CC BY-NC-ND 4.0 · Geburtshilfe Frauenheilkd 2021; 81(08): 966-978
DOI: 10.1055/a-1345-8733
GebFra Science
Original Article/Originalarbeit

Cardiovascular Risk Reduction in Women Following Hypertensive Disorders of Pregnancy – a Prospective, Randomised, Controlled Interventional Study

Article in several languages: English | deutsch
Marcus Riemer
1   Universitätsklinik und Poliklinik für Geburtshilfe und Pränatalmedizin Halle, Martin-Luther-Universität Halle-Wittenberg, Halle, Germany
2   Klinik für Geburtshilfe, Krankenhaus St. Elisabeth und St. Barbara Halle, Halle, Germany
,
Stephan Schulze
3   Department für Orthopädie, Unfall- und Wiederherstellungschirurgie, Martin-Luther-Universität Halle-Wittenberg, Halle, Germany
,
Lisa Wagner
1   Universitätsklinik und Poliklinik für Geburtshilfe und Pränatalmedizin Halle, Martin-Luther-Universität Halle-Wittenberg, Halle, Germany
,
Manon Richter
4   Institut für Leistungsdiagnostik und Gesundheitsförderung, Martin-Luther-Universität Halle-Wittenberg, Halle, Germany
,
Gertrud Ayerle
5   Institut für Gesundheits- und Pflegewissenschaft, Martin-Luther-Universität Halle-Wittenberg, Halle, Germany
,
Andreas Simm
6   Universitätsklinik für Herz- und Thoraxchirurgie Halle, Martin-Luther-Universität Halle-Wittenberg, Halle, Germany
,
Sven Seeger
2   Klinik für Geburtshilfe, Krankenhaus St. Elisabeth und St. Barbara Halle, Halle, Germany
,
René Schwesig
3   Department für Orthopädie, Unfall- und Wiederherstellungschirurgie, Martin-Luther-Universität Halle-Wittenberg, Halle, Germany
,
Michael Tchirikov
1   Universitätsklinik und Poliklinik für Geburtshilfe und Pränatalmedizin Halle, Martin-Luther-Universität Halle-Wittenberg, Halle, Germany
,
Gregor Seliger
1   Universitätsklinik und Poliklinik für Geburtshilfe und Pränatalmedizin Halle, Martin-Luther-Universität Halle-Wittenberg, Halle, Germany
› Author Affiliations
 

Abstract

Background Women have a markedly increased lifetime risk for cardiovascular morbidity and mortality following hypertensive disorders of pregnancy. Arterial stiffness is regarded as a target parameter for reducing cardiovascular risk and can be modified by lifestyle changes.

Methods In a prospective, randomised, controlled interventional study, starting 6 weeks postpartum, the effect of nutritional intervention combined with an intensive 6-month cardiovascular exercise programme on arterial stiffness was investigated by means of pulse wave velocity (PWV) in 38 women with severe hypertensive disorder of pregnancy (preeclampsia with or without pre-existing hypertension and/or HELLP syndrome). A reference group was formed with postpartum women without pregnancy complications or known cardiovascular risk and the arterial stiffness was studied by means of PWV at the time of delivery. The PWV was measured in the intervention and control groups within a week after delivery and after 32 weeks (6 weeks + 6 months). A feasibility analysis was performed in addition.

Results 29 of 38 women with severe hypertensive disorder of pregnancy and 38 postpartum women in the reference group were included in the analysis (intervention group n = 14; control group n = 15; reference group n = 38). Adherence to a) the nutritional counselling and b) the intensive cardiovascular exercise programme was 73% and 79% respectively. A clinically significant difference (d = 0.65) in pulse wave velocity between the intervention and control groups was found after 6 months (6.36 ± 0.76 vs. 7.33 ± 2.25 m/s; group × time: p = 0.632). The PWV of the intervention group corresponded to that of the reference group at the end of the study (6.36 ± 0.76 m/s vs. 6.5 ± 0.70; d = 0.19), while the results in the control group differed markedly from this (7.33 ± 2.25 m/s; d = 0.56).

Conclusion The study documents the feasibility of lifestyle intervention with physical exercise after delivery (starting 6 weeks postpartum). The intervention showed a significant clinical effect by reducing arterial stiffness to the level of the reference group. Before this intervention can be included in the standard of care and prevention, follow-up studies must confirm these results and the medium-term effects on cardiovascular risk.


