Independent brain stem sites for ventilatory neurogenesis

The purpose was to determine if independent ventilatory rhythms could be generated in each half of completely separated brain stems. In decerebrate, cerebellectomized, vagotomized, paralyzed, and ventilated cats, activities of phrenic, recurrent laryngeal (RLN), and/or hypoglossal nerves were monitored. Midsaggital brain stem divisions were performed by sections and lesions. Eupnea continued following divisions of mesencephalon and pons. Hypoglossal and phrenic activities were eliminated after sections approximating the obex. In most preparations, RLNs discharged with independent rhythms after completion of midsagittal brain stem section and a C1 transection. Independent rhythms were also obtained from each half of medulla following transections at the pontomedullary junction and at C1, and midsagittal medullary divisions. In other animals with transections between pons and medulla and at C1, synchronized RLN and hypoglossal activities persisted after sagittal medullary divisions, 2.0 mm lateral to midline contralaterally. Data demonstrate that there is more than one potential brain stem site for ventilatory neurogenesis. It is hypothesized that there are many such sites, possibly having pacemaker cells, in pons and medulla.     

Respiratory neural activities after caudal-to-rostral ablation of medullary regions

The purpose is to assess the importance of medullary mechanisms for the neurogenesis of eupnea. Cats that were used were decerebrate, cerebellectomized, vagotomized, paralyzed, and ventilated. Activities of the phrenic, facial, and mylohyoid nerves were monitored. Progressive caudal-to-rostral transections of the spinal cord and medulla were performed. Phrenic activity was eliminated by C1 spinal transections. Only modest changes in facial and mylohyoid activities resulted from transections as far rostral as the level of the dorsal respiratory nucleus. Rhythmic discharges ceased on transections at the pontomedullary junction. However, rhythmic mylohyoid discharges were maintained if protriptyline and strychnine were administered before and during the transection. In other studies rhythmic phrenic, facial, and mylohyoid discharges continued, albeit with an altered rhythm, after destruction of neurons in the dorsal respiratory nucleus by kainic acid. We conclude that caudal medullary mechanisms do not play an essential role in the neurogenesis of breathing movements. Rather, structures in rostral medulla and pons appear necessary for sustaining eupneic neural activities. The concept of multiple brain stem sites for ventilatory neurogenesis is discussed.     

Respiratory cycle timing and fast inspiratory discharge rhythms in the adult decerebrate rat

In supracollicular decerebrate paralyzed adult rats, neural respiration was monitored by bilateral phrenic recordings. In the study of respiratory cycle timing, the effects of vagal afferent input (lung inflation) on respiratory phase durations resembled those seen in decerebrate cats. 1) Withholding lung inflation during neural inspiration (I) produced lengthening of I phase duration by 46% (mean, n = 11). 2) Maintaining lung inflation during neural expiration (E) produced lengthening of E phase duration by 112% (mean, n = 4). In the study of fast rhythms in inspiratory discharges, phrenic nerve autospectra and bilateral (left-right) phrenic coherences in 16 rats revealed two types of fast rhythm: 1) high-frequency oscillation (HFO), which had significant coherence peaks (n = 9, range 106-160 Hz, mean 132 Hz); and 2) medium-frequency oscillation (MFO), which had autospectral peaks but no distinct coherence peaks (n = 11, range 46-96 Hz, mean 66 Hz). These rhythms resembled MFOs and HFOs in the decerebrate cat, but the modal frequency range was about twice as large. In addition, these frequency values differed markedly from the 20-40 Hz of the rhythms found in earlier studies in neonatal in vitro preparations; the difference may be due to developmental immaturity.     

