A cross-correlation study of interactions among respiratory neurons of dorsal, ventral and retrofacial groups in cat medulla

Mu-opioid receptor agonist effects on medullary respiratory neurons in the cat: evidence for involvement in certain types of ventilatory disturbances

Mu-opioid receptor agonists depress tidal volume, decrease chest wall compliance, and increase upper airway resistance. In this study, potential neuronal sites and mechanisms responsible for the disturbances were investigated, dose-response relationships were established, and it was determined whether general anesthesia plays a role. Effects of micro-opioid agonists on membrane properties and discharges of respiratory bulbospinal, vagal, and propriobulbar neurons and phrenic nerve activity were measured in pentobarbital-anesthetized and unanesthetized decerebrate cats. In all types of respiratory neurons tested, threshold intravenous doses of the micro-opioid agonist fentanyl slowed discharge frequency and prolonged duration without altering peak discharge intensity. Larger doses postsynaptically depressed discharges of inspiratory bulbospinal and inspiratory propriobulbar neurons that might account for depression of tidal volume. Iontophoresis of the micro-opioid agonist DAMGO also depressed the intensity of inspiratory bulbospinal neuron discharges. Fentanyl given intravenously prolonged discharges leading to tonic firing of bulbospinal expiratory neurons in association with reduced hyperpolarizing synaptic drive potentials, perhaps explaining decreased inspiratory phase chest wall compliance. Lowest effective doses of fentanyl had similar effects on vagal postinspiratory (laryngeal adductor) motoneurons, whereas in vagal laryngeal abductor and pharyngeal constrictor motoneurons, depression of depolarizing synaptic drive potentials led to sparse, very-low-frequency discharges. Such effects on three types of vagal motoneurons might explain tonic vocal fold closure and pharyngeal obstruction of airflow. Measurements of membrane potential and input resistance suggest the effects on bulbospinal Aug-E neurons and vagal motoneurons are mediated presynaptically. Opioid effects on the respiratory neurons were similar in anesthetized and decerebrate preparations.

Functional reconnections established by central respiratory neurons regenerating axons into a nerve graft bridging the respiratory centers to the cervical spinal cord

The present work investigated, in adult rats, the long-term functional properties and terminal reconnections of central respiratory neurons regenerating axons within a peripheral nerve autograft bridging two separated central structures. A nerve graft was first inserted into the left medulla oblongata, in which the respiratory centers are located. Three months later, a C3 left hemisection was performed, and the distal tip of the graft was implanted into the C4 left spinal cord at the level of the phrenic nucleus, a natural central inspiratory target. Six to eight months after medullary implantation, the animals (n = 12) were electrophysiologically investigated to test 1) the phrenic target reinnervation by analyzing the phrenic responses elicited by bridge electrical stimulation and 2) the bridge innervation by unitary recordings of the spontaneous activity of regenerated axons within the nerve bridge. In the control group (n = 6), the medullary site of implantation corresponded to the dorsolateral medulla, a region known to be an unsuitable site for inducing respiratory axonal regrowth after nerve grafting. Stimulation of the nerve bridge never elicited phrenic nerve response, and no respiratory units were found within the nerve bridge. In the experimental group (n = 6), the proximal tip of the nerve bridge was implanted within the ventrolateral medulla at the level of the respiratory centers. Electrical stimulation of the nerve bridge induced phrenic nerve responses that reflected a postsynaptic activation of the phrenic target. Subsequent unitary recordings from teased fibers within the bridge revealed the presence of regenerated inspiratory fibers exhibiting discharge patterns typical of medullary inspiratory neurons, which normally make synaptic contacts with the inspiratory phrenic target. These results indicate that, when provided with an appropriate denervated target, central respiratory neurons with regenerated axons along a nerve bridge can remain functional for a long period and can make precise and specific functional reconnections with central homotypic target neurons.

Respiratory rhythm generation: converging concepts from in vitro and in vivo approaches?

The timing and activation pattern of breathing movements are determined by the respiratory network. This network is amenable to a variety of in vivo and in vitro approaches, which offers a unique opportunity to investigate multiple organizational levels. It is only recently, however, that concepts obtained under in vivo and in vitro conditions are being integrated into a coherent model of breathing behavior. For example, the pre-Bötzinger complex as an essential site for rhythm generation was first identified in vitro, but has since been verified in vivo. Conversely, timing signals provided by other central and peripheral neuronal areas have so far been investigated in vivo, but it is now possible to address these issues with more complex in vitro preparations. Several key issues remain unresolved. For example, to what extent is the respiratory pattern controlled independently of the underlying rhythm? Answers to this and other questions require a dissection of mechanisms that is only possible through a complementary combination of experimental approaches.

