Cardiac output increases independently of basal metabolic rate in early human pregnancy

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Cardiac output increases independently of basal metabolic rate in early human pregnancy

M. E. A. Spaanderman, M. Meertens, M. van Bussel, T. H. A. Ekhart, and L. L. H. Peeters

Department of Obstetrics and Gynecology, Academic Hospital Maastricht, 6201 AZ Maastricht, The Netherlands

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Early pregnancy is characterized by the institution of a high-flow low-resistance circulation. In this study, we tested thehypothesis that these hemodynamic changes develop independentlyof changes in basal metabolic rate. In 12 healthy women, we determinedand calculated once during the follicular phase (day 5 ± 2) andat 6, 8, 10, and 12 wk of pregnancy the following variables: bodyweight and length, body mass index, fat-free mass (FFM), meanarterial pressure (MAP), heart rate (HR), stroke volume, cardiacoutput (CO), total peripheral vascular resistance (TPVR), restingenergy expenditure (REE), FFM REE (REE_FFM), and respiratory quotient(RQ). At 6 wk of gestational age, HR and CO had increased, whereasMAP and TPVR had decreased. These changes persisted throughoutthe study period. Meanwhile, REE, REE_FFM, RQ, FFM, and body weightdid not change consistently. The changes with pregnancy in hemodynamicsdid not correlate with those in basal metabolic rate. In earlypregnancy, the institution of a high-flow low-resistance circulationdevelops without a concomitant rise in basal metabolic rate. Thesefindings support the concept that the hemodynamic changes in earlypregnancy develop independently of concomitant changes in basalmetabolicrate.

energy expenditure; arteriovenous shunts

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

IN PREGNANCY, systemic arterial vasodilation represents one of the first detectable changes in systemic hemodynamics. Thisvasodilation then initiates a cascade of compensations in thecirculation and volume homeostasis that include, among others,a rise in cardiac output (CO), hemodilution, and activation ofthe renin-angiotensin-aldosterone system (6, 8, 11-13, 21).Neither the mechanism responsible for the initial hemodynamicchange in early pregnancy nor its functional meaning in this periodof pregnancy is understood. Insight in the interrelation betweenthe early pregnancy increase in CO and a concomitant change inmetabolic rate would improve our understanding of the mechanismand functional meaning of the early pregnancy vasorelaxation.Although in late pregnancy basal metabolism is elevated, the availabledata on change in metabolic rate in early pregnancy are scarceand inconclusive (4, 9, 19, 20). Moreover, to the bestof our knowledge, the metabolic rate in early pregnancy has neverbeen measured simultaneously with CO in a longitudinal study.Therefore, it is still obscure whether or not CO increased beforeor after a rise in metabolic rate in the first trimester ofpregnancy.

The objective of the present study was to test the hypothesis that, in early pregnancy, the CO increases independently ofconcomitant changes in metabolic rate. To this end, we seriallymeasured blood pressure, CO, and resting energy expenditure in12 women during the follicular phase of the menstrual cycle andin subsequent earlypregnancy.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Selection and Patient Characteristics

In this study, 12 nonsmoking healthy women were enrolled. Participants were recruited by advertisement. None of the womenused oral contraceptives or other medication. Measurements wereperformed in the follicular phase (FP; day 5 ± 2) and at 6, 8,10, and 12 wk of pregnancy. The gestational age at the time ofmeasurement was verified by ultrasound biometry of the embryo(series 150; Pie Medical, Maastricht, The Netherlands) beforethe first measurement session in pregnancy. Gestational age wasblinded for the individuals who determined metabolic and hemodynamicparameters.

Experimental Procedure

Metabolism. After participants fasted overnight, each experimental session was started with the measurement of fat-free mass (FFM, kg)and resting energy expenditure (REE, kcal/24 h). Mean arterialblood pressure (MAP, mmHg) and heart rate (HR, beats/min) wererecorded intermittently throughout the measurement session bya semiautomatic oscillometric device (Dinamap Vital Signs Monitor1846; Critikon, Tampa, FL). FFM was determined by bioelectricalimpedance (BIA-101; RJL Systems, Detroit, MI), a method associatedwith 0.3-kg variation between consecutive days (22). REE, whichcomprises the sleeping metabolic rate supplemented with the energycost of being awake, was determined by indirect calorimetry usinga computerized open-circuit ventilated hood system (Oxycon B;Jaeger, Breda, The Netherlands). In a horizontal position, eachparticipant breathes inside a canopy that forms a gas-tight barrierbetween the room air and the respirable air. Using a continuousinflation and suction pump, a constant flow of exhaled air androom air is drawn from and to the canopy. The gas compositionand the velocity of the air flow are measured at the outlet ofthe air suction pump. In steady state, differences in gas compositionbetween the canopy and room air vary as a function of the oxygenconsumption ( $V$ O₂, l/min) and carbon dioxide production ( $V$ CO₂,l/min; see Ref. 23). From these values, the respiratory quotient(RQ) was calculated according to the formula

