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1. Neurological analysis of respiratory, cardiovascular and neuromuscular effects of brevetoxin in cats.

Author

Borison HL, McCarthy LE, and Ellis S

Subjects
Animals, Cats, Electric Stimulation, Ganglia drug effects, Injections, Intraventricular, Muscle Contraction drug effects, Nictitating Membrane drug effects, Reflex drug effects, Sympathetic Nervous System drug effects, Synaptic Transmission drug effects, Vagotomy, Dinoflagellida, Hemodynamics drug effects, Marine Toxins pharmacology, Muscles drug effects, Neurons drug effects, Respiration drug effects
Abstract

Effects of brevetoxin were evaluated in cats anesthetized with pentobarbital under conditions of controlled end-expiratory pCO2 and constant body temperature. Recordings were made of arterial blood pressure, heart rate, respiratory pattern, diaphragm EMG, evoked tibialis muscle twitch and evoked contraction of the nictitating membrane. Electrical stimulation was employed for periodic excitation of the medullary respiratory center, the phrenic nerve, the peroneal nerve and the cervical sympathetic nerve. Brevetoxin was prepared at a concentration of 1.0 mg/ml in an aqueous medium of 2.5% ethanol plus 2.5% Emulphor 620 (General Aniline and Film Corp., New York). Small i.v. bolus injections of the toxin (40 micrograms/kg) evoked, without tachyphylaxis, the Bezold-Jarisch reflex triad of bradycardia, hypotension and bradypnea. This effect was essentially abolished by vagotomy. Continued injections then resulted in pressor reactions and tachycardia, along with the development of respiratory dysrhythmia. Large doses of brevetoxin (160 micrograms/kg i.v.) caused somatomotor seizures accompanied by severe hypertension, that occurred even after decerebration and cervical spinal cord transection. Cranial intra-arterial and intra-cerebroventricular injections of brevetoxin produced hypertension and respiratory depression more effectively than did i.v. injections. Systemic cumulation of the toxin, with the respiration supported artificially, caused death from cardiovascular collapse, without significant blockade of neuromuscular and ganglionic transmission. It is concluded that brevetoxin exerts its major toxic effects on the circulation and respiration through reflex and central actions, largely sparing peripheral motor mechanisms.

Published
1985
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2. Central respiratory and circulatory depression caused by intravascular saxitoxin.

Author

Borison HL, Culp WJ, Gonsalves SF, and McCarthy LE

Subjects
Animals, Cats, Depression, Chemical, Electric Stimulation, Electromyography, Female, Infusions, Intra-Arterial, Male, Medulla Oblongata physiology, Phrenic Nerve drug effects, Saxitoxin administration & dosage, Blood Circulation drug effects, Respiration drug effects, Saxitoxin pharmacology
Abstract

1 In cats anaesthetized with pentobarbitone and vagotomized, observations were made on the phrenic nerve action potential and the diaphragm electromyogram (EMG) at constant end-tidal Pco(2). Arterial blood pressure was stabilized by intravenous infusions of noradrenaline.2 Intravenous administration of saxitoxin (STX) initially abolished respiratory activity in the EMG and caused a slowing of oscillation in the central phrenic neurogram. Additional STX produced apneustic phrenic discharges followed by a progressive loss of nerve action potentials.3 The inspiratory centre in the medulla oblongata was stimulated electrically to evoke a sustained phrenic nerve discharge. STX, given intravenously, resulted in the elimination of spontaneous nerve activity without interfering with the evoked response.4 The cephalic intravascular infusion of STX into a carotid or vertebral artery depressed spontaneous respiratory activity while sparing EMG activity evoked by electrical stimulation of the intact phrenic nerve.5 Spontaneous respiratory discharge in the phrenic nerve was eliminated by smaller doses of STX administered intra-arterially than were required intravenously. In addition, onset of and recovery from neural silence occurred faster following intra-arterial injection of STX.6 Depressant effects on arterial blood pressure coincided with those on respiration when STX was given intra-arterially.7 An electrophysiological assay on frog sartorius muscle was used to measure STX in the cerebrospinal fluid. Levels of STX detected were proportional to amounts of the toxin infused intra-arterially.8 It is concluded that STX exchanges rapidly between blood and brain to bring about central depression and this adds to its peripheral paralytic actions.

