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Title: Cardiac Output In Pre eclampsia Is Determined By The Presence Of
Fetal Growth Restriction, Not Gestation At Onset: A prospective cohort study
Authors: Jasmine TAY 1, 3, Lin FOO 1, 3, Giulia MASINI 1, Phillip R BENNETT3, Carmel M
MCENIERY 2, Ian B WILKINSON 2, Christoph C LEES 1, 3, 4,*
Affiliations:
1Centre for Fetal Care, Queen Charlotte's and Chelsea Hospital, Imperial College Healthcare
NHS Trust, London, United Kingdom.
2Experimental Medicine and Immunotherapeutics, ACCI, Level 3 Addenbrooke’s, Hills Road,
CB2 0QQ, Cambridge.
3 Institute for Reproductive and Developmental Biology, Department of Surgery and Cancer,
Imperial College London, London, United Kingdom
4Department of Development and Regeneration, KU Leuven, Leuven, Belgium
* Dr Christoph C. Lees, [email protected]
Conflict of interest statement: The authors report no conflict of interests
Abstract word count –
Main text word count -
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Abstract:
Background and Objectives
Pre-eclampsia (PE) and fetal growth restriction (FGR) are considered to be placentally-mediated
disorders. The clinical manifestations are widely held to relate to gestation age at onset with
early- and late-onset PE considered to be phenotypically distinct. Recent studies have reported
conflicting findings in relation to cardiovascular function, and in particular cardiac output, in PE
and FGR.
Study Design
We investigated maternal cardiovascular function in relation to clinical subtype in 45
pathological pregnancies (14 ‘PE only’, 16 ‘FGR only’, 15 ‘PE and FGR’) and compared these
with 107 healthy person observations. Cardiac output (CO) was the primary outcome measure,
and was assessed using an inert gas rebreathing method (Innocor®), from which peripheral
vascular resistance was derived (PVR); arterial function was assessed by Vicorder ®, a cuff-
based oscillometric device. Cardiovascular parameters were normalised for gestational age in
relation to healthy pregnancies using Z scores, thus allowing for comparison across the
gestational range 24-40 weeks.
Results
Compared with healthy control pregnancies, women with PE had higher CO Z scores (1.87 ±
1.35; p=0.0001) and lower PVR Z scores (-0.76± 0.89; p=0.025); those with FGR had higher
PVR Z scores (0.57± 1.18; p=0.04) and those with both PE and FGR had lower CO Z scores (-
0.80 ± 1.3; p= 0.007) and higher PVR Z scores (2.16 ± 1.96; p=0.0001). These changes were not
related to gestational age of onset. All those affected by PE and/or FGR had abnormally raised
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augmentation index (AIx) and pulse wave velocity (PWV). Furthermore, in PE, low CO was
associated with low birthweight and high CO with high birthweight. (r=0.42, p=0.03).
Conclusions
PE is associated with high CO, but if PE presents with FGR, the opposite is true; both conditions
are, nevertheless, defined by hypertension. FGR without PE is associated with high PVR.
Though 'early' and 'late' gestation PE are considered to be different diseases, we show that the
haemodynamic characteristics of PE were unrelated to gestation age at onset, but strongly
associated with the presence or absence of FGR. FGR more commonly co-exists with PE at early
gestation, thus explaining the conflicting results of previous studies. Furthermore, anti-
hypertensive agents act by reducing CO or PVR and are administered without reference to
cardiovascular function in PE. The underlying pathology (PE, FGR, PE and FGR) defines
cardiovascular phenotype, providing a rational basis for choice of therapy where high or low CO
or PVR are the predominant features.
Key Words: Cardiac output, vascular resistance, arterial function, pregnancy, hypertension
Condensation: ‘Pure’ PE is characterized by high cardiac output, FGR alone with high vascular
resistance; the co-existence of FGR with PE alters the haemodynamic phenotype of PE to low
cardiac output, high vascular resistance.