RQ = <A><AC>V</AC><AC>˙</AC></A><SC>co</SC>2 / <A><AC>V</AC><AC>˙</AC></A><SC>o</SC>2

Twenty-four-hour REE is calculated using the abbreviated Weir formula (25) and is expressed as kilocalories per 24 h andkilocalories per 24 h per kilogram FFM

REE (kcal/24 h) = (3.9 + 1.1RQ) × <A><AC>V</AC><AC>˙</AC></A><SC>o</SC>2 × 1,440

REEFFM (kcal ⋅ 24 h−1 ⋅ kg−1) = (3.9 + 1.1RQ) × <A><AC>V</AC><AC>˙</AC></A><SC>o</SC>2 × 1,440/FFM

where REE_FFM is FFM REE. In our laboratory, the determination of RQ and that of REE has an intraindividual coefficient ofvariation of 6 and 1.2%, respectively (23).

Hemodynamics. Echocardiography to assess CO was performed in a semileft lateral position, immediately after completion of the REE measurementafter ~5 min of rest, using a cross-sectional, phased-array echocardiographicDoppler system (Hewlett-Packard Sonos 2000 and 2500; see Ref.12).

CO was calculated according to the formula

In this formula, HR was obtained by taking the mean of five consecutive R-R intervals on the electrocardiogram. Stroke volume(SV, ml) was calculated by multiplying the aortic velocity integraland the aortic area. Aortic flow was measured across the aorticvalves from an apical approach. SV was calculated using the averagearea under the aortic velocity curve (aortic velocity integral)of five consecutive ejections. Aortic valve diameter necessaryfor the calculation of the aortic area was measured during systoleby M mode, off-line and at the orifice. Total peripheral vascularresistance (TPVR) was calculated as follows

TPVR (dyn ⋅ s ⋅ cm<SUP>−5</SUP>) = 80 × MAP/CO

The value used for MAP was obtained during the CO measurement and was calculated as the mean of three consecutiverecordings.

Statistical Analysis

Data are presented as means ± SD unless otherwise stated. Differences relative to the value obtained during the FP were evaluatedwith ANOVA for repeated measures. Correlations between concomitantlymeasured variables in the different phases were tested by Spearman'srank correlation analysis. A P value <0.05 was considered statisticallysignificant.

	RESULTS

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The demographic characteristics of the participants are listed in Table 1. In all subjects, the course of pregnancy was uneventful.

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Table 1. Demographic data (follicular phase)

REE, REE_FFM, and RQ did not change consistently in the study period between the FP and the 12th wk of pregnancy (Table 2).Body weight and FFM varied little and inconsistently between thefive measurement sessions. Meanwhile, CO and HR had increased,and TPVR and MAP had decreased consistently in the study period,a change already noticed by the 6th wk (Table 3 and Fig. 1).

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Table 2. Metabolic data

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Table 3. Hemodynamic data

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Fig. 1. Percent change, relative to the follicular phase (FP), in cardiac output (CO, filled bars) and resting energy expenditure (REE, open bars). Data are presented as means and SE and originate from the FP of the menstrual cycle and at 6, 8, 10, and 12 wk of pregnancy. * Significant difference compared with the value at FP.

The CO per unit REE and per unit REE_FFM increased significantly over the study period (P = 0.04, r = 0.90, r² = 0.80 and P = 0.02, r = 0.94, r² = 0.89, respectively). Within one measurement session, HR didnot change appreciably between the period of REE measurement andthe subsequent period of COdetermination.

