Coronary Artery Disease Clinical Trial
Cardiac output (CO) is a key variable when describing the cardiovascular system. Electrical cardiometry (EC) is a non-invasive method in measuring stroke volume and cardiac output. However, its accuracy has been inconsistent. Therefore Martin et al. have compared measurements with echocardiographic measurements and propose calibration with left ventricle outflow tract (LVOT)-measurements obtained from transthoracic echocardiography (TTE). This study was performed in pregnant women at term. Goal of this study is to validate their formula in non-pregnant outpatients undergoing echocardiography for cardiology work-up. Secondary aim is to perform a leg raising test and to compare changes in stroke volume observed with either EC or TTE.
Cardiac output (CO) is a key variable when describing and treating the cardiovascular
system. The ideal cardiac output (CO) monitor would be safe, non-invasive, low-cost,
painless, easy to interpret and would allow for the continuous, hands-free acquisition of
accurate data. Electrical cardiometry (EC), a more recent version of impedance cardiography
(ICG), meets many of the criteria for an ideal monitor and previously published research
suggests that EC successfully trends CO1-3, but its accuracy in measuring absolute values of
stroke volume (SV) has been inconsistent in published research4-8. Electrical cardiometry
works by sending an insensible high frequency alternating current through the thorax and
measures changes in thoracic impedance that are attributed to systolic blood flow
acceleration over the cardiac cycle. Using fiducial points in the tracing of the first
derivative of impedance, EC calculates left ventricular ejection time (LVET) and mean
velocity of blood during systole. By further estimating a patient constant that is primarily
based on body mass ('volume of electrically participating tissue' (VEPT)), stroke volume is
estimated in the following way:
- SVEC = VEPT * Mean blood velocity * corrected Flow Time (FTc).
Cardiac output monitors are typically validated against a reference standard, which has
traditionally been thermodilution using a pulmonary artery catheter (PAC). Given the risks
associated with the use of pulmonary artery catheters9 an alternative method, such as
transthoracic echocardiography (TTE), lends itself as valuable substitute technique for
measuring CO. Transthoracic echocardiography is safe, painless and non-invasive. Similarly
to EC, SV estimate by TTE is based on a measurement of mean blood velocity and ejection time
(mean blood velocity x ejection time = velocity time integral, VTI; (Figure 3)). However, in
contrast to EC, the parameters for blood velocity and left ventricular ejection time are not
multiplied with a normative patient constant, but with a measured parameter: the left
ventricular outflow tract area (LVOT area):
- SVTTE = LVOT area * mean blood velocity * ejection time. Main disadvantage of using TTE
for CO-measurement is advanced training that is needed to obtain VTI measurements and that
it is highly labor intense to obtain repeated VTIs for continuous or repeated CO
measurements. Measurement of LVOT area, by contrast, is a one-time measurement obtained from
parasternal long axis view, which necessitates only basic training of TTE.
Recently Martin and colleagues10 compared SV parameters derived from EC and TTE in a sample
of 44 healthy pregnant volunteers and found excellent agreement in mean left ventricular
ejection time and heart rate. However, agreement in SV was poor with a percentage error of
42% in Bland-Altman analysis. Hypothesizing that both methodologies in estimating SV, EC and
TTE, use measures for blood velocity and systolic ejection time, Martin et al. hypothesized
that agreement between both methods could be significantly improved by calibrating SV-EC
with the LVOT area that is derived from one time TTE measurement. Based on a multiplicative
linear regression model and following log-linear transformation Martin et al. derived the
following formula for calibration:
SVEC_Modified = 2.2 * LVOT_area(0.705) * SV_EC(0.388) * Weight(0.21) By applying this
formula, agreement in SV measurements significantly improved and percentage error decreased
to 22 %. However, data was derived from a very specific patient population (pregnant women)
and accuracy of the modified SV-assessment was not validated in a prospective manner.
Therefore, this study proposes to compare SV-estimates derived from EC and TTE in
non-pregnant outpatients undergoing routine echocardiography assessment. Primary aim of this
study is to evaluate if agreement between both methods can be improved by calibrating
SV-measurements obtained from electrocardiometry with a one-time LVOT area measurement
obtained from TTE.
Secondary aim will be to perform passive leg raising test and compare sensitivity in both
identifying fluid responsiveness between both monitoring methodologies.
Third aim is to compare CO derived measurements from EC and TTE with gold standard
measurements derived from patients undergoing routine right heart catheterisation for
evaluation of cardiac and pulmonary function.
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