Mechanical ventilation increases substance P concentration in the vagus, sympathetic, and phrenic nerves

Substance P (SP), a neurotransmitter localized to primary sensory neurons, is found in the vagus nerve, nodose ganglion, sympathetic chain, and phrenic nerve in various animal species. However, the changes in endogeneous SP concentration under various circumstances that involve the participation of cardiorespiratory afferent nerves are still unexplored. In the present study, attention was focused on the variations in SP content measured by radioimmunoassay (RIA) in respiratory afferent nerves (vagus nerve, cervical sympathetic chain, phrenic nerve) and respiratory muscles (diaphragm, intercostal muscles) during positive inspiratory pressure (PIP) breathing alone or PIP with an expiratory threshold load (ETL) in rabbits. SP was found in all sampled structures in spontaneously breathing control animals, prevailing in the nodose ganglion. Left-versus right-sided differences were noticed in nerves. As compared with that in control animals, the SP concentration was markedly higher in vagal and sympathetic nervous structures during PIP or PIP with ETL, and also in the phrenic nerve during ETL breathing. The SP content did not vary in respiratory muscles. These observations suggest that two very common circumstances of mechanical ventilation are associated with an increased SP concentration in nervous structures participating in the control of breathing.     

Neuroexcitatory effects of digoxin in the cat

The effect of intravenous injections of digoxin (20 mug/kg every 15 minutes) on spontaneously occurring activity in autonomic efferent nerves, motor nerves, afferent nerves, electrocardiogram and on arterial blood pressure was evaluated in chloralose-anesthetized cats. Administration of digoxin enhanced neural activity in pre- and postganglionic cardiac synpathetic nerves and this enhancement occurred near the time the disturbances in ventricular rhym were noted. Neural activity continued to increase during ventricular tachycardia and maximum enhancement was observed just proir to ventricular fibrillation. Similar results were observed when digoxin was administered to animals in which neural activity was recorded from preganglionic splanchnic and superior cervical nerves. Digoxin administration also increased discharge frequency from vagus (efferent fibers), phrenic and carotid sinus nerves. Denervation of cardiovascular reflexogenic areas prevented the increased discharge in vagus nerves, reduced it in phrenic nerves, but did not affect nerve discharge in sympathetic nerves. These results suggest that digoxin-induced hyperactivity in synpathetic nerves was related to a central nervous system effect of the drug, whereas the mechanism for the digoxin-induced hyperactivity in vagus nerves involved a peripheral reflex effect of the drug. Both sites were involved in the digoxin-induced hyperactivity in phrenic nerves. Enhancement of cardiac sympathetic nerve activity appeared to be responsible for the ventricular arrhythmias provoked by digoxin as 1) a temporal relationship was observed between augmented nerve activity and arrhythmia development, 2) a centrally acting sympathetic nervous system depressant drug, clonidine, converted the ventricular arrhythmia to normal rhythm, and 3) removal of sympathetic influence to the heart by spinal cord transection decreased the sensitivity of the heart to the arrhythmogenic effect of digoxin. These results suggest that digoxin partially responsible for its cardiotoxic effects.     

Primary graft dysfunction after liver transplantation: from pathogenesis to prevention

Spontaneous bladder contractions (SBCs) in decerebrate, vagotomized, paralyzed, ventilated cats have been shown to decrease phrenic and hypoglossal inspiratory nerve activities, as well as the activities of other respiratory motor nerves. To determine whether vagal afferents from the lung influence the respiratory inhibition associated with SBCs, we recorded phrenic and hypoglossal nerve activities in decerebrate, paralyzed, vagally intact cats. The animals were ventilated by a servo-respirator, which inflated the lungs in accordance with integrated phrenic nerve activity. Maintained increases in end-expiratory lung volume were produced by the application of 2-10 cm H2O positive end-expiratory pressure (PEEP). SBCs were accompanied by decreases in both phrenic and hypoglossal peak integrated nerve activities, as well as by marked decreases in respiratory frequency. The reduction of respiratory frequency was greater with higher levels of PEEP, a few animals becoming apneic during SBCs. After bilateral vagotomy, SBCs continued to decrease phrenic and hypoglossal peak integrated nerve activities as previously reported, but the reduction of respiratory frequency was much less striking than when the vagi were intact. These results indicate that activity of vagal afferents from the lung augments the respiratory influence of SBCs. Furthermore, SBCs in vagally intact animals can induce periodic breathing.     