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Introduction

Up to 8% of pregnant women suffer from a hypertensive disorder of pregnancy such as preeclampsia, and the incidence is increasing [1], [2]. Preeclampsia is regarded as the leading cause of maternal death in industrialised nations [3], [4], [5]. Apart from the short-term morbidity, preeclampsia increases the long-term cardiovascular risk [6]. Women who have had preeclampsia suffer cardiovascular and cerebrovascular events such as heart attack, heart failure, stroke and terminal kidney failure more often and earlier [6], [7], [8], [9]. Cardiovascular diseases, in particular, have been accepted for decades as the leading cause of death globally independent of sex [10]. In Germany alone cardiovascular diseases were the main cause of death in 2015, with 365 000 deaths (39% of all deaths) and the disease costs were 46.4 billion Euro (13% of total costs) [11], [12]. Consequently, not only the immediate treatment of hypertensive disorders of pregnancy [13], but also the (secondary) prevention of cardiovascular disease following hypertensive disorders of pregnancy is one of the major challenges of innovative medicine in the 21st century.

Regular physical activity can have a positive effect on the lifetime risk for cardiovascular disease, including after preeclampsia [14], [15]. Both the American Heart Association and the European Society of Cardiology proclaim in their guidelines at least 75 min of intensive or 150 min of moderately intensive, aerobic exercise weekly – regardless of pre-existing disease or risk factors – as cardiovascular prevention for the entire population [16], [17].

Apart from regular physical exercise in the form of active sport, a varied and regular diet low in carbohydrate and salt and with reduced saturated fatty acids and high in protein is essential [18], [19], [20], [21].

Pregnancy can also be regarded in otherwise clinically healthy women as a “window to future health” [22], [23], [24], [25]. In this connection, therefore, the postpartum assessment of cardiovascular health risks and secondary and tertiary preventive treatment are of great importance.

Arterial stiffness is an important biomarker for predicting cardiovascular events. Vascular stiffness and thus vascular age increase due to structural changes in the vessel walls with endothelial dysfunction. Because of the increase in velocity of the pulse wave generated in systole, this leads to earlier reflection of this in the periphery and thus to an increase in cardiac afterload. Arterial stiffness is measured non-invasively by means of pulse wave velocity.

Sanders et al. [26], referring in their comments to Zieman et al. [27], conclude that vascular stiffness can be used as a treatment goal even in a young population with cardiovascular risks but that studies must show evidence of an improvement in the results due to treatment-related changes [26], [27].

Arterial stiffness has become an interesting target and the focus of scientific interest because it is measured non-invasively by aortic pulse wave velocity (aPWV) and it is readily available and reproducible including in pregnant women and in the puerperium [28]. Kaihura et al. [29] showed that arterial stiffness is significantly increased at the time of delivery in women with preeclampsia compared with healthy pregnant women. In both the short and long term, arterial stiffness and therefore biological vascular age remain markedly elevated in the group of women who have had preeclampsia [29], [30]. Scholten et al. [14] presented data from an exercise intervention for 12 weeks in women following preeclampsia 6 – 12 months postpartum. They found an improvement in metabolic syndrome factors in the post-preeclampsia and control group but no normalisation of the vascular variables in the women who had had preeclampsia [14]. Thus, both the intervention duration and the timing of the intervention after preeclampsia appear to influence the success of vascular normalisation.

The aim of this study was the reduction of arterial stiffness after the conclusion of the puerperium by means of a complex intervention consisting of basic aerobic endurance exercise and nutritional counselling in women with severe hypertensive disorder of pregnancy (preeclampsia with or without pre-existing hypertension and/or HELLP syndrome). In addition, the acceptance, motivation and adherence of the patients with regard to the planned complex, interdisciplinary, interprofessional and cross-sector interventions were examined in feasibility analyses.


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Methods

Recruitment

The study was conducted at the University Department of Obstetrics and Prenatal Medicine Halle, (Saale) and at St. Elisabeth and St. Barbara Hospital Halle (Saale) from 2016 to 2019 (ClinicalTrials.gov Identifier: NCT02754778). Recruitment took place over 24 months.