Published
1980
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3. Arterial hydrogen ion versus CO2 on depth and rate of breathing in decerebrate cats.

Author

Borison HL, Hurst JH, McCarthy LE, and Rosenstein R

Subjects
Acidosis, Respiratory blood, Alkalosis, Respiratory blood, Animals, Carotid Sinus physiopathology, Cats, Denervation, Hypercapnia physiopathology, Plethysmography, Whole Body, Proprioception, Tidal Volume, Vagotomy, Vagus Nerve physiopathology, Carbon Dioxide blood, Decerebrate State blood, Hydrogen-Ion Concentration, Respiration
Abstract

Arterial blood hydrogen ion concentration (Ha+) was altered over the range of 25 to 110 nM (pH 7.60 to 6.96) by slow intravenous infusion of 1.0 N NaHCO3 or 0.5 N HC1 at controlled levels of Paco2in unanesthetized decerebrate cats. Respiratory f varied as a single function of Vt irrespective of a lterations in Paco2 and Ha+ even after interruption of the carotid sinus nerves. The dependence of f upon Vt was abolished by vagotomy. However, Vt continued to respond to changes in Ha+ over its entire range after combined section of the vagus and carotid sinus nerves. In all statxceeded by 5 to 10 times the delta Vt/delta Ha+ response to acid or bicarbonate infused under isocapnic control. Increases and decreases of ha+ caused downward and upward shifts, respectively, in the operating setpoint of the CO2 regulation system.

Published
1977
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4. Central respiratory and circulatory effects of Gymnodinium breve toxin in anaesthetized cats.

Author

Borison HL, Ellis S, and McCarthy LE

Subjects
Anesthesia, Animals, Cats, Chemoreceptor Cells physiology, Electric Stimulation, Medulla Oblongata physiology, Pressoreceptors physiology, Vagotomy, Dinoflagellida, Hemodynamics drug effects, Marine Toxins pharmacology, Respiration drug effects
Abstract

1 In cats anaesthetized with pentobarbitone, observations were made on respiration, spontaneous and evoked diaphragmatic electromyograms, blood pressure, heart rate, indirectly-induced contractions of the anterior tibialis muscle and nictitating membrane, and electrical excitability of the inspiratory centre in the medulla oblongata.2Gymnodinium breve toxin (GBTX) was administered intravenously, intra-arterially to the brain, and intracerebroventricularly. Physiological effects were recorded while alveolar P(CO) (2) was controlled at a constant level except when changes in gas tension were made in order to measure CO(2)-ventilatory responsiveness.3 Adequate doses of GBTX given intravenously by bolus injection elicited a non-tachyphylactic reflex response triad of apnoea, hypotension and bradycardia mediated by the vagus nerves independently of arterial baroreceptor and chemoreceptor innervation.4 After vagotomy, additional amounts of GBTX (i.v.) resulted in apneustic breathing, hypertension and tachycardia. The cardiovascular effects were abolished by ganglionic blockade with hexamethonium.5 Smaller doses of GBTX were required intra-arterially and intracerebroventricularly than by the intravenous route of injection to produce respiratory irregularity and cardiovascular hyperactivity.6 Evoked motor responses, electrical excitability of the medulla oblongata and CO(2)-ventilatory responsiveness were largely spared even though GBTX caused marked disturbances in respiratory rhythmicity and cardiovascular functions.7 It is concluded that GBTX acts reflexly on vagally innervated receptors to evoke a Bezold-Jarisch effect but that the toxin further acts centrally to cause irregular breathholding and hypertension with tachycardia, leading ultimately to respiratory and circulatory failure.

Published
1980
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5. Central vs. systemic neurotoxicity of hypoglycin (ackee toxin) and related substance in the cat.