Diaphragm EMG measured by cervical magnetic and electrical phrenic nerve stimulation

The purpose of the study was to compare electrical stimulation (ES) and cervical magnetic stimulation (CMS) of the phrenic nerves for the measurement of the diaphragm compound muscle action potential (CMAP) and phrenic nerve conduction time. A specially designed esophageal catheter with three pairs of electrodes was used, with control of electrode positioning in 10 normal subjects. Pair A and pair B were close to the diaphragm (pair A lower than pair B); pair C was positioned 10 cm above the diaphragm to detect the electromyogram from extradiaphragmatic muscles. Electromyograms were also recorded from upper and lower chest wall surface electrodes. The shape of the CMAP measured with CMS (CMS-CMAP) usually differed from that of the CMAP measured with ES (ES-CMAP). Moreover, the latency of the CMS-CMAP from pair B (5.3 +/- 0.4 ms) was significantly shorter than that from pair A (7.1 +/- 0.7 ms). The amplitude of the CMS-CMAP (1.00 +/- 0.15 mV) was much higher than that of ES-CMAP (0.26 +/- 0.15 mV) when recorded from pair C. Good-quality CMS-CMAPs could be recorded in some subjects from an electrode positioned very low in the esophagus. The differences between ES-CMAP and CMS-CMAP recorded either from esophageal or chest wall electrodes make CMS unreliable for the measurement of phrenic nerve conduction time.     

Pulmonary and pulmonary-related reflexes mediated by serotonin receptors in the peripheral nervous system

It is known that serotonin is widely distributed in the body; its receptors are located in various tissues and organs. It has been reported that serotonin receptors without apparent synaptic structure exist in the peripheral nervous system. These serotonin receptors might be the target of circulatory serotonin. In particular, serotonin has a potent depolarizing action on vagal afferent nerves. This stimulation causes various autonomic reflexes, so-called von Bezold-Jarisch reflex, that consist of bradycardia, hypotension and apnea. The peripheral 5-HT3-receptor subtype seems to be responsible for the initiation of these reflexes. The physiological and pathophysiological significance of these serotonin-induced modulations have not, however, been established. The present study was designed to examine the effects of exogenous serotonin on the chemosensitive afferent nerves including carotid sinus nerves, cervical vagus nerve, and efferent motor nerves, such as phrenic nerves and pharyngeal nerves. Because little is known about the involvement of the serotonergic system in the pulmonary reflex and pulmonary-related reflexes (swallowing or vomiting), the distribution of the motor component of these nerves within the brain stem of the rat was also determined.     

Diaphragm activation with intramuscular stimulation in dogs

We studied in 10 supine anesthetized dogs diaphragm contraction produced by electrical activation with intramuscular electrodes surgically implanted in the ventral surface of the diaphragm and compared this with activation of the ipsilateral phrenic nerve (C5, 6, and 7) before it entered the thorax. Repetitive 40-Hz pulse trains with supramaximal current stimulus were used after hyperventilation of the animals to apnea. A single intramuscular electrode within 1 to 2 cm of the site of phrenic nerve entry into the diaphragm produced a mean transdiaphragmatic pressure of 12.0 cm H2O +/- 0.97 SE and mean tidal volume of 0.27 L +/- 0.04 SE. Mean values observed with phrenic nerve stimulation were not statistically different, and both electrode systems produced equivalent outward abdominal motion and upper rib cage paradox, as monitored by inductive plethysmography. There was no difference in gas exchange during stimulation with a single hemidiaphragm electrode and mechanical ventilation compared at the same tidal volume and respiratory rate. Blockade of neuromuscular transmission with curare eliminated intramuscular and phrenic nerve stimulation proportionately, suggesting that activation of the diaphragm is dependent in both cases on the phrenic nerve. This technique does not entail manipulation of the phrenic nerve and may have clinical application as an alternative technique for diaphragm pacing.     

