Respiratory volume-time relationships during resistive loading in the cat.

The first-breath (neural) effects of graded resistive loads added separately during inspiration and expiration was studied in seven anesthetized cats before and after bilateral vagotomy. Additions of airflow resistance during inspiration reduced the volume inspired (VI) and increased inspiratory duration (TI). The duration of the ensuing unloaded expiration (TE) was unchanged. Vagotomy eliminated the TI modulation with inspiratory loads. Tracheal occlusion at the onset of inspiration yielded TI values similar to the fixed values observed following vagotomy. Resistive loads added during expiration produced similar results. Expired volume (VE) decreased and (TE) increased approaching the values obtained after vagotomy. Unlike the inspiratory resistive loads, loading during expiration results in an upward shift in the functional residual capacity (FRC). The FRC shift produces a time lag between the onset of diaphragmatic (EMG) activity and the initiation of airflow of the next (unloaded) inspiration. These studies suggest separate volume-time relationships for the inspiratory and expiratory phases of the breathing cycle. Both relationships are dependent upon vagally mediated volume feedback.     

Vagal contributions to respiratory muscle activity during eupnea in the awake dog.

We examined the effects of reversible vagal cooling on respiratory muscle activities in awake chronically instrumented tracheotomized dogs. We specifically analyzed electromyographic (EMG) activity and its ventilatory correlates, end-expiratory lung volume (EELV) and diaphragmatic resting length via sonomicrometry. Elimination of phasic and tonic mechanoreceptor activity by vagal cooling doubled the EMG activity of the costal, crural, and parasternal muscles, with activation occurring sooner relative to the onset of inspiratory flow. Diaphragmatic postinspiration inspiratory activity in the intact dog coincided with a brief mechanical shortening of the diaphragm during early expiration; vagal blockade removed both the electrical activity and the mechanical shortening. Vagal blockade also doubled the EMG activity of a rib cage expiratory muscle, the triangularis sterni, but reduced that of an abdominal expiratory muscle, the transversus abdominis. Within-breath electrical activity of both muscles occurred sooner relative to the onset of expiratory flow during vagal blockade. Vagal cooling was also associated with a 12% increase in EELV and a 5% decrease in end-expiratory resting length of the diaphragm. We conclude that vagal input significantly modulates inspiratory and expiratory muscle activities, which help regulate EELV efficiently and optimize diaphragmatic length during eupneic breathing in the awake dog.     

Influence of lung volume on activities of branches of the recurrent laryngeal nerve

To investigate the influence of inspiratory lung inflation on the respiratory activities of laryngeal motor nerves, vagally intact decerebrate paralyzed cats were ventilated by a servorespirator in accordance with their own phrenic nerve activity. Records were made of the activities of the phrenic nerve, the superior laryngeal nerve (SLN), the recurrent laryngeal nerve (RLN), and the intralaryngeal branches of the RLN serving the thyroarytenoid (TA) and posterior cricoarytenoid (PCA) muscles. Neural activities were assessed in the steady state at different end-tidal O2 and CO2 concentrations. Transient responses to withholding inspiratory lung inflation and to preventing expiratory lung emptying were also studied. Hypercapnia and hypoxia increased the inspiratory activities of the phrenic nerve, SLN, RLN, and its PCA branch. TA inspiratory activity was not changed. Expiratory activities of RLN, PCA, and TA were all increased in hypoxia. When lung inflation was withheld, neural inspiratory duration and the inspiratory activities of all nerves increased. The subsequent period of neural expiration was marked by an exaggerated burst of activity by the TA branch of the RLN. TA expiratory activity was also sharply increased after inspiratory efforts that were reflexly delayed by the prevention of lung emptying. TA activity in expiration was enhanced after vagotomy and was usually more prominent than when lung inflation was withheld before vagal section. The results demonstrate the importance and complexity of the influence of vagal afferents on laryngeal motor activity.     