Author

Borison HL, Pendleton J Jr, and McCarthy LE

Subjects
Acetates pharmacology, Animals, Butyrates pharmacology, Carbon Dioxide metabolism, Cats, Cerebral Ventricles, Chemoreceptor Cells physiology, Emetics pharmacology, Hydrogen-Ion Concentration, Injections, Injections, Intravenous, Leucine pharmacology, Medulla Oblongata physiology, Pyruvates pharmacology, Syncope chemically induced, Toxins, Biological administration & dosage, Toxins, Biological toxicity, Valerates pharmacology, Vomiting chemically induced, Blood Pressure drug effects, Plants, Respiration drug effects, Toxins, Biological pharmacology
Published
1974

7. Central respiratory inhibition by angiotensin II in anesthetized cats.

Author

Borison HL, Hubbard JI, and McCarthy LE

Subjects
Anesthesia, Animals, Azides pharmacology, Carotid Sinus physiology, Cats, Female, Heart Rate drug effects, Male, Renin-Angiotensin System, Sodium Azide, Vagotomy, Angiotensin II pharmacology, Respiration drug effects
Abstract

Observations were made on respiration, alveolar concentration of CO2, arterial blood pressure and heart rate in barbiturate-anesthetized cats subjected routinely to section of the vagus and carotid sinus nerves and maintained with pure O2 for inhalation. Bolus i.v. injection of angiotensin II (AII), 0.6 to 6.0 micrograms/kg, evoked a prompt shortlasting suppression of breathing, manifested mainly as a reduction in tidal volume susceptible to the development of tachyphylaxis if injections were spaced more closely than 30 min apart. Ablation of the area postrema failed to eliminate the respiratory effect of All. The response also persisted after midbrain transection, spinal cord transection at C8, dorsal rhizotomy of spinal segments C1 to C8 and interruption of cranial nerves V, VII, VIII, IX, X, XI and XII. No influence of All was evident on indirectly evoked tibialis muscle contractions and on pulmonary compliance. A reduction in phrenic nerve impulse traffic coincided with the respiratory response to All. Cranial i.a. injection of All initiated the respiratory effect in its first pass through the brain, before any change occurred in the blood pressure. The degree of All-induced respiratory inhibition was relatively constant at different magnitudes of breathing produced by CO2 inhalation or by electrical stimulation of the respiratory center in the medulla oblongata. It is concluded that All given by bolus intravascular injection causes respiratory inhibition through a direct central action at the final processing step in the CO2-tidal volume controller.

Published
1988

8. Slow respiratory stimulant effect of hyperoxia in chemodenervated decerebrate cats.

Author

Rosenstein R, McCarthy LE, and Borison HL

Subjects
Animals, Carbon Dioxide, Cats, Cerebral Ventricles physiology, Denervation, Tidal Volume, Vagus Nerve physiology, Carotid Sinus physiology, Decerebrate State, Oxygen, Respiration
Abstract

A direct stimulating action of oxygen on the CO2 respiratory control system was determined from steady-state and dynamic observations in unanesthetized decerebrate cats. In peripheral nerve-intact animals, inhalation of oxygen (1 atm) produced a small but significant shift to the left as well as a decrease in slope in the steady-state VT vs. log PACO2 relationship. Carotid sinus neurotomy more than doubled the shift, to the extent that the mean PACO2 apneic point was lowered by 6.5 mmHg. Neither vagotomy nor chronic ablation of the area postrema had any detectable influence on the stimulating effect of oxygen on CO2 responsiveness. The arterial-alveolar PCO2 difference, prior to and following carotid chemo-denervation, remained unchanged or was increased by a negligible amount during oxygen inhalation. The oxygen threshold for respiratory stimulation, obtained isocapnically, occurred between 115 and 200 mmHg; VT then increased exponentially tending to level off as PAO2 approached 1 atm. The dynamic response to sudden presentation of oxygen after carotid chemodenervation consisted of a monotonic rise in VT, starting after 20-30 s with a t 1/2 of about 75 s.

Published
1975
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9. Respiratory and cardiovascular depressant effects of nabilone, N-methyllevonantradol and delta 9-tetrahydrocannabinol in anesthetized cats.

