| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
1 Department of Physiology, University of Cambridge, Downing Street, Cambridge, CB2 3EG, UK
 |
Abstract |
|---|
 Top Abstract IntroductionMethodsResultsDiscussionReferences |
|---|
(Received 7 October 2004;
accepted after revision 14 December 2004;
first published online 20 December 2004)
Corresponding author D. A. Giussani: Department of Physiology, University of Cambridge, Downing Street, Cambridge CB2 3EG, UK. Email: dag26{at}cam.ac.uk
|
Introduction |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
The fetal defence to acute hypoxaemia involves cardiovascular responses that redistribute the combined ventricular output towards essential vascular beds such as the umbilical, adrenal, myocardial and cerebral circulations (for reviews, see Rudolph, 1984 and Giussani et al. 1994a,b). Redistribution of blood flow is largely accomplished by peripheral vasoconstriction, which is triggered by a carotid chemoreflex (Giussani et al. 1993) and then maintained or subsequently modified by endocrine (Iwamoto, 1990; Giussani et al. 1994b; Fletcher et al. 2000) and local components (Vane et al. 1990; Morrison et al. 2003). The resulting increase in pressure-dependent perfusion through the cerebral, myocardial and adrenal vascular beds is further facilitated by active vasodilatation (Carter et al. 1993; Thornburg et al. 2000; Riquelme et al. 2002; Blood et al. 2003). In contrast to the adrenal, myocardial and cerebral circulations, the physiological mechanisms maintaining perfusion of the umbilical vascular bed during adverse intrauterine conditions remain comparatively less well understood.
Calcitonin gene-related peptide (CGRP) is the most potent endogenous vasodilator peptide known (Brain et al. 1985). Recently it has been shown that CGRP has a powerful vasodilator action, which in part is mediated via nitric oxide (NO), in vivo in the ovine fetal lung (Takahashi et al. 2000) and in vitro in the human umbilical artery and vein (Dong et al. 2004). However the in vivo role of CGRP in the control of the umbilical vascular bed during basal or stressful conditions has not been investigated. The present study tested the hypothesis that CGRP plays an important role in the maintenance of umbilical blood flow during acute hypoxaemia in the fetus. Late gestation fetal sheep surgically prepared for long-term recording in the conscious state were used as an experimental model. The hypothesis was tested by investigating the effects of fetal treatment with a selective CGRP antagonist on in vivo umbilical haemodynamics via an indwelling Transonic flow probe during basal and hypoxaemic conditions.
|
Methods |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
All procedures were performed under the UK Animals (Scientific Procedures) Act 1986 and were approved by the Ethical Review Committee of the University of Cambridge. Five Welsh Mountain sheep fetuses, at 120 ± 2 days of gestation (term is 
145 days), were surgically prepared for long-term recording using strict aseptic conditions as previously described in detail (Giussani et al. 2001). In brief, food, but not water, was withheld from the pregnant ewes for 24 h prior to surgery. Following induction with 20 mg kg–1
I.V. sodium thiopentone (Intraval Sodium; Merial Animal Health Ltd; Rhone Mérieux, Dublin, Ireland), general anaesthesia (1.5–2.0% halothane in 50 : 50 O2 : N2O) was maintained using positive pressure ventilation. Midline abdominal and uterine incisions were made, the fetal hind limbs were exteriorized and on one side femoral arterial (i.d., 0.86 mm; o.d., 1.52 mm; Critchly Electrical Products, NSW, Australia) and venous (i.d., 0.56 mm; o.d., 0.96 mm) catheters were inserted. The catheter tips were advanced carefully to the ascending aorta and superior vena cava, respectively. Another catheter was anchored onto the fetal hind limb for recording of the reference amniotic pressure. In addition, a transit-time flow transducer (4SB; Transonic Systems Inc., Ithaca, NY, USA) was placed around one of the umbilical arteries, close to the common umbilical artery, inside the fetal abdominal cavity, for continuous measurement of unilateral umbilical blood flow (Gardner et al. 2001). The fetus was returned to the uterine cavity, the uterine incisions were closed in layers, the dead space of the catheters was filled with heparinized saline (80 i.u. heparin ml–1 in 0.9% NaCl) and the catheters' ends were plugged with sterile brass pins. The catheters and flow probe lead were then exteriorised via a key-hole incision in the maternal flank and kept inside a plastic pouch sewn onto the maternal skin.
