Expression of anion exchanger 3 influences respiratory rate in awake and isoflurane anesthetized mice.

The anion exchanger 3 (AE3) is involved in neuronal pH regulation of which may include chemosensitive neurons. Here we examined the effect of AE3 expression on respiratory rate (RR) in vivo. AE3 knockout (KO, n=5) and wild type (WT, n=6) mice were subjected to body plethysmography, both while awake and during isoflurane anesthesia. RR was significantly lower in awake AE3 KO (162+/-7SE min(-1)) than in WT mice (212+/-20 min(-1), P=0.036). The same was found during isoflurane anesthesia at 0.5 MAC (KO: 123+/-9 min(-1), WT: 168+/-15 min(-1), P=0.026) and 1.0 MAC (KO: 51+/-6 min(-1), WT: 94+/-6 min(-1), P=0.001). Hypercapnia (5% CO2) increased RR in awake and decreased RR in nesthetized (1.0 MAC) mice, whereby relative changes were larger in AE3 KO mice. Recovery from isoflurane anesthesia in respect to RR regaining baseline values was more pronounced in AE3 KO. Results show that AE3 expression profoundly influences control of breathing in mice.

Effects of vitamin D3, 17beta-estradiol, vasoactive intestinal peptide, and glutamate on electric coupling between rat osteoblast-like cells in vitro.

Osteoblast-like cells express receptors for various hormones and neurotransmitters that induce widespread actions in the bone to which intercellular communication and its modulation may contribute. Therefore, we examined the effects of the osteotropic hormones vitamin D3 (vitD3) and 17beta-estradiol (17beta-E2) as well as the neurotransmitter vasoactive intestinal peptide (VIP) and the excitatory amino acid glutamate (Glu) on gap junctions between rat osteoblast-like (ROB) cells in vitro. Electric coupling was measured by simultaneous intracellular recordings from neighboring cells. The coupling factor (cf) was calculated from membrane potential changes induced by alternate current injections into both cells. In ROB cells cf was increased by 5 x 10(-8) mol/L vitD3 to 130 +/- 13% (mean +/- SD; n = 6) of the initial value within 5-20 min. This effect was not reversible after washing with control saline for 10-15 min. In six cell pairs, cf was not affected by vitD3 (94 +/- 5%). In three cell pairs superfusion of 10(-8) mol/L E2 reduced cf to 80 +/- 6% within 10 min, whereas, in two cell pairs, this hormone improved cf to 140% within 20 min. Exposure of VIP (3 x 10(-8) mol/L) did not alter cf in the majority of cells (99 +/- 3%; n = 11). In five cell pairs, cf was improved within 5-15 min to 133 +/- 12%, whereas, in one cell pair, cf was reduced to 22% by VIP. In contrast, brief application of Glu (5 x 10(-3) mol/L) decreased cf to 75 +/- 5% (n = 5), whereas, in nine other cell pairs, cf was not affected (96 +/- 5%). The findings indicate that cell-cell coupling of gap junctions between bone cells can be altered by actions of hormones and transmitters in a cell-pair-specific way, which may depend on their functional state.

GABA-responses of CA3 neurones at epileptogenic threshold concentrations of convulsants.

Epileptogenic actions of convulsants are often attributed to weakened inhibitory synaptic mechanisms. This assumption was tested by studying GABA-induced postsynaptic membrane potential (MP) changes of CA3 neurones (guinea-pig) before and during exposure to bicuculline methoiodide (BMI), pentylenetetrazol (PTZ), penicillin (PEN) and caffeine (CAF). Under control conditions GABA ejections elicited polyphasic MP fluctuations (components I-III). After adding BMI, PTZ, PEN or CAF, early hyperpolarizations (component I) did not change at epileptogenic threshold concentrations. These convulsants, however, exerted differential effects on the depolarizing component II, but only threshold concentrations of penicillin strongly reduced the amplitude of this component. Simultaneously, component III was slightly accentuated. These findings indicate that changes of GABA responses are not an essential prerequisite for the generation of paroxysmal depolarizations.

GABAA-responses of CA3 neurones: contribution of bicarbonate and of Cl(-)-extrusion mechanisms.

