Neuron–transistor coupling: interpretation of individual extracellular recorded signals

The electrical coupling of randomly migrating neurons from rat explant brain-stem slice cultures to the gates of non-metallized field-effect transistors (FETs) has been investigated. The objective of our work is the precise interpretation of extracellular recorded signal shapes in comparison to the usual patch-clamp protocols to evaluate the possible use of the extracellular recording technique in electrophysiology. The neurons from our explant cultures exhibited strong voltage-gated potassium currents through the plasma membrane. With an improved noise level of the FET set-up, it was possible to record individual extracellular responses without any signal averaging. Cells were attached by patch-clamp pipettes in voltage-clamp mode and stimulated by voltage step pulses. The point contact model, which is the basic model used to describe electrical contact between cell and transistor, has been implemented in the electrical simulation program PSpice. Voltage and current recordings and compensation values from the patch-clamp measurement have been used as input data for the simulation circuit. Extracellular responses were identified as composed of capacitive current and active potassium current inputs into the adhesion region between the cell and transistor gate. We evaluated the extracellular signal shapes by comparing the capacitive and the slower potassium signal amplitudes. Differences in amplitudes were found, which were interpreted in previous work as enhanced conductance of the attached membrane compared to the average value of the cellular membrane. Our results suggest rather that additional effects like electrodiffusion, ion sensitivity of the sensors or more detailed electronic models for the small cleft between the cell and transistor should be included in the coupling model.     

Analysis of electric field stimulation of single cardiac muscle cells.

Electrical stimulation of cardiac cells by imposed extracellular electric fields results in a transmembrane potential which is highly nonuniform, with one end of the cell depolarized and the other end hyperpolarized along the field direction. To date, the implications of the close proximity of oppositely polarized membranes on excitability have not been explored. In this work we compare the biophysical basis for field stimulation of cells at rest with that for intracellular current injection, using three Luo-Rudy type membrane patches coupled together as a lumped model to represent the cell membrane. Our model shows that cell excitation is a function of the temporal and spatial distribution of ionic currents and transmembrane potential. The extracellular and intracellular forms of stimulation were compared in greater detail for monophasic and symmetric biphasic rectangular pulses, with duration ranging from 0.5 to 10 ms. Strength-duration curves derived for field stimulation show that over a wide range of pulse durations, biphasic waveforms can recruit and activate membrane patches about as effectively as can monophasic waveforms having the same total pulse duration. We find that excitation with biphasic stimulation results from a synergistic, temporal summation of inward currents through the sodium channel in membrane patches at opposite ends of the cell. Furthermore, with both waveform types, a net inward current through the inwardly rectifying potassium channel contributes to initial membrane depolarization. In contrast, models of stimulation by intracellular current injection do not account for the nonuniformity of transmembrane potential and produce substantially different (even contradictory) results for the case of stimulation from rest.     

Electrical Pacing of Cardiac Tissue Including Potassium Inward Rectification

In this study cardiac tissue is stimulated electrically through a small unipolar electrode. Numerical simulations predict that around an electrode are adjacent regions of depolarization and hyperpolarization. Experiments have shown that during pacing of resting cardiac tissue the hyperpolarization is often inhibited. Our goal is to determine if the inward rectifying potassium current (I_K1) causes the inhibition of hyperpolarization. Numerical simulations were carried out using the bidomain model with potassium dynamics specified to be inward rectifying. In the simulations, adjacent regions of depolarization and hyperpolarization were observed surrounding the electrode. For cathodal currents the virtual anode produces a hyperpolarization that decreases over time. For long duration pulses the current-voltage curve is non-linear, with very small hyperpolarization compared to depolarization. For short pulses, the hyperpolarization is more prominent. Without the inward potassium rectification, the current voltage curve is linear and the hyperpolarization is evident for both long and short pulses. In conclusion, the inward rectification of the potassium current explains the inhibition of hyperpolarization for long duration stimulus pulses, but not for short duration pulses.     

