Acute effects of 17beta -estradiol on ventricular and vascular hemodynamics in postmenopausal women

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Acute effects of 17 $beta$ -estradiol on ventricular and vascular hemodynamics in postmenopausal women

Christopher S. Hayward¹^,², Wally V. Kalnins¹, and Raymond P. Kelly¹

¹ Department of Cardiology, St. Vincent's Hospital, Sydney 2010, Australia; and ² Department of Cardiac Medicine, National Heart and Lung Institute, Imperial College, London SW3 6LY, United Kingdom

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Because premenopausal women have lower cardiovascular morbidity than postmenopausal women, it has been proposed that estrogenmay have a protective role. Estrogen is involved in smooth musclerelaxation both through its specific receptor as well as throughcalcium channel blockade. This study examined the acute effectof estradiol on invasive cardiovascular hemodynamics in 18 postmenopausalwomen (age 62.6 ± 7.6 years, means ± SD). The effect of estradiolon left ventricular chamber performance was studied in 9 womenusing simultaneous left ventricular pressure-volume recordings.In a further group of 9 women, the acute effect of estradiol onarterial function was assessed using input impedance (derivedfrom simultaneous aortic pressure and flow recordings), pressurewaveform analysis, and pulse wave velocity. After 2 mg micronized17 $beta$ -estradiol was administered, serum estradiol levels increasedfrom 50.9 ± 21.9 to 3,190 ± 2,216 pmol/l, P < 0.0001. There wasno effect of estradiol on either left ventricular inotropic orlusitropic function. There was no acute effect of estradiol onarterial impedance, reflection coefficient, augmentation index,or pulse wave velocity. There was a trend to decreased heart rateand cardiac output in both groups of 9 women. Because heart rateand cardiac output were common to both hemodynamic data sets,results for these parameters were pooled. Across all 18 women,there was a small but significant decrease in heart rate (69.2± 10.4 vs. 67.2 ± 9.9 beats/min, P = 0.02), as well as a significantdecrease in cardiac output (4.82 ± 1.77 vs. 4.17 ± 1.56 l/min,P = 0.002). Despite achieving supraphysiological serum levels,this study found no significant effect of acute 17 $beta$ -estradiolon ventricular or large arteryfunction.

estrogen; arterial compliance; pressure-volume study; aortic impedance

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

BECAUSE WOMEN HAVE LOWER CARDIOVASCULAR morbidity and mortality until the time of the menopause (13, 20, 31), it hasbeen speculated that hormones may play an important cardioprotectiverole. It has been shown that estrogen has beneficial effects oncoronary vasomotion (40), through endothelial production ofnitric oxide (7). Vascular smooth muscle cells have also beenshown to possess the classical estrogen receptor (15) and torespond acutely through a nongenomic, receptor-specific mechanism(3). Vascular relaxation due to calcium channel antagonismhas also been widely suggested as an important contributor tothe effect of estrogen on the cardiovascular system (5). Previousstudies have shown that acute sublingual estradiol increases timeto ischemia and exercise capacity in postmenopausal women withcoronary disease undergoing treadmill exercise tests (32). Whereasthe mechanisms of this benefit may involve coronary vasomotoractions, alternate hemodynamic effects have not previously beenstudied. From the widespread distribution of calcium channelsand estrogen receptors, this study was designed to determine whetheracute estradiol administration had direct hemodynamic effectson ventricular or vascular function, or theirinteraction.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Patients