Diaphragm afferent modulation of phrenic motor drive

Experiments were performed in eight lightly anesthetized thiopental sodium (Pentothal) cats to examine whether diaphragmatic afferents can significantly alter the neural drive to the diaphragm when the animal is exposed to lower body negative pressure. Moving-time-averaged diaphragmatic electromyograms (EMGma) were recorded and compared before and during exposure to lower body negative pressure in each of three consecutive conditions: C7 spinalization, bilateral vagotomy, and cervical dorsal rhizotomy. Application of lower body negative pressure in C7-spinalized animals resulted in a decrease in inspiratory time and peak diaphragmatic activity compared with control levels. After bilateral vagotomy, EMGma activity was prolonged with the application of lower body negative pressure. However, there was no increase in peak EMGma activity. After transection of the cervical dorsal roots subserving the phrenic nerve, the prolongation of diaphragmatic activity negative was eliminated. Therefore, we conclude that the significant increase in duration of inspiration in response to application of lower body negative pressure in the C7-spinalized, bilaterally vagotomized cat is mediated by phrenic nerve afferents.     

Tonic activity in inspiratory muscles and phrenic motoneurons by stimulation of vagal afferents

In anesthetized rabbits, direct and integrated phrenic neurogram (Ephr) and electromyograms from the diaphragm (Edi) and intercostal (Eic) (2nd space) and transversus abdominis muscles (Etr) were simultaneously recorded in two protocols. 1) In animals breathing spontaneously, we used infinite inspiratory (RI) or expiratory (RE) resistive load and intravenous injections of carbachol, histamine, or phenyl diguanide (PDG). All circumstances except RE evoked tonic activities in Ephr, Edi, and Eic but never in Etr. Intravenous atropine abolished carbachol-induced bronchoconstriction and associated tonic inspiratory activities, but this effect persisted with RI, histamine, and PDG. Selective procaine block of conduction in thin vagal fibers (with persistence of the Breuer-Hering inflation reflex) reduced or suppressed the tonic response, which was abolished in all cases after vagotomy. 2) In rabbits artificially ventilated with open chest, passive deflation of the lung or intravenous injections of histamine or PDG also produced tonic discharge in Ephr and often in Eic. The present results demonstrate that 1) stimulation of vagal afferents and mostly thin sensory fibers elicits tonic inspiratory discharges, 2) bronchoconstriction is not necessary for the induction of the response, and 3) reflexes from the chest wall do not mediate this response in rabbits.     

Inhibitory influences of vagal afferences on the oesophageal EMG peristaltic pattern

The influence of vagal afferents on the EMG peristaltic pattern was studied in pigeon oesophagus. Bilateral vagotomy did not abolish the primary peristalsis, but induced significant modifications of the peristaltic pattern parameters. Vagal afferent stimulation induced an inhibitory effect consisting of a temporary break or definitive block of the EMG peristaltic activity already in progress. Vagal afferent stimulation also induced a reduction of the spontaneous EMG activity and this effect was abolished either by glossopharyngeal bilateral section or ganglionic block. Likewise vagal afferent stimulation, the crop distension caused inhibitory effects on EMG peristaltic pattern. This effect was abolished by bilateral vagotomy. These results indicate that vagal afferents, originating from the crop, could influence the central neurons responsible for the peristaltic motor programme.     

Cardiorespiratory responses to chemical activation of right ventricular receptors

Previous reports have shown that activation of left ventricular receptors with sympathetic afferents elicits increases in respiratory output and arterial pressure. The purpose of the present study was to determine whether similar responses are produced by chemical activation of epicardial receptors in the right ventricle. Receptors were stimulated by applying either capsaicin (10 micrograms) or bradykinin (500 ng) to the epicardial surface of the right ventricle in anesthetized cats. Application of either chemical evoked an increase in respiratory output (phrenic nerve activity), a decrease in heart rate, and a nonsignificant increase in arterial pressure in intact cats. However, capsaicin and bradykinin produced significant increases in arterial pressure, heart rate, and respiratory output after bilateral cervical vagotomy. In contrast, a fall in both heart rate and arterial pressure with only small increases in respiratory output were evoked after bilateral removal of the stellate ganglia in cats with intact vagi. Only small responses to the chemical stimulation of right ventricular receptors persisted after combined vagotomy and stellate ganglionectomy. These findings suggest that 1) activation of epicardial receptors with sympathetic afferents originating in the right ventricle causes an increase in cardiorespiratory function, and 2) activation of right ventricular receptors with vagal afferents produces decreases in heart rate and arterial pressure.     