Postoperative care
The ewes were housed in individual pens with free access to hay and water, in rooms with a 12 h : 12 h dark : light cycle. They were fed concentrates twice daily (100 g; sheep nuts no. 6; H & C Beart Ltd, Kings Lynn, UK). All ewes received postoperative analgesia (10–20 mg kg–1 oral Penylbutazone; Equipalozone paste, Arnolds Veterinary Products Ltd, Shropshire, UK) and antibiotics (0.20–0.25 mg kg–1 I.M. Depocillin; Mycofarm, Cambridge, UK). The patency of the fetal catheters was maintained by a slow continuous infusion of heparinised saline (80 i.u. heparin ml–1 at 0.1 ml h–1 in 0.9% NaCl) containing antibiotic (1 mg ml–1 benzylpenicillin; Crystapen, Schering-Plough, Animal Health Division, Welwyn Garden City, UK). In addition, the fetuses also received daily antibiotics (150 mg kg–1 Penbritin, SmithKline Beecham Animal Health, Welwyn Garden City, Hertfordshire, UK) I.V and into the amniotic cavity.
Experimental protocol
Following at least 5 days of postoperative recovery, all fetuses were subjected to two experimental protocols, carried out on consecutive days in randomised order. Each protocol consisted of a 2.5 h period divided into1 h normoxia, 0.5 h hypoxaemia and 1 h recovery, during either a slow I.V. infusion of vehicle (80 i.u. heparin ml–1 in 0.9% NaCl) or during fetal treatment with a selective CGRP antagonist (50 µg kg–1
I.A. bolus followed by 20 µgmin–1
I.V. infusion; calcitonin gene related peptide fragment 8–37, CGRP8-37; C-2806; Sigma Chemicals, UK, Fig. 1) which was made in a solution of heparinised saline, identical to that of the vehicle. Acute hypoxaemia in the fetus was induced by maternal inhalational hypoxia. In brief, a large transparent respiratory hood was placed over the ewe's head into which air was passed at a rate of 50 l min–1 for the 1 h period of normoxia. Following this control period, acute fetal hypoxaemia was induced for 30 min by changing the concentrations of gases breathed by the ewe to 6% O2 in N2 with small amounts of CO2 (15 l min–1 air : 35 l min–1 N2 : 1.5–2.5 l min–1 CO2). This mixture was designed to reduce fetal Pa,O2 to 9 mmHg while maintaining Pa,CO2. Following the 0.5 h period of hypoxaemia, the ewe was returned to breathing air for the 1 h recovery period. The dose of CGRP antagonist was chosen from a previous study by Takahashi et al. (2000). In that study, treatment of late gestation fetal sheep with a similar dose of the CGRP antagonist markedly diminished the vasodilator response of the pulmonary vascular bed to exogenous treatment with CGRP. In the present study, fetal treatment with the CGRP antagonist started 30 min before the onset of hypoxaemia and ran continuously until the end of the hypoxaemic challenge. During any acute hypoxaemia protocol, descending aortic blood samples were taken from the fetus at set intervals (arrows; Fig. 1) to determine arterial blood gas and acid base status (ABL5 blood gas Analyser, Radiometer, Copenhagen, Denmark; measurements corrected to 39.5°C; Fig. 1). At the end of the experimental protocol, the ewes and fetuses were killed painlessly using a lethal dose of sodium pentobarbitone (200 mg kg–1
I.V. Pentoject; Animal Ltd, York, UK), the positions of the implanted catheters and the flow probe were confirmed and the fetuses were weighed.
