Recurrent hypoxic exposure and reflex responses during development in the piglet.

The effects of recurrent hypoxia on cardiorespiratory reflexes were characterized in anesthetized piglets at 2-10 d (n=15), 2-3 weeks (n=11) and 8-10 weeks (n=8). Responses of phrenic and hypoglossal electroneurograms (ENG(phr) and ENG (hyp)) to hypoxia (8% 0(2), bal N(2), 5 min), hypercapnia (7% CO(2) bal O(2), 5 min) and intravenous capsaicin were tested before and after recurrent exposure to 11 episodes of hypoxia (8% O(2) bal N(2), 5 min). In piglets 2-10 d, ENG(phr) response to hypoxia declined in proportion to the number of hypoxic exposures; however, ENG (hyp) response to hypoxia was unchanged. In piglets at 2-10 d, intracisternal injection of bicuculline (GABA(A) receptor antagonist) reversed effects of recurrent hypoxia on ENG(phr) hypoxic response, eliminated apnea during hypoxia, as well as the delay in appearance of ENG(phr) after hypoxia. The ENG(phr) response to 7% CO(2) inhalation also decreased after recurrent hypoxia; however, the ENG(phr) response to C-fiber stimulation by capsaicin was unaltered. Piglets at 2-3 and 8-10 weeks were resistant to the depressive effects of recurrent hypoxia on respiratory reflex responses. We conclude that the response of the anesthetized newborn piglet to recurrent hypoxia is dominated by increasing inhibition of phrenic neuroelectrical output during successive hypoxic exposures. Central GABAergic inhibition may contribute significantly to the cumulative effects of repeated hypoxia in the newborn piglet experimental model.

Carotid bodies and ventilatory response to hypoxia in aminophylline-treated piglets.

Peripheral chemoreceptors may be immature in neonatal animals, exhibiting maturational changes in the perinatal period. Even though methylxanthines are respiratory stimulants, many premature neonates do not respond to them. Thus, we hypothesized that carotid body activity is necessary for aminophylline to reverse hypoxia-induced respiratory depression. We exposed 16 anesthetized newborn piglets (age 2-7 days) to hypoxia (inhalation of 12% oxygen) for 5 min. Aminophylline (15 mg/kg iv) was administered either prior to (11 piglets) or following (5 piglets) carotid body denervation (CBD). Before CBD, hypoxia elicited transient initial increases in tidal volume (from 79 +/- 4 to 99 +/- 1% of maximum, mean +/- SE), minute ventilation (from 64 +/- 5 to 93 +/- 4%), and peak phrenic electroneurogram (from 63 +/- 8 to 91 +/- 6%, all P < 0.05). This was followed by a decrease in tidal volume, minute ventilation and phrenic electroneurogram (all P < 0.05). Prior to CBD, aminophylline pretreatment prevented the decrease in all the measures of respiratory output during late hypoxia. After CBD, hypoxia induced an initial and sustained depression of ventilation (tidal volume from 100 to 33 +/- 14%; frequency from 94 +/- 4 to 42 +/- 17%; minute ventilation from 100 to 32 +/- 14%, all P < 0.05) and phrenic electroneurogram (peak phrenic from 100 to 47 +/- 18%; minute phrenic from 85 +/- 6 to 55 +/- 21%, both P < 0.05). Administration of aminophylline after CBD did not prevent the profound respiratory depression elicited by hypoxia in the chemodenervated piglets.(ABSTRACT TRUNCATED AT 250 WORDS)

Central effects of endothelin on respiratory output during development.

Both endothelin-1 protein and endothelin-1 specific binding sites have been identified in areas of the medulla oblongata involved in respiratory control. We examined whether endothelin acting centrally affects respiratory output during early postnatal life. We initially examined the effect of intracisternally administrated endothelin on respiratory output in 10 2- to 18-day-old piglets. Endothelin-1 administration at 50 nmol to 1 mumol caused respiratory inhibition. We subsequently examined whether this response is mediated through chemosensitive areas of the ventral medulla. Endothelin-1 was microinjected into specific ventral or dorsal medullary regions in 31 14- to 22-day-old piglets. Microinjection of endothelin-1 (10 fmol to 0.1 pmol) just above the hypoglossal roots, lateral to the pyramids, and within 1 mm from the surface (n = 24) attenuated respiratory output, and complete apnea occurred with 1 pmol in all animals. However, microinjection of endothelin-1 3 mm below the ventral surface (n = 5) and into the dorsal medulla (n = 3) had no inhibitory effect. Comparable doses of angiotensin II (n = 5) and norepinephrine (n = 5) microinjected into the endothelin-1 sensitive area also did not influence respiratory output. These effects of endothelin-1 were not altered by prior endothelin-B receptor blockade (IRL-1038) but could be reversed by endothelin-A receptor blockade (BQ-610). These results suggest that endothelin-1 release may cause ventilatory depression mediated through endothelin-A receptors located in the chemosensitive areas of the ventrolateral medulla.

Development of cholinergic innervation and muscarinic receptor subtypes in piglet trachea.