Potassium current activated by depolarization of dissociated neurons from adult guinea pig hippocampus

Currents were generated by depolarizing pulses in voltage-clamped, dissociated neurons from the CA1 region of adult guinea pig hippocampus in solutions containing 1 microm tetrodotoxin. When the extracellular potassium concentration was 100 mM, the currents reversed at -8.1 +/- 1.6 mV (n = 5), close to the calculated potassium equilibrium potential of -7 mV. The currents were depressed by 30 mM tetraethylammonium in the extracellular solution but were unaffected by 4-aminopyridine at concentrations of 0.5 or 1 mM. It was concluded that the currents were depolarization-activated potassium currents. Instantaneous current-voltage curves were nonlinear but could be fitted by a Goldman-Hodgkin-Katz equation with PNa/PK = 0.04. Conductance-voltage curves could be described by a Boltzmann-type equation: the average maximum conductance was 65.2 +/- 15.7 nS (n = 9) and the potential at which gK was half-maximal was -4.8 +/- 3.9 mV (mean +/- 1 SEM, n = 10). The relationship between the null potential and the extracellular potassium concentration was nonlinear and could be fitted by a Goldman-Hodgkin-Katz equation with PNa/PK = 0.04. The rising phase of potassium currents and the decay of tail currents could be fitted with exponentials with single time constants that varied with membrane potential. Potassium currents inactivated to a steady level with a time constant of approximately 450 ms that did not vary with potential. The currents were depressed by substituting cobalt or cadmium for extracellular calcium but similar effects were not obtained by substituting magnesium for calcium.     

Effects of barium and ouabain on electrogenesis in various sites of intact and detubulated skeletal muscle fibers of the frog <Emphasis Type="Italic">R. temporaria</Emphasis>

In loose patch clamp experiments on intact sartorius muscle fibers of the frog Rana temporaria, there have been two types of waveforms of extracellularly recorded action potentials (AP). Responses of the first type (T1AP) consisted of an initial positive phase with a subsequent phase of strong negativity, the latter only in a few cases followed by a weak positive phase. Responses of the second type (T2AP) always had an additional positive phase concluding their waveform. In the detubulated fibers, only T1AP were recorded. Application of Ba²⁺ (10 μM) to the muscle led to a significant increase in the amplitude of the third T2AP phase whereas the T1AP characteristics of both intact and detubulated muscle preparations remained unchanged. In some of the studied intact fibers, after Ba²⁺ or ouabain (50 μM) applied, the latest positive signal phase was replaced by a negative phase. The amplitude of this latest negative phase was increased markedly by highfrequency stimulation. Under the simultaneous action of ouabain and Ba²⁺, there was a summation of their effects. Our results can be tentatively explained by that the T-system of a muscle fiber produces electrical responses substantially differing in their pattern and barium sensitivity from those transmitted across cell membranes. These differences could be resultant from the activity of T-tubular inwardly rectifying potassium channels (K_ir) and that of Na,K-ATPase as they both provide absorption of excessive extracellular potassium.     

Diffusion of extracellular K+ can synchronize bursting oscillations in a model islet of Langerhans.

Electrical bursting oscillations of mammalian pancreatic beta-cells are synchronous among cells within an islet. While electrical coupling among cells via gap junctions has been demonstrated, its extent and topology are unclear. The beta-cells also share an extracellular compartment in which oscillations of K+ concentration have been measured (Perez-Armendariz and Atwater, 1985). These oscillations (1-2 mM) are synchronous with the burst pattern, and apparently are caused by the oscillating voltage-dependent membrane currents: Extracellular K+ concentration (Ke) rises during the depolarized active (spiking) phase and falls during the hyperpolarized silent phase. Because raising Ke depolarizes the cell membrane by increasing the potassium reversal potential (VK), any cell in the active phase should recruit nonspiking cells into the active phase. The opposite is predicted for the silent phase. This positive feedback system might couple the cells' electrical activity and synchronize bursting. We have explored this possibility using a theoretical model for bursting of beta-cells (Sherman et al., 1988) and K+ diffusion in the extracellular space of an islet. Computer simulations demonstrate that the bursts synchronize very quickly (within one burst) without gap junctional coupling among the cells. The shape and amplitude of computed Ke oscillations resemble those seen in experiments for certain parameter ranges. The model cells synchronize with exterior cells leading, though incorporating heterogeneous cell properties can allow interior cells to lead. The model islet can also be forced to oscillate at both faster and slower frequencies using periodic pulses of higher K+ in the medium surrounding the islet. Phase plane analysis was used to understand the synchronization mechanism. The results of our model suggest that diffusion of extracellular K+ may contribute to coupling and synchronization of electrical oscillations in beta-cells within an islet.     

Background K+ current in isolated canine cardiac Purkinje myocytes.