Author

Doherty PA, McCarthy LE, and Borison HL

Subjects
Anesthesia, General, Animals, Blood Pressure drug effects, Cats, Depression, Chemical, Dose-Response Relationship, Drug, Female, Heart Rate drug effects, Male, Stereoisomerism, Tidal Volume, Vagotomy, Vagus Nerve physiology, Cardiovascular System drug effects, Dronabinol analogs & derivatives, Dronabinol pharmacology, Phenanthridines pharmacology, Respiration drug effects
Abstract

Drug effects were examined in cats anesthetized with a mixture of pentobarbital and barbital injected i.p. Respiratory observations were analyzed according to effects produced on 1) chemoregulatory responsiveness determined by changes in tidal volume resulting from CO2 inhalation or measured during isocapnic stabilization, and on 2) mechanoreflex control of respiratory frequency through the vagus nerves. Blood pressure and heart rate were recorded concomitantly. Cardiovascular effects were manifested as dose-related hypotension and bradycardia that were generally response-limited by contrast with the respiratory depressant effects which progressed ultimately to failure. Relative potency of the three agents to produce an elevation of 4% in resting alveolar CO2 fraction was 100 times for N-methyllevonantradol and 10 times for nabilone by comparison with delta 9-tetrahydrocannabinol. Marked slowing of respiratory frequency occurred in vagotomized as well as in nerve-intact cats. Apneustic respiration was not observed in any case. It is concluded that the effects of the cannabinoids resulted from 1) an upward shift in CO2 setpoint of the central chemorespiratory "detector"; 2) decreased gain of the CO2-tidal volume "controller"; 3) depression of the respiratory "oscillator" in the lower medulla; 4) depression of the vasomotor center; and 5) a central vagotonic action in addition to a direct cardiodecelerator action on the heart.

Published
1983

10. Respiratory and circulatory effects of saxitoxin in the cerebrospinal fluid.

Author

Borison HL and McCarthy LE

Subjects
Animals, Blood Pressure drug effects, Carbon Dioxide, Cats, Electric Stimulation, Feedback, Injections, Intraventricular, Tetrodotoxin pharmacology, Respiration drug effects, Respiratory Center drug effects, Saxitoxin pharmacology
Abstract

1 In cats anaesthetized with pentobarbitone, saxitoxin and, on a few occasions, tetrodotoxin were injected into a lateral cerebral ventricle or into the subarachnoid space of the lower brain stem. Observations were made on frequency and tidal volume of breathing, on CO(2) responsiveness and on electrical responsiveness of the respiratory centre. Effects on the blood pressure were observed simultaneously.2 A single large dose of toxin, e.g., 250 ng, produced within minutes apneustic breathing and a rise in blood pressure which were converted rapidly to respiratory failure and hypotension. In contrast, repeated small doses, e.g., 25 ng, yielded only progressive slowing of the respiration together with circulatory hypotension. Bulbar depression was produced as effectively by subarachnoid injection as by intraventricular injection of the toxins. Onset of action was detectable within seconds.3 Slowing of the respiration occurred independently of change in tidal volume and whether or not the vagus nerves were cut. The reduction in breathing frequency is attributed to direct toxin-induced depression of the central respiratory oscillator.4 Steady-state measurements of tidal volume at controlled levels of alveolar CO(2) pressure in intermediate stages of respiratory depression showed that the toxins produced an increase in CO(2) stimulation threshold as well as a reduction in gain of CO(2) responsiveness, whether or not the vagus nerves were cut. Carotid arterial chemoreceptor reactivity to O(2) was demonstrable when central sensitivity to CO(2) was depressed. These effects are attributed to a direct influence of the toxins upon the brainstem CO(2)-tidal volume controller.5 Responsiveness of the medullary inspiratory centre to electrical stimulation persisted after the failure of spontaneous breathing was caused by the toxins. Conversely, restitution of electrical responsiveness preceded the reappearance of spontaneous respiratory activity in the recovery phase of toxic depression. Circulatory effects paralleled the changes in respiratory behaviour.6 On the basis of the relatively prompt and discrete alterations in the central respiratory and circulatory control mechanisms produced by saxitoxin and tetrodotoxin placed in the cerebrospinal fluid, it is concluded that the agents rapidly penetrated to deep target loci in the lower brain stem.