反射性呼吸暂停中延髓各类呼吸性神经元的放电变化

在向家兔颈动脉窦区注入拘椽酸钠引起呼吸暂停期间,和在持续性肺充气引起延长的呼气相中,延髓大多数吸气神经元和膈神经停止放电;而大多数呼气性神经元呈连续性放电,放电频率持续地高于或接近于平静呼气时呼气神经元的高峰放电频率,并伴随肋间内肌电活动增强,直至呼气性神经元放电频率衰减或停止放电时,膈神经才恢复放电。这提示呼气性神经元的持续兴奋状态可能与呼气性呼吸暂停的维持或呼气相的延长有关。在延髓闩前部可以记录到少数放电频率渐增型的跨时相呼气-吸气神经元,在呼吸暂停期间,它们呈低频连续放电,逐渐增大放电频率,在其放电频率急剧增高时,膈神经恢复放电。这提示该类神经元可能与吸气的发动有关。本文尚就呼吸节律的发生机制做了讨论。     

D1-dopamine receptor agonists prevent and reverse opiate depression of breathing but not antinociception in the cat

Opioids depress respiration and decrease chest wall compliance. A previous study in this laboratory showed that dopamine-D(1) receptor (D(1)R) agonists restored phrenic nerve activity after arrest by fentanyl in immobilized, mechanically ventilated cats. The reinstated phrenic nerve rhythm was slower than control, so it was not known whether D(1)R agonists can restore spontaneous breathing to levels that provide favorable alveolar gas exchange and blood oxygenation. It was also not known whether the agonists counteract opioid analgesia. In the present study, anesthetized, spontaneously breathing cats were given intravenous doses of fentanyl (18.0 +/- 3.4 microg/kg) that severely depressed depth and rate of respiration, lowered arterial hemoglobin oxygenation (HbO(2)), elevated end-tidal carbon dioxide (ETCO(2)), and abolished the nociceptive hind limb crossed-extensor reflex. Fentanyl (30 microg/kg) also evoked tonic discharges of caudal medullary expiratory neurons in paralyzed mechanically ventilated cats, which might explain decreased chest compliance. The selective D(1)R agonists 6-chloro APB (3 mg/kg) or dihydrexidine (DHD, 1 mg/kg) increased depth and rate of spontaneous breathing after opioid depression and returned HbO(2) and ETCO(2) to control levels. Opioid arrest of the nociceptive reflex remained intact. Pretreatment with DHD prevented significant depression of spontaneous breathing by fentanyl (17.5 +/- 4.3 microg/kg). Tonic firing evoked by fentanyl in expiratory neurons was converted to rhythmic respiratory discharges by DHD (1 mg/kg). The results suggest that D(1)R agonists might be therapeutically useful for the treatment of opioid disturbances of breathing without impeding analgesia.     

Opiate slowing of feline respiratory rhythm and effects on putative medullary phase-regulating neurons

Opiates have effects on respiratory neurons that depress tidal volume and air exchange, reduce chest wall compliance, and slow rhythm. The most dose-sensitive opioid effect is slowing of the respiratory rhythm through mechanisms that have not been thoroughly investigated. An in vivo dose-response analysis was performed on medullary respiratory neurons of adult cats to investigate two untested hypotheses related to mechanisms of opioid-mediated rhythm slowing: 1) Opiates suppress intrinsic conductances that limit discharge duration in medullary inspiratory and expiratory neurons, and 2) opiates delay the onset and lengthen the duration of discharges postsynaptically in phase-regulating postinspiratory and late-inspiratory neurons. In anesthetized and unanesthetized decerebrate cats, a threshold dose (3 microg/kg) of the mu-opioid receptor agonist fentanyl slowed respiratory rhythm by prolonging discharges of inspiratory and expiratory bulbospinal neurons. Additional doses (2-4 microg/kg) of fentanyl also lengthened the interburst silent periods in each type of neuron and delayed the rate of membrane depolarization to firing threshold without altering synaptic drive potential amplitude, input resistance, peak action potential frequency, action potential shape, or afterhyperpolarization. Fentanyl also prolonged discharges of postinspiratory and late-inspiratory neurons in doses that slowed the rhythm of inspiratory and expiratory neurons without altering peak membrane depolarization and hyperpolarization, input resistance, or action potential properties. The temporal changes evoked in the tested neurons can explain the slowing of network respiratory rhythm, but the lack of significant, direct opioid-mediated membrane effects suggests that actions emanating from other types of upstream bulbar respiratory neurons account for rhythm slowing.     

