Techniques for assessing cardiac output and fetal cardiac function

Seminars in Fetal & Neonatal Medicine 16 (2011) 13e21

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Techniques for assessing cardiac output and fetal cardiac function Boris Tutschek a, b, *, Klaus G. Schmidt c a

Department of Obstetrics, Bern University Hospital, Effingerstrasse 102, 3010 Bern, Switzerland Medical Faculty, Düsseldorf University, Düsseldorf, Germany c Department of Pediatric Cardiology, Düsseldorf University Hospital, Düsseldorf, Germany b

s u m m a r y Keywords: Cardiac output Intrauterine growth restriction Myocardial performance index Strain analysis Tei index Twinetwin transfusion syndrome

Fetal echocardiography was initially used to diagnose structural heart disease, but recent interest has focused on functional assessment. Effects of extracardiac conditions on the cardiac function such as volume overload (in the recipient in twinetwin transfusion syndrome), a hyperdynamic circulation (arterio-venous malformation), cardiac compression (diaphragmatic hernia, lung tumours) and increased placental resistance (intrauterine growth restriction and placental insufficiency) can be studied by ultrasound and may guide decisions for intervention or delivery. A variety of functional tests can be used, but there is no single clinical standard. For some specific conditions, however, certain tests have shown diagnostic value. Ó 2010 Elsevier Ltd. All rights reserved.

1. Introduction Although fetal echocardiography was initially used for the identification of structural congenital heart disease, attention has more recently moved to its value in functional assessment of the fetal heart and circulation.1,2 Whereas attention initially focused on cardiac function in fetuses with intrinsic cardiac problems such as severe semilunar valvular stenosis or poor myocardial contraction, the potential importance of these techniques in assessing wellbeing of the fetus with other pathologies is gradually being recognized. Extracardiac causes of cardiac dysfunction such as volume overload (the recipient in twinetwin transfusion syndrome, TTTS), a hyperdynamic circulation (arterio-venous malformation), cardiac compression (diaphragmatic hernia, lung tumours) and increased placental resistance (intrauterine growth restriction and placental insufficiency) can be assessed prenatally and may guide decisions for intervention or delivery. A normally functioning heart maintains appropriate cardiac output in a sustained fashion and is able to adapt to changing circulatory demands. Postnatally, the cardiac ventricles work in series and left ventricular (systemic) output (Qs) is normally the same as right ventricular (pulmonary) output (Qp). Cardiac output measurements are related to the left ventricle. In fetal life, however, both ventricles work in parallel (with the exception of the relatively small pulmonary blood flow pumped by the right ventricle) and cardiac output * Corresponding author. Department of Obstetrics, Bern University Hospital, Effingerstrasse 102, 3010 Bern, Switzerland. Tel.: þ41 31 951 1606; fax: þ41 31 632 9806. E-mail address: [email protected] (B. Tutschek). 1744-165X/$ e see front matter Ó 2010 Elsevier Ltd. All rights reserved. doi:10.1016/j.siny.2010.09.005

measurements usually consider the combined output of both ventricles. Cardiac output is dependent on fetal heart rate and stroke volume, on preload (circulatory volume), afterload (circulatory resistance) and myocardial contractility. Direct measurement of cardiac output is difficult. Postnatal methods of assessment are based on Fick’s principle and either require measurements of oxygen consumption at venous and arterial sites, or use thermo- or dye dilution methods e invasive methods that are not suitable for fetal assessment. The assessment of myocardial performance is complicated by the small size of the fetal heart, fetal position and movement which can hinder accurate assessment.3 Cardiac function is typically assessed with a variety of techniques (Table 1): direct measurement of cardiac dimensions (M-mode and B-mode ultrasound) or ventricular volumes (4D ultrasound) at different points of the cardiac cycle can be used to estimate cardiac output, as can measurement of blood flow (Doppler ultrasound) through vessels near to the heart, although these methods are often technically challenging.4e6 Indirect indices involve qualitative assessment of blood flow, tissue excursion or time intervals during the cardiac cycle and are often easier to measure. Investigation of arterial and venous Doppler measurements of the peripheral vasculature also provide an indirect means of assessing cardiac function; these tools are described in this issue by A. Baschat. Measurement of time intervals during the cardiac cycle, in particular the relationship of isovolumic relaxation and contraction time to ejection time, have also been used to evaluate the fetal heart with impaired function.7e9 Tissue Doppler echocardiography and related techniques such as strain analysis are other promising tools for the assessment of fetal cardiac function in special situations.10,11 This article reviews established techniques and describes new developments in the assessment of fetal cardiac function.