|
Calibrated mean fetal arterial blood pressure (corrected for amniotic pressure) and mean umbilical blood flow were recorded continually at 1 s intervals using a computerised Data Acquisition System (Department of Physiology, Cambridge University, UK). Umbilical vascular conductance was calculated by dividing mean umbilical blood flow by mean supra-amniotic arterial blood pressure. Values for all variables are expressed as mean ± S.E.M. Cardiovascular variables are expressed as minute averages of either absolute values or of the absolute change from mean normoxic baseline. Summary measure analysis was then applied to the serial data to focus the number of comparisons, and areas under the curve were calculated for the absolute change from baseline for statistical comparison, as previously described in detail (Matthews et al. 1990). Variables were assessed using two-way ANOVA with repeated measures (Sigma-Stat; SPSS Inc., Chicago, IL, USA), comparing the effect of time (normoxia versus hypoxaemia/recovery), group (control versus CGRP antagonist) and interactions between time and group. Where a significant effect of time or group was indicated, the post hoc Student–Newman–Keuls test was used to isolate the statistical difference. For all comparisons, statistical significance was accepted when P < 0.05.
|
Results |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
Basal values for arterial blood gas and acid base status were similar in fetuses during saline infusion or during treatment with the CGRP antagonist. In all fetuses, acute hypoxaemia induced significant falls in arterial pH (pHa), arterial partial pressure of oxygen (Pa,O2), percentage saturation of haemoglobin with oxygen (Sat Hb) and acid base excess (ABE) without any alteration to arterial partial pressure of carbon dioxide (Pa,CO2) (Fig. 2). The magnitude of these changes was similar during saline infusion or during treatment with the CGRP antagonist. During recovery, both Pa,O2 and Sat Hb recovered to basal values in all fetuses. In contrast fetal pHa and ABE remained significantly lower than basal values until the end of the experimental protocol.
|
Basal values for fetal arterial blood pressure (62.5 ± 1.7 versus 61.1 ± 1.5 mmHg), unilateral umbilical blood flow (132 ± 9 versus 140 ± 14 ml min–1) and umbilical vascular conductance (2.1 ± 0.2 versus 2.3 ± 0.3 (ml min–1 mmHg–1) were similar in fetuses during saline infusion or during treatment with the CGRP antagonist, respectively (Fig. 3). During acute hypoxaemia, a significant increase in arterial blood pressure occurred in all fetuses during either saline infusion or during treatment with the CGRP antagonist, with arterial blood pressure increasing from baseline by 16.9 ± 2.0 and 17.4 ± 1.9 mmHg, respectively (Figs 3 and 4). In contrast, while umbilical blood flow (from 132 ± 9 to 198 ± 15 ml min–1) and umbilical vascular conductance (from 2.1 ± 0.2 to 2.7 ± 0.2 (ml min–1 mmHg–1) increased during the hypoxaemic period in fetuses during saline infusion, pronounced falls in both umbilical blood flow (from 140 ± 14 to 90 ± 10 ml min–1) and umbilical vascular conductance (from 2.3 ± 0.3 to 1.3 ± 0.2 ml min–1 mmHg–1) occurred early during the hypoxaemic period in fetuses during treatment with the CGRP antagonist (Figs 3 and 4). After 10 min of acute hypoxaemia during treatment with the CGRP antagonist, umbilical flow and vascular conductance returned towards basal values. By the end of the hypoxaemic challenge during the antagonist infusion, umbilical flow had increased to values above baseline (from 140 ± 13 to 187 ± 18 ml min–1), and umbilical vascular conductance had recovered to basal values (from 2.3 ± 0.3 to 2.5 ± 0.2 ml min–1 mmHg–1, Figs 3 and 4). During recovery, values for arterial blood pressure and umbilical blood flow remained significantly elevated by the end of the experimental protocol in all fetuses, during either saline infusion or treatment with the CGRP antagonist (Figs 3 and 4).