Brainstem neurons projecting to the rostral ventral respiratory group (VRG) in the medulla oblongata of the rat revealed by co-application of NMDA and biocytin

Groups of neurons in the medulla and pons are essential for the rhythm generation, pattern formation and modulation of respiration. The rostral Ventral Respiratory Group (rVRG) is thought to be a crucial area for rhythm generation. Here we co-applied biocytin and NMDA in the rVRG to label retrogradely brainstem neurons reciprocally connected to a population of inspiratory neurons in the rat rVRG. The procedure excited rVRG neurons in multi-unit recordings and led to a Golgi-like labelling of distant cells presumably excited by efferents from the rVRG. Injection of biocytin without NMDA did not label neurons in distant structures. Several brainstem ipsi- and contralateral structures were found to project to the rVRG, but three major respiratory-related structures, the nucleus of the solitary tract (NTS), the parabrachialis medialis and Kölliker-Fuse nuclei (PB/KF) and the caudal VRG, which are known to project bilaterally to the rVRG, were exclusively labelled ipsilaterally, suggesting an ipsilateral excitation of these structures by the rVRG. The pathways of efferent axons from labelled neurons in the rVRG were traced rostrally towards the pons and caudally to the spinal cord. Terminal axonal arborizations were seen in the same regions where retrogradely filled neurons were found as well as in a few other motor nuclei (the dorsal vagal motor nucleus and XII nucleus). Moreover, in the NTS and the PB/KF, efferent terminal varicosities were seen closely apposed to the soma and proximal dendrites of labelled neurons, suggesting monosynaptic connections between the rVRG and these nuclei.

Depressant effects on inspiratory and expiratory activity produced by chemical activation of Bötzinger complex neurons in the rabbit

The respiratory role of the Bötzinger complex (Böt. c.) was investigated in alpha-chloralose-urethane or pentobarbitone anesthetized rabbits by means of microinjections of DL-homocysteic acid (DLH). The animals were either spontaneously breathing or vagotomized, paralysed and artificially ventilated. Both phrenic and abdominal activities were monitored; extracellular recordings from medullary respiration-related neurons were performed. Unilateral microinjections (5-30 nl) of DLH (160 mM) into the Böt. c., at sites where intense expiratory activity with an augmenting discharge pattern was encountered, provoked mild or moderate depressant effects on inspiratory activity characterized by decreases in frequency as well as in peak amplitude and rate of rise of phrenic nerve discharge. Stronger depressant effects up to complete apnea were consistently obtained in response to bilateral microinjections. Concomitant depressant effects on the activity of both expiratory motoneurons and expiration-related (ER) neurons of the caudal ventral respiratory group (cVRG) were observed. At variance with previous findings in the cat, the results indicate that chemical activation of Böt. c. augmenting ER neurons may exert inhibitory influences not only on inspiratory activity, but also on cVRG ER neurons and, hence, on expiratory motoneurons. The functional role of the Böt. c. in the control of respiration deserves further investigations; present findings suggest that the rabbit may profitably be used for such a purpose.

Synchronicity of nociceptive and non-nociceptive adjacent neurons in the spinal dorsal horn of the rat: stimulus-induced plasticity

Current knowledge of spinal processing of sensory information is largely based on single-cell recordings; however, temporal correlation of multiple cell discharges may play an important role in sensory encoding, and single electrode recordings of several neurons may provide insights into the functions of a neuronal network. The technique was applied to the lumbar spinal dorsal horn of pentobarbital-anaesthetized rats during background activity, steady-state noxious heat stimulation (48 degrees C, 100 s), cold block spinalization or radiant heat-induced inflammation of the skin, and the recordings were evaluated by means of auto-correlation, autospectral and cross-correlation analysis. Background patterns obtained by these three methods were extremely stable in time. Autocorrelation with short lag peaks was observed in 72.2% of neurons (n = 223). Background correlated discharges were found in 83.6% of the neuron pairs (n = 134). Cross-correlation with a central peak, suggestive of common input to the recorded cells, was the most common pattern observed in almost all laminae and was associated with high incidence (91.8%) of overlapping receptive fields and with neurons with initial peak autocorrelation pattern. Cross-correlations with central trough were associated with increase autocorrelation patterns. Bilateral peaks in cross-correlation, suggestive of reverberating circuitry, were observed only for pairs of neurons located in laminae IV and V and were associated with rhythmic discharges in one or in both simultaneously-recorded neurons. Lagged peaks or troughs were observed in 4.6% and 2.2% of neuronal pairs, respectively. Long-lasting skin heating induced qualitative changes (pattern changes) in the cross-correlation of 21.6% of the neuron pairs and quantitative changes in 85.7% of them. During skin inflammation qualitative changes in the cross-correlation pattern were observed in 30.8% of the neuron pairs, and quantitative changes (strength and/or synchronization time) in about 57.7% of them. Spinalization induced quantitative changes in cross-correlation in the vast majority of neuron pairs. The results of the present study suggest that discharges of neighbouring spinal dorsal horn neurons are strongly synchronized probably by propriospinal and primary afferent sources. The existence of functional reverberating circuitry was also evidenced. Finally, the functional synchronicity in the spinal dorsal horn presents stimulus-induced plasticity which consists mainly of changes on the strength and/or time of the synchronization and rarely of activation of new connectivities.

