of depolarization of metabolically compromised axons is dependent on external Na+. The Ca2+-dependent hyperpolarizing phases and reduction in rate of depolarization at later times may reflect intrinsic mechanisms designed to limit axonal injury during anoxia/ischemia.

Ion transport and membrane potential in CNS myelinated axons I. Normoxic conditions.

Compound resting membrane potential was recorded by the grease gap technique during normoxic conditions (37 degrees C) in rat optic nerve, a representative CNS myelinated tract. Mean potential was -47 +/- 3 (SD) mV and remained stable for 2-3 h. Input impedance of a single optic nerve axon was calculated to be approximately 5 Gomega. Contribution of the Na+ pump to resting axonal potential is estimated at -7 mV. Ouabain (10 microM to 10 mM) evoked a dose-dependent depolarization that was maximal at >/=1 mM, depolarizing the nerves to approximately 35-40% of control after 60 min. Inhibiting energy metabolism (CN- and iodoacetate) during high-dose ouabain (1-10 mM) exposure caused an additional depolarization, suggesting additional ATP-dependent, ouabain-insensitive ion transport systems. Perfusion with zero-Na+ (choline substituted) caused a transient hyperpolarization, that was greater than with tetrodotoxin (TTX; 1 microM) alone, indicating both TTX-sensitive and -insensitive Na+ influx pathways in resting rat optic nerve axons. Resting probability (P)K:PNa is calculated at 20:1. In contrast to choline-substituted solution, Li+-substituted zero-Na+ perfusate caused a rapid depolarization due to Na+ pump inhibition and the ability of Li+ to permeate the Na+ channel. TTX reduced, but did not prevent, ouabain- or zero-Na+/Li+-induced depolarization. We conclude that the primary Na+ influx path in resting rat optic nerve axons is the TTX-sensitive Na+ channel, with evidence for additional TTX-insensitive routes permeable to Na+ and Li+. In addition, maintenance of membrane potential is critically dependent on continuous Na+ pump activity due to the relatively high exchange of Na+ (via the above mentioned routes) and K+ across the membrane of resting optic axons.

Neurodiagnostic techniques.

Neurodiagnostic techniques.

Intracellular concentrations of major ions in rat myelinated axons and glia: calculations based on electron probe X-ray microanalyses.

Electron probe x-ray microanalysis (EPMA) was used to measure water content (percent water) and dry weight elemental concentrations (in millimoles per kilogram) of Na, K, Cl, and Ca in axoplasm and mitochondria of rat optic and tibial nerve myelinated axons. Myelin and cytoplasm of glial cells were also analyzed. Each anatomical compartment exhibited characteristic water contents and distributions of dry weight elements, which were used to calculate respective ionized concentrations. Free axoplasmic [K+] ranged from approximately 155 mM in large PNS and CNS axons to approximately 120-130 mM in smaller fibers. Free [Na+] was approximately 15-17 mM in larger fibers compared with 20-25 mM in smaller axons, whereas free [Cl-] was found to be 30-55 mM in all axons. Because intracellular Ca is largely bound, ionized concentrations were not estimated. However, calculations of total (free plus bound) aqueous concentrations of this element showed that axoplasm of large CNS and PNS axons contained approximately 0.7 mM Ca, whereas small fibers contained 0.1-0.2 mM. Calculated ionic equilibrium potentials were as follows (in mV): in large CNS and PNS axons, E(K) = -105, E(Na) = 60, and E(Cl) = -28; in Schwann cells, E(K) = -107, E(Na) = 33, and E(Cl) = -33; and in CNS glia, E(K) = -99, E(Na) = 36, and E(Cl) = -44. Calculated resting membrane potentials were as follows (in mV, including the contribution of the Na+,K+-ATPase): large axons, about -80; small axons, about -72 to -78; and CNS glia, -91. E(Cl) is more positive than resting membrane potential in PNS and CNS axons and glia, indicating active accumulation. Direct EPMA measurement of elemental concentrations and subsequent calculation of ionized fractions in axons and glia offer fundamental neurophysiological information that has been previously unattainable.