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[Main Text:]
Introduction
Pre-eclampsia (PE) is not simply a pregnancy-specific syndrome: its implications on later life
cardiovascular1 and cognitive function2 and healthcare cost3 are only now being understood. Fetal
growth restriction (FGR) has a close but poorly understood relationship with PE. Although PE
and FGR frequently present in isolation, they may occur together, particularly at early gestation
4. The underlying pathophysiology of PE has never been fully understood, but the cause has often
been attributed to the placenta as PE resolves completely after delivery. Inadequate trophoblast
invasion leading to uteroplacental malperfusion is thought to underlie both PE and FGR5,6.
However, this placental theory does not explain why women who had PE in their pregnancies
have a higher cardiovascular risk in later life7-9 or why women with pre-pregnancy
cardiovascular risk factors have a higher risk of PE and FGR in pregnancy10. Emerging data
suggests that maternal cardiovascular function is impaired post-delivery in women with PE11,12
and high blood pressure prior to pregnancy increases the risk of PE developing10. Nevertheless,
PE and FGR are commonly referred to as ‘placenta mediated disorders’, suggested to arise
through defective placentation.
Studies of cardiovascular function in pregnancy have shown inconsistent, and in some cases,
contradictory results. The classic studies of Easterling suggested that PE was associated with a
high CO state13, though this relationship was thought to be explained, at least in part, by the
increased body surface area 14. Other studies have suggested that PE should be subdivided into
those where low or high CO is predominant.15 FGR with and without PE have a different
cardiovascular profile 16,17 though the relationship of these changes to healthy pregnancy or PE
without FGR has not been studied. A recent systematic review concluded that studies of
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cardiovascular function in gestational hypertension and PE show conflicting results. The authors
concluded that “increased peripheral vascular resistance correlates with disease severity” but of
note, the co-existence of FGR was not considered in majority of the studies. 18
Previous studies on cardiovascular function in PE have incompletely characterized FGR 19,
recruited only within a particular gestation range 16 and/or not compared findings to a healthy
reference pregnant population. 20 Existing studies provide interesting insights to cardiovascular
dysfunction in pathological pregnancies but leave important questions unanswered in relation to
gestational effects and pregnancies where PE and FGR are combined.
Over the last two decades it has become customary to subdivide PE into “early” and “late”
variants with an arbitrary 34 week gestational age ‘cut-off’. This distinction arose not because of
a pathophysiological difference between the conditions, but because of the inability of screening
by uterine artery Doppler to effectively identify cases of late onset disease.21-23 It is suggested
that early and late variants have different underlying vascular characteristics, though in most
studies, late PE is rarely or never associated with FGR. 20 Adding further complexity, recent
studies have suggested that PE at term is associated with babies with larger birth weight.14
We sought to investigate the relationship between cardiovascular function and clinical phenotype
of PE and FGR alone and in combination across a gestation range, with cardiac output being the
primary outcome measure. Cardiovascular function changes with gestational age, therefore, in
order to allow comparison we transformed all data in relation to that obtained from women with
healthy pregnancies using the statistical technique of z-scoring. This removed the need for a
gestation matched cohort design and allowed all data points to be considered. 19 In doing so, we
performed comprehensive haemodynamic assessments from 24 weeks gestation onwards in
women with healthy pregnancies, with PE in combination with FGR (PE and FGR), PE without
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FGR (PE only), and FGR without PE (FGR only), managed and monitored in a single maternity
unit.
Materials and Methods
Study protocol
In this prospective cross-sectional study, women between weeks 24-40 of pregnancy were
recruited from the antenatal clinic, labour ward, day assessment unit and antenatal ward of a
tertiary level London teaching hospital between January 2015 – May 2017. The study protocol
was approved by NHS National Research Ethics Committee, London Riverside and all
participants gave written informed consent. Gestation of pregnancy was determined by
measurement of crown-rump length between 11-13 weeks in early pregnancy.
Women were recruited at presentation or diagnosis where it was feasible to conduct a detailed
cardiovascular examination and were not included if they were already in labour, undergoing
induction of labour or imminent delivery was planned. (Figure 1) We describe the diagnosis as
those with PE alone ‘PE only’, FGR alone ‘FGR only’ and PE together with FGR ‘PE and FGR’.
Women’s assessments are reported at the time of initial diagnosis of one of these conditions, and
the diagnosis assigned at the time of study inclusion. One hundred and seven healthy person
observations acted as control cases with no control subject assessed twice within the same epoch.