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Table 1 Sonographic methods for assessing cardiac function

Measurement of cardiac dimensions

Dimension

Method

Functional parameter

Short axis diameters (EDD, ESD)

M-mode, B-mode

Long-axis length, volume (EDV, ESV)

Extrapolated from M-mode (Teichholz) or B-mode (Biplane Simpson’s rule) Directly from 3D/volume ultrasound

Ventricular size Fractional shortening Long-axis function, ventricular volumes, ejection fraction, cardiac output Ventricular volumes (possibly ventricular mass), ejection fraction, cardiac output

Measurement of cardiac output

Vessel area, mean blood flow velocity

B-mode, pulsed-wave Doppler

Cardiac output

Other measures of cardiac function

Ventricular inflow velocities

Pulsed-wave Doppler

Valve insufficiency Isovolumetric relaxation and contraction times, ejection time

Color Doppler, pulsed-wave Doppler Pulsed-wave (or tissue) Doppler

Preload, ventricular relaxation and passive filling Preload Myocardial performance index

Myocardial tissue movement (global or regional)

Tissue Doppler imaging

Assessment of myocardial tissue motion

Strain analysis

Myocardial contraction force (global, possibly regional) Myocardial contraction force (global, possibly regional)

EDD, end-diastolic diameter; ESD, end-systolic diameter; EDV, end-diastolic volume; ESV, end-systolic volume; 3D, three-dimensional.

2. Cardiac dimensions

EDV ¼ (7/(2.4 þ EDD)) * EDD3

In axial section, the four-chamber view of the heart occupies one third of the chest. The cardio-thoracic ratio is calculated by measuring the fetal cardiac and thoracic areas or circumferences and is normally 33% and 50%, respectively.12,13 The key to functional cardiac assessment in the fetus is measurement of cardiac dimensions and their changes during the cardiac cycle that relate to cardiac function and output. Individual chambers, measured using either M-mode or B-mode echocardiography, can be assessed in end-diastole (ED) and endsystole (ES), estimated by the largest and smallest ventricular cavity size as electrocardiographic gating is not available in clinical practice. M-mode echocardiography reports tissue density along a single axis. The short axis view, aligned perpendicular to the interventricular septum and free walls of the ventricles at the tips of the AV valve leaflets in a lateral four-chamber view, allows one-dimensional measurements of the ventricular chambers and myocardial thicknesses in systole and diastole (Fig. 1). Normal data for such measurements in the human fetus throughout the second half of gestation have been published and ventricular diameters used to calculate functional indices such as shortening and ejection fractions.2,14,15 The shortening fraction (SF) is derived from the enddiastolic and end-systolic diameters (EDD and ESD):

This formula has also been used in the human fetus.21 The problem of volume calculations based on M-mode is that inaccuracies in measurement are compounded by a formula that extrapolates ventricular volume. An alternative method of examining ventricular function assesses motion of the atrioventricular (AV) valve annulus during the cardiac cycle (Fig. 2). The M-mode cursor is placed over the AV valve parallel to its excursion in an apical or basal insonation and the maximal displacement of the valve ring between diastole and systole (analyzed visually) is recorded. A study of 159 normal fetuses found a linear increase in valve annulus displacement with gestation for tricuspid and mitral valves of 4e9 and 3e6 mm, respectively, between 15 and 38 weeks of gestation.22 Measurement of individual cardiac structures can be made using B-mode ultrasound (Fig. 3).23e25 The relatively regular ‘truncated ellipsoid’ shape of the left ventricle lends itself to volume calculations, which may simply

SF ¼ (EDD  ESD)/EDD This is best applied to the left ventricle with a simpler geometric shape; the right ventricle is better assessed functionally in long axis view.7 M-mode studies are dependent on a correct insonation angle and therefore on fetal position. Angle dependency can be overcome by using an M-mode with an adjustable angle.16 Regardless of the relative values, an increase in diastolic dimensions is often found in decreased cardiac function and should be evaluated further.17 Shortening fraction decreases with fetal cardiac compromise.18,19 Ventricular diameters can also be used to estimate end-diastolic and end-systolic volumes (EDV, ESV) which are in turn used to calculate the ejection fraction (EF): EF ¼ (EDVESV)/EDV In adults the best correlation between angiographic and Mmode echocardiographic left ventricular volume measurements uses the Teichholz formula,20 where

Fig. 1. A lateral four-chamber view of the fetal heart showing the M-mode interrogation line placed perpendicular to the interventricular septum and just apical to the tips of the atrioventricular valves. Measurements of the cardiac ventricular diameters in end-diastole (EDD) and end-systole (ESD) are shown. LV, left ventricle; RV, right ventricle.

