ber das Verhalten der Atmung und des arteriellen Drucks bei Einbringen von Veratridin, Lobelin und Cyanid in den Liquor cerebrospinalis

Sensing arterial CO(2) levels: a role for medullary P2X receptors

ATP has been shown to act as an excitatory neurotransmitter in the central nervous system. In this review, evidence is presented to indicate that when ATP is micro-injected into the ventrolateral medulla (VLM) of the rat, changes in respiratory activity are elicited. These effects, and accompanying changes in heart rate and blood pressure are mediated by P2X purinoreceptors. Immunocytochemistry indicates a prevalence of P2X(2) and P2X(6) purinoreceptors in this region of the medulla. The P2 purinoceptor antagonists, suramin and PPADS blunt the respiratory responses to changes in arterial CO(2) levels when micro-injected into the VLM. This effect is shown electrophysiologically to be mediated by purinoreceptors located primarily on respiratory neurones of the VLM including the Bötzinger complex. As the effects of agonist activation of P2X(2) purinoceptors expressed in HEK293 cells and Xenopus oocytes are potentiated by lowering pH, these data imply that the central respiratory response to CO(2) depends in part on the pH sensitivity of purinoreceptors located on inspiratory neurones. The implications for respiratory activity and control are discussed.

Pre-Bötzinger complex functions as a central hypoxia chemosensor for respiration in vivo

Recently, we identified a region located in the pre-Bötzinger complex (pre-BötC; the proposed locus of respiratory rhythm generation) in which activation of ionotropic excitatory amino acid receptors using DL-homocysteic acid (DLH) elicits a variety of excitatory responses in the phrenic neurogram, ranging from tonic firing to a rapid series of high-amplitude, rapid rate of rise, short-duration inspiratory bursts that are indistinguishable from gasps produced by severe systemic hypoxia. Therefore we hypothesized that this unique region is chemosensitive to hypoxia. To test this hypothesis, we examined the response to unilateral microinjection of sodium cyanide (NaCN) into the pre-BötC in chloralose- or chloralose/urethan-anesthetized vagotomized, paralyzed, mechanically ventilated cats. In all experiments, sites in the pre-BötC were functionally identified using DLH (10 mM, 21 nl) as we have previously described. All sites were histologically confirmed to be in the pre-BötC after completion of the experiment. Unilateral microinjection of NaCN (1 mM, 21 nl) into the pre-BötC produced excitation of phrenic nerve discharge in 49 of the 81 sites examined. This augmentation of inspiratory output exhibited one of the following changes in cycle timing and/or pattern: 1) a series of high-amplitude, short-duration bursts in the phrenic neurogram (a discharge similar to a gasp), 2) a tonic excitation of phrenic neurogram output, 3) augmented bursts in the phrenic neurogram (i.e., eupneic breath ending with a gasplike burst), or 4) an increase in frequency of phrenic bursts accompanied by small increases or decreases in the amplitude of integrated phrenic nerve discharge. Our findings identify a locus in the brain stem in which focal hypoxia augments respiratory output. We propose that the respiratory rhythm generator in the pre-BötC has intrinsic hypoxic chemosensitivity that may play a role in hypoxia-induced gasping.

Cardiorespiratory changes induced by vertebral artery injection of sodium cyanide in cats

Brain stem hypoxia caused by vertebral artery injection of sodium cyanide (NaCN) (1-20 micrograms) in artificially ventilated cats depressed phrenic and stimulated sympathetic nerve activity with a simultaneous increase in arterial blood pressure. Larger doses of NaCN caused greater effects. Hypercapnia produced by inhalation of 7% CO2 in O2 tended to reduce NaCN-induced responses on phrenic activity but not on blood pressure or sympathetic activity. Infusion into the vertebral artery with hypoxic saline (3% CO2 in N2) altered blood pressure, also affecting phrenic and sympathetic nerves similarly to NaCN administration. However, washout of CO2 by infusion of 100% O2 bubbled saline at high flow rates (3.6 ml/min) depressed phrenic as well as sympathetic activity and blood pressure. Spinal transection at the first cervical level eliminated sympathetic excitatory response to intravertebral cyanide injection. However, a large dose of NaCN (600 micrograms) given intravenously in spinal animal excited sympathetic activity. We conclude that intravertebral injection of NaCN can be used to study the effects of local hypoxia of the brain stem on cardiorespiratory responses and that hypoxia acts at both these sites (brain stem and spinal cord) to stimulate sympathetic excitation.