The current-voltage (I-V) relation of the background current, IK1, was studied in isolated canine cardiac Purkinje myocytes using the whole-cell, patch-clamp technique. Since Ba2+ and Cs+ block IK1, these cations were used to separate the I-V relation of IK1 from that of the whole cell. The I-V relation of IK1 was measured as the difference between the I-V relations of the cell in normal Tyrode (control solution) and in the presence of either Ba2+ (1 mM) or Cs+ (10 mM). Our results indicate that IK1 is an inwardly rectifying K+ current whose conductance depends on extracellular potassium concentration. In different [K+]0's the I-V relations of IK1 exhibit crossover. In addition the I-V relation of IK1 contains a region of negative slope (even when that of the whole cell does not). We also examined the relationship between the resting potential of the myocyte, Vm, and [K+]0 and found that it exhibits the characteristic anomalous behavior first reported in Purkinje strands (Weidmann, S., 1956, Elektrophysiologie der Herzmuskelfaser, Med. Verlag H. Huber), where lowering [K+]0 below 4 mM results in a depolarization.     

兔血管平滑肌延迟整流钾通道研究及其与克隆Kv1.5通道的电生理特性比较

本文用膜片箝全细胞技术比较了研究了单个兔肺动脉血管平滑肌细胞上延迟整流钾通道与克隆Ｋｖ１．５通道的电生理及药理学特性。将平滑肌细胞箝制在－４０ｍＶ,以１０ｍＶ的步跨阶跃去极化（０￣６０ｍＶ）可产生一系列快速上升的外向电流,几无衰减,其激活曲线的Ｖ１／２为２７．２ｍＶ。灌流液中加入１００ｍｍｏｌ／Ｌ和ＴＥＡ １ｍｍｏｌ／Ｌ ４ＡＰ,电流幅度均明显减小,细胞外Ｃａ＾２＋水平由１．５ｍｍｏｌ／Ｌ降至０．     

Modulatory effects of acid-sensing ion channels on action potential generation in hippocampal neurons

Extracellular acidification has been shown to generate action potentials (APs) in several types of neurons. In this study, we investigated the role of acid-sensing ion channels (ASICs) in acid-induced AP generation in brain neurons. ASICs are neuronal Na⁺ channels that belong to the epithelial Na⁺ channel/degenerin family and are transiently activated by a rapid drop in extracellular pH. We compared the pharmacological and biophysical properties of acid-induced AP generation with those of ASIC currents in cultured hippocampal neurons. Our results show that acid-induced AP generation in these neurons is essentially due to ASIC activation. We demonstrate for the first time that the probability of inducing APs correlates with current entry through ASICs. We also show that ASIC activation in combination with other excitatory stimuli can either facilitate AP generation or inhibit AP bursts, depending on the conditions. ASIC-mediated generation and modulation of APs can be induced by extracellular pH changes from 7.4 to slightly <7. Such local extracellular pH values may be reached by pH fluctuations due to normal neuronal activity. Furthermore, in the plasma membrane, ASICs are localized in close proximity to voltage-gated Na⁺ and K⁺ channels, providing the conditions necessary for the transduction of local pH changes into electrical signals. cellular excitability; neuronal signaling; pH     

胞外钙对豚鼠耳蜗Deiters细胞钾电流的调制

为观察胞外钙对豚鼠耳蜗单个离体Deiters细胞钾电流的调控作用并探讨其机制,实验记录了Deiters细胞在正常细胞外液和无钙外液中的全细胞钾电流(whole cell K^ currents,IK),并分析了其电生理学特性的改变。结果观察到,Deiters细胞与在正常细胞外液中相比,在祛除细胞外液中的Ca^2 后Ik电流幅值明显增加,弦电导值亦明显增加,但其平衡电位未明显改变。在无钙外液中Ik电流的反转电位向超极化方向明显移位,更接近于按照Ner-nst方程得出的K^ 理论平衡电位;而且其稳态激活曲线亦向超极化方向明显移位,但其激活趋势与正常相比无明显改变。此外,观察了Deiters细胞中钙抑制性钾电流的电流-电压关系和电导-电压关系,发现两者均呈“S”形,提示此钙抑制性钾电流可能存在2种不同的钾电导成分。由此,推测可能有两种机制参与胞外钙对Deiters细胞钾电流的调控：(1)Deiters细胞中的Ik通道可能存在一个Ca^2 敏感结构域,胞外Ca^2 可能通过改变此结构域而对Ik电流产生调制;(2)Deiters细胞中可能存在一种新型的双相门控性钾通道或钾通道耦联型受体或是一种新型的钾通道亚型,祛除胞外Ca^2 可激活此新型钾电导而对L电流产生调制。由此推测,在听觉形成过程中,胞外钙浓度下降可以对Deiters细胞的全细胞钾电流产生调制,从而更有利于Deiters细胞内K^ 外流,进而有效地缓冲外毛细胞周围的K^ 浓度：而且还可以使Deiters细胞产生更快的复极化并有利于维持其静息状态。     