正常猫膈神经单纤维电活动特征

在麻醉猫和麻痹的切断迷走神经的清醒猫,观察了膈神经单纤维电活动特征。1.电活动类型:按膈神经单纤维放电与其总干放电的相位关系分为三种类型。(1)完全同步型,即单纤维放电与总干放电同时开始并同时停止,占76.9％。(2)部分同步型占15.4％,其中早期同步,即单纤维放电与总干放电同时开始,但提前终止,占1.9％,中期同步,即单纤维放电较总干放电开始晚,又提前终止,占5.8％,晚期同步,即单纤维放电较总干放电开始晚,但两者同时终止,占7.7％。(8)非同步型,即吸气相和呼气相都有放电,但呼气相时冲动频率较低,占7.7％。前两型为单纯的吸气性放电,共占92.3％。2.单纤维放电平均参数值:麻醉猫每次吸气发放11个冲动,其频率为21次/秒,清醒猫每次吸气发放18个冲动,其频率为34次/秒。结果表明:猫膈神经单纤维放电类型和文献上报导的直接记录膈神经运动神经元放电一致,即以单纯的吸气性放电为最多。     

Mechanisms of abdominal muscle activation during vomiting

The possible contribution of spinal reflexes to abdominal muscle activation during vomiting was assessed in decerebrate cats. The activity of these muscles is partly controlled by bulbospinal expiratory neurons in the caudal ventral respiratory group (VRG). In a previous study it was found that the abdominal muscles are still active during vomiting after midsagittal lesion of the axons of these neurons between C1 and the obex (A.D. Miller, L.K. Tan, and I. Suzuki. J. Neurophysiol. 57: 1854-1866, 1987). The present experiments indicate that this postlesion activity was due to spinal stretch reflexes because 1) such midsagittal lesions eliminate abdominal muscle nerve activity during fictive vomiting in paralyzed cats in which there are no abdominal stretch reflexes, 2) the abdominal muscles are activated during vomiting by spinal reflexes after upper thoracic cord transections, and 3) the normal 100-ms delay between diaphragmatic and abdominal activation during vomiting is reduced to approximately 20-25 ms after both types of lesions, which is consistent with postlesion abdominal reflex activation. Our results also suggest that, during normal vomiting, abdominal stretch and tension reflexes have only a minor role if any and abdominal muscle activation is probably mediated primarily or exclusively by expiratory neurons in the caudal ventral respiratory group. However, our finding that phrenic activity is reduced both during vomiting after thoracic transections and during fictive vomiting after paralysis is consistent with a contribution of reflex activity from abdominal and/or intercostal muscles to phrenic discharge during normal vomiting.     

Involvement of ventral medullary surface in respiratory responses induced by 2,4-dinitrophenol

We examined the contribution of the neural elements near the ventral medullary surface (VMS) to the respiratory response caused by 2,4-dinitrophenol (DNP). Two series of experiments were performed on 12 vagotomized and sinoaortic denervated cats. The first series examined the effect of focal cooling of the VMS on the respiratory response to DNP in four spontaneously breathing, anesthetized cats. When the VMS temperature was 37 degrees C, systemic administration of DNP increased minute ventilation under nearly isocapnic conditions, and focal cooling of the intermediate area of VMS to 20 degrees C attenuated the ventilatory augmentation caused by DNP. To eliminate the influence of anesthetics, a second group of experiments was performed on eight decerebrate, artificially ventilated cats while phrenic nerve activity was monitored as an index of respiration. AgNO3 (10%) was topically applied to the VMS until the respiratory response to inhaled CO2 was abolished. Apnea occurred in seven of eight cats after AgNO3, whereas in the remaining one animal, tidal phrenic activity decreased substantially. Systemic administration of DNP produced no respiratory excitation in any of the animals. On the other hand, rhythmic respiratory activity could be provoked by electrical stimulation of the mesencephalic locomotor area and carotid sinus nerve and by excitation of somatic afferents. Histological examination of the brain stem showed that the AgNO3 had penetrated no more than 350 microns from the ventral medullary surface. These results indicate superficial structures of the VMS are of potential importance in mediating the respiratory responses to hypermetabolism.     