Chemosensitivity of sympathoexcitatory neurones in the rostroventrolateral medulla of the cat

The hypothesis that sympathoexcitatory neurones within the rostroventrolateral medulla (RVLM) may be chemosensitive was tested in chloralose-anaesthetized cats by artificial perfusion of the RVLM via the left vertebral artery. The baroreceptors and peripheral chemoreceptors were denervated by bilaterally dissecting the carotid sinus and vagus nerves. Either white ramus T3 (WR-T3) or the renal nerve was recorded to monitor sympathetic activity. Perfusion with saline or Ringer solution bubbled with CO2 (10%-100%) produced a rapid and pronounced increase in sympathetic activity and blood pressure. Solutions adjusted to the same pH (pH 5.2 for 100% CO2) with HCl resulted in a much weaker excitation. A linear relationship between PCO2 and sympathetic activity was demonstrated. During prolonged perfusion (90 s) sympathetic activity returned to the control level after initial excitation and fell below control levels when perfusion ceased. The sympathetic activity response to CO2-bubbled solutions was unaffected by blockade of synaptic input by microinjection of CoCl2 into the RVLM, whereas spontaneous sympathetic activity and the supraspinal somato-sympathetic reflex from intercostal nerve T4 to WR-T3 were markedly reduced. It is therefore concluded that sympathoexcitatory bulbospinal neurones in the RVLM are directly chemosensitive to changes in arterial PCO2 and pH.

Is central chemoreceptor sensitive to intracellular rather than extracellular pH?

The chemosensitive area on the ventral surface of the brain stem responds to local acidosis by eliciting hyperventilation and to local alkalosis by hypoventilation. The stimulus is conventionally thought to be the hydrogen ion concentration in the area's extracellular fluid. It is pointed out, however, that the elegant studies by Loeschcke & Ahmad have demonstrated that [pH]e and [pH]i are normally tightly and rapidly coupled (Loeschcke & Ahmad, 1980). For this reason, the stimulus might just as well be the intracellular hydrogen ion concentration in the chemoreceptor area. The administration of acetazolamide allows the dissociation of [pH]e from [pH]i. With acetazolamide a sharp acid shift of CSF pH [( pH]c) is measured and in two consonance with this shift a marked increase in CBF is seen. Comparing these two reactions to that obtained with CO2 breathing, it is apparent that 7% CO2 causes about the same decrease in [pH]e and the same increase in CBF. In other words CBF acidosis can quantitatively account for the CBF increase induced by acetazolamide. But CO2 and acetazolamide influence [pH]i quite differently, as CO2 drops [pH]i to almost the same extent as [pH]c, while two recent studies by MR spectroscopy have shown that acetazolamide does not drop [pH]i measurably, if tissue hypercapnia is prevented in artificially ventilated rabbits or by the mild spontaneous hyperventilation caused by acetazolamide in normal man.(ABSTRACT TRUNCATED AT 250 WORDS)

Topography of the respiratory and circulatory responses to acetylcholine and nicotine on the ventral surface of the medulla oblongata

1. Acetylcholine and nicotine were superfused on the ventral medullary surface between the ponto-medullary border and C1 in anaesthetized cats in order to determine the topical distribution of their actions on respiration and circulation. 2. Acetylcholine (10(-4) g . ml-1 = 5.5 . 10(-4) mMol . ml-1) produced an increase in respiration and a lowering of blood pressure. The magnitude and the time course of the responses varied according to the points of superfusion on the surface. 3. Nicotine (10(-4) g . ml-1 = 6.2 . 10(-4) mMol . ml-1) elicited hyperventilation and more often an increase in arterial pressure on unilateral superfusion of the surface. In some cases, however, a drop in blood pressure was also observed. 4. The responsive regions of the surface on which nicotine acted and elicited hyperventilation, bear a close resemblance to the regions responsive to acetylcholine. 5. The topographical distribution of the respiratory effects elicited by the above-mentioned drugs were similar to the distribution of the responses to changes in pH on the ventral medullary surface or to electrical stimulation. 6. Procaine (2 . 10(-2) g . ml-1 = 7.3 . 10(-2) mMol . ml-1) applied bilaterally in the intermediate zone (S) caused profound inhibition of respiration and of arterial pressure. Procaine at this concentration also inhibited respiratory hyperventilation caused by nicotine (10(-4) g . ml-1 = 6.2 . 10(-4) mMol . ml-1) applied to the caudal and rostral areas.