Percutaneous repair of a traumatic bile duct laceration in a liver transplant allograft

BACKGROUND: Phrenic nerve palsy in infants and young children usually results from birth injury or iatrogenic damage. The newborn almost invariably presents with severe respiratory distress, diaphragmatic elevation, and paradoxical movement at the affected side. METHODS/RESULTS: In this retrospective analysis a group of 23 patients below the age of 1 year with an obstetric or postoperative phrenic nerve injury was studied and compared with cases in the literature. All patients were admitted between 1986 and 1997 to the Pediatric Surgical Center, Amsterdam. Thirteen of 18 patients with an obstetric phrenic nerve injury underwent plication of the diaphragm after an average observation period of 100 days. In the remaining five children with an obstetric phrenic nerve injury, spontaneous recovery appeared within 1 month. Only one of five patients with a phrenic nerve palsy after a cardiac surgical procedure underwent plication of the diaphragm. Fifteen of the 34 patients described in the literature underwent plication of the diaphragm after an average of 54 days. CONCLUSIONS: If after 1 month no spontaneous recovery of the diaphragmatic paralysis caused by a phrenic nerve injury occurs, plication of the diaphragm is indicated. This operation proved to be successful for relief of symptomatic phrenic nerve injury in all cases. If the condition of the patient clinically deteriorates during this first month of life, the patient should be operated on immediately.     

Changes in serum pepsinogen, gastrin, and immunoglobulin G antibody titers in helicobacter pylori-positive gastric ulcer after eradication of infection

The feasibility of using the spiral nerve cuff electrode design for recordings of respiratory output from the hypoglossal (HG) and phrenic nerves is demonstrated in anesthetized, paralyzed, and artificially ventilated cats. Raw neural discharges of the HG nerve were analyzed in terms of signal-to-noise ratios and frequency spectra. The rectified and integrated moving average activity of the HG nerve had a peak value of 1.74 +/- 0.21 microV and a baseline value of 0.72 +/- 0.11 microV at elevated respiratory drive induced by increases in CO2 or oxygen deprivation when recorded with 10-mm-long cuffs. The frequency content of the HG electroneurogram extended from several hundred hertz to 6 kHz. Spiral nerve cuff recordings without desheathing of the nerve provided large enough signal-to-noise ratios that allowed them to be used as a measure of respiratory output and had much wider frequency bandwidths than the hook electrode preparations. A major advantage of the cuff electrode over the hook electrode was its mechanical stability, which significantly improved the reproducibility of the recordings both in terms of signal amplitudes and frequency contents.     

Frequency response analysis of the diaphragm in vivo

Frequency response analysis was used to determine the dynamic response characteristics of cat diaphragm under isovolumetric conditions at functional residual capacity (FRC) and at lung volumes above and below FRC. In apneic cats, sinusoidally modulated pulse rate patterns were applied to both phrenic nerves. Modulation frequencies over the range of 0.05-4 Hz were used. Amplitude ratio vs. frequency plots obtained at FRC for intratracheal, intraesophageal, and intragastric pressures were essentially flat at low frequencies but decreased at higher frequencies. Intratracheal and intraesophageal pressure responses were altered by changes in resting lung volume while intragastric pressure was not. The amplitude ratio was decreased at lung volumes above FRC but increased at volumes below FRC. Thus, lung volume significantly affected the input-output relations between phrenic nerve input and diaphragm muscle output. In all preparations studied, significant phase lags were present throughout the entire modulation frequency range. However, in contrast to the effect of lung volume on amplitude ratio, phase lag was not dependent on changes in lung volume.     