Responses of bulbospinal and laryngeal respiratory neurons to hypercapnia and hypoxia

The purpose was to evaluate activities of medullary respiratory neurons during equivalent changes in phrenic discharge resulting from hypercapnia and hypoxia. Decerebrate, cerebellectomized, paralyzed, and ventilated cats were used. Vagi were sectioned at left midcervical and right intrathoracic levels caudal to the origin of right recurrent laryngeal nerve. Activities of phrenic nerve and single respiratory neurons were monitored. Neurons exhibiting antidromic action potentials following stimulations of the spinal cord and recurrent laryngeal nerve were designated, respectively, bulbospinal or laryngeal. The remaining neurons were not antidromically activated. Hypercapnia caused significant augmentations of discharge frequencies for all neuronal groups. Many of these neurons had no change or declines of activity in hypoxia. We conclude that central chemoreceptor afferent influences are ubiquitous, but excitatory influences from carotid chemoreceptors are more limited in distribution among medullary respiratory neurons. Hypoxia will increase activities of neurons that receive sufficient excitatory peripheral chemoreceptor afferents to overcome direct depression by brain stem hypoxia. The possibility that responses of respiratory muscles to hypoxia are programmed within the medulla is discussed.     

兔孤束核腹外侧区微量注射谷氨酸钠及甘氨酸对膈神经放电的影响

实验在４０只麻醉、制动、断双侧颈迷走神经和人工通气的家兔上进行。在孤束核腹外侧区微量注射神经元胞体兴奋剂谷氨酸钠和抑制剂甘氨酸,探讨膈神经放电的变化。结果：微量注射谷氨酸钠,可使膈神经放电脉冲数明显增加,吸气时程延长,呼气时程缩短,呼吸频率变化不明显;微量注射甘氨酸,则膈神经放电脉冲数显著减少,甚至停止,吸气时程缩短,呼气时程不规则延长,呼吸频率降低。上述结果提示：孤束核腹外侧区对呼吸节律的形成具     

Central neural stimulation of respiration in unanesthetized decerebrate cats.

A previously reported central neural respiratory control process was restudied in unanesthetized decerebrate cats during spontaneous breathing, and during conditions of constant chemical stimulation where phrenic nerve activity was used to quantitate respiratory output. Respiration was increased by carotid sinus nerve stimulation. The pattern of respiration was examined at the cessation of such stimulation. In spontaneously breathing animals, active hyperventilation (HV) was followed by hyperpnea for up to 30 s and never by apnea. Passive HV was always followed by apnea. In animals with controlled chemical conditions, the transient at the end of stimulation consisted of two components, the first an immediate decrease in respiratory output and the second a slow decrease with a period of over 5 m. It is suggested that a facilitatory feedback process, probably located in the reticular activating system, maintains respiratory output for some time after cessation of a stimulus. This study duplicates the results of previous studies and shows that no area of the brain above the pons is required for the mechanism's operation.     

Efferent activity in the phrenic nerve during startle reflex in chloralose anesthetized cats

Efferent activity was investigated in the phrenic nerve during startle reflex manifesting as somatic nerve discharges (lower intercostal nerves and the nerve endings) in chloralose anesthetized cats. Inhibition (usually of short duration, lasting 23–36 msec) of inspiration activity was found to be the main component of response in the phrenic nerve in the shaping of "low threshold" startle reflex produced by acoustic and tactile stimuli and stimulation of low threshold peripheral afferents. Reflex discharge prevailed amongst the response patterns produced in the phrenic nerve by stimulating high threshold afferents, i.e., early (propriospinal) and late (suprasegmental, arising from stimulating intercostal nerve) or late only (when stimulating the hindlimb nerves). Two patterns of late response could be distinguished, one on inspiration (found in roughly 3 out of 4 experiments) and other on exhalation — the respiratory homologs of somatic startle reflex. Response pattern is described throughout the respiratory cycle. Structure and respiratory modulation of reflex responses produced in the phrenic nerve by stimulating bulbar respiratory structure are also examined. Possible neurophysiological mechanisms underlying phrenic response during the shaping of startle reflex are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 19, No. 4, pp. 473–482, July–August, 1987.     