Functionally intact in vitro preparation generating respiratory activity in neonatal and mature mammals

The present report describes a novel rhythmically active brainstem slice preparation that generates respiratory activity spontaneously in both mice and rats of varying maturational states. The brainstems of neonatal (0-4 days) and mature (3-8 weeks) mice and rats were isolated and a 600- to 750-microns thick slice cut to include the dorsomedial and the ventrolateral regions of the complete rostro-caudal extent of the medulla. This plane of section we have termed "tilted-sagittal". Rhythmically discharging neurones were recorded extracellularly from both the dorsal and ventral regions of the slice. The recording sites of these neurones were found in the hypoglossal motonucleus (XII) and in areas of the ventrolateral medulla that includes the ventral respiratory group (VRG) region. Histological examination revealed the preservation of neuronal structures important for cardiorespiratory regulation and reflex control including the nucleus of the solitary tract as well as the nucleus ambiguus. In addition, pontine structures including the A5 region were also preserved. Rhythmic activity was found only in slices where the ambiguual column was preserved in its entirety. The mean frequency of discharge of XII neurones was 20 and 10 bursts per minute in neonates and mature rodents respectively. In preparations of mature animals we demonstrate that this frequency increased significantly (P < 0.05) by either raising temperature from 29 degrees C to 38 degrees C (54%), elevating extracellular potassium concentration from 4 to 7.5 mM (52%), blocking potassium channels (20%) or decreasing pH from 7.4 to 7.0 (18%). The burst duration to frequency ratio of XII and VRG rhythmic neurones was similar and therefore indicative of a common brainstem oscillator. Consistent with this finding was that rhythmic activity in the VRG persisted despite removal of the dorsomedial region of the slice. In contrast, rhythmic XII neurones became tonic following mechanical disconnection of the VRG.

Morphological study of long axonal projections of ventral medullary inspiratory neurons in the rat

The aim of this study was to examine medullary and spinal axonal projections of inspiratory bulbospinal neurons of the rostral ventral respiratory group (VRG) in the rat. A direct visualization of long (9.8-33 mm) axonal branches, including those projecting to the contralateral side of the medulla oblongata and the spinal cord, was possible due to intracellular labeling with neurobiotin and long survival times (up to 22 h) after injections. Seven of the nine labeled neurons had bilateral descending axons, which were located in discrete regions of the spinal white matter; ipsilateral axons in the lateral and dorsolateral funiculus, contralateral in the ventral and ventromedial funiculus. The collaterals issued by these axons at the mid-cervical level formed close appositions with dendrites of phrenic motoneurons, which had also been labeled with neurobiotin. None of these collaterals crossed the midline. The significance of this finding is discussed in relation to the crossed-phrenic phenomenon. Additional spinal collaterals were identified in the C1 and T1 segments. Within the medulla, collaterals with multiple varicosities were identified in the lateral tegmental field and in the dorsomedial medulla (in the hypoglossal nucleus and in the nucleus of the solitary tract). These results demonstrate that inspiratory VRG neurons in the rat have some features which have not been previously described in the cat, including frequent bilateral spinal projection and projection to the nucleus of the solitary tract. In addition, this study shows that intracellular labeling with neurobiotin offers an effective way of tracing long axonal projections, supplementing results previously obtainable only with antidromic mapping, and providing morphological details which could not be observed in previous studies using labeling with horseradish peroxidase.