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Fig. 2. An apical four-chamber view of a normal fetal heart in systole showing the Mmode interrogation line placed through the ventricular free wall attachment of the tricuspid valve annulus (TVA). The difference of maximal systolic (sys) and diastolic (dia) excursion can be measured. RV and LV, right and left ventricle; RA and LA, right and left atrium.

involve assessment of the circumference and length of the chamber or use the more complex Simpson’s biplane method.26,27 By calculating ventricular volumes in end-diastole and end-systole, cardiac output and ejection fraction can be calculated from 2D imaging, although this method is time-consuming and not suited for daily clinical practice. This approach has been used to show an

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exponential increase in both right and left EDV during the second half of gestation, whereas the EF remains at a constant level in normal fetuses.28 As M-mode and B-mode echocardiography are limited by accuracy of measurement, several groups have investigated the potential of 3D or ‘volume’ ultrasound for the assessment of fetal cardiac chamber size.29e35 Volumes are most commonly generated by spatialetemporal image correlation (STIC) using an automatic two-dimensional sweep across the heart that acquires several hundred frames that are rearranged spatially and temporarily to form a ‘virtual’ high resolution cardiac cycle containing up to 40 volumes for one heart beat.36 The endocardial contour can be detected semi-automatically and is used to quantify chamber volumes in end-diastole and end-systole, enabling the calculation of ejection fraction and cardiac output (Fig. 4).37 STIC volumes have been validated using in-vitro volumes comparable to second and third trimester fetal hearts; STIC it has been found to be suited for diastolic measurements and volumes >2.5 mL, and measurements appear to be reproducible.9 Normal ranges for right and left stroke volumes and cardiac output have been proposed and this technique has been used to demonstrate that chamber volumes in structurally malformed hearts differ markedly from the norm.34,38e40 STIC is dependent on fetal position (ideally supine) and quiescence, allowing acquisition of the entire fetal heart in one volume sequence.40 These views are particularly difficult to obtain at later gestations e with less amniotic fluid, more mineralization of fetal bones and often a dorso-anterior fetal position e which may prohibit its use for functional assessment in the later part of pregnancy. Despite this, a comparison of STIC with 2D and Doppler sonography found that although these methods gave similar results

Fig. 3. Schematic diagrams showing B-mode echocardiographic measurements. (a) Long-axis view of the left ventricle with aortic valve (1) and ascending aorta (2). (b) Aortic arch view with aortic valve (1), ascending and descending aorta (2, 3) and the inferior vena cava (4). (c) Short-axis view with the pulmonary valve (1), main, right and left (2, 3, 4) pulmonary arteries. (d) Oblique short-axis view showing the arterial duct (5). (e) Four-chamber view showing the tricuspid valve (1), right ventricular end-diastolic diameter (2), right ventricular inlet length (3), right ventricular area (dashed line, 4). On the left side are the mitral valve (5), left ventricular end-diastolic diameter (6), left ventricular inlet length (7) and left ventricular area (dotted line, 8). Ao, aorta; Desc Ao, descending aorta; IVC, inferior vena cava; LA, left atrium; LPA, left pulmonary artery; LV, left ventricle; MPA, main pulmonary artery; RA, right atrium; RPA, right pulmonary artery; RV, right ventricle. (Reproduced with permission from Schneider et al.24)

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Fig. 4. Fetal cardiac volumetry using three-dimensional datasets. (a) Use of a spatialetemporal image correlation (STIC) volume with semi-automatic volume tracing and automatic endocardial border detection (with permission from Messing et al.34). (b) Ventricular volume calculation from a non-reconstructed real-time volume acquired with a matrix transducer (with permission from Tutschek and Sahn37). (c) Semi-automatically generated endocardial casts derived from a STIC volume (with permission from Tutschek and Sahn35). Colour-filled areas of the left atrium (LA), right (RV) and left (LV) ventricles and aortic origin (Ao) are visible. The cavity of the right ventricle appears shorter than the left because of its apical trabeculation.