Potential subjects were screened for participation in the study in accordance with the inclusion and exclusion criteria within 7 days after delivery if they had a severe hypertensive disorder of pregnancy (preeclampsia with or without pre-existing hypertension and/or HELLP syndrome) and were invited to take part if the inclusion and exclusion criteria were met and adequate communication was possible (acquisition). After consenting to take part in the study, the first study visit took place with randomisation to the intervention and control group in the ratio 1 : 1 using a web-based random generator (recruitment).

The inclusion and exclusion criteria and previous findings, especially with regard to cardiovascular disease were established from the medical history, review of the maternity log and, if necessary, obtaining previous external reports in the event of uncertainties.


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Inclusion criteria

Women over 18 years with evidence of preeclampsia with or without pre-existing hypertension and/or HELLP syndrome ([Fig. 1]) on the day of delivery and up to 7 days postpartum after full differential diagnosis and according to the definition of the 2016 S1 guideline “Diagnosis and treatment of hypertensive disorders of pregnancy” and who had capacity to give consent were included [31], [32].

Zoom Image
Fig. 1 Definition criteria according to S1 guideline 015/018: Diagnosis and treatment of hypertensive disorders of pregnancy (as of 12/2013) [45].

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Exclusion criteria

Women were excluded who had heart failure > NYHA II, peripheral arterial disease (regardless of stage) or a serious neurological or orthopaedic disease postpartum, which would have made exercise training on the bicycle ergometer impossible. Women whose newborn or premature baby required intensive care at home and who could not have been expected to make the journey to the weekly exercise session were also excluded.


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Discontinuation criteria

If any of the points listed in the exclusion criteria appeared only in the aerobic basic endurance exercise, these subjects had to drop out of the study.


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Internal medicine check-up

The subjects in the intervention group also had a medical check-up 5 weeks postpartum (± 7 days) to obtain independent medical approval for the exercise intervention.


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Reference group of healthy women (inclusion/exclusion criteria)

In the participating hospitals, the same number of women without a history or diagnosis of pregnancy complications and without known previous cardiovascular disease, who were legally of age and capable of giving consent and when the babyʼs course was uncomplicated – regardless of case number estimation – were recruited for the study as a reference group for aortic pulse wave velocity measurement up to 7 days after delivery (reference group recruitment target: 38 women).


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Measurement of pulse wave velocity

The cuff-based Vicorder® (SMT Medical, Würzburg, Germany) was used to measure the aortic pulse wave velocity as the gold standard for determining arterial stiffness. This has already been validated repeatedly in studies against alternative measurement methods such as tonometry and magnetic resonance imaging [33], [34], [35], [36]. The measurements were done in a standardised setting in the patientʼs air-conditioned room in the respective hospital (room temperature 22 – 25 °C, in supine position, after resting for 10 min, upper body elevated 30°). At the patientʼs bedside, the measurement setting was adjusted to be equivalent to that used for the Vicorder validation study [37]. Comparable settings were also used in studies elsewhere of non-invasive measurement of pulse wave velocity (tonometric, oscillometric), e.g., in children, simultaneously in MRI and in intensive care units and during angiological interventions in the operating theatre [38], [39], [40], [41], [42]. If the baby had not been transferred to the neonatal ICU but was in the room with the patient, it was given into the care of the ward nurse while the measurements were performed. A 10 cm wide BP cuff was then applied around the right thigh to measure the femoral pulse and a narrow 3 cm cuff was placed around the neck at the level of the right carotid artery to measure this. The distance between the jugular fossa and the cranial edge of the cuff applied to the thigh was measured as recommended by the manufacturer. Unlike the usual use of the Vicorder a tape measure was not used but rather a pelvimeter so as to avoid an incorrect measurement of length due to the postpartum distension of the abdominal wall. Both cuffs were pumped up to 65 mmHg and 2 high-quality measurement curves were recorded for 3 seconds simultaneously by means of a volume displacement, from which the aPWV was derived [43]. The measurement was repeated 3 times in succession and the mean of all 3 measurements was used for statistical analysis.

The pulse wave velocity was measured in the intervention and control group both on the day of inclusion in the study (time 1 [T1]) and after 32 weeks (6 weeks puerperium + 6 months intervention period, time 2 [T2]) and at the start of the exercise intervention in the subjects of the intervention group ([Fig. 2]). In the reference group of healthy subjects, the measurement took place once on the day of inclusion in the study (T1).

Zoom Image
Fig. 2 Flow chart for the different study phases.