Postsynaptic GABAA-responses of cortical neurones may be composed of an early 'somatic' hyperpolarization (h-GABAA) and a 'dendritic' depolarization (d-GABAA). In order to study underlying anion-fluxes the gradient of bicarbonate across the membrane of CA3-neurones in hippocampal slices (guinea-pig) was reduced by several manoeuvres (NH4-prepulse-technique, CO2/bicarbonate-withdrawal-technique, acetazolamide, DIDS). Each manoeuvre resulted in an attenuation of d-GABAA. The inhibition of a Cl-/bicarbonate-exchanger with DIDS could also weaken h-GABAA which was selectively impaired by ethacrynic acid--known to block an ATP-driven somatic Cl(-)-extrusion mechanism. In conclusion, bicarbonate-fluxes contribute to d-GABAA rather than to h-GABAA which is mainly driven by Cl(-)-fluxes. An uneven distribution of Cl(-)-extrusion mechanisms along the adult CA3-neurones is likely to build up the anion-gradients necessary to generate biphasic GABAA-responses.

Ethacrynic acid: effects on postsynaptic GABA responses and electric activity of CA3 neurones.

Ethacrynic acid (ETA) inhibits somatic Cl(-)-extrusion from hippocampal pyramidal neurones. We analysed the dependence of postsynaptic gamma-aminobutyric acid (GABA) responses on this Cl- extrusion. ETA irreversibly reduced the 'somatic' hyperpolarizing GABAA response (hGABAA) within a few minutes, without altering the following depolarizing GABAA (dGABAA) and hyperpolarizing GABAB responses. GABA-induced changes of the membrane resistance were not affected by ETA, indicating that ETA does not act primarily on receptor-operated channels. In about 50% of the tested CA3 neurones spontaneous activity and caffeine-induced epileptiform discharges increased initially after adding ETA. All neurones lost their activity during prolonged ETA exposure. The early ETA-induced increase of neuronal activity coincided with the decrease of hGABAA (disinhibition). The late suppressive action may be caused by intracellular acidosis.

CO2-sensitive medullary neurons: activation by intracellular acidification.

Bioelectric activity of CO2-sensitive, ventrolateral medullary neurons (VLN(CS)) in organotypic cultures from the obex level of newborn rats was tested during changes of the intracellular pH (pHi) measured in BCECF-AM loaded cultures. Hypercapnia (pCO2 80-100 mmHg) reduced pHi by 0.15 +/- 0.06 units and stimulated neuronal discharges. Replacement of CO2/HCO3- in the bath by HEPES (26 mM, pH 7.4) for 10 min acidified pHi (0.07 +/- 0.03 units) and also excited VLN(CS). Ammonium chloride (10 mM, 1 min) initially alkalized (0.1 +/- 0.04) and thereafter acidified pHi (0.06 +/- 0.03), while the extracellular pH was first acidified and then alkalized. This resulted in neuronal discharge which were first suppressed and then accelerated. The findings strongly suggest that intracellular rather than extracellular acidification activates CO2-sensitive neurons.

DAPAS, a computerised workplace for Digital Acquisition and Processing of Analog Signals, with up to two gigabytes data per registration.

A comprehensive and flexible arrangement for Digital long-term Acquisition and Processing of Analog Signals (DAPAS) has been developed. It is especially designed for neurophysiological laboratories and mainly based on IBM-compatible PC components. A/D converters are used, which allow sampling rates of up to 100 kHz (up to 16 bits, 1-16 channels). Signals are stored continuously on DOS devices and on a fast tape streamer, which uses standard video-8 tapes, and which is 2.8 times faster than DAT-based systems. As the recording speed is adapted to the sampling rate, one tape allows recording times of (uncompressed) data acquired at a sampling rate of 100 or 10 kHz of 6.8 and 68 h, respectively. Using a coprocessor-video device, recordings may be scrolled on- or off-line on the screen. In addition, up to eight multi-channel oscilloscopes are displayed simultaneously. DAPAS allows the use of a conventional matrix printer which can act as an inertia-free multi-pen recorder. Defined stored signals are recalled by means of a time code or textual markers. All sections of recordings lasting milliseconds to hours may be displayed within seconds. DAPAS supports export filters for further processing. Thus, this system replaces analog devices (multi-pen recorder, oscilloscope, data recorder), and enables quick, complete digital processing and analysis of neurophysiological data.

Cutting of living hippocampal slices by a highly pressurised water jet (macromingotome).