STIC was less operator dependent and required significantly less time for acquisition and offline analysis.40 3. Blood flow and cardiac intervals Stroke volume (and therefore cardiac output) can also be calculated by combining B-mode and pulsed-wave Doppler ultrasound to measure valvular diameter (D) and the velocity of flow (V) across the valve (see also Fig. 5):4,6,41,42 SV ¼ (p * D2/4)* V Both the diameters of the aortic and pulmonary valves and the flow velocities through the outflow tracts increase in a linear fashion with advancing gestation, so the stroke volumes and combined cardiac output increase exponentially from 160 to 1300 mL/min between 16 weeks and term. The right ventricle appears to make a greater contribution to combined cardiac output as the ratio of pulmonary artery to aorta is 1.2.4,6,42e44 This technique is limited by the fact that any inaccuracy in measurement of valvular diameter is compounded by squaring this value. It also assumes that the valve is circular and fails to account for vessel wall compliance. Velocity measurement by pulsed-wave Doppler also becomes unreliable if the angle for insonation is >15e20 , and angle correction is required in this situation. Comparison of the reproducibility of fetal cardiac ventricular volume estimations by M-mode, cross-sectional B-mode and Doppler-derived volume flow measurements finds that M-mode measurements are least

reproducible whereas the other two techniques have comparable intra- and interobserver error.21 Doppler ultrasound can also be used to examine cardiac function indirectly by examining the pattern of flow through the atrioventricular valves. The pattern of passive and active ventricular filling during diastole reflects relaxation properties of the cardiac ventricles. In fetal life, normal ventricular inflow is characterized by a smaller early (E) wave, followed by a larger (A) wave during atrial contraction. With advancing gestation the E/A ratio increases which is considered a sign of normal maturation towards a normally compliant (less stiff) myocardium.45,46 An increased or even reversed fetal E/A ratio is related to ventricular diastolic dysfunction.47 Monophasic atrioventricular inflow patterns are seen at high fetal heart rates and also in fetuses with reduced cardiac function.17,48 In the normal fetal heart, both AV valves are competent. The finding of more than a trace of regurgitation across the tricuspid and mitral valve should prompt further investigation for altered cardiovascular physiology.17 Whereas a trace of TR is typically benign, holosystolic TR is likely to be abnormal and warrants further investigation.49 Functional TR may reverse when the underlying pathology is corrected: for example in fetal anaemia, sustained fetal tachycardia or in the recipient in TTTS. Several groups have suggested scoring systems that combine methods of assessment to give a more global overview of cardiac function and that can be used to define imminent or absolute cardiac failure (Table 2).17,48 These scoring systems aim to standardize the current practice of multimodal assessment which is in part based on subjective parameters such as grading of ‘ventricular dysfunction’.

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Fig. 5. Quantitative assessment of cardiac output (CO) using pulsed-wave Doppler. (a) Pulsed-wave flow profile in the aorta; the sample volume is placed just distal to the aortic valve. The angle of insonation for Doppler assessment is minimized so that the flow velocity time integral (VTI) can be measured directly from the spectral display. (b) The aortic root diameter (red line) is used to calculate aortic valve area (VA). (c) Graph demonstrating the increase in left ventricular output with gestational age (Modified from Allan et al.4). (LV output ¼ VTI  VA  heart rate.) LV, left ventricle; RV, right ventricle; Ao, aorta; asc. Ao, ascending aorta.

Scores may be superior to single measurements in defining compromised cardio-circulatory function. Some recent studies have examined the potential for measuring time intervals during the cardiac cycle to assess global cardiac function. Systolic dysfunction causes prolongation of the isovolumic contraction time (ICT) and shortening of the ejection time (ET), and diastolic dysfunction prolongs the isovolumic relaxation time (IRT).50 These factors can be used to define the myocardial performance (MPI) or ‘Tei’ index51: MPI ¼ (IRT þ ICT)/ET Initial studies in adults found these parameters were easily and reproducibly measured and were predictive for cardiac failure in a stage-dependent fashion in patients with dilated cardiomyopathy.51 In the fetus these time intervals are best calculated using

a single pulse-wave Doppler recording of ventricular flow by recording a large sample volume that covers both mitral inflow and aortic outflow, demonstrating opening and closure of the valves (Fig. 6).52 The MPI has been applied to several clinical situations in fetal medicine (see below). 4. Clinical applications Fetal cardiac function can be compromised either by placental dysfunction, resulting in intrauterine growth restriction, by maternal illness (e.g. diabetes) or by the presence of some congenital anomalies. A better understanding of fetal cardiovascular status has been shown to improve our understanding and management in several clinical situations including the assessment of intrauterine growth restriction, TTTS and congenital diaphragmatic hernia.