Early assessment of diaphragmatic dysfunction in children in the ITU: chest radiology and phrenic nerve stimulation

Diaphragmatic dysfunction is a common postoperative complication of cardiac surgery in children, with important effects on respiratory morbidity. Its early diagnosis, followed by prompt surgical intervention, has been shown to reduce morbidity. However, the commonest method of diagnosis, based on hemi-diaphragmatic elevation on the chest radiograph, may be less accurate than direct techniques for assessing phrenic nerve function. We have compared electrophysiological and radiological diagnoses of diaphragmatic abnormality in 100 children (aged 3 days to 17.5 yrs) undergoing cardiac surgery, looking at respiratory morbidity as assessed by the duration of ventilation, the time spent on the cardiac intensive care unit (CICU), and the requirement for reintubation. Despite showing good reproducibility, radiological diagnosis was neither sensitive nor specific in identifying patients with electrophysiological phrenic nerve damage. Analysis of the measures of outcome supported the electrophysiological technique. Patients with electrophysiological evidence of damage had a longer duration of ventilation, spent longer on the CICU, and had a greater incidence of reintubation than either radiologically abnormal or "normal" patients. Chest X-rays are not a good method for diagnosing phrenic nerve damage in the early postoperative period in children. If early diagnosis is needed, then direct assessment of phrenic nerve function, such as the measurement of phrenic latency, may be a better technique.     

Functional magnetic stimulation of the respiratory muscles in dogs

This study assessed the ability of functional magnetic stimulation (FMS) to activate the respiratory muscles in dogs. With the animal supine, FMS of the phrenic nerves using a high-speed magnetic stimulator was performed by placing a round magnetic coil (MC) at the carotid triangle. Following hyperventilation-induced apnea, changes in volume (deltaV) and airway pressure (deltaP) against an occluded airway were determined. FMS of the phrenic nerves produced substantial inspired function (deltaV = 373 +/- 20.5 mL and deltaP = -20 +/- 2.0 cm H2O). After bilateral phrenectomies, maximal inspired deltaV (219 +/- 12.2 mL) and deltaP (-10 +/- 1.0 cm H2O) were produced when the MC was placed near the C6-C7 spinous processes, while maximal expired deltaV (-199 +/- 22.5 mL) and deltaP (11 +/- 2.3 cm H2O) were produced following stimulation near the T9-T10 spinous processes. We conclude: (1) FMS of either the phrenic or upper intercostal nerves results in inspired volume production; (2) FMS of the lower intercostal nerves generates expired volume production; and (3) FMS of the respiratory muscles may be a useful noninvasive tool for artificial ventilation and assisted cough in patients with spinal cord injuries or other neurological disorders.     

The pathophysiology of REM-sleep behavior disorder

Congenital partial pericardial defect is a rare anomaly that causes no symptoms and is often noticed by chance at autopsy or thoracotomy. During an operation on a patient with bronchiectasis, a partial pericardial defect and anomaly of left phrenic nerve were found incidently. A 58-year-old man complaining hemoptysis was referred to our hospital for surgical treatment of the left cystic bronchiectasis. During a thoracotomy, a partial pericardial defect was noticed. Moreover the left phrenic nerve could not be found within the operative field. We performed left pneumonectomy without repair of pericardial defect, and the patient had a satisfactory postoperative course. A relationship was suggested between congenital pericardial defect and the anomaly of the phrenic nerve.     

Inhibitory effects of centrally administered somatostatin on the adrenal zona glomerulosa in male rats

Segmental zoster paresis (SZP) is the focal, asymmetrical neurogenic weakness which may occur in a limb affected by cutaneous zoster. We have summarized the features of this syndrome, based on a retrospective review of 8 personal and 96 published cases. Limb SZP becomes apparent in at least 3-5% of patients with cutaneous zoster, who are usually over the age of sixty and weak proximally (C5,6,7 or L2,3,4 innervated muscles). Functional motor recovery occurs in about 75% of cases, generally by 1-2 years. Limb weakness is probably due to a lesion of the ventral nerve root, in close proximity to the initiating dorsal ganglionitis. The electrodiagnostic findings, scarce in the literature, typically consist of absent compound sensory nerve action potentials in the involved limb, with less frequent reduction or loss of compound muscle action potentials. Fibrillations and positive sharp waves become detectable within 1-4 months in limb and related paraspinal muscles, decreasing or disappearing later. In addition to this radiculopathy, peripheral nerves may also occasionally become involved, manifest as mononeuropathies of the median, ulnar, long thoracic, recurrent laryngeal, and phrenic nerves. The zoster infection or consequent inflammatory response appears able to affect motor axons distally as well as proximally.     