In the intervention and control group the first measurement was done at the patientʼs bedside in the delivery ward and the second measurement and final measurement on an examination couch. Stressors that influence blood pressure and also the newborn babies were not present in the examination or patientʼs room during the measurement.


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Ergometry

Following the analysis of vascular stiffness, exercise ergometry was performed in the sport science laboratory in a standardised setting on a bicycle ergometer (motion cycle 600 med, emotion Fitness, Hochspeyer, Germany). An exercise protocol based on the WHO protocol was used (initial workload 25 watts, increment 25 watts, stage duration 3 min) at a specified frequency of 60 – 65 revolutions/min. To generate a submaximal load, reaching a target heart rate of 150 beats/min was defined as stop criterion. The load stage at which this value was reached was completed and the performance was reduced to 25 watts in the subsequent active cool-down. Before the start of the test, at the end of each load stage and after a 2 and 4 minute recovery period, the lactate level in capillary blood was determined (drawn from the hyperaemised earlobe) and the heart rate was recorded (RS800 CX, Polar electro Oy, Kempele, Finland). The test results were analysed using Winlactat software (version 4.7; mesics GmbH, Münster, Germany) and the individual lactate threshold (LT) of the lactate performance curve was determined as the limit of the performance generated mainly aerobically for controlling the load in the subsequent intervention phase [44].


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Exercise programme to increase aerobic basic endurance and general strength endurance

During the 6-month intervention phase an exercise unit was performed once a week under laboratory conditions. The exercise consisted of a heart rate-controlled exercise unit on a bicycle ergometer, with the load parameters based on the lactate threshold test results. Starting with a load duration of 25 min at the heart rate at the LT (HRLT; mean: 129 beats/min; min.: 121 beats/min; max.: 137 beats/min) the load duration in the intervention period was gradually increased to 50 min within 14 weeks. The ergometer training was followed by strength and mobilisation training guided by a trained midwife. At the start of the intervention phase the focus was on postnatal and general pelvic floor exercises (c. 15 min). In the course of the intervention period, depending on individual performance, general trunk-stabilising exercises (isometric postural exercises, simple coordinated strengthening exercises, mobilisation exercises) were added. Similarly to the ergometer training, the exercise duration was gradually increased from 15 to 30 min. The subjects were responsible for including additional weekly exercise in their daily routine consisting of a brisk walk at an interval of 2 to 3 days. They were asked about this at each exercise date and the answer was documented in the training record.


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Individual nutritional counselling

Apart from the risk factors according to the guideline [45], the lifestyle factor “Nutrition” was examined in more detail in the hospital discharge and final interview with all study patients in the intervention and control groups and the treating doctors explained this factor in their counselling. This counselling, based on the 10 nutritional rules of the German Nutrition Society (DGE), concentrated on a Mediterranean diet as well as fat quality, whole-grain products, fruit and vegetable intake and also salt reduction. All patients were also motivated actively in this discussion to change their lifestyle (including regular physical exercise).

The patients in the intervention group also had a second and third individual nutritional counselling session (each of 90 – 120 min, 6 weeks postpartum and 32 weeks postpartum → final session). The content of these counselling sessions by a nutritional adviser and qualified dietician certified according to German Nutrition Society regulations consisted of:

  • nutritional counselling based on the nutritional rules of the German Nutrition Society (DGE), including the Mediterranean diet as well as fat quality, whole-grain products, fruit and vegetable intake and also salt reduction,

  • Medical history (history questionnaire – Society for nutritional therapy and prevention [FET] e. V.),

  • Determination of body weight and composition (TANITA® BC-545),

  • Recording of the nutritional behaviour using a questionnaire (after Winkler 1998) [46].


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Feasibility analysis

To examine the feasibility of the study, adherence with nutritional counselling and the aerobic basic endurance exercise were documented by the study personnel at all contacts. In addition, the subjects were given a direct possibility for feedback through analysis of nutrition and performance tests at the beginning and end of the aerobic basic endurance exercise. In the dropout subjects, the reasons were evaluated and the subjects were asked about this. The subjects were also given the possibility of giving their feedback on the study personally by email at any time during the nutritional counselling sessions, measurements of pulse wave velocity or aerobic basic endurance exercise so as to achieve greater adherence to the study.

In particular, the midwife-supported setting in the context of the exercise, in addition to ensuring qualified care of the baby, was also designed to give the subjects the opportunity of obtaining the midwifeʼs advice on specific topics such as postnatal recovery, breast-feeding or psychosocial questions and problems.