Effects of separate rib cage and abdominal restriction on exercise performance in normal humans

We assessed the effects of selective restriction of movements of the rib cage (Res,rc) and abdomen (Res,ab) on ventilatory pattern, transdiaphragmatic pressure (Pdi), and electrical activity of the diaphragm (Edi) in five normal subjects exercising at a constant work rate (80% of maximum power output) on a cycle ergometer till exhaustion. Restriction of movements was achieved by an inelastic corset applied tightly around the rib cage or abdomen. Edi was recorded by an esophageal electrode, rectified, and then integrated, and peak values during inspiration were measured. Each subject exercised at the same work rate on 3 days: with Res,rc, with Res,ab, and without restriction (control). Res,rc but not Res,ab reduced exercise time (tlim). Up to tlim, minute ventilation (VE) was similar in all three conditions. At any level of VE, however, Res,rc decreased tidal volume and inspiratory and expiratory time, whereas Res,ab had no effect on the pattern of breathing. Res,ab was associated with higher inspiratory Pdi swings at any level of VE, whereas peak Edi was similar to control. Inspiratory Pdi swings were the same with Res,rc as control, but the peak Edi for a given Pdi was greater with Res,rc (P less than 0.05). During Res,rc the abdominal pressure swings in expiration were greater than with Res,ab and control. We conclude that Res,rc altered the pattern of breathing in normal subjects in high-intensity exercise, decreased diaphragmatic contractility, increased abdominal muscle recruitment in expiration, and reduced tlim. On the other hand, Res,ab had no effect on breathing pattern or tlim but was associated with increased diaphragmatic contractility.     

Role of vagal fibers in the hypoxia-induced increases in end-expiratory lung volume and diaphragmatic activity

Bonora, M., and M. Vizek. Role of vagalfibers in the hypoxia-induced increases in end-expiratory lung volumeand diaphragmatic activity. J. Appl.Physiol. 83(3): 700-706, 1997.The possible role of pulmonary C fibers in thehypoxia-induced concomitant increases in end-expiratory lung volume(EELV) and in the activity of the diaphragm at the end of expiration(DE) were evaluated bymeasuring the effects of hypoxia (10%O₂) on ventilation, EELV, andDE in eight chloralose-urethananesthetized rats. Recordings were made before and after blocking vagalC fibers and after bilateral vagotomy. C-fiber conduction was blockedby applying capsaicin perineurally to the cervical vagi. The efficiencyof C-fiber blockade was tested with intravenous capsaicin and itsselectivity by the Hering-Breuer reflex. Perineural capsaicin abolishedthe reflex apnea induced by intravenous capsaicin and transientlyreduced Hering-Breuer reflex. Perineural capsaicin affected neitherventilation, DE, and EELV in airnor the hypoxia-induced increases in these parameters. Vagotomy causedthe typical changes of breathing pattern in air, but the ventilatoryresponse to hypoxia was unchanged. Vagotomy performed during hypoxiaresulted in large decreases inDE and EELV. Hypoxia increasedDE and EELV in vagotomized rats but less than in intact rats. We conclude that the hypoxia-induced increases in EELV and diaphragmatic activity are probably not mediatedby vagal C fibers and that vagal afferents are involved but not fullyresponsible for this phenomenon.

     

串脉冲致兔隔肌疲劳的动物模型

本实验采用串脉冲刺激兔隔神经法复制了家兔膈肌疲劳模型。测定隔肌张力（Ｔｄｉ）、跨膈压（Ｐｄｉ）及其频率特性（Ｔｄｉ－Ｆ、Ｐｄｉ－Ｆ）、呼吸流速（Ｖ）、肺阻力（ＲＬ）、膈肌肌电图（ＥＭＧｄｉ等作为评价膈肌收缩力量的指标。结果发现：经串脉冲刺激后,Ｐｄｉ－Ｆ曲线在３０、５０和１００Ｈｚ时显著降低,Ｐｄｉ、Ｔｄｉ、Ｖ和跨肺压均显著下降。氨茶碱可增加隔肌收缩力,延缓膈肌疲劳过程。结果提示,用串脉冲刺激兔膈神经法建立的模型是一种灵敏、可靠和稳定的膈肌疲劳动物模型。     