Spontaneous synaptic activities in rat nucleus tractus solitarius neurons in vitro: evidence for re-excitatory processing

The pattern of synaptic interactions between neurons of the nucleus tractus solitarius (NTS) has been analyzed using whole cell recording in rat brainstem slices. Following tractus solitarius (TS) stimulation 15/55 neurons presented a prolonged (up to 300 ms) increased excitability (PIE neurons) and 40/55 neurons presented a prolonged (up to 200 ms) reduced excitability (PRE neurons). In the absence of afferent sensory input all neurons showed spontaneous synaptic activity. Ongoing synaptic activity in PIE cells was glutamatergic and characterized by the absence of detectable inhibitory potentials while in PRE cells it was 90% GABAergic and 10% glutamatergic. Glutamatergic synaptic currents in PIE cells and GABAergic synaptic currents in PRE were studied using probability density and intensity functions. Distribution of time intervals between synaptic events indicated the latter were generated, in both PIE and PRE cells, by two simultaneous processes: (1) a close to Poisson process generating independent events; and (2) a subsidiary re-excitatory process generating synaptic events separated by intervals shorter than 20 ms. Blockade of glutamatergic transmission by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 10 microM) or blockade of action potentials by tetrodotoxin (TTX; 1 microM) suppressed the subsidiary process. In conclusion, we propose that PIE cells (1) form a re-excitatory network contributing to generation of excitatory activity in the NTS and (2) are located presynaptically with respect to PRE cells.

Correlation analysis of respiratory neuron activity in ventrolateral medulla of brainstem-spinal cord preparation isolated from newborn rat

Cross-correlation analysis was used to study functional connections between one inspiratory (I) neuron and another, and between one pre-inspiratory (Pre-I) neuron and another, in 54 brainstem-spinal cord preparations isolated from newborn rats. Pre-I neurons usually fired in the pre- and post-inspiratory phases. Neurons were recorded extracellularly with pairs of microelectrodes placed on the same or opposite sides of the brainstem. Fourteen pairs of Pre-I neurons recorded bilaterally in the rostral ventrolateral medulla (RVL), 14 pairs of ipsilateral Pre-I neurons in the RVL, 14 pairs of bilateral I neurons in the RVL and 12 pairs of ipsilateral I neurons in the ventrolateral medulla were studied. Cross-correlation histograms (CCHs) were computed. Significantly high peak bin counts were detected in 24 of 54 pairs. Peaks on one side of the origin of the CCHs were observed for one pair of ipsilateral Pre-I neurons, four pairs of bilateral I neurons and five pairs of ipsilateral I neurons. These findings suggest mono- or oligo-synaptic excitatory connections between paired neurons or shared inputs. Only one trough suggesting an oligo-synaptic inhibitory connection was evident in a CCH obtained from the pair of bilateral I neurons. This CCH revealed the peak and the trough on opposite sides of the origin, which was consistent with reciprocal excitatory and inhibitory connections between recorded neurons. Peaks on both sides of the origin were observed for three pairs of bilateral I neurons. From auto-correlation analysis and the latencies of these peaks, two of the three CCHs were consistent with reciprocal excitatory connections between recorded neurons, whereas the other CCH suggests shared inputs. Peaks at the origin were observed for two pairs of ipsilateral Pre-I neurons, four pairs of bilateral I neurons and five pairs of ipsilateral I neurons. These results suggest shared inputs. For Pre-I neurons recorded in opposite sides, no significant bin counts were detected. Peaks on one side were detected for three pairs. Present results suggest short-term synchronisation of I neurons, and of Pre-I neurons via excitatory coupling, and the likelihood of comparatively strong interaction between I neurons, which may be important in maintaining the I burst.

Possible mutual excitatory couplings between inspiratory neurons in caudal ventrolateral medulla of brainstem-spinal cord preparation isolated from newborn rat

In in vitro brainstem-spinal cord preparations, projection of inspiratory neurons in the caudal ventrolateral medulla (CVL) was examined electrophysiologically, and connectivity between bilateral inspiratory neurons in the CVL was analyzed by pulse-cross correlation (PCC) analysis. CVL inspiratory neurons were found to project to the contralateral CVL and/or mainly ipsilateral spinal cord. PCC analysis revealed significant peaks with different latency on both sides of time zero in 3 of 8 pairs. Results were consistent with mono- or oligo-synaptic excitatory connections between bilateral inspiratory neurons in the CVL.

Inhibition of caudal medullary expiratory neurones by retrofacial inspiratory neurones in the cat