Mode of action of an insecticidal peptide toxin from the venom of a weaving spider ( Diguetia canities)

A recently discovered spider toxin (DTX9.2) induced a rapid paralysis when injected into insects. In neurophysiological experiments, DTX9.2 elevated spike discharges in sensory nerves and at the neuromuscular junction, and also caused a depolarization of the membrane potential in cockroach giant axons. All these effects were reversed by treatment with the specific sodium channel blocker, tetrodotoxin. These findings suggest that DTX9.2 acts upon the voltage-dependent sodium channels of insect nerve membrane.

Ornstein-Uhlenbeck model neuron revisited

The temporal patterns of action potentials fired by a two-point stochastic neuron model were investigated. In this model the membrane potential of the dendritic compartment follows the Orstein-Uhlenbeck process and is not affected by the spiking activity. The axonal compartment, corresponding to the spike initiation site, is described by a simplified RC circuit. Estimators of the mean and variance of the input, based on a sampling of the axonal membrane potential, were derived and applied to simulated data. The dependencies of the mean firing frequency and of the coefficient of variation and serial correlation of interspike intervals on the mean and variance of the input were also studied by computer simulation in both 1- and 2-point models. The main property distinguishing the 2-point model from the classical 1-point model is its ability to produce clusters of short (or long) intervals between spikes under conditions of constant stimulation, as often observed in real neurons. It is shown that the nearly linear frequency response of the neuron, starting with subthreshold values of the input, is accounted for by the variability of the input (noise), which indicates that noise can play a positive role in nervous systems. The linear response frequency with respect to noise of the models suggests that the neuron can function as a noise encoder.

Conduction slowing without conduction block of compound muscle and nerve action potentials due to sodium channel block

We studied the effect of lidocaine on nerve conduction in vivo. Recovery of the compound muscle action potential (CMAP), sensory nerve action potential (SNAP), and single motor unit potential (MUP) of median nerve stimulation was recorded in four healthy volunteers after intravenous infusion of 20 ml of 0.5% lidocaine. During loading, CMAP and SNAP amplitudes rapidly decreased and their latencies increased. After recovery of the CMAP and SNAP amplitudes, nerve conduction velocity improved gradually over a period of 3–6 h, the amplitudes and configurations of CMAP and SNAP remaining unchanged. The conduction velocity of the single MUP markedly slowed before it is blocked. This indicates that maximum conduction velocity of CMAP and SNAP could be slowed by the partial inactivation of sodium channels without accompanying conduction block. Prolongation of the rise time of depolarization of the axonal membrane potential may be the active mechanism in this slowing because of sodium channel inactivation. Abnormalities in sodium channels at the nodes of Ranvier should be considered as a mechanism of conduction slowing even when there is no conduction block.

Quantitative structure-Activity studies of pyrethroids: 28. Type differentiation of action-potential changes in crayfish giant axons caused by substituted benzyl chrysanthemates and pyrethrates

The neurophysiological actions of variously substituted benzyl (1R)-trans-chrysanthemates and (1R)-trans-(E)-pyrethrates on the membrane potential of crayfish giant axons were observed by use of an intracellular microelectrode. The compounds were classified into three types according to their effects: deceleration of the falling phase of the action potential (type A), elevation of the depolarizing afterpotential (type B), and a combination of these effects (type C). The effects of substituents on the benzyl-benzene ring of the alcohol moiety on the type differentiation of actionpotential changes were examined by such statistical procedures as linear discriminant and logistic regression analyses with physicochemical substituent parameters. Logistic regression analysis was especially efficient in type classification. The most important substituent factors governing the type differentiation were steric bulk and electronic property. With increases in the bulkiness of substituents in terms of the van der Waals volume, the compound tended to change in its effects in the order of type A, type C, and type B. The greater the electron-withdrawing property, the greater was the tendency of compounds to be classified as type B.