We studied physiological and pharmacological maturation of cholinergic innervation to tracheal smooth muscle in piglets at three ages: < 7 days, 2-3 wk, and 10 wk. Change in tracheal tension was measured in vivo from a tracheal segment and normalized for its size. Electrical vagal stimulation induced a significantly weaker increase in tracheal tension at < 7 days when compared with 2-3 and 10 wk. In vivo studies employing vagal stimulation before and after topical application of pirenzepine (an M1 muscarinic receptor blocker) and in vitro pharmacological studies evaluating the inhibition of [3H]quinuclidinyl benzilate (QNB) binding by pirenzepine demonstrated that immature M1-receptor function could not account for the weak tracheal smooth muscle responses in the first week. Topical application of the cholinergic agonist methacholine to the tracheal segment also induced a significantly weaker contractile response at < 7 days when compared with 2-3 and 10 wk. Total density of muscarinic receptors, as well as the M1 and M3 muscarinic subtypes, was not statistically different among < 7-day-old, 1- to 3-wk-old, and adult animals. Receptor binding studies in 1-3 wk and adult animals demonstrated biphasic dose-dependent inhibition of [3H]QNB binding in tracheal smooth muscle membranes by methacholine, with a high-affinity component dependent on the availability of G protein. These high-affinity muscarinic receptors coupled to G protein were absent in < 7-day-old piglets. We speculate that the weak tracheal smooth muscle contraction observed during the first week of life is in part secondary to immature G protein function.

Regulation of expiratory muscles during postnatal development in anesthetized piglets.

We compared maturation of the responses of the rib cage [triangularis sterni (TS)] and abdominal [transversus abdominis (TA)] expiratory muscles with each other and with the responses of the diaphragm (DIA) during hypercarbic and hypoxic stimulation. Studies were performed in anesthetized (urethan and chloralose) piglets of two age groups (< 6 days, n = 10; 14-21 days, n = 11) before and after bilateral cervical vagotomy. Hypercarbia (7% CO2-93% O2) was associated with comparable sustained increases in the minute electromyograms (EMGs) of both TS and TA, which were closely coupled to the DIA responses in both age groups. Hypoxia (12% O2-88% N2) caused a biphasic response of the minute EMG of both expiratory muscles and DIA; these biphasic responses were less prominent at 14-21 days than at < 6 days. Vagotomy caused an increase in the amplitude of both TS and TA (38 +/- 30 and 27 +/- 21%, respectively) as well as the DIA (45 +/- 16%) but did not affect their relative responses to chemostimulation. We conclude that during postnatal development 1) the rib cage and abdominal expiratory muscle responses to chemostimulation are coupled to each other and parallel those of the DIA and 2) the presence of vagal afferents attenuates the drive to both inspiratory and expiratory motoneurons under the current experimental conditions but does not influence the relative responses of expiratory muscles and DIA to hypercarbia or hypoxia. We speculate that comparable activation of inspiratory and expiratory pumping muscles serves to stabilize respiratory control in the face of altered chemosensory or vagal inputs during early postnatal life.

Response of upper airway and chest wall muscles to selective brain stem hypoxia in the newborn.

In animals with intact peripheral chemosensory afferents, hypoxia differentially affects upper airway (UA) and chest wall muscles. To determine the contribution of brain stem (BS) hypoxia to the response of UA and chest wall muscles during early life, we perfused the BS through a vertebral artery intermittently with blood from an extracorporeal circuit in nine newborn piglets (age 1-5 days). BS perfusions were performed with hypoxemic blood (arterial PO2 32 +/- 6 to 38 +/- 8 Torr) with different levels of BS PCO2 (28 +/- 2, 37 +/- 4, and 56 +/- 5 Torr) while systemic normocapnic hyperoxia was maintained (arterial PCO2 36 +/- 3 to 40 +/- 6 Torr, arterial PO2 345 +/- 73 to 392 +/- 37 Torr). Electromyograms (EMGs) of alae nasi (AN), external intercostal (EI), and diaphragm (DIA) were recorded. Normocapnic hypoxia of the BS induced a sustained increase in AN EMG (P < 0.01, analysis of variance) and depression of EI and DIA EMGs without a transient increase. These contrasting responses were also observed during hypocapnic and hypercapnic hypoxia of the BS and were not affected by inputs from the peripheral chemoreceptors or rostral cerebral structures that were not exposed to hypoxia. We conclude that, despite eliciting the known central respiratory depression, BS hypoxia causes an increase in the respiratory drive to an UA airway muscle. Thus, BS hypoxia elicits a selective rather than a generalized respiratory muscle depression. The respiratory muscles with high energy expenditure (DIA and EI) are depressed while UA muscles are stimulated or disinhibited. This response is independent of the level of BS arterial PCO2.

Tracheal smooth muscle responses to substance P and neurokinin A in the piglet.