Eighteen postmenopausal women (defined by history of amenorrhea and subsequent serum estradiol <105 pmol/l) were recruitedfrom those undergoing elective cardiac catheterization. The ResearchEthics Committee of St. Vincent's Hospital approved the study,and all patients gave written informed consent. The acute effectsof estradiol on left ventricular (LV) chamber function were examinedin nine women, and its effects on aortic impedance and pulse wavevelocity were examined in a further group of nine women. The meanage of the cohort was 62.6 ± 7.6 (±SD) years, and mean body massindex was 26.6 ± 5.0 kg/m². Fourteen subjects had no significant coronary artery disease,two had double vessel disease, and two had triple vessel disease.All subjects had normal global LV function (ejection fraction>50%), although one subject had minor inferior hypokinesis onventriculography. There was no difference in effect between thosewith no coronary disease and the remaining few, so results arepresented for the entire cohort. Two subjects were diabetic andten had a history of treated hypertension. Patients were studiedon their usual medication. Current medications included $beta$ -blockersin four subjects, calcium channel antagonists in five, angiotensin-convertingenzyme inhibitors in five, isosorbide mononitrate in three subjects,and diuretics in two subjects. Of the entire cohort, nine weretaking long-acting vasodilators (angiotensin-converting enzymeinhibitors, calcium antagonists, or isosorbide mononitrate) administeredon the morning of the study. Hemodynamic study was performed ~3hpostdose.

Estradiol Administration Protocol

All subjects had baseline hemodynamic recordings and serum estradiol assays taken before sublingual estradiol was given. Estradiolassays were taken from arterial blood from the femoral sheath.Subjects were then given crushed micronized 1 mg 17 $beta$ -estradiol(Trisequens, Novo Nordisk, Denmark) sublingually with a sip ofwater. LV pressure volume and aortic pressure-flow recordingswere taken for 10 min and then a further 1-mg micronized estradiolwas given by the same route. Recordings were continued for a further10 min, at which time the second estradiol assay was taken. Thisprotocol was used prospectively to allow delineation of any acute(10 min) estradiol effect at the lower dose. Serum for estradiollevels was taken at the commencement of the recordings and aftercompletion of the 20-minprotocol.

Data Acquisition

Pressure-volume loops LV pressure-volume (PV) loops were obtained by simultaneous measurement of LV pressure (micromanometer) and volume (conductancemethod) as has been previously described (9). Briefly, an 8-Fr.conductance volume catheter (9 mm electrode spacing, Webster 7212-08,Webster Lab) was inserted into the LV cavity via a femoral arterialsheath under fluoroscopic control. The micromanometer was theninserted to the tip of the volume catheter and connected for dataacquisition. Volume signals were processed via a Leycom signalconditioner (Sigma 5, Cardiodynamics, Rijnsburg, Netherlands)to a data acquisition board in a portable computer (Intel 486processor, DX50). Data were displayed on-line at a sampling rateof 250 Hz with high-frequency, noise-filtering cut-off at 50 Hz,20 dB/decade. End-systolic and end-diastolic volumes (ESV, EDV)were calculated off-line using single-plane contrast ventriculography,calibrated against a radioopaque sphere of known diameter. A 35-mmvena caval balloon catheter (Cordis 530000A-15565, Cordis, Miami,FL) positioned within the right atrium was used for acute preloadreduction by intermittent inferior vena caval occlusion(IVCO).

Arterial parameters. Aortic impedance studies were performed using a Millar combined micromanometer pressure and electromagnetic velocity flowmeter(Millar Instruments, Houston, TX) connected to standard transducerbox (Millar SPC-501) and Biotronix flowmeter (BLI 613). Simultaneousthree-lead electrocardiogram, LV pressure, aortic pressure, aorticflow, femoral pressure and Finapres digital pressure were acquireddirectly to an analog-digital converter via customized software.Volume flow was calculated by multiplying integrated flow velocityby aortic root area calibrated using a radioopaque sphere. Aorticdiameter measurements were taken immediately above the level ofthe aortic sinuses at end diastole. The mean aortic diameter forthe seven subjects with adequate flow recordings was 3.39 ± 0.54cm. Calibration for the electromagnetic flowmeter was performedusing saline ejected from a pulsatile pump with fixed output andtubing of knowndiameter.

Femoral pressure was measured using a Millar micromanometer connected to the sidearm of an 8-F femoral sheath through whichthe ventricular catheter was passed. The short (20 cm) sheathsidearm was filled and flushed periodically with saline to ensurethe sheath remained free from thrombus. The femoral pressure wasused, in combination with the aortic pressure waveform, for derivationof the aorto-femoral transfer function and for calculation ofaortic pulse wave velocity. A Finapres cuff (Ohmeda) was placedaround the second inter-phalangeal joint of the third finger ofthe left hand before cardiac catheterization to allow peripheralwaveformrecording.