Phrenic motoneuron discharge during sustained inspiratory resistive loading

I determined whether prolonged inspiratory resistive loading (IRL) affects phrenic motoneuron discharge, independent of changes in chemical drive. In seven decerebrate spontaneously breathing cats, the discharge patterns of eight phrenic motoneurons from filaments of one phrenic nerve were monitored, along with the global activity of the contralateral phrenic nerve, transdiaphragmatic pressure, and fractional end-tidal CO2 levels. Discharge patterns during hyperoxic CO2 rebreathing and breathing against an IRL (2,500-4,000 cmH2O.1-1.s) were compared. During IRL, transdiaphragmatic pressure increased and then either plateaued or decreased. At the highest fractional end-tidal CO2 common to both runs, instantaneous discharge frequencies in six motoneurons were greater during sustained IRL than during rebreathing, when compared at the same time after the onset of inspiration. These increased discharge frequencies suggest the presence of a load-induced nonchemical drive to phrenic motoneurons from unidentified source(s).     

Adenosine-related ventricular asystole

A case of phrenic nerve paralysis following interpleural analgesia for cholecystectomy is reported. The pre-operative chest X ray was normal but chest X ray after cholecystectomy and interpleural analgesia revealed a raised right hemidiaphragm. This resolved after discontinuation of the interpleural analgesia and was probably a result of phrenic nerve paralysis produced by the interpleural local anaesthetic.     

Ultrastructural changes in the rat phrenic nucleus developing within 2 h after cervical spinal cord hemisection

The present study was conducted to describe the ultrastructural changes which occur in the young adult rat phrenic nucleus within 2 h after an ipsilateral C2 spinal cord hemisection. The main objective was to determine if there is a temporal relationship between specific ultrastructural changes in the phrenic nucleus and a significant augmentation of crossed phrenic nerve activity which occurs as early as 2 h after hemisection. Phrenic motoneurons were identified at electron microscopic levels by retrograde HRP labeling. Ultrastructural features in the phrenic nucleus of control and experimental rats were qualitatively analyzed and then quantitated. At 2 h posthemisection, there was a significant increase in the mean percentage of phrenic dendrodendritic appositions. In the control rats, 4.73 +/- 0.18% of phrenic dendrites were in apposition, and this percentage increased significantly to 8.58 +/- 0.54% at 2 h after injury. Furthermore, the mean lengths of asymmetrical and symmetrical synaptic active zones increased significantly at 2 h posthemisection from control lengths of 0.372 +/- 0.009 microns and 0.404 +/- 0.007 microns to 0.410 +/- 0.011 microns and 0.513 +/- 0.032 microns, respectively, in experimental rats. The phrenic nucleus is therefore capable of morphological plasticity as early as 2 h after spinal cord hemisection and this plasticity coincides temporally with the physiological augmentation of crossed phrenic nerve activity at 2 h. The data further suggest that these morphological changes may be part of the substrate for the unmasking of ineffective synapses during the crossed phrenic phenomenon.     

The nucleus is the target for radiation-induced chromosomal instability

Laparoscopic mapping of the phrenic nerve motor points using test stimulation was conducted for the implant of epimysial electrodes for diaphragm pacing in dogs. Both visual assessment of muscle activation and measurements of recruitment were useful for identifying an implant location resulting in a mean electrode placement approximately 14 mm from the phrenic nerve motor points in 16 dogs. Postmortem analysis of the stimulus test site locations and corresponding recruitment curves suggested that the phrenic nerve motor points could be predicted during the laparoscopic procedure to within 4.5 mm of the anatomical motor point.     