PE was defined as blood pressure at diagnosis of >140/90 mmHg and urine protein creatinine
ratio of >30. FGR was defined as fetal abdominal circumference or estimated fetal weight <10th
centile24 and umbilical Doppler PI >95th centile on ultrasound scan. 25 Those women with known
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underlying cardiovascular conditions, multiple pregnancies and fetal anomalies were excluded
from the study.
Participants underwent peripheral blood pressure measurement, comprehensive cardiovascular
assessments and fetal ultrasound scans as detailed below.
Cardiovascular Assessments
Participants were requested to abstain from caffeinated drinks for 4 hours before the visit. In
brief, cardiovascular measurements were performed with the patient standing upright for the
assessment of cardiac output and in left lateral lying position for assessment of arterial function.
Cardiac output was measured using Innocor TM , a non-invasive inert gas rebreathing technique as
previously described 26,27. Brachial blood pressure was measured using Omron TM M-7 (OMRON
Healthcare Europe B.V.) which has been validated in pregnancy 28. Blood pressure was measured
on the right arm in the seated position following recommendations from the European Society of
Hypertension 29. Mean arterial pressure (MAP) was calculated by [diastolic pressure + (systolic
pressure - diastolic pressure)/ 3]. Peripheral vascular resistance (PVR) was derived with the
following formula, PVR = MAP x 80 / cardiac output.
Arterial analysis was performed using the Vicorder TM (Skidmore Medical, Bristol, UK), an
oscillometric device validated for the measurements of AIx and pulse wave velocity (PWV).30
With the patient lying in the left lateral position, a brachial cuff was applied to the right upper
arm, a leg cuff applied to the right upper thigh and a neck sensor positioned over the carotid
artery. A standard measuring tape was used to measure the linear distance between the
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suprasternal notch and a defined point on the femoral cuff. Augmentation Index (AIX), PWV
and maternal heart rate (beats/minute) were recorded.
Ultrasound
Obstetric ultrasound assessment was performed on Samsung WS80 equipment (Samsung
Medison, Korea). Fetal growth parameters (head circumference, biparietal diameter, abdominal
circumference and femur length) and Doppler studies (umbilical, middle cerebral artery, ductus
venosus and uterine artery) were recorded in all pathological pregnancy cases.
Statistical Analysis
Statistical analyses were performed using SPSS (Version 24_0_0, 2016; SPSS Inc., Chicago,
Illinois, USA). The Kruskal-Wallis test was used to compare the demographic characteristics
between the four groups. The normality of distribution of the data was examined with the
Shapiro-Wilk test and histograms and data are expressed as means ± SD or medians
(interquartile range) for normally- and non-normally distributed data, respectively. We analysed
the data using BMI, age and ethnicity as co-variates. Since cardiovascular function changes with
gestational age, and in order to compare haemodynamic characteristics across groups with
different gestational ages, we transformed all data in relation to that obtained from women with
healthy pregnancies using the statistical technique of z-scoring. This removed the need for a
gestation-matched cohort design and allowed all data points to be considered.16 Briefly,
measurements were transformed to the corresponding Z scores with reference to means and SD
values derived from Controls in four-weekly gestational epochs (24-27+6; 28-31+6; 32-35+6 and
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36-39+6 weeks) for CO, PVR, AIx and PWV. The Z scores of each cardiovascular parameter
were then compared using unpaired t-test. In our cohort, heart rate did not change with gestation
and comparisons were made with untransformed data.
Results
Forty-five pathological pregnancies (14 ‘PE only’, 16 ‘FGR only’, 15 ‘PE and FGR’) were
recruited, of whom three had a prior history of PE and or FGR. All women remained within the
category to which they were first assigned at recruitment. A further sixty four women with
healthy pregnancies and normal pregnancy outcomes were studied across the gestation, yielding
one hundred and seven healthy pregnancy observations. Kruskal- Wallis test showed no
statistically significant differences between age and ethnicity within the 4 groups. The group
with ‘PE’ had a higher booking BMI when compared to the control group (P =0.001) [Table 1].