|
|
|
Discussion |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
Previous investigations from this laboratory, which have measured continuous changes in flow in the umbilical vascular bed, have reported increases in umbilical blood flow during acute hypoxaemia as a result of pressure-dependent (Gardner et al. 2001) and pressure-independent mechanisms (Gardner & Giussani, 2003). Past data show that during moderate fetal hypoxaemia (i.e. a decrease in fetal Pa,O2 to 13 mmHg) there are equivalent elevations in arterial blood pressure and umbilical blood flow with no changes in umbilical vascular conductance. This suggests that during moderate fetal hypoxaemia, maintenance of umbilical perfusion is entirely pressure dependent (van Huisseling et al. 1991). However, in fetuses which have previously suffered a sustained period of intrauterine adversity, the increase in umbilical blood flow during moderate acute hypoxaemia is greater than can be accounted for by the increase in perfusion pressure (Gardner & Giussani, 2003). Therefore, in pregnancies complicated by chronic adverse intrauterine conditions, pressure-independent mechanisms may become recruited to induce an increase in umbilical conductance, signifying active vasodilatation of the umbilico-placental vascular beds. Additional data suggest that, under these conditions, recruited pressure-independent mechanisms elicit vasodilatation via an increased production of NO (Gardner & Giussani, 2003), although their identity remains unknown.
Increasing clinical (Franco-Cereceda et al. 1987; Gennari et al. 1990; Hasbak et al. 2002; Hasbak et al. 2003) and scientific (DiPette et al. 1987; Dhillo et al. 2003) evidence suggests a role for the novel and potent vasodilator peptide CGRP in cardiovascular regulation in the adult circulation. In addition, increased levels of CGRP during pregnancy (Saggese et al. 1990), in cord blood and human neonatal blood (Parida et al. 1998), and its distribution at the site of implantation (Tsatsaris et al. 2002) and throughout the human placenta (Graf et al. 1996; Lafond et al. 1997) suggest a vasomotor role for the peptide in the feto-placental vascular beds. In the present study, we investigated whether CGRP is a potential candidate for mediating pressure-independent increases in umbilical blood flow in the late gestation fetus during stressful conditions, and tested the hypothesis that CGRP plays an important role in the umbilical vascular bed during basal and hypoxaemic conditions. In this study, acute severe hypoxaemia (reducing the fetal Pa,O2 to 9 mmHg) during a background of saline infusion also led to greater increases in umbilical blood flow than could be accounted for by the magnitude of the fetal hypertension alone. Consequently, during acute severe hypoxaemia a significant increase in umbilical vascular conductance occurred. Fetal treatment with a selective CGRP antagonist did not modify basal umbilical haemodynamics but caused pronounced falls in both umbilical blood flow and umbilical vascular conductance during acute hypoxaemia. Therefore, these data support the hypothesis tested and suggest that during acute severe hypoxaemia, pressure-independent mechanisms mediated by CGRP are recruited to maintain or increase umbilical perfusion. Interestingly, as the hypoxaemic challenge progressed during treatment with the CGRP antagonist, umbilical vascular conductance returned to basal levels and increased above baseline during the recovery period. This suggests that, at this time, additional vasoactive mechanisms may become recruited to compensate for the loss of the potent umbilical vasodilator
CGRP. Such agents may include prostaglandin E2 (Young & Thorburn, 1994), oestrogen (Rosenfeld et al. 1996), corticotrophin releasing hormone (Perkins & Linton, 1995) and adenosine (Read et al. 1993). They may act to modify fetal vasomotor responses to acute hypoxaemia either by nitric oxide-dependent or nitric oxide-independent mechanisms.
Combined, past and present data therefore suggest that pressure-dependent mechanisms suffice to maintain adequate perfusion of the umbilical vascular bed during fetal exposure to acute moderate hypoxaemia. However, when the fetus is exposed to acute severe hypoxaemia in normal pregnancies or to acute moderate hypoxaemia in pregnancies complicated with chronic adverse intrauterine conditions, active vasodilator mechanisms are recruited to ensure maintained adequate delivery of oxygen and nutrients to the umbilical vascular bed. This study has shown that during severe acute fetal hypoxaemia, such a mechanism is provided for by CGRP.
|
References |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
Blood AB, Hunter C & Power G (2003). Adenosine mediates decreased cerebral metabolic rate and increased cerebral blood flow during acute moderate hypoxia in near-term fetal sheep. J Physiol 533, 935–945.