Elimination of central chemosensitivity by coagulation of a bilateral area on the ventral medullary surface in awake cats

Breathing and respiratory response to CO2 were observed in 6 awake cats and 1 control before and after bilateral coagulation of the formerly described area S (Schläfke and Loeschcke, 1967) on the ventral medullary surface under hyperoxic conditions. Ventilation decreased, PCO2 rose and CO2 response was almost or completely abolished in 4 cats, and moderately reduced in 2 cats. Inhalation of CO2 had an inhibitory effect on ventilation in two cases. In some instances the respiratory frequency was increased by CO2. Periodic breathing as well as spontaneous hyperventilation elicited by 'arousal' indicate parallels to the Pickwickian or Ondine's curse syndrome. No respiratory changes were produced by a lesion on the pyramidal tract medial to the area S. It is concluded that central chemosensitivity can be eliminated within the superficial layer of the area S. The loss of CO2 response seems to be correlated with complete destruction of the superficial nerve cells located within the area S (Petrovický, 1968) and degeneration within the ventral part of the nucleus paragigantocellularis.

Metabolic control of respiratory neuronal activity and the accompanying changes in breathing movements of the rabbit. 1. Mainpulation of inspiratory and expiratory-inspiratory neurons

The property of the neuronal membrane to be permeable to metabolic modifiers of two regulatory enzymes has been utilized to manipulate the spike activity of inspiratory (I) and expiratory-inspiratory (EI) neurons of the bulbar respiratory centre. The neurons have been classified according to their response to lung distention or collapse (alpha- or beta-type) and to hyperventilation (tonic firing denoted by "+", cessation of activity by "-"). Using extracellular microelectrodes for single unit recording, the medulla oblongata was superfused with a metabolite-containing CSF. The various neuronal sub-types exhibited a differential activating or inhibitory response to one or several metabolic effectors. For example Ialpha+ units were activated by 5 mM glucose-6-phosphatase (G-6-P) and 3.5 mM 3-phosphoglycerate (3-PGA), which both inhibited Ibeta+ neurons, while 5 mM AMP inhibited Ialpha+ much more strongly than Ibeta+ cells. The spike density of Ialpha- and Ibeta- neurons was increased in the presence of 2.5 mM fructose-6-phosphate and 3.5--5 mM AMP, but became reduced by G-6-P. In contrast, 3 mM fructose-1,6-diphosphate and 5 mM 3-PGA activated the Ialpha- but inhibited the Ibeta- neurons. The EIbeta units were characteristically activated by 10 mM citrate, which inhibited all I-type neurons. Activations of the Ialpha and Ibeta neurons led to an accelerated respiratory rate and a higher tidal volume, while the opposite was true for EIbeta neurons. Intravenous injection of metabolites could not duplicate the striking effects under local applications.

A vasodepressor effect of pentobarbitone sodium

1. In anaesthetized cats under artificial ventilation, a few milligrams of pentobarbitone sodium injected into the cerebral ventricles produced a pronounced fall in arterial blood pressure, which was central in origin and resulted from inhibition of vasomotor tone.2. Pentobarbitone sodium was more effective in lowering blood pressure when injected into the cerebral ventricles than when injected into the cisterna magna, yet the pentobarbitone sodium did not act on structures in the ventricular wall, but acted on structures reached from the subarachnoid space.3. To produce its vasodepressor effect, the pentobarbitone sodium had to pass through the foramina of Luschka into the subarachmoid space beneath the medulla oblongata and to penetrate its ventral surface in a region caudal to the trapezoid bodies and lateral to the pyramids. This was the outcome of experiments in which the pentobarbitone sodium was injected into or perfused through the cerebral ventricles with or without an outflow cannula inserted into the aqueduct or into the fourth ventricle, and of experiments in which pentobarbitone sodium solutions were applied by means of Perspex rings to this region of the exposed ventral surface of the medulla. Whereas the application of pentobarbitone sodium to this region on one side had a weak vasodepressor effect only, its application on both sides produced a pronounced fall in arterial blood pressure.4. The region where pentobarbitone acted on topical application covers the region where nerve cells are found in the marginal glia immediately under the pia mater. The possibility is discussed that these cells are the morphological substrate on which the pentobarbitone acts, that arterial blood pressure is maintained by their activity which is suppressed by the pentobarbitone sodium.