1. Comparisons between the spike discharge of inspiratory neurons within the retrofacial area (RFN), and the membrane potential of expiratory neurones within the caudal medulla were made in pentobarbitone-anaesthetized, vagotomized, artificially ventilated cats. Spike-triggered averaging (STA) of synaptic potentials, triggered by the discharge of inspiratory RFN neurones, was utilized to test for synaptic connectivity. 2. Eighty-nine neurons with respiratory-phased discharge patterns were recorded in the vicinity of the RFN. Fifty-four neurones discharged at or slightly before the onset of the inspiratory burst activity of the phrenic nerve and continued firing throughout inspiration. Two continued to fire during post-inspiration. Forty-five of fifty-four inspiratory RFN neurones exhibited incrementing discharge patterns, six discharged with a plateau pattern, while only three neurones had a decrementing discharge pattern. 3. The membrane potential trajectories of caudal expiratory neurones revealed a typical wave of early inspiratory hyperpolarization. Occasionally, a second wave of hyperpolarization occurred during late inspiration, in conjunction with increased phrenic nerve activity. 4. Spike-triggered averaging revealed averaged inhibitory postsynaptic potentials (IPSPs), indicative of inhibitory synaptic connections, between eight and sixty-three pairs of RFN inspiratory and caudal expiratory neurones. 5. Inhibitory postsynaptic potentials detected by STA exhibited a relatively long latency and a slow time course. The IPSPs began, on average, 3.8 ms after an RFN action potential. The rise times, half-widths and durations of IPSPs were longer than expected for a monosynaptic somal input from myelinated axons of inspiratory RFN neurones. It is suggested that an inhibitory relay neurone in the immediate vicinity of the expiratory neurones is activated by a collateral of the RFN inspiratory neurone. 6. Retrofacial inspiratory neurones were antidromically activated only when high-intensity electrical stimulation was applied in the vicinity of caudal expiratory neurones. 7. The averaged IPSPs were preceded by diphasic and triphasic 'spike potentials'. The averaged spike potentials were highly entrained to the action potentials of RFN inspiratory neurones which triggered IPSPs. The spike potentials may be terminal potentials recorded from axons of RFN inspiratory neurones. 8. Evidence for convergence of synaptic inputs was obtained from STA tests in a caudal expiratory neurone receiving IPSPs from four RFN neurones. 9. The functional significance of this observation is discussed. We conclude that RFN inspiratory neurones exert a moderate inhibitory influence and act conjointly with other types of medullary inspiratory neurones.

Expiration-related neurons in the caudal ventral respiratory group of the cat: influences of the activation of Bötzinger complex neurons

The functional role of Bötzinger complex (Böt. c.) projections to the expiration-related (ER) area of the caudal ventral respiratory group (cVRG) was investigated in anesthetized, vagotomized, paralyzed and artificially ventilated cats. ER neurons in both the ipsi- and the contralateral cVRG displayed excitatory responses to Böt. c. electrical microstimulation. They were also activated by microinjections of D,L-homocysteic acid into the Böt. c. region. We propose that at least part of the Böt. c. projections to the cVRG have an excitatory function.

Extensive monosynaptic inhibition of ventral respiratory group neurons by augmenting neurons in the Bötzinger complex in the cat

Axonal projections and synaptic connectivity of expiratory Bötzinger neurons with an augmenting firing pattern (Bot-Aug neurons) to neurons in the ipsilateral ventral respiratory group (VRG) were studied in anaesthetized cats. Antidromic mapping revealed extensive axonal arborizations of Bot-Aug neurons (24 of 45) to the rostral or caudal VRG, with some having arbors in both regions. Of 234 pairs of neurons studied with intracellular recording and spike-triggered averaging, monosynaptic inhibitory postsynaptic potentials (IPSPs) were evoked in 49/221 VRG neurons by 38/98 Bot-Aug neurons. The highest incidence of monosynaptic inhibition was found in inspiratory bulbospinal neurons (10 of 23 tested). Evidence was also found for monosynaptic inhibition, by a separate group of Bot-Aug neurons, of expiratory bulbospinal neurons (12/58), while excitatory postsynaptic potentials (EPSPs) were identified in another two of these neurons. In addition, monosynaptic IPSPs were recorded from 13 of 53 identified laryngeal motoneurons, and from 14 of 100 respiratory propriobulbar neurons. Presumptive disynaptic IPSPs were recorded from 11 of the 221 VRG neurons. We conclude that Bot-Aug neurons exert widespread inhibition on all major neuron categories in the ipsilateral VRG, and should be regarded as an important element in shaping the spatiotemporal output pattern of both respiratory motoneurons and premotor neurons.