Living brain slices are usually cut with razor blades, which compress a ca. 50-microm-thick layer of tissue. This results in cell debris and lesioned cells which, e.g. form diffusion barriers between the bath and living neurons underneath, thereby prolonging response times of neurons to drugs in the bath saline and impeding the experimental access to intact neurons. To avoid such drawbacks, a macromingotome was developed which cuts nervous tissue with water jets. Physiological saline under pressures of 100-1800 bar was ejected through nozzles of 35-100 microm to cut 300-500-microm-thick hippocampal slices. Systematic variations of pressure and nozzle diameter revealed best results at 400-600 bar and with nozzle diameters of 60-80 microm. Under these conditions, intact CA1- and CA3-neurons as well as granule cells were detected with infrared microscopy at less than 10 microm underneath the surface of the slice. Superficial neurons with intact fine structures were also seen when the slices were studied by light-microscopy. Intra- and extracellular recordings from superficial neurons showed normal membrane- and full action potentials and the development of stable epileptiform discharges in 0 Mg(2+)-saline. These results indicate that the macromingotome offers an alternative way of cutting slices which may facilitate electrophysiological/neuropharmacological or fluorometric studies on superficial neurons.

Microcutting of living brain slices by a pulsed ultrafine water jet which allows simultaneous electrophysiological recordings (micromingotome).

Up to now microsurgical dissections in living nervous tissue (e.g. in slices or cell cultures) are performed either by micro-scalpels or by laser beams. As an alternative technique, a device for cutting with an ultrafine pulsed water jet was developed to allow precise, visually controled dissections in neuronal circuits even during electrophysiological recordings. Water is ejected by pressure (20-30 bar) from patch pipettes with tip diameters of 10-12 microm. By means of a piezo-element the pipette and the water jet are forced to oscillate vertically with a frequency of 200-400 Hz with an adjustable amplitude. These oscillations facilitate the transsection of neuronal connections even in thick slice preparations. Best results were obtained when the tip of the pipette was about 500 microm above the surface of the submerged slice tissue. This micromingotome offers the following advantages: (i) histological studies show that the water jet cleans the cutting surface, thus avoiding debris and its uncontrolable effects on cells underneath; (ii) the arrangement enables ongoing electrophysiological recordings from hippocampal slices during the cutting procedure and thus facilitates studies of the functions of neuronal connections; (iii) the device allows even disconnection in cultured nervous tissue overgrowing polyamid grids with 50 microm wide meshes.

Epileptogenic actions of xanthines in relation to their affinities for adenosine A1 receptors in CA3 neurons of hippocampal slices (guinea pig).

In order to analyze the epileptogenic mechanisms of caffeine and related xanthines, putative effects of these drugs were studied on adenosine receptors of CA3 neurons in hippocampal slices. Epileptogenic concentrations of different xanthine derivatives strongly correlated with their affinities for the inhibitory A1 adenosine receptor subtype. The A1 receptor agonists adenosine and R-PIA reversibly depressed xanthine-induced epileptic activity without effects on the resting membrane potential or on spontaneously occurring action potentials. These findings suggest that the epileptogenic potency of xanthines is primarily due to the blockade of the A1 receptors through an abnormal rise of intracellular cAMP and to the excessive transmembrane calcium fluxes underlying paroxysmal depolarization shifts.

pO2-dependent distribution of potassium in hippocampal slices of the guinea pig.

The distribution of extracellular K+-concentration (cK+s) in 200-1000-micron thick hippocampal slices was studied with ion-selective microelectrodes. In ca. 500-micron thick slices cK+s increased from the surface to the innermost layers by ca. 2 mmol/liter if the pO2 of the bath (pBO2) ranged from 300-600 mm Hg and if the temperature was 28 degrees C. In thicker slices and lowered pO2-values further elevations of cK+s were observed. In vital slices thinner than 500 micron cK+s-values exceeded the potassium-concentration of the bath (cK+B) only when pBO2 was markedly lowered. When pBO2 was reincreased in such thin slices, cK+s rapidly declined and often decreased transiently below ck+B. Similar undershoots of cK+s were observed when cK+B was lowered from high to normal levels. The rapid decline was blocked by hypoxia, ouabain, antimycine and a temperature of 18 degrees C. A stepwise rise of cK+B also caused rapid changes of cK+s in vital thin slices. The rates of changes, however, were hardly affected e.g. by a transient hypoxia. Diffusion did not contribute significantly to these steep changes of cK+s. These rapid distribution modes were widely missing in slices thicker than 500 micron. Therefore in such preparations, the extracellular microenvironment of neurons may markedly differ from the ionic concentrations in the bath.