The A-like potassium current of a leech neuron increases with age in cell culture

Single leech neurons isolated and maintained in culture sprout and form electrical and chemical synapses, as they do in vivo, retaining most of the electrical properties of the intact membrane. However, some cells, such as Retzius, Anterior Pagoda (AP) cells and motoneurons, exhibit consistent changes of biophysical characteristics, which mimic those induced by axotomy in vivo and are reversed after reconnection. To improve our understanding of the mechanisms involved in these alterations and of their physiological significance, we investigated the early changes in outward currents developed by cultured AP neurons, using the patch-clamp technique in the whole-cell recording configuration. Different currents were isolated and a differential sensitivity to the time spent in culture and to internal calcium was observed. Three potassium currents were dissected: an A-like current, a delayed rectifier and a third unidentified component. The A-like potassium current was significantly increased with neuronal age in cell culture and was a function of the internal Ca²⁺ concentration, whereas the two other potassium currents remained unchanged. Intracellular recordings performed from axotomized neurons of cultured ganglia revealed clear-cut alterations in spike adaptation, which might be due to changes of the A-like current. Accepted: 24 September 1998     

Depletion and accumulation of potassium in the extracellular clefts of cardiac Purkinje fibers during voltage clamp hyperpolarization and depolarization: experiments in sodium-free bathing media

Voltage clamp hyperpolarization and depolarization result in currents consistent with depletion and accumulation of potassium in the extracellular clefts o cardiac Purkinje fibers exposed to sodium-free solutions. Upon hyperpolarization, an inward current that decreased with time (id) was observed. The time course of tail currents could not be explained by a conductance exhibiting voltage-dependent kinetics. The effect of exposure to cesium, changes in bathing media potassium concentration and osmolarity, and the behavior of membrane potential after hyperpolarizing pulses are all consistent with depletion of potassium upon hyperpolarization. A declining outward current was observed upon depolarization. Increasing the bathing media potassium concentration reduced the magnitude of this current. After voltage clamp depolarizations, membrane potential transiently became more positive. These findings suggest that accumulation of potassium occurs upon depolarization. The results indicate that changes in ionic driving force may be easily and rapidly induced. Consequently, conclusions based on the assumption that driving force remains constant during the course of a voltage step may be in error.     

Increased excitability of acidified skeletal muscle: role of chloride conductance

Generation of the action potentials (AP) necessary to activate skeletal muscle fibers requires that inward membrane currents exceed outward currents and thereby depolarize the fibers to the voltage threshold for AP generation. Excitability therefore depends on both excitatory Na+ currents and inhibitory K+ and Cl- currents. During intensive exercise, active muscle loses K+ and extracellular K+ ([K+]o) increases. Since high [K+]o leads to depolarization and ensuing inactivation of voltage-gated Na+ channels and loss of excitability in isolated muscles, exercise-induced loss of K+ is likely to reduce muscle excitability and thereby contribute to muscle fatigue in vivo. Intensive exercise, however, also leads to muscle acidification, which recently was shown to recover excitability in isolated K(+)-depressed muscles of the rat. Here we show that in rat soleus muscles at 11 mM K+, the almost complete recovery of compound action potentials and force with muscle acidification (CO2 changed from 5 to 24%) was associated with reduced chloride conductance (1731 +/- 151 to 938 +/- 64 microS/cm2, P < 0.01) but not with changes in potassium conductance (405 +/- 20 to 455 +/- 30 microS/cm2, P < 0.16). Furthermore, acidification reduced the rheobase current by 26% at 4 mM K+ and increased the number of excitable fibers at elevated [K+]o. At 11 mM K+ and normal pH, a recovery of excitability and force similar to the observations with muscle acidification could be induced by reducing extracellular Cl- or by blocking the major muscle Cl- channel, ClC-1, with 30 microM 9-AC. It is concluded that recovery of excitability in K(+)-depressed muscles induced by muscle acidification is related to reduction in the inhibitory Cl- currents, possibly through inhibition of ClC-1 channels, and acidosis thereby reduces the Na+ current needed to generate and propagate an AP. Thus short term regulation of Cl- channels is important for maintenance of excitability in working muscle.     

Expression of voltage dependent potassium currents in freshly dissociated rat articular chondrocytes.