Respiratory responses to chemical pulses in the cerebrospinal fluid of cats

1. In cats anaesthetized with pentobarbitone, the fluid spaces in and around the brain stem were perfused from the third ventricle to the foramen magnum with artificial cerebrospinal fluid (c.s.f.) flowing usually at the rate of 5 ml/minute. Test solutions were substituted for the artificial c.s.f. without switching artifact for periods varying from 5 to 60 seconds. Observations were made on respiratory excursions, end-expiratory% CO(2) and arterial blood pressure.2. Perfusion with sucrose solution equiosmolar with the c.s.f. produced no respiratory or cardiovascular response. Replacement of sodium with potassium (60 to 133 mM) resulted in a prompt but mild respiratory stimulation and a delayed fall in blood pressure associated with a slowing of the heart beat. Replacement of sodium with magnesium (40 to 131 mM) resulted in a late prolonged apneustic depression of breathing and in an early but slight reduction in blood pressure.3. Procaine (1 to 50 mg/ml) elicited a respiratory response similar to that of excess magnesium; however, an initial rise in blood pressure to as high as 200 mmHg was evoked with procaine. Nicotine (0.05 to 0.5 mg/ml) produced an immediate brief bradypnea followed by a vigorous and slowly reversing hyperpnea accompanied most often by a fall in blood pressure. Tachyphylaxis was observed in the response to nicotine. Noradrenaline (0.001 and 0.1 mg/ml) did not produce any effect, and it did not alter the responses elicited by procaine and nicotine given by perfusion either simultaneous with or subsequent to the noradrenaline. Acetylcholine (0.5 mg/ml) produced weak transient respiratory stimulation and a small fluctuation in blood pressure which disappeared in repeated tests. Methacholine (1 mg/ml) caused a brief hyperpnea and a fall in blood pressure both of which were abolished after atropine (0.2 mg) was injected into the third ventricle. Pilocarpine (10 mg/ml) elicited no change in respiration or blood pressure. Respiratory and cardiovascular effects produced by strychnine (1 mg/ml) were attributable non-specifically to convulsive movements of the animal. Ethamivan (1 mg/ml) produced a single deep breath and a slowly reversing rise in blood pressure. Cyanide (0.5 mg/ml) barely stimulated the respiration but it produced a long lasting rise in blood pressure. Ethyl alcohol (0.1 ml/ml) elicited brisk though brief respiratory stimulation and a short lasting fall in blood pressure.4. It was shown that the effects of procaine and nicotine were not qualitatively altered when the perfusion effluent was collected through a ventral craniotomy instead of the cisterna magna.

Temperature responses and other effects of 5-hydroxytryptophan and 5-hydroxytryptamine when acting from the liquor space in unanaesthetized rabbits

1. In unanaesthetized rabbits 5-hydroxytryptophan (5-HTP) and 5-hydroxytryptamine (5-HT) were injected into the cisterna magna or into the cannulated left lateral cerebral ventricle while rectal temperature was recorded.2. 5-HTP injected intracisternally in a dose of 1.5-3 mg produced a fall in temperature often followed by a rise beyond the pre-injection level. With 6 mg the main effect was a rise in temperature. The intraventricular injection of 1-2 mg 5-HTP usually produced a fall followed by a rise.3. 5-HT injected intracisternally in a dose of 0.2 mg produced a fall in temperature similar to that produced with this dose injected intraventricularly. Following an intracisternal injection of 1-4 mg 5-HT there was either a fall, or a fall followed by a rise, but in a few experiments the effect consisted mainly of a rise in temperature.4. Additional effects regularly observed with these injections were tachypnoea, ear twitching, rapid movements of the vibrissae, shaking of the head, wiping and scratching movements, ataxia, nodding and sideways movements of the head and long-lasting catalepsy.5. The sites where 5-HTP and 5-HT act when producing the temperature responses and the various behavioural effects are discussed.