Brain SD, Williams TJ, Tippins JR, Morris HR & MacIntyre I (1985). Calcitonin gene-related peptide is a potent vasodilator. Nature 313, 54–56.[CrossRef][Medline]
Carter AM, Richardson BS, Homan J, Towstoless M & Challis JR (1993). Regional adrenal blood flow responses to adrenocorticotropic hormone in fetal sheep. Am J Physiol 264, 264–269.
Cohn HE, Sacks EJ, Heyman MA & Rudolph AM (1974). Cardiovascular responses to hypoxaemia and acidemia in fetal lambs. Am J Obstet Gynecol 120, 817–824.[Medline]
Dalitz P, Harding R, Rees SM & Cock ML (2003). Prolonged reductions in placental blood flow and cerebral oxygen delivery in preterm fetal sheep exposed to endotoxin: possible factors in white matter injury after acute infection. J Soc Gynecol Invest 10, 283–290.[Medline]
Dhillo
WS, Small
CJ, Jethwa
PH, Russell
SH, Gardiner
JV, Bewick
GA
et al. (2003). Paraventricular nucleus administration of calcitonin gene-related peptide inhibits food intake and stimulates the hypothalamo-pituitary-adrenal axis. Endocrinology
144, 1420–1425.
DiPette DJ, Schwarzenberger K, Kerr N & Holland OB (1987). Systemic and regional hemodynamic effects of calcitonin gene-related peptide. Hypertension 9, 142–146.
Dong
YL, Vegiraju
S, Chauhan
M, Gangula
PRR, Hankins
GDV, Goodrum
L
et al. (2004). Involvement of calcitonin gene-related peptide in control of human fetoplacental vascular tone. Am J Physiol Heart Circ Physiol
286, H230–H239.
Downing GJ, Yarlagaddia P & Maulik D (1991). Effects of acute hypoxaemia on umbilical artery Doppler indices in a fetal ovine model. Early Human Dev 25, 1–10.[Medline]
Faiz SA, Habib FA, Sporrong BG & Khalil NA (2003). Results of delivery in umbilical cord prolapse. Saudi Med J 24, 754–757.[Medline]
Fletcher
AJW, Edwards
CMB, Gardner
DS, Fowden
AL
&
Giussani
DA (2000). Neuropeptide Y in the sheep fetus: effects of acute hypoxaemia and dexamethasone during late gestation. Endocinology
141, 3976–3982.
Franco-Cereceda
A, Gennari
C, Nami
R, Agnusdei
D, Pernow
J, Lundberg
JM
et al. (1987). Cardiovascular effects of calcitonin gene-related peptides I and II in man. Circ Res
60, 393–397.
Galanti B, Kaihura T, Ricci L, Bedocchi L, Rossi T, Benassi G et al. (2000). Perinatal morbidity and mortality in children born to mothers with gestational hypertension. Acta Biomed Ateneo Parmense 71, 361–365.[Medline]
Gardner
DS, Fletcher
AJW, Fowden
AL
&
Giussani
DA (2001). A. novel method for controlled and reversible long-term compression of the umbilical cord in fetal sheep. J Physiol
535, 217–230.
Gardner
DS
&
Giussani
DA (2003). Enhanced umbilical blood flow during acute hypoxaemia after chronic umbilical cord compression: a role for nitric oxide. Circulation
108, 331–335.
Gardner
DS, Powlson
AS
&
Giussani
DA (2001). An in vivo nitric oxide clamp to investigate the influence of nitric oxide on continuous umbilical blood flow during acute hypoxaemia in the sheep fetus. J Physiol
537, 587–596.
Gennari
C, Nami
R, Agnusdei
D
&
Fischer
JA (1990). Improved cardiac performance with human calcitonin gene related peptide in patients with congestive heart failure. Cardiovasc Res
24, 239–241.
Giussani
DA, Gardner
DS, Cox
DT
&
Fletcher
AJW (2001). Purinergic contribution to circulatory, metabolic, and adrenergic responses to acute hypoxaemia in fetal sheep. Am J Physiol Regul Integr Comp Physiol
280, R678–R685.