The electrophysiological properties of voltage dependent potassium channels from freshly dissociated rat articular chondrocytes were studied. The resting membrane potential (-42.7+/-2.0 mV) was significantly depolarized by increasing concentrations of external potassium. No change was observed when external chloride concentration was varied. Addition of TEA, 4AP, alpha-Dendrotoxin and charybdotoxin depolarized resting membrane potential. Whole cell patch clamp studies revealed the presence of outwardly rectifying currents whose kinetic and pharmacological properties suggest the expression of voltage dependent potassium channels. Two kinds of currents were observed under the same experimental conditions. The first one, most frequently observed (80%), starts activating near -50 mV, with V(1/2)=-18 mV, G(max)=0.30 pS/pF. The second kind was observed in only 10% of cases; It activates near -40 mV, with(1/2)=+28.35 mV, G(max)=0.28 pS/pF pA/pF and does not inactivates. Inactivating currents were significantly inhibited by TEA (IC(50)=1.45 mM), 4AP (IC(50)=0.64 mM), CTX (IC(50) = 10 nM), alpha-Dendrotoxin (IC(50) < 100 nM) and Margatoxin (IC(50)=28.5 nM). These results show that rat chondrocytes express voltage dependent potassium currents and suggest a role of voltage-dependent potassium channels in regulating membrane potential of rat chondrocytes.     

The dependence of calcium-activated potassium currents on membrane potential.

Previous experiments on cholinergic synapses in chick cochlear hair cells have shown that calcium entering through acetylcholine-activated synaptic channels in turn activates calcium-dependent potassium currents, resulting in synaptic inhibition. In voltage-clamp experiments such currents would be expected to increase with depolarization (as the driving force for potassium entry is increased) and then decrease towards zero as the membrane approaches the calcium equilibrium potential (when calcium entry is suppressed). In the hair cells, however, such currents approached zero at about +20 mV, more than 170 mV negative to the calcium equilibrium potential. Another feature of the synapse is its post-junctional morphology: a uniform 20 nm cleft is formed between the postsynaptic membrane and the outermost membrane of an underlying cisterna. Here we present a model in which synaptic activation results in calcium influx into the subsynaptic cleft and thence into the bulk of the cytoplasm. The model suggests that the voltage dependence of the calcium-activated potassium current can be accounted for by only two basic assumptions: (i) entry of calcium through the activated synaptic channels by simple diffusion; and (ii) activation of the potassium channels by the cooperative action of four calcium ions. In addition, the model suggests that during activation the calcium concentration in the restricted subsynaptic space can reach levels adequate to activate the potassium channels, without requiring additional, more complicated, considerations (for example, secondary calcium release from the cisterna).     

Characteristics of store-operated calcium channels activated by depletion of the endoplasmic reticulum ryanodine-sensitive calcium stores in rat dorsal root ganglion neurons

In neurons of the rat dorsal root ganglia (DRG), using a patch-clamp technique in the whole-cell configuration, we studied the characteristics of calcium channels activated by depletion of the ryanodine-sensitive calcium stores of the endoplasmic reticulum. Current-voltage (I-V) relationships of these store-operated calcium channels were obtained by subtraction of the integral I-V characteristics after application of caffeine from the integral I-V characteristics of calcium channels in the control. Currents through store-operated calcium channels could be induced by application of a series of hyperpolarization current pulses to the cell under conditions of replacement of a calcium-free solution containing caffeine by a caffeine-free solution containing 2 mM Ca²⁺. In this case, the following two main conditions were abserved: Voltage-operated calcium channels were inactivated, while a gradient of the electrochemical potential for calcium ions was increased, which made easier passing of these currents through store-operated calcium channels. Therefore, we found that in DRG neurons, despite the presence of great numbers of both voltage-operated and receptor-dependent calcium channels, one more mechanism underlying the entry of calcium through store-operated channels does exist. Neirofiziologiya/Neurophysiology, Vol. 39, No. 3, pp. 195–200, May–June, 2007.     

Analysis of an equivalent electric circuit of the hepatocyte during stopping and restoration of the blood flow

An analysis of an electric scheme of hepatocyte under conditions of stopping and restoring the blood flow taking into account the morphological and biochemical characteristics of the normal and injured liver was carried out. It is shown that the fast phase of restoring the membrane potential (MP) when restoring the blood flow following ischemia is stipulated by restoring extracellular concentrations of potential-generating ions; and slow restoring of the normal liver MP is connected with the phase of potassium efflux hyperpolarization. The injured liver MP stability to ischemia is higher because of the transmembrane ion gradient decrease before ischemia and next effect of depolarisation of passive currents weakening under conditions of closed extracellular space, and total ATPase activity decrease, i.e. a more economical ATP expenditure by the cell at ischemia.     