Diffusion in slice preparations bathed in unstirred solutions.

A diffusion model is described here, which allows for the estimations of drug concentration changes in porous media, such as in slice tissues of the central nervous system (CNS) bathed in unstirred solutions following abrupt changes of drug concentration. This model may be used for the interpretation of data obtained in neuropharmacological studies if (i) the diffusion coefficient of the molecules under investigation is constant within the excised tissue, (ii) drug molecules are diffusing only in the extracellular space (ECS) and are not bound by the tissue, (iii) drug molecules diffuse mainly within one dimension, (iv) the drug concentration in the bath is changed within 5 s, and (v) the bathing solutions at the surfaces of the slices are stagnant during the period of diffusion. To test this model, estimated tetramethylammonium (TMA) ion concentrations within a tissue slice were compared to actual TMA concentration changes measured at the same depth in the tissue of hippocampal slices by means of TMA-sensitive microelectrodes. A statistically significant correlation (P less than 0.05) was observed between the estimated and measured TMA concentrations which indicates that the model is valid under the defined conditions.

CO2/HCO3(-)-withdrawal from the bath medium of hippocampal slices: biphasic effect on intracellular pH and bioelectric activity of CA3-neurons.

Many studies analyzing interactions of pH and bioelectric activity focus on changes of the extracellular pH, whereas data concerning central neuronal excitability and intracellular pH (pHi) are rare. Here, we report on the spontaneous bioelectric activity and epileptiform activity of CA3-neurons during a procedure which changed pHi. As monitored in BCECF-AM loaded cells, the change from a CO2/HCO3(-)-buffered to a HEPES-buffered medium (CO2/HCO3(-)-withdrawal, hereafter termed W) was associated with a transient intracellular alkalosis (delta pH = 0.2 +/- 0.04) which preceded a sustained intracellular acidosis (delta pH = 0.4 +/- 0.04). Coinciding with this W-induced biphasic shift of pHi a biphasic alteration of spontaneous bioelectric activity was recorded: as a rule, an up to 30 min lasting increase (excitatory phase) preceded a typical sustained suppression (inhibitory phase). This biphasic action was also observed using various in vitro-epilepsy-models (bicuculline, penicillin, caffeine): epileptiform discharges were completely suppressed after an initial increase in frequency. This modulation of bioelectric activity was unlikely due to alterations of the postsynaptic GABA-system as hyperpolarizing GABAA- and GABAB-responses of CA3-neurons were hardly affected. In the majority of the neurons, the initial increase of spontaneous bioelectric activity (excitatory phase) culminated in transient burst periods lasting 5-30 min. These transient burst periods were blocked by NMDA- or AMPA-antagonists: DL-2-amino-5-phosphonovalerate (APV, 50 microM) or 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 50 microM). The calcium-antagonist verapamil (50 microM) reduced amplitudes of depolarizations and duration of the transient burst periods. The results suggest that the biphasic alteration of pHi modulates the susceptibility of glutamate receptors and voltage-gated calcium-channels, which leads to respective changes of bioelectric activity.

Reduced signal complexity of intracellular recordings: a precursor for epileptiform activity?

Recent studies have shown that time windowed extraction of nonlinear parameters like an effective correlation dimension from intracranially recorded EEG of epileptic patients often allows to detect and identify an unequivocal "pre-ictal phase" preceding an epileptic seizure. In another study, however, such an anticipation could not be made. These conflicting findings may indicate that observed changes in nonlinear parameters probably depend on the type of elementary mechanisms underlying epileptic processes and/or the spatial distribution of neurons primarily involved in generation of epileptiform discharges. To test the existence of such dependencies, the transition from normal to epileptiform activity (EA) of CA3-neurons in hippocampal slices was analyzed in four epilepsy models, using a time windowed computation of an effective correlation dimension. Indeed, in xanthine and penicillin models, signal complexity in intracellular recordings was reduced before manifestation of paroxysmal depolarization shifts (PDS), whereas a preceding loss of complexity was missing in low-magnesium and veratridine models. These findings indicate that interictal-like EA is predictable only in some epilepsy models.