Neurogenesis, control, and functional significance of gasping

Gasps are frequently the first and last breaths of life. Gasping, which is generated by intrinsic medullary mechanisms, differs fundamentally from other automatic ventilatory patterns. A region of the lateral tegmental field of the medulla is critical for the neurogenesis of the gasp but has no role in eupnea. Neuronal mechanisms in separate brain stem regions may be responsible for the neurogenesis of different ventilatory patterns. This hypothesis is supported by the recording of independent respiratory rhythms simultaneously from isolated brain stem segments. Data from fetal and neonatal animals also support gasping and eupnea being generated by separate mechanisms. Gasping may represent the output of a simple but rugged pattern generator that functions as a backup system until the control system for eupnea is developed. Pacemaker elements are hypothesized as underlying the onset of inspiratory activity in gasping. Similar elements, in a different brain stem region, may be responsible for the onset of the eupneic inspiration with neural circuits involving the pons, the medulla, and the spinal cord serving to shape efferent respiratory-modulated neural discharges.     

Persistence of central respiratory rhythmogenesis after maximal acetylcholinesterase inhibition in unanaesthetized cats

Cats were given systemically the anticholinesterase paraoxon at a dosage (3 mg/kg i.v.) that produced a maximal (over 90%) inhibition of brainstem acetylcholinesterase. All paralyzed and artificially ventilated animals were either unanaesthetized (decerebrated or ventilated with 70% nitrous oxide and 30% oxygen) or anaesthetized (with pentobarbital, alpha-chloralose, or halothane). In unanaesthetized cats, paraoxon produced an immediate rise in arterial blood pressure and did not suppress phrenic nerve respiratory discharges, while in anaesthetized animals it produced an immediate and long-lasting hypotension and a complete arrest of central respiratory activity. It is concluded that acetylcholine accumulation may not suppress respiratory rhythmogenesis and that most anaesthetics may considerably alter the response of cardiorespiratory cholinergic mechanisms to anticholinesterase administration.     

CO(2)/H(+) chemoreception in the cat pre-B?tzinger complex in vivo.

We examined the effects of focal tissue acidosis in the pre-B?tzinger complex (pre-B?tC; the proposed locus of respiratory rhythm generation) on phrenic nerve discharge in chloralose-anesthetized, vagotomized, paralyzed, mechanically ventilated cats. Focal tissue acidosis was produced by unilateral microinjection of 10-20 nl of the carbonic anhydrase inhibitors acetazolamide (AZ; 50 microM) or methazolamide (MZ; 50 microM). Microinjection of AZ and MZ into 14 sites in the pre-B?tC reversibly increased the peak amplitude of integrated phrenic nerve discharge and, in some sites, produced augmented bursts (i.e., eupneic breath ending with a high-amplitude, short-duration burst). Microinjection of AZ and MZ into this region also reversibly increased the frequency of eupneic phrenic bursts in seven sites and produced premature bursts (i.e., doublets) in five sites. Phrenic nerve discharge increased within 5-15 min of microinjection of either agent; however, the time to the peak increase and the time to recovery were less with AZ than with MZ, consistent with the different pharmacological properties of AZ and MZ. In contrast to other CO(2)/H(+) brain stem respiratory chemosensitive sites demonstrated in vivo, which have only shown increases in amplitude of integrated phrenic nerve activity, focal tissue acidosis in the pre-B?tC increases frequency of phrenic bursts and produces premature (i.e., doublet) bursts. These data indicate that the pre-B?tC has the potential to play a role in the modulation of respiratory rhythm and pattern elicited by increased CO(2)/H(+) and lend additional support to the concept that the proposed locus for respiratory rhythm generation has intrinsic chemosensitivity.     

Spectral analysis on fluctuation of heat period in paralyzed,vagotomized, and unanesthetized decerebrate cats

Spectral analysis was performed on the heart period fluctuation in vagotomized, paralyzed, and unanesthetized decerebrate cats. The heart period was measured as the time interval between successive R waves of the electrocardiograms. When end-tidal P _{CO 2} was set at the same level as that before immobilization, the power spectral density plot of the heart period fluctuation showed several distinct peaks: one peak corresponded to the frequency of the artificial ventilator and the others to its harmonics. In addition, the spectral density plot had another peak centered at the intrinsic respiratory frequency evaluated by recording efferent phrenic neural discharges. The amplitude of these spectral peaks tended to become greater when the end-tidal P _{CO 2}was increased by adding CO₂ to the input gas. Our results, therefore, provide evidence that the heart period is modulated not only by the artificial ventilation rhythm but also by the centrally generated respiratory rhythm, and suggested that the strength of such central interactions between cardiac and respiratory rhythms varies depending on the end-tidal P _{CO 2} level.     