Inhibition in synchronously firing human hippocampal neurons

In order to study the extent of inhibition in human epileptic hippocampus, we recorded extracellular unit activities of human hippocampal neurons and their responses to single pulse stimulation in temporal lobe epilepsy patients during interictal periods. The criteria for diagnosing the hippocampus as epileptic were: (1) all seizures originated in that one hippocampus, (2) surgical removal of that hippocampus resulted in seizure relief, and (3) the surgically excised hippocampus was sclerotic. Analysis of firing pattern by cross-correlation showed that synchronized firing between neurons occurred only in the epileptic hippocampus. However, synchronized firing was not limited to only bursting neurons, as previously reported in some animal models of epilepsy, but was also observed among non-bursting neurons in the epileptic hippocampus. Furthermore, no significant difference in distribution of burst-discharge neurons was found between epileptic and non-epileptic hippocampi. In response to single pulse stimulation, neurons in both 'normal' (contralateral hippocampus) and epileptic hippocampus showed a rapid increase of firing (excitation), cessation of firing (inhibition), or a sequence of both (initial excitation followed by inhibition). However, a significant difference was found in the duration of the inhibition between synchronously firing neurons and non-synchronously firing neurons: the inhibition evoked by a single stimulation in synchronously firing epileptic neurons was significantly longer (373.8 msec +/- 35.9 S.E.M., P less than 0.005) than that of non-synchronously firing neurons (83.9 msec +/- 8.9 S.E.M.). Moreover, prolonged inhibition in synchronously firing epileptic neurons could occur with little or no prior excitation, suggesting that this inhibition does not necessarily depend on an intrinsic Ca2+-dependent K+-mediated after-burst hyperpolarization but is rather likely to be synaptic. As this inhibition was longer when epileptic neurons fired in synchrony, it could be interpreted that principal neurons recruited more recurrent inhibitory circuits by firing synchronously. By taking into account the previously reported neurophysiological evidence in human in vitro epileptic tissue showing GABA-mediated inhibition and the neuroanatomical evidence in excised human epileptic hippocampus showing GAD-positive neurons and synapses, our data suggest that, in human chronic epileptic hippocampus, recurrent inhibition remains functional, and alterations in GABA-mediated inhibition may not represent the critical change responsible for seizure generation.

Brainstem projections to the major respiratory neuron populations in the medulla of the cat

Efferent and afferent connections of the dorsal and ventral respiratory groups in the medulla of the cat were mapped by axonal transport of wheat germ agglutinin conjugated to horseradish peroxidase. Injections of wheat germ agglutinin-horseradish peroxidase into the dorsal respiratory group and the three principal subdivisions of the ventral respiratory group (caudal, rostral, and Bötzinger Complex) revealed extensive interconnections between these regions and with a limited number of other brainstem neuron populations. Major neuron populations with efferent projections to the regions of the dorsal and ventral respiratory groups include the parabrachial nuclear complex (medial parabrachial, lateral parabrachial, and Kölliker-Fuse nuclei), subregions of the lateral paragigantocellular reticular nucleus, subregions of the lateral and magnocellular tegmental fields, inferior central and postpyramidal nuclei of the raphe, and sensory trigeminal nuclei. A previously unidentified neuron population with extensive efferent projections to the dorsal and ventral respiratory groups was found near the ventral surface of the rostral medulla; we refer to this group as the retrotrapezoid nucleus. The results suggest that the dorsal and ventral respiratory groups form an extensively interconnected neuronal system receiving convergent inputs from the same brainstem nuclear groups, consistent with the hypothesis that the dorsal and ventral groups are primarily sites for integration of sensory and premotor respiratory drive inputs. Neuron populations in the rostral ventrolateral medulla with projections to both the dorsal and ventral respiratory groups, particularly the retrotrapezoid nucleus and neighboring subregions of the lateral paragigantocellular reticular nucleus, are candidate sites for participation in respiratory rhythmogenesis or other critical functions of the brainstem respiratory control system such as intracranial chemoreception.

Effects of electrical and chemical stimulation of the Bötzinger complex on respiratory activity in the cat

The effects of electrical and chemical stimulation of the expiratory neuronal population in the region of the retrofacial nucleus, the so called 'Bötzinger complex' (Böt. c.), on respiratory activity were investigated in vagotomized cats under pentobarbitone anaesthesia. Some of the experiments were performed on paralyzed or bilaterally thoracotomized, artificially ventilated animals. Sustained tetanic electrical stimulation (20 to 100-Hz, 0.5-ms current pulses at intensities of 5-60 microA) induced strong depressant effects on the inspiratory motor output which could lead to complete apnoea. The apnoeic response was accompanied by tonic activation of expiratory muscles; the appearance and the strength of tonic expiratory activity were dependent upon the frequency of stimulation. Brief tetani (40 to 100 ms trains of 0.5-ms rectangular pulses at 100-300 Hz) timed either during the inspiratory or the expiratory phase caused depression of inspiratory activity and prolongation of expiratory time, respectively. These effects increased gradually as the onset of stimulation was progressively delayed during each respiratory phase. The effects of sustained tetanic stimulation were mimicked by microinjections (25-100 nl) of 0.5 M L-glutamate or 0.16 M DL-homocysteic acid in the same region, thus indicating that they were the result of the stimulation of cell bodies and not of axons of passage. The present results support the hypothesis that Böt. c. neurons play an important role in the control of the breathing pattern by exerting inhibitory influences on inspiratory activity and, possibly, by contributing to the off-switch mechanisms. Furthermore, they suggest that these neurons are involved in the central control of expiratory activity.