Subdiaphragmatic vagal afferent nerves modulate visceral pain

Activation of the vagal afferents by noxious gastrointestinal stimuli suggests that vagal afferents may play a complex role in visceral pain processes. The contribution of the vagus nerve to visceral pain remains unresolved. Previous studies reported that patients following chronic vagotomy have lower pain thresholds. The patient with irritable bowel syndrome has been shown alteration of vagal function. We hypothesize that vagal afferent nerves modulate visceral pain. Visceromotor responses (VMR) to graded colorectal distension (CRD) were recorded from the abdominal muscles in conscious rats. Chronic subdiaphragmatic vagus nerve sections induced 470, 106, 51, and 54% increases in VMR to CRD at 20, 40, 60 and 80 mmHg, respectively. Similarly, at light level of anesthesia, topical application of lidocaine to the subdiaphragmatic vagus nerve in rats increased VMR to CRD. Vagal afferent neuronal responses to low or high-intensity electrical vagal stimulation (EVS) of vagal afferent Adelta or C fibers were distinguished by calculating their conduction velocity. Low-intensity EVS of Adelta fibers (40 microA, 20 Hz, 0.5 ms for 30 s) reduced VMR to CRD at 40, 60, and 80 mmHg by 41, 52, and 58%, respectively. In contrast, high-intensity EVS of C fibers (400 microA, 1 Hz, 0.5 ms for 30 s) had no effect on VMR to CRD. In conclusion, we demonstrated that vagal afferent nerves modulate visceral pain. Low-intensity EVS that activates vagal afferent Adelta fibers reduced visceral pain. Thus EVS may potentially have a role in the treatment of chronic visceral pain.     

Localization of the reflex pathway responsible for the vasodepressor reaction induced by inferior vena caval occlusion and isoproterenol.

Vasodepressor reactions were induced in 27 rats by a combination of inferior vena caval occlusion and an infusion of isoproterenol. A vasodepressor reaction was defined as paradoxical heart rate slowing during inferior vena caval occlusion. The R-R intervals were measured at 5-s intervals before, during, and after 60 s of inferior vena caval occlusion. The purpose of this study was to examine the role of the right and left vagus nerve and the right and left stellate ganglia in this reflex. Under control conditions inferior vena caval occlusion accelerated the rate (R-R, -15.9 +/- 0.9 ms). During an infusion of isoproterenol (0.5-1.0 micrograms.min-1), inferior vena caval occlusion produced paradoxical rate slowing, i.e., a vasodepressor reaction (R-R, +75.0 +/- 2.2 ms). The vasodepressor reaction was examined during inferior vena caval occlusion and isoproterenol under the following additional states: atropine methyl bromide or right vagotomy did not alter the reaction; left vagotomy eliminated the reaction; and right or left stellectomy greatly reduced the vasodepressor reaction. We conclude the following: (1) left vagal afferents mediate the vasodepressor reaction; (2) cardiac sympathetic fibers participate in the vasodepressor reaction by withdrawing efferent tone through the right stellate ganglion, and by generating the afferent signal, which triggers the vasodepressor reaction through the left stellate ganglion.     

Phasic pulmonary stretch receptor feedback modulates both eupnea and gasping in an in situ rat preparation

The perfused in situ juvenile rat preparation produces patterns of phrenic discharge comparable to eupnea and gasping in vivo. These ventilatory patterns differ in multiple aspects, including most prominently the rate of rise of inspiratory activity. Although we have recently demonstrated that both eupnea and gasping are similarly modulated by a Hering-Breuer expiratory-promoting reflex to tonic pulmonary stretch, it has generally been assumed that gasping was unresponsive to afferent stimuli from pulmonary stretch receptors. In the present study, we recorded eupneic and gasplike efferent activity of the phrenic nerve in the in situ juvenile rat perfused brain stem preparation, with and without phrenic-triggered phasic pulmonary inflation. We tested the hypothesis that phasic pulmonary inflation produces reflex responses in situ akin to those in vivo and that both eupnea and gasping are similarly modulated by phasic pulmonary stretch. In eupnea, we found that phasic pulmonary inflation decreases inspiratory burst duration and the period of expiration, thus increasing burst frequency of the phrenic neurogram. Phasic pulmonary inflation also decreases the duration of expiration and increases the burst frequency during gasping. Bilateral vagotomy eliminated these changes. We conclude that the neural substrate mediating the Hering-Breuer reflex is retained in the in situ preparation and that the brain stem circuitry generating the respiratory patterns respond to phasic activation of pulmonary stretch receptors in both eupnea and gasping. These findings support the homology of eupneic phrenic discharge patterns in the reduced in situ preparation and eupnea in vivo and disprove the common supposition that gasping is insensitive to vagal afferent feedback from pulmonary stretch receptor mechanisms.     