Blocking of glutamate ionotropic receptors: Influence on the respiratory activity generated by medullo-spinal preparations of rats in hypoxia

We studied the influences of a non-competitive blocker of glutamate NMDA-receptors ketamune and of a competitive blocker of AMPA-kainate non-NMDA receptors, CNQX, on the respiratory activity generelated by superfusedin situ semi-isolated medullo-spinal preparations (SIMSP) of 3- to 4-day-old rats. We compared the ampes recorded under conditions of superfusion, a standard solution and the solution saturated with an anoxic isocapine gas mixture were compared; pO₂ in these solutions were 440±22 and 41±8 mm Hg, respectively. The experments were carried out with the ventrolateral medullary region (VLMR) left intact or after separation of its rostral part, which propertchonally corresponded to the chemosensitiveM zone. A 3-min-long hypoxic test initially evoked an increase in the frequency of inspiratory discharges (IR) in the phrenic nerve followed by a frequency drop within the final half of the test. After the rostral VLMR had been separated, the hypoxic test did not elicit a significant decrease in the IR frequency. After preliminary application of 1.0 or 10.0 μM ketamine or CNQX on intact preparations, the IR frequency under hypoxic conditions dropped within the first half of the test and increased in the second half, while the amplitude and integral intensity of these discharges were depressed more intensively than in hypoxia with no applications. Using ketamme and CNQX in the same concentrations resulted in significant drops in the amplitude, frequency, and integral intensity of IR recorde din the hypoxic test. Our experiments showed that in the early postnatal period glutamate ionotropic receptors of rostral VLMR neurons are involved in the control of IR frequency under hypoxic conditions. The possible role of glutamatergic control of the respiratory rhythm and mechanisms of the influences resulting from blocking of NMDA and non-NMDA receptors on the parameters of respiratory activity are discussed.     

Analysis of entrainment of respiratory rhythm by somatic afferent stimulation in cats using phase response curves

To elucidate how peripheral somatic afferents synchronize the respiratory rhythm to the exercise rhythm, the phrenic nerve activity in the vagotomized, paralyzed, and artificially ventilated cats anesthetized with chloralose-urethane was recorded during electrical stimulation of the superficial radial nerve afferents. At first, a single pulse train was given at various times of the respiratory cycle to obtain a phase-response curve (PRC). The stimulation given at mid to late expiration produced a phase advance, but the stimulation during inspiration produced no measurable phase shifts in most animals (8/10). The maximum phase advance changed depending on the stimulus intensity. The stronger the stimulus intensity, the greater became the maximum phase advance. Repetitive somatic afferent stimulation produced 1:1 entrainment of the respiratory frequency to the repetitive stimulation. Theoretical predictions on the stable entrainment phase and on the entrainment frequency range from the obtained PRC were close to the experimental results. The present study demonstrated the presence of a neuronal circuit synchronizing the respiratory rhythm to the periodic somatic afferents and the manner of how such entrainment occurs.     

Entrainment of respiratory rhythm to respiratory oscillations of arterial PCO2 in vagotomized dogs.

The aim of this study was to demonstrate that the medullary respiratory rhythm generator is capable of entraining to respiratory oscillations of arterial PCO2 (CO2 oscillations). We used 10 anesthetized, paralyzed, vagotomized, and mechanically ventilated dogs. First, rate of mechanical ventilation was manually adjusted so that it matched the dog's spontaneous respiratory rate, which established a constant phase relationship between the mechanical ventilation and the burst of phrenic neurogram (initial phase). Then this phase relationship was temporally disturbed by a brief electrical stimulation of the superior laryngeal nerve (SLN). In the control group, the initial phase and the steady-state phase relationship after SLN stimulation were randomly distributed within the phase plane, implying no interaction between the respiratory center and mechanical ventilation. In contrast, when CO2 output from the lung was increased 2.6-fold above the control level by venous CO2 loading, the initial phase and the steady-state phase after SLN stimulation were locked in such a way that the onset of the burst of phrenic neurogram coincided with the peak of CO2 oscillations. This was not demonstrated when the dog was made hyperoxic. We therefore conclude that the respiratory center could entrain to phasic chemical afferent inputs originating from CO2 oscillations, provided they are considerably amplified.