The differential organization of medullary post-inspiratory activities

Membrane potential trajectories of 68 bulbar respiratory neurones from the peri-solitary and peri-ambigual areas of the brain-stem were recorded in anaesthetized cats to explore the synaptic influences of post-inspiratory neurones upon the medullary inspiratory network. A declining wave of inhibitory postsynaptic potentials resembling the discharge of post-inspiratory neurones was seen in both bulbospinal and non-bulbospinal inspiratory neurones, including alpha- and beta-inspiratory, early-inspiratory, late-inspiratory and ramp-inspiratory neurones. Activation of laryngeal and high-threshold pulmonary receptor afferents excited bulbar post-inspiratory neurones, whilst in the case of inspiratory neurones such stimulation produced enhanced postsynaptic inhibition during the same period of the cycle. Activation of post-inspiratory neurones and enhanced post-inspiratory inhibition of inspiratory bulbospinal neurones was accompanied by suppression of the after-discharge of phrenic motoneurones. These results suggest that a population of post-inspiratory neurones exerts a widespread inhibitory function at the lower brain-stem level. Implications of such an inhibitory function for the organization of the respiratory network are discussed in relation to the generation of the respiratory rhythm.

Diversity in periodic pattern of firing in human hippocampal neurons

Firing periodicity was examined in human hippocampal neurons using autocorrelation analysis. Extracellular single-unit activities were recorded from the anterior hippocampus through fine platinum microelectrodes, and the typical firing pattern in an entire recording period was reconstructed statistically in autocorrelograms (average number of firings analyzed: 5639.0 +/- 968.1 SE, range: 1158 to 31,203; number of single-unit trains was 57). Three types of periodic firing were identified as highly consistent. The first pattern consisted of a random recurrence of high-frequency action potentials (100 to 300 Hz) and was observed as an intermittent burst. In this burst, the first 10 to 30 ms after the onset of the burst was the patterned firing of several action potentials, suggesting that the generation of this stereotyped portion of the burst is primarily due to intrinsic membrane characteristics. The second pattern was the continuous rhythmical firing with a lower frequency ranging from 1 to 30 Hz. The third pattern was a clustered rhythmical firing in which a series of short rhythmical firings recurred with regular intervals; the frequency of short rhythmical firing varied from 6.7 to 17 Hz between neurons, and the interval of the regular recurrence of these rhythmical firings ranged from 0.5 to 10 s among neurons. These firing periodicities not only cover a cellular rhythm in the theta frequency reported in the lower mammalian hippocampus but also appear to be more diverse than those previously reported for hippocampal neurons in the animal literature.

Axonal projections to the ventrolateral nucleus of the solitary tract revealed by double labelling of retrograde fluorescent markers in the cat

The retrofacial nucleus project bilaterally to the ventrolateral nucleus of the tractus solitarius (vlNTS) as revealed by means of retrograde transport of the fluorescent markers, Fast blue (FB) and Diamidino yellow (DY), in the cat. Some of the neurons of the retrofacial nucleus send axonal ramifications to both vlNTS. Extensive projections from other brainstem respiratory related nuclei to the vlNTS were also observed: bilaterally from the nucleus ambiguus, nucleus retroambiguus and nucleus parabrachialis medialis, and ipsilaterally from the Kölliker-Fuse nucleus. Axonal projections from the contralateral vlNTS were also observed.

Differential effects of halothane anesthesia on the pattern of discharge of inspiratory and expiratory neurons in the region of the retrofacial nucleus

The influence of halothane anesthesia on respiratory neurons of the region of the retrofacial nucleus were studied in decerebrate, bivagotomized, paralyzed and artificially ventilated cats. Compared with the control situation without anesthesia, the infusion of halothane induced an important decline of spike activity of inspiratory neurons, at times abolishing their activity, but had no significant effect on the expiratory neurons. The functional significance of these findings is briefly discussed.