Data Analysis

Steady-state data. Volume results were not available for two subjects due to LV catheter movement or artifact. All nine subjects had availablepressure data. Steady-state data for each patient were averagedover 10-20 continuous beats after smoothing. Data in which therewas a >10% change in heart rate were excluded. Preectopic, ectopic,and postectopic beats were excluded from analysis. Steady-stateparameters were automatically determined from the averaged PVloop by customized software (PVAN, Pressure-Volume Analysis, JohnsHopkins University, Baltimore, MD). Steady-state variables includedheart rate, cardiac output, LV systolic pressure, end-diastolicpressure (pre a wave), peak positive pressure development overtime (dP/dt_max), peak negative dP/dt (dP/dt_min), time constantof relaxation (T, tau), duration of contraction, and end-systolicpressures and volumes. For the purposes of steady-state diastolicparameters, the point of end diastole was determined separatelyusing pressure derivatives to calculate the pressure and volumeimmediately before the atrial filling wave. End systole was definedby the maximum of time-varying ventricular elastance (E_t) as describedby the equation E_t = P_t/(V_t $-$ V₀), where V₀ is the volume axisintercept as defined below. Tau was determined using a logarithmicleast-squares regression commencing at peak dP/dt_min and extendingfor a further 80 ms. Duration of electromechanical systole wasdefined from the midpoint of the electrocardiographic QR waveto dP/dt_min. This measure was used as a measure of duration ofcontraction (25).

Chamber function. The load-independent indexes end-systolic PV relations (ESPVR), preload-recruitable stroke work relations (PRSWR), and end-diastolicPV relations (EDPVR) were obtained during transient IVCO. Becauselinear relationships were assumed for all indexes, individualIVCO runs with a linear correlation of <0.80 were not includedin analysis. For ESPVR, an iterative procedure was performed fromthe linear regression of the data using an initial estimate ofV₀ of 0 ml. Subsequent iterations were continued until errorswere minimized as previously described (18). Because of poorcorrelations in individual runs or ventricular ectopy in responseto IVCO, some studies were found to be unsuitable for load-independentanalyses.

End-diastolic relationships were determined from two EDP/EDV points on each PV loop. The points chosen were those immediatelybefore the a wave and a second point 10% of the filling volumeearlier in the same loop as has been described previously (21).By examining diastole before atrial contraction, this providesan assessment of the passive diastolic properties of the leftventricle. A linear model was used to describe the EDPVR becausethis is simpler and has been shown to be as valid as more complexexponential regression models (16). Although the slope of theregression describes an elastance, the results are usually reportedas the inverse, namely chamber compliance C_Dia (17). The equationfor diastolic compliance is therefore V = C_Dia · P + V_oDia, whereV_oDia is the volume axisintercept.

Arterial parameters. Because of problems with flow catheter positioning and flow waveform, impedance results were only available for seven of thenine subjects. Problems with the Finapres device and with thefemoral pressure trace in two separate patients meant that pulsewave velocity and aorto-femoral transfer function results wereavailable for seven of the nine patients. Data were averaged fromsteady-state recordings. Pressure, flow, and Finapres waveformswere ensemble averaged using electrocardiogram triggering to obtainan averaged waveform before entry into a discrete Fourier transformcalculation to determine impedance and transfer functions. Individualimpedance and transfer function results were derived from theratio of the Fourier components of the aortic pressure to correspondingaortic flow and femoral pressure, respectively. Sampling ratewas 250 Hz for all channels. The last one-third of the flow waveformwas assumed to be zero and was used to autocalibrate for offsetdrift. Results for frequency-dependent parameters were reportedup to the tenth harmonic, beyond which the signal-to-noise ratiois too low for meaningful analysis. Characteristic impedance (Z_c)was defined as the mean of impedance modulus for harmonics 4-10.