Cardiovascular parameters in pathological and control groups are presented in Table 2. The
cardiovascular parameters in pathological pregnancies are presented in Table 3; Z scores were
calculated in relation to control cases from healthy pregnancies which were subdivided into four
weekly gestational epochs.
FGR only
In women with FGR only, PVR Z score was significantly higher (0.57 ± 1.18, p= 0.04) [Figure
3], and CO Z score was no different to healthy controls (-0.35 ± 0.99, p= 0.19) [Figure 4]. The Z
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scores of AIx (1.18 ± 1.44, p= 0.0001) [Figure 5] and PWV (0.87± 1.34, p= 0.002) [Figure 6]
were higher than controls.
PE only
Women with PE only had a higher CO Z score than controls 1.87 ± 1.35, p= 0.0001) [Figure 4],
a lower PVR Z score (-0.76 ± 0.89, p= 0.025) [Figure 2], higher AIx Z score (1.52 ± 1.39, p=
0.0001) [Figure 5] and higher PWV (0.71 ± 1.47, p=0.05) [Figure 6].
Of the 13 women with PE only, 7 women were examined before starting anti-hypertensive
medication, 3 women were on labetalol and 1 on nifedipine. The Z scores for CO and PVR of
those examined on treatment versus those without were not different (p= 0.55 and p = 0.57,
respectively).
PE and FGR
In PE and FGR cases, a lower CO Z score (-0.80 ± 1.3, p=0.007) [Figure 4] and higher PVR Z
score (2.16 ± 1.95, p= 0.0001) [Figure 3] was observed compared to controls. There was higher
AIx Z score (1.45 ± 1.09, p= 0.0001) [Figure 5] and higher PWV Z score (2.01 ± 1.55, p=
0.0001) [Figure 6].
Of the 14 women with ‘PE and FGR’; 3 were examined before starting anti-hypertensive
medication, 4 were taking labetalol, 2 nifedipine and 3 both labetalol and nifedipine. Comparing
the Z scores for CO and PVR of those examined on treatment versus those without, there were
no differences (p=0.52 and p=0.99, respectively).
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Heart Rate
There was no difference in observed heart rate between the four groups. (p=0.26) [Figure 7].
Gestation vs CO/PVR
When compared across gestation (decimal weeks by estimated due date derived from dating
scan), there was no relationship between gestation and either CO Z score (Pearson correlation =
0.16, p = 0.35) or PVR Z score (Pearson correlation = -0.21, p = 0.2) for PE only, FGR only and
PE and FGR.
There was no difference between CO Z score (p=0.41) or PVR Z Score (p=0.18) in ‘PE only’
prior to 34 weeks and those after 34 weeks. In ‘PE and FGR’ cases, there was again no
difference between CO Z score (p=0.34) or PVR Z score (p=0.76) in cases prior to 34 weeks and
those after.
CO vs Z score birth weight
Within the group of women with PE (‘PE only’ and ‘PE and FGR’), CO was positively
associated with Z score birth weight (r= 0.42, p=0.03). Within the group of women with ‘FGR
only’, CO was not associated with Z score birth weight (r=0.27, p=0.31).
Post Hoc power calculation
Since this was novel work, a formal sample size calculation prior to undertaking the study was
not possible and the enrolment period was guided by our previous pre-pregnancy studies in
healthy women27,31,32. However, a formal post hoc power calculation, assuming four unequal
groups and a standard deviation for the CO z-score equivalent to the highest SD obtained in the
three pathological pregnancy groups, gave >98% power to detect a significant overall difference
in CO z-score, at an alpha level of 0.05.
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Discussion
We report that women with ‘PE only’, ‘FGR only’ and ‘PE and FGR’ have distinctly different,
and, in some cases, opposing cardiovascular characteristics. The predominant abnormalities in
‘PE only’ were a higher CO and lower PVR, while ‘FGR only’ was characterized by higher PVR
than healthy pregnancies. When both PE and FGR occur together, the effect was a cardiovascular
phenotype characterised by a markedly higher PVR and lower CO than FGR only. Previous
studies of PE and FGR have reported inconsistent findings however none have studied
haemodynamic findings across the whole gestation range in relation to healthy pregnancies
recruited concurrently, nor have considered FGR, PE and PEFGR as separate entities.