Augmentation of N-methyl-D-aspartate induced depolarizations by GABA in neocortical and archicortical neurons.

The influence of the inhibitory transmitter gamma-aminobutyric acid (GABA) on depolarizations elicited by the excitatory amino acid N-methyl-D-aspartate (NMDA) was tested in neurons of organotypic neocortical tissue cultures (newborn rat) and in CA3 neurons of the hippocampal slice (guinea pig). Drugs were applied through a 3-barrelled micropipette by pressure ejection. Applications of GABA before the ejection of NMDA increased the amplitude of the depolarizations induced by the excitatory amino acid. It is suggested that the enhancement of NMDA responses by GABA may be mainly mediated by an intracellular common pathway.

Elevated potassium prevents neuronal death but inhibits network formation in neocortical cultures.

Chronic depolarization is inimical to neuronal growth and synaptogenesis so that spontaneous action potential generation appears to be required for the normal cytomorphological maturation of neocortical networks. The efficacy of 25 mM K in suppressing spontaneous bioelectric activity was monitored by extra- and intracellular recording from the explants. Intracellular recording from individual neurons showed that membrane potentials were reduced to ca -30 mV in potassium cultures but rapidly repolarized to ca -50 mV when returned to normal growth medium. Though action potentials could be readily evoked from these explants, spontaneous discharges and postsynaptic potentials were absent from potassium-treated cultures. Both spontaneous bioelectric activity and postsynaptic potentials returned to the cultures by 5 days after returning the explants to normal growth medium. Extracellular recordings also showed that the explants were bioelectrically silent in the presence of 25 mM K or 25 mM K plus tetrodotoxin. In contrast to tetrodotoxin alone, bioelectric activity was absent when the cultures (with or without tetrodotoxin) were returned to normal growth medium. The explants gradually began to evince spontaneous bioelectric activity between 3 and 5 days after being returned to normal growth medium. Massive cell death induced by chronic exposure to tetrodotoxin was totally prevented by concomitant addition of 25 mM potassium, though these explants were significantly thinner than controls due to a large decrease in neuropil. We conclude that chronic depolarization of neonatal cortical explants by potassium results in a delayed return of spontaneous bioelectric discharges. Chronic depolarization results in a retardation of network formation in these explants apparently due to a lack of neurite and/or synapse formation.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of chronic exposure to high magnesium on neuron survival in long-term neocortical explants of neonatal rats in vitro.

In order to assess the effect of elevated magnesium, neuronal morphology and physiology was studied in chronically cultured organotypic neonatal rat occipital neocortex. Explants grown in 10 mM magnesium were found to experience an approximate 30% cell loss (as shown by cell count and DNA-protein analysis), while 12.5 and 15 mM magnesium showed ca. 47 and 60% cell losses, respectively. Intracellular recording from 10 mM magnesium explants revealed that measurable postsynaptic potentials and action potentials could occur, apparently depending on the type of cell examined. All post-synaptic activities ceased in 12.5 mM magnesium cultures, though action potentials could be elicited by current stimulation. The effects of known depolarizing agents, viz. potassium and N-methyl-D-aspartate, on 12.5 mM magnesium-grown explants were also examined. Explants grown in the presence of 12.5 mM magnesium plus 10 mM potassium showed a dramatic increase in the loss of neurons. The simultaneous addition of 6,7-dinitro-quinoxaline-2,3-dione showed this to be due to an increase in non-N-methyl-D-aspartate mediated cell death in response to glutamate release brought about by the depolarizing effects of the potassium. The addition of 10 microM N-methyl-D-aspartate to 12.5 mM magnesium-grown cultures, on the other hand, improved cell survival to control levels. The mechanism of this reciprocal neuroprotective effect of N-methyl-D-aspartate against magnesium has yet to be elucidated. We conclude that these findings are consistent with regard to the opposing actions of N-methyl-D-aspartate and magnesium on calcium influx and various metabolic processes within the explants.

Rhythm generation in organotypic medullary cultures of newborn rats.