Presynaptic GABAA and GABAB Receptor-mediated Phasic Modulation in Axons of Spinal Motor Interneurons.

The lamprey spinal cord has been utilized to investigate the role of presynaptic inhibition in the control of the spinal motor system. Axons of the lamprey spinal cord are comparatively large because of their lack of myelination. Axons impaled with microelectrodes demonstrate depolarizing responses to the application of GABAA and GABAB receptor agonists, muscimol and baclofen. These depolarizing effects are counteracted by the specific GABAA and GABAB receptor antagonists, bicuculline and phaclofen. GABAA receptor activation leads to a gating of Cl- channels on the axons. However, the ionic mechanism leading to axonal depolarization following GABAB receptor activation is unknown. After initiation of fictive locomotion, these axons demonstrate oscillations in axonal membrane potential related to the locomotor cycle. During ficitive locomotion they depolarize in phase with the bursting of the ipsilateral ventral root of the same segment. These axonal membrane potential oscillations are due to a phasic GABAA and GABAB receptor-mediated gating of ion channels on the axonal membrane. Fictive locomotion in the lamprey spinal cord is largely unaffected by antagonism of one or other GABA receptor subtype alone, but is severely disrupted by simultaneous antagonism of both subtypes. In conclusions, we demonstrate, for the first time, an agonist-gated depolarization of a vertebrate presynaptic element measured by direct impalement of the axon under study. We also demonstrate that GABA-mediated presynaptic inhibition occurs in axons of spinal interneurons. It is not limited to the primary afferents as has previously been believed.

Quantitative structure-activity studies of pyrethroids: 21. Substituted benzyl esters of “kadethric” acid and depolarization of the axonal membrane of crayfish

The effects of a set of kadethrin analogs in which the alcohol moiety was replaced by various meta-substituted benzyl groups on the resting membrane potential in crayfish giant axons were measured with an intracellular recording technique. These compounds depolarized the membrane to various extents. Variations in the rate of depolarization, estimated from the time required to reach half the maximum depolarization, were related parabolically to the hydrophobicity of the compounds. Depolarization within 30 min after the start of treatment with each compound was mostly related to an increase in the axonal membrane permeability for sodium ions. With prolonged treatment, other factors, such as the loss of the ion selectivity of channels (perhaps caused by damage of the membrane structure), became progressively more important with time. Two kinds of depolarizing potency parameters, one mainly due to the change in permeability to sodium ions and the other including other factors, were defined and estimated from membrane potentials observed under different conditions. When the effect of the hydrophobicity of the compounds on the transport process was considered separately, such whole-body symptomatic activities as lethal and convulsive activities against American cockroaches and knockdown activity against house flies were correlated well to the depolarizing potency parameters. The higher depolarizing activity correlated well with higher whole-body activities.

Calcium-dependent regulation of potassium permeability in the glial perineurium (blood-brain barrier) of the crayfish