The tachykinins substance P (SP) and neurokinin A (NKA) have been shown to induce airway smooth muscle contraction in mature animals, and the enzyme neutral endopeptidase (NEP) modulates this effect. We evaluated maturation of SP- and NKA-induced tracheal smooth muscle contraction and modulation of their effects by NEP in anesthetized, paralyzed, and artificially ventilated piglets less than 4 days, 2-3 wk, and 10 wk of age. Tracheal smooth muscle tension was measured in vivo from an open tracheal segment by use of a force transducer. Intravenous SP caused a dose-dependent increase in tracheal tension in all three age groups; however, the response in less than 4-day-old piglets was significantly weaker than in 2- to 3- and 10-wk-old piglets. NKA caused a dose-dependent increase in tracheal tension only in 2- to 3- and 10-wk-old piglets. The response of tracheal tension to NKA was weaker than the response to SP in all age groups. Atropine (2 mg/kg) significantly diminished the responses of tracheal tension to SP and NKA, indicating a cholinergic contribution to these responses at all ages. Intravenous thiorphan, a known NEP inhibitor, potentiated the effects of SP only in 2- to 3- and 10-wk-old piglets and did not affect the response of tracheal tension to NKA at any age. Biochemical analyses demonstrated a significant increase in tracheal NEP activity in comparably aged piglets over the first 10 wk of life.(ABSTRACT TRUNCATED AT 250 WORDS)

Maturation of respiratory reflex responses in the piglet.

Stimulation of chemo-, irritant, and pulmonary C-fiber receptors reflexly constricts airway smooth muscle and alters ventilation in mature animals. These reflex responses of airway smooth muscle have, however, not been clearly characterized during early development. In this study we compared the maturation of reflex pathways regulating airway smooth muscle tone and ventilation in anesthetized, paralyzed, and artificially ventilated 2- to 3- and 10-wk-old piglets. Tracheal smooth muscle tension was measured from an open tracheal segment by use of a force transducer, and phrenic nerve activity was measured from a proximal cut end of the phrenic nerve. Inhalation of 7% CO2 caused a transient increase in tracheal tension in both age groups, whereas hypoxia caused no airway smooth muscle response in either group. The phrenic responses to 7% CO2 and 12% O2 were comparable in both age groups. Lung deflation and capsaicin (20 micrograms/kg iv) administration did not alter tracheal tension in the younger piglets but caused tracheal tension to increase by 87 +/- 28 and 31 +/- 10%, respectively, in the older animals (both P less than 0.05). In contrast, phrenic response to both stimuli was comparable between ages: deflation increased phrenic activity while capsaicin induced neural apnea. Laryngeal stimulation did not increase tracheal tension but induced neural apnea in both age groups. These data demonstrate that between 2 and 10 wk of life, piglets exhibit developmental changes in the reflex responses of airway smooth muscle situated in the larger airways in response to irritant and C-fiber but not chemoreceptor stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)

Reflex and chemical responses of tracheal submucosal glands in piglets.

In adult animals, airway fluid secretion is enhanced reflexly via central nervous system pathways, and locally by mediators such as substance P. To evaluate the role of maturation on these regulatory mechanisms, we compared the effects of reflex stimulation and intravenous substance P administration on airway secretion in anesthetized, paralyzed and artificially ventilated piglets, 9 to 22 days of age, and older piglets all aged 10 weeks. Airway secretion was monitored by counting the hillocks appearing in the upper trachea in an exposed field of tracheal epithelium (1.2 cm2) coated with powdered tantalum. In younger animals, mechanical stimulation of the larynx had no discernible effect on tracheal submucosal gland secretion. Neither excitation of airway irritant receptors nor stimulation of pulmonary C-fiber receptors by capsaicin caused a significant increase of fluid secretion from tracheal submucosal glands. In addition, stimulation of peripheral chemoreceptors by ventilating animals with 12% O2 in N2, and 6% O2 in N2, failed to induce a substantial change in airway secretion, when compared with number of hillocks in the control period. Furthermore, administration of sodium cyanide had little or no effect on baseline secretion. In contrast, to the weak reflex responses in younger piglets electrical stimulation of the vagus nerve caused the number of hillocks to increase on average by 16.3 +/- 2.3 (P less than 0.01). In addition, local application of a pledget soaked in solution of methacholine caused the number of hillocks to increase by 32.1 +/- 5.2 (P less than 0.01). Intravenous administration of substance P also induced an augmentation in fluid secretion. Increase in concentration of substance P (10(-8), 10(-7), 10(-6), and 10(-5) M, 1 ml) was associated with a concomitant elevation in the number of activated submucosal glands (5.3 +/- 2.6, 10.0 +/- 4.4, 27.1 +/- 4.5, 41 +/- 5). In older piglets, stimulation of laryngeal mucosa, airway irritant receptors, as well as stimulation of pulmonary C-fiber receptors induced a significant increase in tracheal secretion, although stimulation of peripheral chemoreceptors had no effect on airway secretion. These data suggest that reflex responses of submucosal glands are weak during early postnatal development, however, tracheal submucosal glands do respond to exogenously administered cholinergic substances and tachykinin peptides.