Organotypic transverse medullary slices (obex level) from six-day-old rats, cultured for two to four weeks in chemically defined medium contained rhythmically discharging neurones which were activated by CO2 and H+. The mechanisms underlying this rhythmicity and the spread of excitation and synaptic transmission within this organotypic tissue were examined by modifying the composition of the external solution. Our findings showed that (1) Exposure to tetrodotoxin (0.2 microM) or to high magnesium (6 mM) and low calcium (0.2 mM) concentrations abolished periodic activity. (2) Neither the blockade of GABAergic potentials with bicuculline methiodide (200 microM) and/or hydroxysaclofen (200 microM) nor the blockade of glycinergic potentials with strychnine hydrochloride (100 microM) abolished rhythmicity. (3) While atropine sulphate (5 microM) was ineffective in modulating periodic discharges nicotine (100 microM) - like CO2-shortened the intervals between the periodic events; hexamethonium (50-100 microM) reduced both periodic and aperiodic activity. (4) Exposure to the NMDA antagonist 2-aminophosphonovaleric acid (50 microM) suppressed periodic events only transiently. In the presence of 2-aminophosphonovaleric acid rhythmicity recovered. However, the AMPA-antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (10-50 microM), abolished periodic activity reversibly within less than 5 min. When 6-cyano-7-nitroquinoxaline-2,3-dione and nicotine were administered simultaneously periodic events persisted for up to 10 min. These findings indicate that synaptic excitatory drive is a prerequisite for the generation of rhythmic discharges of medullary neurones in this preparation. This drive may activate voltage-dependent channels or it may facilitate endogenous cellular mechanisms which initiate oscillations of intracellular calcium concentration. To test the latter possibility (5) calcium antagonists were added to the bath saline. The organic calcium antagonists verapamil and flunarizine (50-100 microM each) and the inorganic calcium antagonists cobalt (2 mM) and magnesium (6 mM) suppressed periodic activity and abolished or weakened the chemosensitivity towards CO2/acidosis. (6) Dantrolene (10 microM). an inhibitor of intracellular calcium release decreased the periodicity, while thapsigargin (2 microM) which blocks endoplasmic Ca(2+)-ATPase, transiently accelerated the occurrence of periodic events. (7) Oscillations of intracellular free calcium concentrations in Fura-2 AM-loaded cells were weakened or abolished by cobalt (2 mM). The results of (5)-(7) indicate that transmembrane calcium fluxes as well as intracellular Ca(2+)-release and -clearance mechanisms are a prerequisite for intracellular free calcium oscillations which may be important in the generation of rhythmic discharges in medullary neurones.

Rhythm generation in brainstem cultures grown in a serum-free medium.

Electrophysiological studies were carried out on long term cultured brainstem tissue taken from neonatal rats with the object of investigating mechanisms underlying respiratory rhythm generation. The preparations were derived from 360 microns thick horizontal medullary slices which were explanted into a chemically defined nutrient medium and which remained organotypically intact for ca. 1 month. In 44 of the 50 explants examined both periodic and aperiodic bioelectric activity was detected, the cycle length of the former ranging from 0.5 to 10 s (mean, 2.7 s) at a pH of 7.4 and bath temperature of 32 degrees C. Periodic activity could take several forms, but commonly consisted of regularly repeated, 100-300 ms long, depolarizing (D-) waves or sequences of inhibitory and/or excitatory postsynaptic potentials. Lowering the pH of the superfusate by lowering the bicarbonate concentration, increasing the pCO2 or adding H+ shortened the interval between periodic events, and increased both the amplitude and duration of the D-waves. The interval was also shortened when the bath temperature was increased (Q10: ca.2.5). The mean resting membrane potential of neurons exhibiting periodic activity was -49 mV (n = 62) and not significantly different from that of aperiodically discharging neurons either in the same preparations or in cultured explants from the neocortex. These observations suggest that brainstem cultures constitute a useful 'model' system for studying pH-dependent rhythm generation in small neuronal networks of the medulla.

Electrophysiological properties of neurons in neonatal rat occipital cortex slices grown in a serum-free medium.

The electrophysiological properties of individual neurons within organotypic explants of neonatal rat cortex were examined via intracellular recordings. The explants were grown for two weeks in a serum-free medium. The electrophysiological properties of the neurons within these explants were similar to those reported for both adult cortex in vivo and short-term in vitro slice preparations. The results of the present study show that cortical explants grown under serum-free conditions can serve as a useful model for long-term developmental studies associated with the physiological basis of neural network formation.