Time domain parameters such as augmentation index (19), reflection wave ratio (37), and ejection duration were derivedusing pressure derivatives. Whereas augmentation index is definedby the ratio of the difference between the late and early systolicshoulders to the aortic pulse pressure, the reflection wave ratiouses the ratio of the height of the late to early pressure peaksfrom the pressure waveform. The indexes are similar in the informationderived from them. Pulse onset for pulse wave velocity calculationwas determined using the peak of the second derivative. Distanceswere determined from the sternal notch to femoral transducer tipand from the sternal notch to Finapres cuff by surfaceanatomy.

Systemic vascular resistance was calculated using the ratio of the mean aortic pressure to cardiac output multiplied by 80(to convert to units of dyn · s · cm⁵). This assumes a right atrial pressure of zero, which may leadto a minor overestimation of systemic vascular resistance. Reflectioncoefficient ( $Gamma$ ) was calculated according to $Gamma$ = (Z_t $-$ Z_c)/(Z_t+ Z_c), where Z_t is the terminal impedance, and Z_c the characteristicimpedance. Absolute Finapres pressures were not found to be reliableand were not further analyzed. The Finapres waveform was usedsolely for timing purposes for calculation of brachial pulse wavevelocity.

Statistics

Results are shown as means ± SD. The effect of estradiol on steady-state parameters was analyzed using paired t-tests. Todetermine the effect of estrogen on chamber function (ESPVR, EDPVR,PRSWR), a multiple linear regression model was used coding forthe effect of estrogen on both the slope and intercept of theappropriate relationship after accounting for the baseline differencesbetween individuals using dummy coding (34).

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Estradiol Levels

Serum estradiol levels increased in all subjects. The smallest change in serum estradiol level in any subject was a greaterthan fivefold increase in concentration, from 92 to 548 pmol/l.In the entire cohort estradiol levels increased from 50.9 ± 21.9to 3,190 ± 2,216 pmol/l, P < 0.0001.

Estradiol and LV Chamber Function

Steady-state recordings. Baseline steady-state parameters and results for the last 5 min of the study are shown in Table 1. Interim analysis revealedno effect of estrogen at 10 min. It is of note that, despite markedelevation of the serum estradiol level, no change in blood pressureor ejection fraction were found. There was a trend to decreasedheart rate and cardiac output. There was no evidence for any lusitropiceffect, as shown by either tau or dP/dt_min. There was no changein arterial elastance, suggesting no marked change in arterialor arteriolar tone. Indeed, arterial elastance tended to increasein this study (P = 0.19).

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Table 1. Effect of estradiol on steady-state parameters in patients undergoing pressure-volume study

LV chamber function. Systolic function was assessed using ESPVR and PRSWR (Table 2). There was no inotropic effect of estradiol (P = 0.59 and0.51, respectively). An example of PV loops before and at theend of the study period is shown in Fig. 1. As can be seen inthis patient, there was no significant change in LV contractilitydue to estradiol. Passive diastolic ventricular function was assessedby examining EDPVR. Again, there was no effect of estradiol administrationon chamber distensibility (P = 0.68).

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Table 2. Effect of estradiol on left ventricular chamber function

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Fig. 1. Example of a series of pressure-volume (PV) loops during inferior vena caval occlusion (IVCO) in a single patient used in derivation of the end-systolic PV relationship (ESPVR) before estrogen (solid line, open circles) and at study completion, 20 min after estrogen (dotted line, filled circles). As can be seen, ESPVR did not change. LV, left ventricular.

Estradiol and Arterial Hemodynamics

Baseline parameters. There was a statistically significant, but small, decrease in heart rate (69.8 ± 9.4 vs. 66.0 ± 6.9 beats/min, P < 0.05) frombaseline to 10 min; however, overall heart rate had not changedsignificantly from baseline at the end of the study period (P= 0.12). Whereas there was no change in any pressure-related parameter,there was a significant decrease in cardiac output and peak aorticflow velocity with time (Table 3). Calculated systemic vascularresistance increased significantly over the first 10 min of thestudy period, with a trend to increased vascular resistance remainingat the end of the study period (P = 0.06). Tau (arterial) derivedfrom an exponential decay model of the aortic pressure waveform(windkessel model) tended to suggest a decrease in aortic compliance(P = 0.07).