The physiological basis of the high selective potassium permeability of the crayfish glial perineurium was studied. The transient spike-like perineurial potential generated in high external [K +] was used as a measure of barrier K + permeability. The medial giant axon membrane potential was used to monitor interstitial [K +]. Perineurial current-voltage relations of the perineurium were used to measure electrical resistance and to determine changes in K + conductance of the perineurial barrier. Of a range of cations studied only Rb +, in addition to K + generated a large transient sheath potential. In some experiments “regenerative” multiple spikes were observed during the continued exposure of the perineurium to high [Rb +] 0. This degree of ion selectivity is typical of glial cell membranes and K channels. Barrier conductance increased only very briefly in Rb +; the potential falling rapidly to a steady 5–10 mV. The P Cl/P Rb, and the P Cl/P k ratios at the peak transient potential were similar suggesting the permeability site for these cations was the same. The permeability of Rb + in the plateau phase was significantly lower than K + suggesting that high [Rb +] 0 may act to block K + channels. The K +-selective permeability was reversibly blocked by extracellular Ba 2+ at both the peak and the plateau phase, in a concentration-dependent manner. Other K-channel blocking agents, tetraethylammonium ions (10 mM), caesium ions (20 mM), and 3,4-diaminopyridine (0.5 mM) were ineffective. The effect of Ba 2+ on the peak potential was similar to the removal of external Ca 2+ or exposure to the Ca 2+-channel blockers, verapamil (10 −4M) or La 3+ (5 mM). The time- and concentration-dependent reversible block of the K + permeability of the perineurium was consistent with the known action of these agents on voltage-gated Ca 2+ channels in nerve and glia. La 3+ caused an irreversible decrease in perineurial conductance and K + influx. Lanthanum titration of the negative charges of glial membranes and mucopolysaccharide matrix of the intercellular space suggest they may be important factors in determining the magnitude of the perineurial leak and paracellular K + permeability. Electron microscopic examination of La 3+ distribution demonstrated a diffusion barrier at the outer layer of perineurial glia. The binding of La 3+ at the basolateral membranes of the glial barrier suggested this was the site at which La 3+ had its physiological actions. The results suggest that the increase in glial membrane K + conductance in high [K +] 0 was most likely due to voltage-gated Ca 2+ and K + channels and Ca 2+-activated K + channels of the membranes of perineurial glia.

Intra-axonal recordings of cutaneous primary afferents during fictive locomotion in the cat.

1. Cutaneous primary afferents were recorded intracellularly during fictive locomotion in decorticated cats with the goal of improving our understanding of how locomotor networks might centrally control the transmission in cutaneous pathways at a presynaptic level. 2. Identified cutaneous axons from superficialis peroneal nerve (SP) or tibialis posterior nerve (TP) were recorded intracellularly together with the electroneurograms (ENGs) of representative flexor and extensor muscle nerves of the hindlimb as well as dorsal root potential from L6 or L7 (DRP). Fictive locomotion occurred spontaneously after decortication (n = 12) or was induced by stimulation of the mesencephalic locomotor region (MLR) (n = 6). 3. The results revealed that all cutaneous axons (82 units with resting potential greater than 45 mV) showed fluctuations of their membrane potential (greater than or equal to 0.5 mV) at the rhythm of the fictive locomotion. The characteristics of fluctuation patterns, common to all cutaneous units, consisted of two depolarization waves per cycle: one related to the flexor activity, the other related to the extensor activity. The flexor-related depolarization was followed by a sharp trough of membrane repolarization. The extensor-related depolarization usually overlapped partly with the flexor-depolarization of the following cycle. The relative size of each depolarization could vary among different afferents of the same nerve in the same animal. Hence, maximal depolarization could occur in different parts of the locomotor cycle, but, for the majority of units (82%), it occurred during the flexor activity. These results were similar for SP and TP units. 4. Twenty percent of the units were discharging with a constant or irregular frequency. Phasic antidromic discharges related to locomotor ENGs were rarely encountered (5/82 units). 5. Linear regression analysis of the temporal relationships between fluctuations of membrane potential of cutaneous axons and locomotor bursts over several cycles showed that the timing of presynaptic events in cutaneous afferents is related to the events of the locomotor output. However, the same type of analysis showed that the amplitude of axonal depolarizations and the amplitude of flexor and extensor locomotor bursts could vary independently. Tight temporal relationships were also found between the depolarizations recorded in cutaneous units and the fluctuations recorded at the dorsal root level (DRP). 6. Based on the assumption that the locomotor fluctuations of cutaneous membrane potential are mediated through the primary afferent depolarization (PAD) pathways associated with presynaptic inhibition, it is proposed that the central pattern generator for locomotion (CPG) could phasically control the efficacy of transmission of cutaneous pathways at a presynaptic level as part of the locomotor program.