Recently, a meta-analysis by Castleman18 found that in gestational hypertensive
diseases “severity of disease corresponded with increasing vascular resistance”. We suggest that
this is an oversimplification in that according to our data it holds for PE with FGR; the converse
being true for PE not affected by FGR. 18 Irrespective of differences in CO and PVR, all three
pregnancy complications were associated with abnormal arterial function assessed by increased
augmentation index and increased pulse wave velocity.
The implications for understanding of the disease process is important, particularly in respect of
the deeply ingrained, but empirical and arbitrary distinction between ‘early’ and ‘late’ PE with a
“cut off” at 34 weeks.22,33 It is true that the cardiovascular features of early and late PE were
different, but this was purely by virtue of the association with FGR rather than because of the
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gestational age at onset of the disease. ‘PE only’ had the same cardiovascular findings (high CO
and low PVR) at early and late gestational ages, but if PE was associated with FGR, CO was low
and PVR high, irrespective of gestational age. Importantly, in our study, pathological cases were
similarly represented in numerical terms before and after 34 weeks; 24 and 21 cases respectively.
The contradictory findings of previous studies, namely that gestational age is the determinant of
haemodynamic profile in PE, may be explained because PE and FGR commonly co-exist at early
gestational ages 34 and FGR is uncommonly encountered in late PE 14. PE is therefore more
precisely defined by the presence or absence of FGR rather than by virtue of its gestational age at
onset. We trace the origins of the categorization of ‘early’ and ‘late’ PE to a study on the
sensitivity of second trimester uterine artery Doppler for these complications which was high for
‘early’ but low for ‘late’ disease. Interestingly, early PE was frequently found with FGR in that
study.
In women with PE, with and without FGR, we found a significant positive association between
CO Z score and birthweight normalized for gestation which was no different before or after 34
weeks.. We did not specifically select women with PE, with and without FGR, but instead
recruited 'all comers' and categorized FGR based on ultrasound and Doppler findings. Hence,
there was no selection bias within women with PE as it might be argued that a larger fetus and
placenta will 'drive' a larger CO. We previously reported that the incremental increase in
maternal CO from prior to pregnancy to the mid-second trimester was positively associated with
larger birthweight in normally grown babies 35 irrespective of the size of the fetus in the mid
trimester. This suggests that fetal size on its own did not determine CO. A recent study in women
with PE found that those with the lowest CO had the smallest babies 15. There is strong-albeit
circumstantial-evidence that CO may be at least in part responsible for birthweight, likely
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mediated through an effect on uteroplacental perfusion. Though this is tempting to speculate, we
cannot infer causality from our results.
Of direct clinical relevance is that the current management of hypertension in pregnancy is
exclusively based on a ‘one size fits all’ philosophy where BP alone is the target of therapy
irrespective of the underlying aetiology. 36,37 This approach does not distinguish between PE with
FGR (low CO and high PVR) from PE without FGR (high CO). There is, however, a clear
rationale in targeting therapy according to the underlying cardiovascular phenotype. Drugs with
beta blocking activity are negatively chronotropic and reducing CO may be harmful in women
with FGR where the uteroplacental circulation is already impaired; previous studies have
reported an association with small for gestational age babies 38-40. We report that PE only was
typically associated with high CO: for these women, a beta blocker might be preferable whereas
a drug leading to vasodilation primarily, such as a calcium channel antagonist, may be less
effective. Conversely calcium antagonists are likely to be more effective in the high PVR state
that characterizes PE with FGR. Though a model using haemodynamic parameters to determine
response to labetalol in gestational hypertension has been reported 41, the effectiveness of anti-
hypertensive agents with different modes of action has not. Indeed, if impaired utero-placental
function is the by-product of a low CO-high PVR state such as that found in PE with FGR, then
this should be amenable to targeted manipulation. Recent approaches have included expanding
the intravascular compartment 42, with and without nitrovasodilators 43 and calcium antagonists 44
with reported improvement in maternal cardiovascular and/or fetal parameters.