Vagal modulation of intestinal afferent sensitivity to systemic LPS in the rat

The central nervous system modulates inflammation in the gastrointestinal tract via efferent vagal pathways. We hypothesized that these vagal efferents receive synaptic input from vagal afferents, representing an autonomic feedback mechanism. The consequence of this vagovagal reflex for afferent signal generation in response to LPS was examined in the present study. Different modifications of the vagal innervation or sham procedures were performed in anesthetized rats. Extracellular mesenteric afferent nerve discharge and systemic blood pressure were recorded in vivo before and after systemic administration of LPS (6 mg/kg iv). Mesenteric afferent nerve discharge increased dramatically following LPS, which was unchanged when vagal efferent traffic was eliminated by acute vagotomy. In chronically vagotomized animals, to eliminate both vagal afferent and efferent traffic, the increase in afferent firing 3.5 min after LPS was reduced to 3.2 +/- 2.5 impulses/s above baseline compared with 42.2 +/- 2.0 impulses/s in controls (P < 0.001). A similar effect was observed following perivagal capsaicin, which was used to eliminate vagal afferent traffic only. LPS also caused a transient hypotension (<10 min), a partial recovery, and then persistent hypertension that was exacerbated by all three procedures. Mechanosensitivity was increased 15 min following LPS but had recovered at 30 min in all subgroups except for the chronic vagotomy group. In conclusion, discharge in capsaicin-sensitive mesenteric vagal afferents is augmented following systemic LPS. This activity, through a vagovagal pathway, helps to attenuate the effects of septic shock. The persistent hypersensitivity to mechanical stimulation after chronic vagal denervation suggests that the vagus exerts a regulatory influence on spinal afferent sensitization following LPS.     

Assessment of the reflex vagal origin of broncho-constrictor effects of hypercapnia in cats (author's transl)

Breath-by-breath measurements of pulmonary resistance (RL) were used to study the bronchomotor effects produced by the inhalation of a CO2-enriched gas mixture in anaesthetized, spontaneously breathing cats. A significant increase in RL occurred from the second inhalation of the hypercapnic gas mixture. This bronchoconstrictor effect lasted about 18 seconds, then a marked decrease in RL was observed. The secondary bronchodilatation persisted during the entire hypercapnic test (4 min). After surgical suppression of the sensory vagal component at the level of the nodose ganglion (bilateral sensory vagotomy), the early bronchoconstrictor effect of CO2 disappeared, but the secondary bronchodilatation was unchanged. In other experiments, after procaine block of the nervous conduction in non-myelinated vagal fibers, the bronchomotor effects of CO2 were the same as those observed after sensory vagotomy. In contrast, an electrotonic block of both vagus nerves, which abolished nervous conduction in myelinated fibers, did not suppress the bronchoconstrictor response to hypercapnia. Thus, the early increase in RL, which follows inhalation of a hypercapnic gas mixture, seems to be reflexly mediated by vagal afferents, especially by non-myelinated fibers.     

Supranodose vagotomy precludes reflex respiratory responses to serotonin in cats

Mediation of the respiratory reflex effects of an exogenous serotonin challenge goes beyond the lung vagi and is suggested to involve the nodose ganglia. In the present experiments the effects of an intravenous serotonin challenge on breathing pattern were studied in 8 pentobarbitone-chloralose anaesthetised cats. Bolus injection of serotonin oxalate (50 µg/kg) into the right femoral vein evoked prompt apnoea of 19.2 (±2.4)-second duration in all 8 cats while intact; the apnoea was much shorter after midcervical vagal section (8.1±0.9 s, p<0.001), and was abolished by supranodose vagotomy. In post-apnoeic breaths, the tidal volume was reduced from a baseline of 34.1±4.0 to 13.5±1.1 ml (p<0.001) prior to, and from a baseline of 43.9±5.4 to 33.8±6.6 ml (p<0.01) after midcervical vagotomy; the serotonin challenge did not affect tidal volume following supranodose vagal section (p=0.4). The increase in respiratory rate found in intact (p<0.001) and midcervically vagotomised cats (p<0.01) was eliminated by the neurotomy above the nodose ganglia. Supranodose vagotomy altered cardiovascular response to serotonin by replacing the fall in blood pressure with an increase. These data suggest that the sequelae of serotonin-induced pulmonary chemoreflex, i.e. respiratory arrest, cardiovascular changes and post-apnoeic pattern of breathing require intact nodose ganglia.     