Structurally stable burst and synchronized firing in human amygdala neurons: auto- and cross-correlation analyses in temporal lobe epilepsy

Burst structure and synchronized firing of bursts were studied, in the interictal period, using auto- and cross-correlation analyses in human amygdala neurons in temporal lobe epilepsy patients diagnosed as having a unilateral limbic seizure focus in anterior hippocampus and/or amygdala. Satisfactory single unit recordings were obtained from chronically implanted microelectrodes in 51 amygdala neurons, and auto-correlation analysis identified 27 of 51 neurons where burst firings recurred with regular interspike interval structures (structurally stable burst: S-burst). This structural stability was characteristic only for a short burst, or at the beginning of a series of repetitive firings, involving 2-5 action potentials. In 'non-epileptic' amygdala neurons located contralateral to the seizure focus, the average duration of S-burst was 15 msec and the number of action potentials (spikes) in the S-burst was inversely related to the interspike intervals in the S-burst, suggesting that endogenous membrane characteristics of non-epileptic amygdala neurons determine the patterns of S-burst. In contrast, in the seizure focus amygdala ('epileptic'), the duration of the S-burst was prolonged among epileptic neurons, not because of the occurrence of more action potentials within the S-burst, but because of a prolonged interspike interval within the S-burst. Furthermore, there was no relationship between the interspike interval and the number of action potentials in the S-burst, suggesting that synaptic inputs and/or extracellular environmental factors may affect an intrinsic mechanism for generating stable S-burst in epileptic neurons. Cross-correlation analysis identified synchronized firings in epileptic neurons: when two epileptic neurons both exhibited S-bursts, when either epileptic neuron exhibited S-burst, but never when neither exhibited S-bursts. Conversely, non-epileptic neurons rarely fired synchronously; even though they showed S-bursts. The difference in the pattern of S-bursts between epileptic and non-epileptic amygdala neurons seems to be the degree of firing synchrony. Our results provide, for the first time, direct evidence that human epileptogenic amygdala neurons recorded in vivo have unique burst firing patterns and significant synchronous excitatory interactions, different from a burst pattern found in non-epileptogenic amygdala neurons during the interictal period.

Respiratory resetting induced by activation of inspiratory bulbo-spinal neurons

The respiratory effects elicited by spinal (C2-C3) stimulation at the level of descending inspiratory axons were studied in paralysed, non-vagotomized and artificially ventilated cats anaesthetized with urethane-chloralose. The activation of inspiratory bulbospinal axons in the ventrolateral quadrant was confirmed by recording the ipsilateral phrenic excitation following a single pulse. Brief stimulus trains delivered at the same locus during expiration elicited short- and long-term phrenic activations. The short-term activation consisted of a tetanic orthodromic response. The long-term activation, of central origin, exhibited the same pattern as a spontaneous inspiration and consisted of an inspiratory resetting which necessitated weak anaesthesia and light hypocapnia. Control experiments (restricted lesions of the medulla and the cervical cord, recording of afferent activity in thalamic sensory nuclei, medullary stimulation) revealed that this inspiratory resetting could not be related to appreciable activation of either non-respiratory efferents or spinal afferent pathways studied but was likely to depend on the activation of the descending inspiratory axons. We conclude that the respiratory resetting obtained by spinal stimulation resulted from mass antidromic activation of the inspiratory bulbospinal neurons which thus appear to be involved in the generation of the respiratory rhythm.

Discharge patterns of bulbar respiratory neurons in response to the morphinomimetic agent, fentanyl, in chloralosed dogs

In anaesthetized, paralysed and artificially ventilated dogs, activities were recorded from the phrenic nerve and from respiratory units within the nucleus tractus solitarii (nTS), the nucleus ambiguus (nA) and the nucleus retroambigualis (nRA). The respiratory neurons were classified according to their discharge pattern and their response to lung inflation. Fentanyl injected into the vertebral artery (0.5-2 micrograms/kg) or intravenously (10 micrograms/kg) produced a depressant effect on the phrenic nerve motoneurons, on inspiratory cells (I alpha and I beta) and on phase-spanning expiratory-inspiratory neurons of the nTS and the nA. The duration of the inspiratory burst increased and the number of spikes and the peak activity were reduced. This pattern of inhibition was followed by complete blockade of spike genesis. Fentanyl also altered expiratory neurons: the duration of the expiratory discharge was enhanced. An increase followed by a decrease in the number of spikes per burst and a reduction in the peak activity were observed. When the phrenic nerve was silent, continuous discharges appeared. High doses of fentanyl were needed to inhibit these tonic discharges. This pattern of inhibition concerns late peak expiratory units, expiratory units with a constant discharge pattern and the phase-spanning inspiratory-expiratory neurons. Naloxone antagonized these effects but induced the appearance of tonic discharges in fentanyl-treated phase-spanning expiratory-inspiratory neurons. Stimulation of peripheral chemoreceptors with almitrine (0.2 mg/kg i.v.) antagonized the effects of fentanyl. In addition, fentanyl facilitated the lung inflation reflex on respiratory neurons.(ABSTRACT TRUNCATED AT 250 WORDS)

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

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