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Table 3. Effect of estradiol on resting hemodynamics in patients undergoing pressure-flow recordings

Aortic input impedance. Analysis of impedance spectra showed no significant changes at any harmonic (Fig. 2). Z_t (impedance at zero frequency = systemicvascular resistance) increased significantly in the interim timeperiod but was not significantly different by the end of the study.Z_c did not change significantly in response to estradiol (Table3). Because the small changes in Z_c were in a similar directionto those in Z_t, there was no significant change in the calculated $Gamma$ .

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Fig. 2. Acute effect of sublingual estradiol (E2) on aortic input impedance. There was no effect of estradiol at 10 min or at completion of the study at 20 min. NS, not significant.

Pulse waveform analysis and pulse wave velocity. The aortic augmentation index and reflection wave ratios were used as further markers of peripheral arterial wave reflection.There was no significant change in systolic augmentation, ejectionduration, or pulse wave velocity at any time during the study(Table 3). Consistent with other studies in older subjects, theaortic pulse wave velocity was greater thanbrachial.

Aorto-femoral transfer function. To further delineate any change in arterial function, as may be expected by smooth muscle relaxation, the aorto-femoral transferfunction was derived for each time period. There was a characteristicamplification of lower frequencies with diminution of higher harmonics(Fig. 2). This is similar to that seen in brachial and radialtransfer functions (14). The phase decreases in an approximatelylinear manner in accordance with the delay between the two pulsesdue to transit delay. There was no significant change in eitheramplification or phase delay over the first 10 min. At 20 min,there was a small but significant decrease in mean femoral arterialpressure, as shown by a decrease in amplification at zero frequencyat 20 min (Fig. 3). This may have been due to intraluminal thrombusdeposition with time, despite regular flushing, due to the closefit of the pressure-flow catheter within the arterial sheath.There was no change in mean aortic pressure (Table 3). Therewere no changes in phase delays due to estradiol administration.

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Fig. 3. Acute effect of sublingual E2 on aorto-femoral transfer function. There was a small but significant decrease in femoral pressure at study completion, which was not associated with any change in aortic pressure. There was no change in either amplification or phase delay due to E2 during the study period.

Pooled data. Because heart rate and cardiac output were common to the two studies, analysis could be performed across all 18 subjects,increasing statistical power. Across all 18 subjects, there wasa small, but significant, decrease in heart rate across the studyperiod (from 69.2 ± 10.4 to 67.2 ± 9.9 beats/min, P = 0.02). Cardiacoutput was derived by stroke volume in the ventricular study (n= 7) and by integrated aortic flow velocity (n = 7) in the impedancestudy. Because the results were compared using paired t-tests,this was not considered a barrier to appropriate interpretationof the results. There was a significant decrease in cardiac outputacross the entire group (from 4.82 ± 1.69 to 4.17 ± 1.56 l/min,P = 0.002). From the variability in increase in serum estradiollevels, the relation between either change in estradiol levelsor absolute estradiol levels was also examined. There was no relationship(P = 0.68-0.83) between either the percentage change in estradiollevel or absolute estradiol level and changes in either heartrate or cardiacoutput.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

This study found no significant acute effects of estradiol administration on ventricular or arterial function, despite achievingmarkedly supraphysiological estradiol serum concentrations withinthe study period. There was a significant decrease in cardiacoutput and heart rate in the pooled data of all subjects followingestrogen administration. This result is surprising because a numberof studies have shown that estrogen may act directly as a smoothmuscle relaxant, with consequent vasodilating properties (12,23). At least one previous study, however, has documented asignificant combined decrease in heart rate and cardiac outputin association with estrogen therapy (22), similar to the currentstudy. Whereas the decrease in heart rate may be partially responsiblefor the decrease in cardiac output, in the absence of changesin ventricular function, a further possible mechanism is througha decrease in preload due to venodilation. This is suggested bythe tendency toward a decrease in right atrial pressure in theeight subjects in whom it wasmeasured.