Laryngeal influences on breathing pattern and posterior cricoarytenoid muscle activity

Receptors responding to transmural pressure, airflow, and contraction of laryngeal muscles have been previously identified in the larynx. To assess the relative contribution of these three types of receptors to the reflex changes in breathing pattern and upper airway patency, we studied diaphragmatic (DIA) and posterior cricoarytenoid muscle (PCA) activity in anesthetized dogs during spontaneous breathing and occluded efforts with and without bypassing the larynx. Inspiratory duration (TI) was longer, mean inspiratory slope (peak DIA/TI) was lower, and PCA activity was greater with upper airway occlusion than with tracheal occlusion (larynx bypassed). Bilateral section of the superior laryngeal nerves eliminated these differences. When respiratory airflow was diverted from the tracheostomy to the upper airway the only change attributable to laryngeal afferents was an increase in PCA activity. These results confirm the importance of the superior laryngeal nerves in the regulation of breathing pattern and upper airway patency and suggest a prevalent role for laryngeal negative pressure receptors.     

Changes in afferent and efferent phrenic activities with electrically induced diaphragmatic fatigue.

In anesthetized artificially ventilated cats, diaphragmatic fatigue was produced by direct muscle stimulation with trains of pulses for 30 min. Failure of contraction was assessed from decrease in the maximal relaxation rate of transdiaphragmatic pressure twitches. Motor activities (electromyogram and motor phrenic neurogram) were processed by fast-Fourier transform analysis, which provided the power spectrum density function (PSDF). The discharge frequency of diaphragmatic afferents was also measured. In control conditions (before fatigue), intra-arterial bolus injection of lactic acid enhanced tonically active diaphragmatic afferents, whereas it reduced the firing rate of afferent fibers activated in phase with diaphragmatic contraction or relaxation. The same sensory response pattern was observed with the development of diaphragmatic fatigue. Leftward shift in PSDFs of motor phrenic neurogram also occurred, but it preceded the failure of diaphragmatic contraction as well as the changes in the electromyogram's PSDF and afferent paths, which were closely associated with lengthening of both inspiratory and total breath durations. After section of the phrenic nerves, the motor phrenic response disappeared during the fatigue trial. This demonstrates the existence of complex reflex-induced changes in the ventilatory control during diaphragmatic fatigue. They seem to involve the participation of several types of phrenic afferents.     

Excitation of dorsal and ventral respiratory group neurons by phrenic nerve afferents

The projections of phrenic nerve afferents to neurons in the dorsal (DRG) and ventral (VRG) respiratory group were studied in anesthetized, paralyzed, and vagotomized cats. Extracellular recordings of neuronal responses to vagal nerve and cervical phrenic nerve stimulation (CPNS) indicated that about one-fourth of the DRG respiratory-modulated neurons were excited by phrenic nerve afferents with an onset latency of approximately 20 ms. In addition, non-respiratory-modulated neurons within the DRG were recruited by CPNS. Although some convergence of vagal and phrenic afferent input was observed, most neurons were affected by only one type of afferent. In contrast to the DRG, only 3 out of 28 VRG respiratory-modulated neurons responded to CPNS. A second study determined that most of these neuronal responses were due to activation of diaphragmatic afferents since 90% of the DRG units activated by CPNS were also excited at a longer latency by thoracic phrenic nerve stimulation. The difference in onset latency of neuronal excitation indicates an afferent peripheral conduction velocity of about 10 m/s, which suggests that they are predominately small myelinated fibers (group III) making paucisynaptic connections with DRG neurons. Decerebration, decerebellation, and bilateral transection of the dorsal columns at C2 do not abolish the neuronal responses to cervical PNS.     

Cardiovascular effects of atrial natriuretic extract in the whole animal

Atrial tissue extract (AE) and ventricular tissue extract cause identical decreases in total peripheral resistance when they are injected i.v. into anesthetized rats. However, only AE causes significant hypotension because of cardiac inhibition. This involves both bradycardia and failure of stroke volume to increase appropriately. The observations cannot be explained by direct action of AE on myocytes, but are more likely to be the result of interactions with cardiovascular reflex mechanisms. Excitation of chemosensitive cardiac receptors with vagal afferents appears to be an important afferent mechanism. The efferent limb for the negative chronotropic response resides partly in the vagus nerves and partly in cardiac sympathetic nerves. The negative inotropic response of AE was not altered by vagotomy, spinal section, atropine, or propranolol. These results suggest that atrial peptides may cause the release of a negatively inotropic substance from a site that is not yet identified.