Table 2 Fetal cardiovascular profile score combining direct and indirect functional parameters (Modified from Huhta17)

Cardiomegaly Valve insufficiency Hydrops Venous blood flow Umbilical artery blood flow

Normal (score 2 points)

Abnormal (minus 1 point)

Severely abnormal (minus 2 points)

CTR <0.35 No TR, no MR, biphasic filling No Normal umbilical vein, positive DV a-wave Positive EDF

CTR 0.35e0.50 Holosystolic TR Ascites or pleural effusion or pericardial effusion Normal umbilical vein, reversed DV a-wave No EDF

CTR >0.50 Holosystolic MR or monophasic filling Skin edema Pulsatile umbilical vein Reversed EDF

CTR, cardio-thoracic ratio; DV, ductus venosus; TR, tricuspid regurgitation; MR, mitral regurgitation; EDF, end-diastolic flow. For ‘normal’ fetal cardiac function the five parameters yield a score of 10.

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Fig. 6. The myocardial performance index (MPI or Tei index) in a normal fetus. The (modified) MPI is calculated from time intervals derived from pulsed-wave Doppler of left ventricular inflow (negative velocities, biphasic with E and A waves) and outflow (aortic outflow, positive velocities), incorporating the mitral and aortic valve clicks; T1, isovolumic contraction time; T2, ejection time; T3, isovolumic relaxation.

Crispi et al. used several markers of cardiac function including the MPI, E/A ratio and calculation of cardiac output to compare growth-restricted fetuses with appropriately grown fetuses.53 The MPI and E/A ratio (but not cardiac output) correlated with hemodynamic deterioration and were significantly increased in fetuses that died. Hernandez-Andrade et al. studied cardiovascular function in preterm growth-restricted fetuses. Although perinatal mortality was independently predicted by an abnormal MPI (>95th centile), this had less predictive power than other factors such as gestational age at delivery or abnormal venous Doppler findings (reversal of the A-wave of the ductus venosus).54 A combination of these parameters best predicted perinatal mortality. For example, for a fetus below 28 weeks with positive a-wave and normal MPI, the estimated perinatal mortality (PNM) was 18%, but with DV areversal and abnormal MPI, PNM was 97%. The circulations of monochorionic twins are almost invariably intertwined by placental vascular anastamoses. In the majority of cases volume exchange is balanced, but in 15% an imbalance causes net transfusion from one twin (the ‘donor’) to the other (the ‘recipient’), Twin-to-twin transfusion syndrome or TTTS.55 The twins have unique cardiovascular problems: the recipient

has a persistent increase in cardiac preload, whereas the donor has inadequate placental return of oxygen and nutrients. Treatment by laser ablation of the communicating placenta vasculature provides a further cardiovascular challenge.56 The recipient that previously had to compensate for a chronic increase in preload needs to readjust cardiac function to a lower preload. The donor experiences an abrupt increase in peripheral resistance due to occlusion of the communicating vessels and a relative loss of perfusable placental territory; from a cardiac perspective, this fetus must adapt to an increase in afterload.57 Although transient and permanent cardiovascular anomalies are frequently seen in fetuses with TTTS, the current staging system only includes indirect signs of cardiac dysfunction.58,59 Cardiovascular dysfunction in the recipient twin can be detected using a score that encompasses arterial and venous Doppler alterations, cardiac size, and atrio-ventricular valve regurgitation as well as abnormal inflow patterns.48 Because the preload of the recipient is increased, the right ventricle MPI is also increased; assessing cardiac function using MPI might improve the selection of appropriate candidates for intrauterine therapy and also be of value in monitoring improvement in fetal condition after treatment.60 Maternal diabetes is the most common cause of a fetal hypertrophic cardiomyopathy, characterized by thickening of the interventricular septum and ventricular outflow obstruction in an otherwise structurally normal fetal heart; it occurs in about a quarter of affected pregnancies.47,61,62 In affected fetuses diastolic function, judged for example by the diastolic filling pattern or flow velocity waveforms in the ductus venosus, can be altered even in well-controlled maternal glycemia.62e65 In severe congenital diaphragmatic hernia (CDH), compression of the fetal heart by herniated viscera impairs cardiac function.66 LV volumes as determined by the Teichholz formula in CDH were about one-third smaller compared to normal fetuses.67 Temporal fetal endoscopic tracheal occlusion, in addition to improving lung size, also has an effect on cardiac function: placement of the tracheal occlusion improved the myocardial performance index by shortening the isovolumic contraction time interval.68 Other examples of extracardiac abnormalities affecting cardiac function are sacrococcygeal teratoma or arterio-venous malformations (AVM), characterized by high blood flow through the tumour that can lead to cardiac failure. As the fetus with