A Continuum Neuronal Model for the Instigation and Propagation of Cortical Spreading Depression

Cortical spreading depression (CSD) waves can occur in the cortices of various brain structures and are associated with the spread of depression of the electroencephalogram signal. In this paper, we present a continuum neuronal model for the instigation and spreading of CSD. Our model assumes that the brain-cell microenvironment can be treated as a porous medium consisting of extra- and intracellular compartments. The main mechanisms in our model for the transport of ions into and out of neurons are cross-membrane ionic currents and (active) pumps, coupled with diffusion in the extracellular space. To demonstrate the applicability of our model, we have carried out extensive numerical simulations under different initial conditions and inclusion of various mechanisms. Our results show that CSD waves can be instigated by injecting cross-membrane ionic currents or by applying KCl in the extracellular space. Furthermore, the estimated speeds of CSD waves are within the experimentally observed range. Effects of specific ion channels, background ion concentrations, extracellular volume fractions, and cell swelling on the propagation speed of CSD are also investigated.     

Electrophysiological study on the effects of leptin in rat dorsal motor nucleus of the vagus

Immunoreactivity of leptin receptor (Ob-R) has been detected in rat dorsal motor nucleus of the vagus (DMNV). Here, we confirmed the presence of Ob-R immunoreactivity on retrograde-labeled parasympathetic preganglionic neurons in the DMNV of neonatal rats. The present study investigated the effects of leptin on DMNV neurons, including parasympathetic preganglionic neurons, by using whole cell patch-clamp recording technique in brain stem slices of neonatal rats. Leptin (30-300 nM) induced membrane depolarization and hyperpolarization, respectively, in 14 and 15 out of 80 DMNV neurons tested. Both leptin-induced inward and outward currents persisted in the presence of TTX, indicating that leptin affected DNMV neurons postsynaptically. The current-voltage (I-V) curve of leptin-induced inward currents is characterized by negative slope conductance and has an average reversal potential of -90 +/- 3 mV. The reversal potential of the leptin-induced inward current was shifted to a more positive potential level in a high-potassium medium. These results indicate that a decrease in potassium conductance is likely the main ionic mechanism underlying the leptin-induced depolarization. On the other hand, the I-V curve of leptin-induced outward currents is characterized by positive slope conductance and has an average reversal potential of -88 +/- 3 mV, suggesting that an increase in potassium conductance may underlie leptin-induced hyperpolarization. Most of the leptin-responsive DMNV neurons were identified as being parasympathetic preganglionic neurons. These results suggest that the DMNV is one of the central target sites of leptin, and leptin can regulate parasympathetic outflow from the DMNV by directly acting on the parasympathetic preganglionic neurons of the DMNV.     

Axonal excitability revisited

The original papers of Hodgkin and Huxley (J. Physiol. 116 (1952a) 449, J. Physiol. 116 (1952b) 473, J. Physiol. 116 (1952c) 497, J. Physiol. 117 (1952d) 500) have provided a benchmark in our understanding of cellular excitability. Not surprisingly, their model of the membrane action potential (AP) requires revisions even for the squid giant axon, the preparation for which it was originally formulated. The mechanisms they proposed for the voltage-gated potassium and sodium ion currents, IK, and INa, respectively, have been superceded by more recent formulations that more accurately describe voltage-clamp measurements of these components. Moreover, the current-voltage relation for IK has a non-linear dependence upon driving force that is well described by the Goldman-Hodgkin-Katz (GHK) relation, rather than the linear dependence on driving force found by Hodgkin and Huxley. Furthermore, accumulation of potassium ions in the extracellular space adjacent to the axolemma appears to be significant even during a single AP. This paper describes the influence of these various modifications in their model on the mathematically reconstructed AP. The GHK and K+ accumulation results alter the shape of the AP, whereas the modifications in IK and INa gating have surprisingly little effect. Perhaps the most significant change in their model concerns the amplitude of INa, which they appear to have overestimated by a factor of two. This modification together with the GHK and the K+ accumulation results largely remove the discrepancies between membrane excitability of the squid giant axon and the Hodgkin and Huxley (J. Physiol. 117 (1952d) 500) model previously described (Clay, J. Neurophysiol. 80 (1998) 903).