Giussani DA, McGarrigle HHG, Spencer JA, Moore PJ, Bennet L & Hanson MA (1994a). Effect of carotid denervation on plasma vasopressin levels during acute hypoxaemia in the late gestation sheep fetus. J Physiol 477, 81–87.[Medline]
Giussani DA, Spencer JA & Hanson MA (1994b). Fetal cardiovascular reflex responses to hypoxaemia. Fetal Matern Med Rev 6, 17–37.
Giussani
DA, Spencer
JA, Moore
PJ, Bennet
L
&
Hanson
MA (1993). Afferent and efferent components of the cardiovascular reflex responses to acute hypoxia in term fetal sheep. J Physiol
461, 431–449.
Graf AH, Hutter W, Hacker GW, Steiner H, Anderson V, Staudach A et al. (1996). Localization and distribution of vasoactive neuropeptides in the human placenta. Placenta 17, 413–421.[CrossRef][Medline]
Hall DM (1989). Birth asphyxia and cerebral palsy. BMJ 299, 279–282.[Medline]
Hasbak P, Lundby C, Olsen NV, Schifter S & Kanstrup IL (2002). Calcitonin gene-related peptide and adrenomedullin release in humans. effects of exercise and hypoxia. Regul Pept 108, 89–95.[CrossRef][Medline]
Hasbak
P, Opgaard
OS, Eskesen
K, Schifter
S, Arendrup
H, Longmore
J
et al. (2003). Investigation of CGRP receptors and peptide pharmacology in human coronary arteries. Characterization with a nonpeptide antagonist. J Pharmacol Exp Ther
304, 326–333.
Huch A, Huch R, Schneider H & Rooth G (1977). Continuous transcutaneous monitoring of fetal oxygen tension during labour. Br J Obstet Gynecol 84, 1–39.[Medline]
Itskovitz J, LaGamma EF & Rudolph AM (1983). The effect of reducing umbilical blood flow on fetal oxygenation. Am J Obstet Gynecol 145, 813–818.[Medline]
Iwamoto HS (1990). Endocrine regulation of the fetal circulation. In. Fetal and Neonatal Physiology, ed. Polin RA & Fox WM, pp. 646–655. W.B. Saunders Co, Philadelphia, PA.
Johnston MV, Trescher WH, Ishida A & Nakajima W (2001). Neurobiology of hypoxic-ischemic injury in the developing brain. Pediatr Res 49, 735–741.[Medline]
Klingner MC & Kruse J (1999). Meconium aspiration syndrome: pathophysiology and prevention. J Am Board Fam Pract 12, 450–466.[Medline]
Kovalovszki L, Villanyi E & Benko G (1990). Placental villous edema: a possible cause of antenatal hypoxia. Acta Paediatr Hung 30, 209–215.[Medline]
Lafond J, St-Pierre S, Masse A, Savard R & Simoneau L (1997). Calcitonin gene-related peptide receptor in human placental syncytiotrophoblast brush-border and basal plasma membranes. Placenta 18, 181–188.[Medline]
Leszczynska-Gorzelak B, Poniedzialek-Czajkowska E & Oleszczuk J (2002). Fetal blood saturation during the 1st and 2nd stage of labor and its relation to the neonatal outcome. Gynecol Obstet Invest 54, 159–163.[CrossRef][Medline]
Low JA, Galbraith RS, Muir DW, Killen HL, Pater EA & Karchmar EJ (1985). The relationship between perinatal hypoxia and newborn encephalopathy. Am J Obstet Gynecol 152, 256–260.[Medline]
Low JA, Simpson LL, Tonni G & Chamberlain S (1995). Limitations in the clinical prediction of intrapartum fetal asphyxia. Am J Obstet Gynecol 172, 801–804.[CrossRef][Medline]
Macfarlane CM & Tsakalakos N (1985). Evidence of hyperinsulinaemia and hypoxaemia in the cord blood of neonates born to mothers with gestational diabetes. S Afr Med J 67, 81–84.[Medline]
Maier RF, Bialobrzeski B, Gross A, Vogel M, Dudenhausen JW & Obladen M (1995). Acute and chronic fetal hypoxia in monochorionic and dichorionic twins. Obstet Gynecol 86, 973–977.[Abstract]
Manzar S (2000). Maternal sickle cell trait and fetal hypoxia. Am J Perinatol 17, 367–370.[CrossRef][Medline]
Matthews JN, Altman DG, Campbell MJ & Royston P (1990). Analysis of serial measurements in medical research. BMJ 300, 230–235.[Medline]
Morrison
S, Gardner
DS, Fletcher
AJW, Bloomfield
M
&
Giussani
DA (2003). Enhanced nitric oxide activity offsets peripheral vasoconstriction during acute hypoxaemia via chemoreflex and adrenomedullary actions in the fetus. J Physiol
547, 283–291.