There have been no prior invasive human studies of the effect of estradiol on load-independent indexes of LV function. Twostudies that have suggested a positive inotropic effect of estrogenfound increases in peak aortic flow velocities in response toshort-term hormone replacement therapy and attributed those changesin aortic velocities to "enhanced inotropism" (26, 28). Thesestudies were noninvasive and did not record corresponding serumestradiol concentrations. Two further noninvasive echocardiographicstudies have also found no effect on cardiac function in responseto hormone replacement therapy (24, 35), in agreement withthe currentstudy.

The current study confirms what has been found in an isolated rat heart study (6). In that study, 17 $beta$ -estradiol was associatedwith a negative chronotropic effect in the right atrium withoutany negative inotropic effect. Of note, however, is the fact thatglobal ventricular function improved with estradiol only if thecoronary arteries had been preconstricted with acetylcholine (6).Because the majority of subjects in the current study had normalcoronary arteries, it may be expected that no significant effecton global LV function would be found. A study in the isolatedrabbit heart found a significant negative inotropic effect onlyat very high concentrations (>1 µmol/l) (29). Consistent witha calcium blockade mechanism, a similar negative inotropic effecthas been shown in an isolated guinea pig myocyte study, againat high in vitro concentrations (10-30 µmol/l) (11). Anotherstudy, in the rat heart following gonadectomy, found that estrogen(2 mg/day) tended to improve the cardiac dysfunction associatedwith gonadectomy (33). Serum estrogen levels were not measuredin that study. A frequent problem with all of the in vivo studiesin experimental animals is that significantly higher estrogenconcentrations are used than are typically seen during hormonereplacement therapy (400-600 pM) making direct extrapolation toeffects on cardiac function in postmenopausal women difficult.The current study suggests that even at serum concentrations ataround five times the standard therapeutic levels, estrogen doesnot significantly affect cardiac performance in the acutephase.

Preliminary reports have suggested that estrogen may acutely improve arterial compliance (36). In the study by Stefanadiset al. (36), aortic compliance was calculated from invasivelymeasured pressure-diameter relations. Contrary to this, the currentstudy found a tendency to decreased arterial compliance, in bothpressure-volume and pressure-flow protocols. This was suggestedby a trend toward an increase in effective arterial elastance,and an increase in the aortic pressure diastolic decay constant(tau) in aortic pressure waveform analysis. There was no trendwith respect to Z_c, augmentation index, or pulse wave velocity.One difference with the study by Stefanadis et al. (36) wasthat measurements were taken for 40 min rather than 20 min inthis study. This timing difference may be crucial because in thenoninvasive study by Volterrani and colleagues (39), forearmblood flow changes were not apparent at 20 min but became significantat 40 min. The rationale for completing this study within 20 minwas based on results that showed that both the negative inotropiceffects in isolated myocytes (11) and activation of nitric oxidesynthase from endothelial cells (3) occur within 5 min of estrogenexposure. Whereas longer term estrogen has been shown to improvearterial compliance (derived noninvasively) in some studies (30),this is not a universal finding (8, 10).

Possible reasons contributing to the negative results reported here may relate to the effect of radiographic contrast administeredduring cardiac catheterization. One effect of cardiac catheterizationis to gradually deplete intravascular volume due to the diureticeffect of the contrast in fasting patients. This would be expectedto increase the peripheral vascular resistance slightly, as wasfound in this study (with a tendency to increased arterial elastanceand a tendency to increased calculated systemic vascular resistance).Any significant sympathetic response associated with volume depletionwould tend to increase heart rate. This was not evident in thisstudy, suggesting that the decrease in heart rate may be a directeffect of estrogen. This is consistent with other data demonstratinga negative chronotropic effect of estrogen (1, 22).

Because different classes of calcium antagonists have been shown to have variable effects on the periphery and on the heart(4), it is conceivable that estrogen may also exhibit selectivityof action. Because the urogenital bed may be considered the primetarget for estrogen, regional increases in blood flow may haveoccurred that were not reflected in overall cardiac output orhemodynamic parameters (23). A number of vascular studies ofthe effects of estrogen have used intra-arterial injections, makingvascular effects more apparent. Nonetheless in the study by Gilliganet al. (7), estradiol doses were used to achieve "premenopausal"estrogen levels. At that concentration, however, estradiol didnot directly cause vasodilatation or increase blood flow but onlypotentiated acetylcholine responses (7). The negative chronotropiceffect in the absence of significant vasodilatation remains consistentwith calcium antagonism as a possible mechanism of action. Importantly,because this was an acute study, it remains possible that genomiceffects of estrogen on other elements in the vascular tree orthe heart may be seen with more prolonged use. This may be animportant factor in the increase in arterial compliance associatedwith pregnancy (27).