Respiratory activity of the rat posterior cricoarytenoid muscle

An anatomic and electrophysiological study of the rat posterior cricoarytenoid (PCA) muscle is described. The intramuscular nerve distribution of the PCA branch of the recurrent laryngeal nerve was demonstrated by a modified Sihler's stain. The nerve to the PCA was found to terminate in superior and inferior branches with a distribution that appeared to be confined to the PCA muscle. Electromyography (EMG) recordings of PCA muscle activity in anesthetized rats were obtained under stereotaxic control together with measurement of phrenic nerve discharge. A total of 151 recordings were made in 7 PCA muscles from 4 rats. Phasic inspiratory activity with a waveform similar to that of phrenic nerve discharge was found in 134 recordings, while a biphasic pattern with both inspiratory and post-inspiratory peaks was recorded from random sites within the PCA muscle on 17 occasions. The PCA EMG activity commenced 24.6 +/- 2.2 milliseconds (p < .0001) before phrenic nerve discharge. The results are in accord with findings of earlier studies that show that PCA muscle activity commences prior to inspiratory airflow and diaphragmatic muscle activity. The data suggest that PCA and diaphragm motoneurons share common or similar medullary pre-motoneurons. The earlier onset of PCA muscle activity may indicate a role for medullary pre-inspiratory neurons in initiating PCA activity.     

Putative projection of phrenic afferents to the limbic cortex in humans studied with cerebral-evoked potentials

Respiratory sensations may rely in part on cortical integration of respiratory afferent information. In an attempt to study such projections, we recorded evoked potentials at scalp and cervical sites in 10 normal volunteers undergoing transcutaneous phrenic stimulation (0.1-ms square pulses, intensity liminal for diaphragmatic activation, series of 600 shocks at 2 Hz). A negative cerebral component of peak latency (12.79 +/- 0.54 ms; N13) was constant, and a negative spinal component (7.09 +/- 1.04 ms; N7) could also be recorded, all results being reproducible over time. Monitoring of cardiac frequency, skin anesthesia, and stimulation adjacent to the phrenic nerve made the phrenic origin of N7 and N13 the foremost hypothesis. Increasing stimulation frequency and comparison with median nerve stimulation provided arguments for the neural nature of the signals and their cerebral origin. Recordings from intracerebral electrodes in a patient showed a polarity reversal of the evoked potentials at the level of the cingulate gyrus. In conclusion, phrenic stimulation could allow one to study projections of phrenic afferents to the central nervous system in humans. Their exact site and physiological meaning remain to be clarified.     

Effects of halothane on the phrenic nerve responses to carbon dioxide mediated by carotid body chemoreceptors in vagotomized dogs

BACKGROUND: Previous studies in dogs showed that the phrenic nerve response to an acute hypoxic stimulus was dose dependently depressed by 0.5-2.0 minimum alveolar concentration (MAC) of halothane but not abolished. Because a carbon dioxide stimulus is transduced by a different mechanism in the carotid body chemoreceptors (CBCRs) than is a hypoxic stimulus, inhalational anesthetics may preferentially depress one of these transduction processes, the central neuronal processing, or both, of the integrated responses to these two types of inputs. METHODS: Carotid body chemoreceptor stimulation was produced by short (1-1.5 s), bilateral, 100% carbon dioxide in saline infusions into the carotid arteries during neural inspiration in unpremedicated, halothane-anesthetized, paralyzed, vagotomized dogs during constant mechanical ventilation. The phrenic neurogram quantified the neural inspiratory response. Four protocols were performed in the study: (1) the dose-dependent effects of halothane anesthesia (0.5-2.0 MAC) during hyperoxic hypercapnia on phrenic nerve activity, (2) the effects of three background levels of the partial pressure of carbon dioxide (PaCO2) on the magnitude of the carbon dioxide infusion responses at 1 MAC halothane, (3) the effects of anesthetic type on the magnitude of the carbon dioxide infusion response, and (4) the effects of CBCR denervation. RESULTS: Peak phrenic nerve activity (PPA) increased significantly during the carbon dioxide-stimulated phrenic burst in protocols 1-3; after denervation there was no response (protocol 4). Halothane produced a dose-dependent reduction in the PPA of control and carbon dioxide infusion-stimulated phrenic bursts and in the net carbon dioxide response. The net PPA responses for the different PaCO2 background levels were not different but were somewhat larger for sodium thiopental anesthesia than for 1.0 MAC halothane. CONCLUSIONS: The phrenic nerve response to an acute, severe carbon dioxide stimulus was dose dependently depressed by surgical doses of halothane. The observed responses to carbon dioxide infusion were mediated by the CBCRs because they were eliminated by CBCR denervation. These results suggest that the CBCR transduction and central transmission of the carbon dioxide signal in terms of inspiratory excitatory drive are not abolished at surgical levels of halothane anesthesia.