Morrow
RJ, Adamson
SL, Bull
SB
&
Ritchie
JW (1990). Acute hypoxaemia does not affect the umbilical artery flow velocity waveform in fetal sheep. Obstet Gynecol
75, 590–593.
Muijsers GJJM, Hassart THM, Riussen CJ, Van Huisseling H, De Peeters LLH & Hann J (1990). The response of the umbilical and femoral artery pulsatility indices in fetal sheep to progressively reduced uteroplacental blood flow. J Dev Physiol 13, 215–221.[Medline]
Mukherjee
AB
&
Hodgen
GD (1982). Maternal ethanol exposure induces transient impairment of umbilical circulation and fetal hypoxia in monkeys. Science
218, 700–702.
Mukhopadhyay S & Arulkumaran S (2002). Breech delivery. Best Pract Res Clin Obstet Gynaecol 16, 31–42.[CrossRef][Medline]
Parer JT (1980). The Effect of acute maternal hypoxia on fetal oxygenation and the umbilical circulation in the sheep. Eur J Obstet Gynecol Reprod Biol 10, 125–136.[CrossRef][Medline]
Parer JT (1983). The influence of beta-adrenergic activity on fetal heart rate and the umbilical circulation during hypoxia in fetal sheep. Am J Obstet Gynecol 147, 592–597.[Medline]
Parer JT & Livingston EG (1990). What is fetal distress? Am J Obstet Gynecol 162, 1421–1427.[Medline]
Parida SK, Schneider DB, Stoss TD, Pauly TH & McGillis JP (1998). Elevated circulating calcitonin gene-related peptide in umbilical cord and infant blood associated with maternal and neonatal sepsis and shock. Pediatr Res 43, 276–282.[Medline]
Perkins AV & Linton EA (1995). Identification and isolation of corticotrophin-releasing hormone-positive cells from the human placenta. Placenta 163, 233–243.
Preston
R, Crosby
ET, Kotarba
D, Dudas
H
&
Elliott
RD (1993). Maternal positioning affects fetal heart rate changes after epidural analgesia for labor. Can J Anesth
40, 1136–1141.
Read MA, Boura AL & Walters WA (1993). Vascular actions of purines in the foetal circulation of the human placenta. Br J Pharmacol 1101, 454–460.
Riquelme
RA, Sanchez
G, Liberona
L, Sanhueza
EM, Giussani
DA, Blanco
CE
et al. (2002). Nitric oxide plays a role in the regulation of adrenal blood flow and adrenocorticomeduallry functions in the llama fetus. J Physiol
544, 267–276.
Rosenfeld CR, Cox BE, Roy T & Magness RR (1996). Nitric oxide contributes to estrogen-induced vasodilation of the ovine uterine circulation. J Clin Invest 989, 2158–2166.
Rudolph AM (1984). The fetal circulation and its response to stress. J Dev Physiol 6, 11–19.[Medline]
Saggese G, Bertelloni S, Baroncelli GI, Pelletti A & Benedetti U (1990). Evaluation of a peptide family encoded by the calcitonin gene in selected healthy pregnant women. A longitudinal study. Horm Res 34, 240–244.[Medline]
Salafia CM, Minior VK, Lopez-Zeno JA, Whittington SS, Pezzullo JC & Vintzileos AM (1995). Relationship between placental histologic features and umbilical cord blood gases in preterm gestations. Am J Obstet Gynecol 173, 1058–1064.[CrossRef][Medline]
Slotkin
TA (1998). Fetal nicotine or cocaine exposure: which one is worse?