The absence of any demonstrable benefit of acute estrogen administration in this study may relate to patients continuing theirantianginal therapy at the time of catheterization. Previous (32)studies that have found an increase in exercise capacity in patientswith angina due to sublingual estrogen administration have studiedpatients off anginal therapy, which may make any vasodilationeasier to detect. Whereas none of the women in this study weretaking hormone replacement therapy, a number of the women werealready taking long-acting vasodilators, including calcium antagonists,angiotensin-converting enzyme inhibitors, and long-acting nitrates.A recent study (38) has suggested that estrogen may modulatethe effect of nitrovasodilators. In that study, whereas higherdoses of estrogen (10 µM) were associated with in vitro vasodilatation,no relaxation was seen at 1 nM. In the presence of other vasodilators,including sodium nitroprusside, however, 1 nM estradiol enhancedvasodilatation. This study may have been confounded, therefore,by concurrent anginal therapy. Nonetheless, the important conclusioncan be made that acute supraphysiological levels of estradioldid not have any additive beneficial hemodynamic effect for womenalready receiving appropriate cardiovascular treatment. A subanalysisof subjects who were not taking vasodilators (9 of the 18 womenstudied) did not appreciably alter the cardiac output results.There remained a trend toward a decrease in cardiac output from4.7 ± 0.9 to 4.2 ± 1.1 l/min (n = 6 subjects, P = 0.08). Heartrate changes following estrogen in women not taking vasoactivetherapy remained significant, decreasing from 74.4 ± 9.7 to 71.4± 10.1 (n = 9 subjects, P = 0.03).

The kinetics of sublingual estradiol were not examined in this study. Our concern was to ensure that sufficient serum druglevels were achieved within the time frame of the study. The dosewas chosen because it had previously been shown to acutely increaseserum levels in a cohort of postmenopausal women (32). The levelsachieved in the current study are similar (3,190 ± 2,216 pmol/l)to those from the study by Rosano et al. (32) (2,531 ± 1,192pmol/l), despite the fact that the estradiol was given 40 minbefore exercise in that study. This suggests that the serum levelincrease quickly and remain elevated in the short term. A pharmacodynamicstudy in five women suggested that the peak level occurred within2 h and had returned to baseline before 24 h (2).

In conclusion, despite increasing serum estradiol from low postmenopausal to supraphysiological levels, we found no acutealteration in either ventricular or vascular function. There wasa small but significant decrease in heart rate associated witha significant decrease in cardiac output over the entire cohortwithout any evidence of a negative inotropic effect. Previouslydescribed improvements in arterial compliance due to estrogenmay be related to structural or receptor-mediated changes associatedwith longerexposure.

	ACKNOWLEDGEMENTS

The assistance of the staff of the St. Vincent's Hospital Cardiac Catheterisation Laboratory is gratefullyacknowledged.

	FOOTNOTES

This work was supported by a Postgraduate Research Fellowship for C. Hayward and a Project Grant for R. P. Kelly, both fromthe National Health and Medical Research Council (Canberra, Australia).C. Hayward is currently supported by an Overseas Research Fellowshipfrom the National Heart Foundation (Canberra,Australia).

Address for reprint requests and other correspondence: C. Hayward, Department of Cardiology, St. Vincent's Hospital, VictoriaSt., Darlinghurst, Sydney NSW 2010,Australia.

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.Section 1734 solely to indicate thisfact.

Received 3 January 2000; accepted in final form 28 April 2000.

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Acute effects of 17-estradiol on ventricular and vascular hemodynamics in postmenopausal women

Acute effects of 17 $beta$ -estradiol on ventricular and vascular hemodynamics in postmenopausal women