Arterial function was abnormal in ‘PE only’, ‘FGR only’ and the combination of both ‘PE and
FGR’ as assessed by AIx and PWV, irrespective of whether CO and PVR were increased or
decreased. Aortic AIx is an index of wave reflection and may be considered as a measure of
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arterial function 45-48. Raised AIx is an important predictor of future cardiovascular risk 49 and in
hypertensive patients an independent predictor of future myocardial infarction 50. Although AIx
is influenced by endothelial function, PWV describes aortic stiffness and is determined largely
by the elastic component of large vessels. It is also known to be a reliable marker of
cardiovascular risk in patients with hypertension 51.
The strength of this study is that detailed cardiovascular assessments were undertaken in women
who were phenotyped according to accepted definitions for both PE and FGR. Importantly, our
definition of FGR did not rely simply on fetal smallness52, but required abnormal fetal umbilical
artery Doppler. Our sample size allowed a high power to detect small differences in CO between
the groups. A weakness is that as our protocol required time consuming examinations, not all
women wished to or could take part, in particular where delivery or further therapy was being
planned. This limited the number of women eligible for recruitment, but there was no attempt at
selection other than through women consenting or otherwise for logistical and therapeutic
reasons. Furthermore, though we intended to recruit women prior to starting anti-hypertensive
treatment, these drugs were often started prior to hospital admission. Though we found no
difference in CO and PVR within the ‘PE only’ and ‘PE and FGR’ groups for those on
antihypertensive treatment, the modest numbers within these groups preclude discrimination
between small effect sizes in anti-hypertensive agents and the duration of therapy.
Whilst not being validated specifically in pregnancy, Innocor has been validated extensively in
healthy populations and those with diseases, including chronic heart failure and during
haemodynamic perturbation caused by exercise as a method of assessing cardiac output. 53-56 In
addition, our group has previously shown that this method has good reproducibility in pregnant
women and is sensitive enough to detect longitudinal changes in CO both in very early
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pregnancy and throughout the gestation period.27,35,57 All our participants were examined in a
similar position which limits any potential bias. Moreover as the gas re-breathing method is not
operator dependent, there is no-inter observer bias compared to echocardiography, which is the
other widely used method. The Vicorder has been validated for use against SphygmoCor which
is the most widely used technique to assess pulse wave velocity. There is no agreed gold
standard non-invasive technique to assess pulse wave velocity in pregnancy.58
In summary, we found no evidence to support the categorization of PE of “early” and “late” as
different disease processes, though early onset PE was much more likely to be associated with
FGR. The significance of this is that PE which is not associated with FGR has the same
cardiovascular phenotype, namely high CO whether it is diagnosed at 24 or 36 weeks. The
presence of FGR was associated with high PVR whether or not in combination with PE. Whether
the abnormal haemodynamic profiles that we have observed in the distinct subtypes of PE, FGR
and PE combined with FGR are the cause of the clinical manifestation of hypertension and FGR,
or the effect of an inherent underlying maternal cardiovascular dysfunction is unclear. This study
raises an intriguing question as to whether the cardiovascular dysfunction seen in pathological
pregnancies is a result of maladaptation to the increased cardiovascular demands of pregnancy in
a woman with normal cardiovascular function, or is predisposed by an inherently abnormal pre-
pregnancy cardiovascular status and its expression modulated through placental release of
vasoactive substances.
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Acknowledgments: We wish to thank the participants for taking part at what for many was a
critical and difficult point in their pregnancies
Author contributions: JT was involved in data collection, statistical analysis and drafting the
manuscript. LF, GM, CMM contributed to analysis and interpretation of the manuscript.
PB, CMM, IBW, CCL were involved in project supervision and manuscript editing. CCL
conceived the idea for this study and is the principle investigator.
Funding: JT is funded by Imperial College NHS Trust with support from the Imperial
Healthcare Charities. CCL and PB are supported by the UK National Institute for Health
Research Biomedical Research Centre (BRC) based at Imperial College Healthcare
National Health Service Trust and Imperial College London. CMM is funded, in part by
the NIHR Cambridge BRC. LF is supported by Action Medical Research, Tommy’s and
the Genesis Research Trust.
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