J Pharmacol Exp Ther
285, 931–945.
Socol ML, Manning FA, Murata Y & Druzin ML (1982). Maternal smoking causes fetal hypoxia: experimental evidence. Am J Obstet Gynecol 142, 214–218.[Medline]
Stubblefield
PG
&
Berek
JS (1980). Perinatal mortality in term and post-term births. Obstet Gynecol
56, 676–682.
Takahashi
Y, De Vroomen
M, Roman
C
&
Heymann
MA (2000). Mechanisms of calcitonin gene-related peptide-induced increases of pulmonary blood flow in fetal sheep. Am J Physiol Heart Circ Physiol
279, H1654–H1660.
Tchirikov M, Eisermann K, Rybakowski C & Schroder HJ (1998). Doppler Ultrasound evaluation of ductus venosus blood flow during acute hypoxaemia in fetal lambs. Ultrasound Obstet Gynecol 11, 426–431.[CrossRef][Medline]
Thilaganathan B, Salvesen DR, Abbas A, Ireland RM & Nicolaides KH (1992). Fetal plasma erythropoietin concentration in red blood cell-isoimmunized pregnancies. Am J Obstet Gynecol 167, 1292–1297.[Medline]
Thornburg KL, Jonker S & Reller MD (2000). Nitric oxide and fetal coronary regulation. J Card Surg 17, 307–316.
Tomson T, Danielsson BR & Winbladh B (1997). Epilepsy and pregnancy. Balancing between risks to the mother and child. Lakartidningen 94, 2827–2835.[Medline]
Tsatsaris
V, Tarrade
A, Merviel
P, Garel
JM, Segond
N, Jullienne
A
et al. (2002). Calcitonin gene-related peptide (CGRP) and CGRP receptor expression at the human implantation site. J Clin Endocrin Metab
87, 4383–4390.
Vane JR, Anggard EE & Botting RM (1990). Regulatory functions of the vascular endothelium. N Engl J Med 323, 27–36.[Medline]
van Huisseling H, Hasaart TH, Muijsers GJ & De Haan J (1991). Umbilical artery pulsatility index and placental vascular resistance during acute hypoxaemia in fetal lambs. Gynecol Obstet Invest 31, 61–66.[Medline]
Walther FJ, Siassi B, Ramadan NA & Wu PU (1985). Cardiac output in newborn infants with transient myocardial dysfunction. J Pediatr 107, 781–785.[CrossRef][Medline]
Witlin AG (1997). Asthma in pregnancy. Semin Perinatol 21, 284–297.[CrossRef][Medline]
Yaffee H, Parer JT, Block BS & Llanos AJ (1987). Cardio respiratory responses to graded reductions in uterine blood flow in the sheep fetus. J Dev Physiol 9, 325–336.[Medline]
Young IR & Thorburn GD (1994). Prostaglandin E2 fetal maturation and ovine parturition. Aust NZ J Obstet Gynaecol 34, 342–346.[Medline]
|
Acknowledgements |
|---|
This article has been cited by other articles:
|
|
 |
|
  W. Pearce Hypoxic regulation of the fetal cerebral circulation J Appl Physiol, February 1, 2006; 100(2): 731 - 738. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 A.S. Thakor and D.A. Giussani Role of Nitric Oxide in Mediating In Vivo Vascular Responses to Calcitonin Gene-Related Peptide in Essential and Peripheral Circulations in the Fetus Circulation, October 18, 2005; 112(16): 2510 - 2516. [Abstract] [Full Text] [PDF]
|
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
; n
= 5) or during treatment with CGRP antagonist (•; n
= 5). Significant differences: *P < 0.05 for normoxia versus hypoxaemia or recovery. pHa, arterial pH; Pa,CO2, arterial partial pressure of CO2; Pa,O2, arterial partial pressure of O2; Sat Hb, percentage saturation of haemoglobin with oxygen; ABE, acid base excess.
P < 0.05, saline versus CGRP antagonist.