Electrical activity of phrenic nerve and diaphragm in utero

Phrenic nerve activity, diaphragmatic EMG, and tracheal or pleural pressure changes were recorded in a chronic fetal sheep preparation. Three patterns of fetal phrenic nerve activity were observed: 1) a single burst; 2) irregular nonrhythmic bursts; and 3) prolonged rhythmic activity, seen only prior to fetal death. The total recording time was 54.53 h and the total duration of phrenic nerve activity was 65.34 min (2.16%). When an inactive period was defined as the absence of phrenic nerve activity for 60 s or more, active periods occupied 44.7% of the total time. Phrenic nerve activity was present in all fetuses and 97.5% of the time was coupled with diaphragmatic EMG. Both diaphragmatic EMG and intrapulmonary pressure changes occurred in the absence of phrenic nerve activity. In three fetal animals both phrenic nerves were transected. Tracheal pressure changes were seen which were not coupled with corresponding intrauterine pressure changes. Thus, changes in fetal tracheal pressure or diaphragmatic EMG do not necessarily represent the output of the fetal respiratory center. This study suggests that the fetal respiratory center is active in utero, but this activity is minimal and has a different pattern that that present after birth.

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Spontaneous phrenic nerve activity in the exteriorized fetal lamb

Journal of Applied Physiology ◽

10.1152/jappl.1975.39.1.124 ◽

1975 ◽

Vol 39 (1) ◽

pp. 124-128 ◽

Cited By ~ 3

Author(s):

I. Wyszogrodski ◽

H. W. Taeusch ◽

R. L. Williams

Keyword(s):

Neural Activity ◽

Phrenic Nerve ◽

High Frequency ◽

Single Unit ◽

Nervous Activity ◽

Nerve Activity ◽

Phrenic Nerve Activity ◽

Tracheal Pressure ◽

Fetal Lamb ◽

Pressure Changes

Phrenic nerve activity and tracheal pressure changes were recorded in four exteriorized fetal lambs (120–135 days gestation) from lightly anesthetized ewes to study possible mechanisms involved in the establishment of rhythmical breathing patterns. Two types of spontaneous neural activity were found. The first consisted of high-frequency multiunit bursts (mean duration 820 ms; range 450–2,500 ms) that preceded a gasp. Individual units within these bursts reached peak discharge frequencies as high as 40 impulses/s. The second type of neural activity consisted of single-unit, low-frequency (1–14 impulses/s), irregular background discharges lasting up to several seconds without changes in tracheal pressure. Occasionally, higher frequency bursts of single-unit activity were detected that were also unassociated with tracheal pressure changes. The data indicate that the neural correlate of a fetal gasp includes high-frequency synchronized bursting activity in the phrenic nerve. In addition, background phrenic activity can be detected in the exteriorized fetal lamb that reflects central nervous activity in the absence of tracheal pressure changes.

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Microinjections of glycine into the pre-Bötzinger complex inhibit phrenic nerve activity in the rat

Brain Research ◽

10.1016/s0006-8993(02)02902-5 ◽

2002 ◽

Vol 947 (1) ◽

pp. 25-33 ◽

Cited By ~ 7

Author(s):

V.C Chitravanshi ◽

H.N Sapru

Keyword(s):

Phrenic Nerve ◽

Nerve Activity ◽

Phrenic Nerve Activity ◽

Bötzinger Complex

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Daily acute intermittent hypoxia enhances phrenic motor output and stimulus-evoked phrenic responses in rats

Journal of Neurophysiology ◽

10.1152/jn.00112.2021 ◽

2021 ◽

Author(s):

Raphael Rodrigues Perim ◽

Michael D. Sunshine ◽

Joseph F. Welch ◽

Juliet Santiago ◽

Ashley Holland ◽

...

Keyword(s):

Motor Neurons ◽

Phrenic Nerve ◽

Intermittent Hypoxia ◽

Neural Control ◽

Respiratory Cycle ◽

Evoked Responses ◽

Nerve Activity ◽

Synaptic Inputs ◽

Phrenic Nerve Activity ◽

The Impact

Plasticity is a hallmark of the respiratory neural control system. Phrenic long-term facilitation (pLTF) is one form of respiratory plasticity characterized by persistent increases in phrenic nerve activity following acute intermittent hypoxia (AIH). Although there is evidence that key steps in the cellular pathway giving rise to pLTF are localized within phrenic motor neurons (PMNs), the impact of AIH on the strength of breathing-related synaptic inputs to PMNs remains unclear. Further, the functional impact of AIH is enhanced by repeated/daily exposure to AIH (dAIH). Here, we explored the effects of AIH vs. 2 weeks of dAIH preconditioning on spontaneous and evoked responses recorded in anesthetized, paralyzed (with pancuronium bromide) and mechanically ventilated rats. Evoked phrenic potentials were elicited by respiratory cycle-triggered lateral funiculus stimulation at C2 delivered prior to- and 60 min post-AIH (or an equivalent time in controls). Charge-balanced biphasic pulses (100 µs/phase) of progressively increasing intensity (100 to 700 µA) were delivered during the inspiratory and expiratory phases of the respiratory cycle. Although robust pLTF (~60% from baseline) was observed after a single exposure to moderate AIH (3 x 5 min; 5 min intervals), there was no effect on evoked phrenic responses, contrary to our initial hypothesis. However, in rats preconditioned with dAIH, baseline phrenic nerve activity and evoked responses were increased, suggesting that repeated exposure to AIH enhances functional synaptic strength when assessed using this technique. The impact of daily AIH preconditioning on synaptic inputs to PMNs raises interesting questions that require further exploration.