Neither the change in REE nor that in REE_FFM in the course of the five measurement sessions correlated with the observed concomitantchanges in CO (r = $-$ 0.29, r² = 0.09 and r = $-$ 0.44, r² = 0.19,respectively).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Early pregnancy is characterized by the development of a high-flow low-resistance circulation (6, 7, 9, 12, 13,21). However, at present, the exact mechanism responsible forthis effect is still obscure. A rise in metabolic rate could beone of the possible triggers for these circulatory adjustments.Conversely, when the metabolic rate does not increase, the high-flowlow-resistance circulation is associated with a CO rise in excessof metabolic demands. In this study, we explored the possibleinterrelationship between systemic vasorelaxation and metabolicrate in 12 healthy women by measuring CO together with REE duringfive consecutive sessions in the 1st wk of pregnancy when hemodynamicchanges are the largest. In our study, the institution of a high-flowlow-resistance circulation in early pregnancy develops withouta concomitant rise in basal metabolicrate.

Reports on REE in early pregnancy are rather conflicting, with some studies reporting an increment and others a fall in basalmetabolic rate in early pregnancy (9, 20). Some of thesedifferences can be explained by the methods employed, the procedureused to standardize measurement conditions, and the role of fatmass with REE. In fact, suppression of REE in early pregnancyis mainly observed in women with a low body mass index, and also,in advanced pregnancy, the largest increase in REE occurs in womenwith the highest body mass indexes (4, 20). During the first12 wk of pregnancy, we did not find an appreciable change in REEand RQ. Conversely, the concomitantly measured CO had alreadyincreased by the 6th wk of pregnancy. Meanwhile, the time-dependentchange in CO and that in REE did not correlate. Also, the CO perunit REE and REE_FFM was found to increase with advancing amenorrhea.All of these phenomena support the development of a hyperdynamiccirculation in the first weeks of pregnancy. To maintain the balancein Starling forces within the capillary bed, the institution ofa hyperdynamic circulation should be paralleled by the openingof protective arteriovenous shunts and with it a fall in arteriovenousoxygen difference over the circulation, an effect that has beenobserved by others in both human and animal pregnancy (2, 5,14, 18). Opening of these arteriovenous fistulas is consideredto be primarily systemic rather than placental, since intervillouscirculation has not been established until the end of the firsttrimester (16).

Obviously, these results should be interpreted in the context of the methods employed, particularly with respect to potentialpitfalls. We performed the CO measurement immediately after theREE determination, a choice made for logistic reasons. These observationscan only be considered "simultaneously made" if the participantswere really in a steady state. The latter was highly probable,since REE is a continuously measured variable that can only bedetermined reliable when RQ had been stable for at least 15 min.The steady-state conditions during the REE measurement were maintainedduring the subsequent CO measurement, a condition verified onthe basis of maintained steady state in HR and MAP values throughoutthe latter period until completion of dataacquisition.

These findings indicate that the early pregnancy systemic vasorelaxation develops independently of changes in basal metabolism.How this initial change in pregnancy is induced remains to beestablished. Prolonged changes in steroid environment giving riseto an altered balance between vasoconstrictive and vasodilatorystimuli are thought to be responsible for the initial arterialrelaxation (15, 17). The support for this concept comes fromobservations during the menstrual cycle and in the (pseudo)pregnantrat. During the luteal phase of the menstrual cycle, the hemodynamicsand renal function change slightly in the direction similar tothat observed in early pregnancy (8). In rat pseudopregnancy,initial adaptations in hemodynamic and volume homeostasis aresimilar to those observed in normal rat pregnancy (1, 3,24). Moreover, although not found by all investigators, suppletionof sex steroid hormones in ovariectomized rats to a level observedin pregnancy can alter vascular sensitivity to vasodilatory stimuliin a manner comparable to that seen in normal pregnancy (10,15). This indicates that neither trophoblastic hormones northe placenta itself is needed to induce these hemodynamicchanges.

In conclusion, early pregnancy is characterized by the development of a hyperdynamic circulation. This adaptive change seemsto be the result of a primary relaxation of the arterial vasculaturetogether with the opening of protective arteriovenousshunts.

	FOOTNOTES

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests and other correspondence: M. E. A. Spaanderman, Dept. of Obstetrics & Gynecology, Academic Hospital Maastricht, PO Box 5800, 6201 AZ Maastricht, The Netherlands (E-mail: marc.spaanderman{at}OG.unimaas.nl).

Received 26 April 1999; accepted in final form 17 November 1999.

	REFERENCES

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

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