Fig. 7. Strain rate (SR) analysis, using speckle tracking, of a normal fetal heart at 32 weeks of gestation. Left panel: the ventricular wall is tracked throughout the cardiac cycle; lengthening and shortening during diastole and systole are calculated for individual segments (colored dots). Right panel: quantitative analysis of regional (colored lines) and global (white dotted line) strain rates; x-axis denotes time (ms), y-axis indicates strain rate (1/s). The major peaks indicate (from left to right): two diastolic SR peaks above the x-axis (SRE, SRA) indicating lengthening during early and late diastolic tissue motion, followed by a negative SR peak (SRS) during systole.

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a sacrococcygeal teratoma deteriorates, the inferior vena cava and the cardiac ventricles dilate due to increased venous return from the tumour, even though these fetuses typically maintain a normal shortening fraction.69 Similarly a dilated superior vena cava and cardiomegaly develop in deteriorating fetuses with a large cerebral AVM such as an aneurysm of the vein of Galen.69 In both these conditions neonatal outcomes are poorer in fetuses that develop hydrops prior to delivery and recognition of more subtle signs of cardiac failure may prompt antenatal intervention or delivery.70 Fetal tachyarrhythmias may also impair cardiac function, but may be difficult to assess functionally, because indices such as the MPI are difficult to measure at high heart rates. For this condition, scoring systems as described above may be better suited.17

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Practice points  Quantification of cardiac function in the human fetus is technically difficult.  Cardiac volume measurements enable calculation of cardiac output and ejection fraction.  3D fetal echocardiography is promising, but still lacks standardization.  At present, assessment of peripheral and central blood flow remain the most useful clinical tools.

Research directions 5. Other new technologies Whereas traditional Doppler studies of blood flow are based on high velocityelow intensity signals, tissue Doppler records low velocityehigh intensity signals; it can be used to assess the force of cardiac contraction and relaxation in the fetus.71e73 Both pulsedwave and colour Doppler can record motion of cardiac structures. Sampling with pulsed-wave Doppler over the AV valve annulus uses the same insonation as that used for M-mode recording of this structure. A theoretical advantage is that tissue Doppler data might be more closely related to mechanical force than blood flow Doppler. Unfortunately quantification is limited by the angle dependency and poor lateral resolution of Doppler imaging. Strain analysis is a concept adopted from adult cardiology. Strain describes tissue ‘deformation’: lengthening in diastole and shortening in systole. By definition, strain can only be calculated by comparison of fixed points in the myocardium that are tracked throughout the cardiac cycle. Strain is defined as the relative change in the distance between two points in systole and diastole. Strain rate is the time taken to reach a specific level of tissue deformation. Both tissue Doppler imaging and strain analysis are used postnatally to assess and quantify regional and global cardiac wall motion. Fetal strain analysis can be performed using tissue Doppler imaging, but angle dependency, sensitivity to extracardiac movement and high fetal heart rate hamper this approach.72,74e76 Strain analysis requires high spatial and temporal resolution which is inherently difficult to achieve in fetal studies due to the small cardiac size and the high heart rate. Speckle tracking is a novel imaging modality that can be used to assess cardiac function; it is not based on the Doppler principle, but tracks individual reflectors in the myocardium over time. It is therefore less angle dependent. Fig. 7 shows an example of fetal strain rate analysis by speckle tracking. Early studies suggest that functional indices are in a similar range to the adult, although they vary with gestational age.3,77e79 6. Conclusions Clinical assessment of fetal ‘well-being’ currently relies on a multimodal approach examining fetal growth, behavioural state, amount of amniotic fluid, peripheral Doppler studies and fetal heart rate tracing. Fetal cardiac function may be affected by a number of environmental or congenital anomalies. Research efforts have recently recognized the potential value of monitoring cardiac function for clinical management. Unfortunately, there is no single simple test to measure fetal cardiac function. Further studies will show which approach to functional cardiac assessment in the fetus has true value in terms of improved neonatal outcome.

 Newer methods of assessment such as measurement of cardiac intervals and tissue deformation require further validation.  Potential markers for defined pathologies need to be clarified.  The effect of the intrauterine environment on fetal cardiac development needs to be explored.

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