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Evaluation of a New Valveless all Purpose Ventilator: Effect of Ventilating Frequency PEEP, PACO2 and PAO2 on Phrenic Nerve Activity

Perspectives in High Frequency Ventilation - Developments in Critical Care Medicine and Anesthesiology ◽

10.1007/978-94-009-6711-3_15 ◽

1983 ◽

pp. 140-145 ◽

Cited By ~ 2

Author(s):

M. K. Chakrabarti ◽

J. G. Whitwam

Keyword(s):

Phrenic Nerve ◽

Nerve Activity ◽

Phrenic Nerve Activity

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Influence of the ventral surface of the medulla on tracheal responses to CO2

Journal of Applied Physiology ◽

10.1152/jappl.1986.61.3.1091 ◽

1986 ◽

Vol 61 (3) ◽

pp. 1091-1097 ◽

Cited By ~ 19

Author(s):

E. C. Deal ◽

M. A. Haxhiu ◽

M. P. Norcia ◽

J. Mitra ◽

N. S. Cherniack

Keyword(s):

Motor Activity ◽

Phrenic Nerve ◽

Ventral Surface ◽

Intermediate Area ◽

Tracheal Pressure ◽

Cervical Trachea ◽

Airway Responses ◽

Airway Tone ◽

Pressure Changes ◽

Nerve Discharge

These studies investigated the role of the intermediate area of the ventral surface of the medulla (VMS) in the tracheal constriction produced by hypercapnia. Experiments were performed in chloralose-anesthetized, paralyzed, and artificially ventilated cats. Airway responses were assessed from pressure changes in a bypassed segment of the rostral cervical trachea. Hyperoxic hypercapnia increased tracheal pressure and phrenic nerve activity. Intravenous atropine pretreatment or vagotomy abolished the changes in tracheal pressure without affecting phrenic nerve discharge. Rapid cooling of the intermediate area reversed the tracheal constriction produced by hypercapnia. Graded cooling produced a progressive reduction in the changes in maximal tracheal pressure and phrenic nerve discharge responses caused by hypercapnia. Cooling the intermediate area to 20 degrees C significantly elevated the CO2 thresholds of both responses. These findings demonstrate that structures near the intermediate area of the VMS play a role in the neural cholinergic responses of the tracheal segment to CO2. It is possible that neurons or fibers in intermediate area influence the motor nuclei innervating the trachea. Alternatively, airway tone may be linked to respiratory motor activity so that medullary interventions that influence respiratory motor activity also alter bronchomotor tone.

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Effects of hypercapnia and hypoxia on phrenic nerve activity and respiratory timing

Journal of Applied Physiology ◽

10.1152/jappl.1981.51.3.732 ◽

1981 ◽

Vol 51 (3) ◽

pp. 732-738 ◽

Cited By ~ 18

Author(s):

J. F. Ledlie ◽

S. G. Kelsen ◽

N. S. Cherniack ◽

A. P. Fishman

Keyword(s):

Phrenic Nerve ◽

Carotid Sinus ◽

Peak Height ◽

Inspiratory Time ◽

Nerve Activity ◽

Phrenic Nerve Activity ◽

Chemical Stimuli ◽

Proprioceptive Inputs ◽

Spontaneously Breathing ◽

Respiratory Responses

In the spontaneously breathing animal, respiratory responses to chemical stimuli are influenced by phasic proprioceptive inputs from the thorax. We have compared the effects of hypercapnia and hypoxia on the level and timing of phrenic nerve activity while these phasic afferent signals were absent. Progressive hyperoxic hypercapnia and isocapnic hypoxia were produced in anesthetized paralyzed dogs by allowing 3–5 min of apnea to follow mechanical ventilation with 100% O2 or 35% O2 in N2, respectively; during hypoxia, isocapnia was maintained by intravenous infusion of tris(hydroxymethyl)aminomethane buffer. The peak height (P) of nerve bursts, inspiratory time (TI), and expiratory time (TE) were measured from the phrenic neurogram. With the vagi intact or severed, hypoxia decreased TI, whereas hypercapnia did not; both stimuli decreased TE. At the same minute phrenic activity (P x frequency), P, TI, and TE were all less during hypoxia than during hypercapnia. The decreases in TI and TE with hypoxia were significantly less after carotid sinus denervation. The results indicate that the patterns of phrenic nerve activity in response to hypoxia and hypercapnia are different: hypoxia has a greater effect on respiratory timing, whereas hypercapnia has a greater effect on peak phrenic nerve activity. The effect of hypoxia on respiratory timing is largely mediated by the peripheral chemoreceptors.

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