Published
1977
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11. Peripheral and central actions of sodium azide on circulatory and respiratory homeostasis in anesthesized cats.

Author

Kaplita PV, Borison HL, McCarthy LE, and Smith RP

Subjects
Animals, Blood Pressure drug effects, Carbon Dioxide pharmacology, Carotid Sinus physiology, Cats, Female, Injections, Intravenous, Injections, Intraventricular, Male, Sodium Azide, Vagus Nerve physiology, Azides toxicity, Brain drug effects, Cardiovascular System drug effects, Homeostasis drug effects, Respiration drug effects
Abstract

In pentobarbital-anesthesized cats, bolus i.v. injections of sodium azide produced dose-dependent transient hypotension accompanied by a modest tachycardia and a brief hyperpnea. Intracerebroventricular injections of azide elicited graded effects similar to the i.v. doses, but the responses were slower in onset and could be delayed by occluding the cranial blood supply. This is interpreted to mean that intracerebroventricular azide acts systematically after escaping from the cerebrospinal fluid into the bloodstream. The hypotensive response to i.v. azide was not affected by cholinergic or adrenergic blockade or buffer nerve section. The tachycardia was blocked by sympathetic neural blockade or buffer nerve section indicating that it is a baroreflex response to the vasodepressor effect. Respiratory effects of bolus i.v. azide occurred independently of the hypotensive response and were abolished by peripheral chemodenervation. Infusion of azide facilitated CO2-tidal volume responsiveness in the steady state, an effect that was essentially eliminated by carotid sinus neurotomy. The azide did not affect the tidal volume-respiratory frequency relationship mediated by the pulmonary stretch receptors. Thus, the respiratory stimulant effect of azide in subtoxic doses is attributable to an excitatory action on the arterial chemoreceptors. Toxic doses of azide resulted in centrally mediated hypertension, tachycardia, cardiac arrhythmia, respiratory depression, seizures and death.

Published
1984

12. Respiration unaffected by anemia in chemodenervated cats.

Author

Borison HL, Hurst JH, and McCarthy LE

Subjects
Animals, Carbon Dioxide, Carotid Sinus innervation, Cats, Decerebrate State physiopathology, Denervation, Hematocrit, Oxygen physiology, Tidal Volume, Vagus Nerve surgery, Anemia physiopathology, Chemoreceptor Cells physiology, Respiration
Published
1982
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15. Respiratory responses to chemical pulses in the cerebrospinal fluid of cats.

Author

Borison HL, Haranath PS, and McCarthy LE

Subjects
Acetylcholine pharmacology, Animals, Apnea chemically induced, Benzamides pharmacology, Blood Pressure, Carbon Dioxide, Cats, Choline pharmacology, Cyanides pharmacology, Ethanol pharmacology, Heart Rate drug effects, Magnesium pharmacology, Nicotine pharmacology, Norepinephrine pharmacology, Perfusion, Pilocarpine pharmacology, Potassium pharmacology, Procaine pharmacology, Sodium pharmacology, Strychnine pharmacology, Sucrose pharmacology, Brain drug effects, Cerebrospinal Fluid, Respiration drug effects
Abstract

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.

Published
1972
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18. Separation of central effects of CO2 and nicotine on ventilation and blood pressure.

Author

McCarthy LE and Borison HL

Subjects
Animals, Brain Stem drug effects, Cats, Cerebrospinal Fluid, Drug Antagonism, Hexamethonium Compounds pharmacology, Hypothermia physiopathology, Nicotine antagonists & inhibitors, Perfusion, Stimulation, Chemical, Tachyphylaxis, Blood Pressure drug effects, Carbon Dioxide pharmacology, Central Nervous System drug effects, Nicotine pharmacology, Respiration drug effects
Published
1972
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