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Estimation of case numbers and statistical analysis

In advance of the pilot study, the case numbers were estimated at the Institute for Medical Epidemiology, Biometrics and Informatics of Martin Luther University Halle-Wittenberg, based on the changes in pulse wave velocity (primary outcome) within 6 months. At a significance level of p < 0.05, a power (1-beta) of 80%, a 2-sided t-test and an assumed difference in the mean of 0.90 m/s between the healthy population of the same age (pulse wave velocity: 6.35 m/s) and the intervention group after 6 months (7.25 m/s), at a given standard deviation of 1.00 m/s, at least 17 subjects are needed per group, with an expected dropout of 20% [47], [48]. Accordingly, 20 subjects would have to be included initially in both groups.

Statistical analysis of the data was performed with SPSS version 25.0 (SPSS Inc., IBM, Armonk, NY, USA). Continuous and categorical variables were shown as mean ± standard deviation (SD) or as a percentage. Differences in the mean were examined by general linear model. In addition the effect size was calculated according to Hartmann et al. (1992) (difference in the mean divided by the pooled standard deviation of the 2 measurement times [T]) [49]. The interpretation of the effect sizes is based on Cohenʼs recommendations (1988) [50]. According to this, small effects (d < 0.5) must be distinguished from moderate effects (d < 0.8) and large effects (d ≥ 0.8). Positive effect sizes are interpreted as an increase in performance.

Differences in the mean were interpreted as significant when p < 0.05 and d > 0.5, ηp 2 > 0.10 and the power (observed power) was greater than 0.8 [51].

Relations between metrically scaled variables were examined by means of product-moment correlations (Pearson).


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Ethics committee approval

The study was approved by the ethics committees of the medical faculty of Martin Luther University Halle-Wittenberg and of the Medical Council of Saxony-Anhalt (decision no.: 2015-134) and then registered in ClinicalTrials.gov (identifier: NCT02754778).


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Results

Subjects

In the period from May 2016 to April 2018 (24 months) 344 women were screened for the interventional part of the study and 198 women were approached according to the inclusion and exclusion criteria and if adequate communication was possible (acquisition). 38 women gave their consent to take part in the study and were randomised (recruitment) ([Table 1]).

Table 1 Demographic and anthropometric subject characteristics.

Variables

Intervention group

n = 14

Control group

n = 15

Total

n = 29

Total

n = 38

The data are given as ° mean ± standard deviation and * number (percentage).

IUGR: intrauterine growth retardation; BP: blood pressure

Age (years)°

31 ± 3.89

31 ± 3.32

31 ± 4

31 ± 5

Height (cm)°

166 ± 5.55

167 ± 7.03

166 ± 6

168 ± 7

Weight (kg)°

86.3 ± 14

87.5 ± 19.5

86.9 ± 17

82.3 ± 11

Abdominal girth (cm)°

104.2 ± 9.80

108.1 ± 16.23

106.3 ± 14

102.6 ± 10

Thigh circumference (cm)°

61.3 ± 8.04

62.4 ± 11.32

61.9 ± 9.6

57.8 ± 7.0

Systolic BP postpartum (mmHg)°

148 ± 16

148 ± 10

148 ± 13

120 ± 11

p < 0.01

Diastolic BP postpartum (mmHg)°

85 ± 9

84 ± 9

85 ± 9

72 ± 7

p < 0.01

Delivery (weeks of pregnancy)°

36 ± 4

35 ± 5

36 ± 5

40 ± 2

p < 0.01

Birth weight (g)°

2547 ± 960

2114 ± 1054

2323 ± 1016

3505 ± 513

p < 0.01

Pre-existing hypertension*

1 (7)

3 (20)

4 (14)

1 (3)

Primigravida*

9 (64)

6 (40)

15 (52)

16 (42)

Primipara*

13 (93)

10 (67)

23 (79)

22 (58)

Multiple pregnancy*

2 (14)

2 (13)

4 (14)

0 (0)

p < 0.05

Previous infertility treatment*

4 (29)

4 (27)

8 (28)

0 (0)

p < 0.01

Pathological uterine resistance*

2 (14)

4 (27)

6 (21)

0 (0)

p < 0.01

IUGR*

3 (21)

6 (40)

9 (31)

3 (8)

p < 0.05

For the reference group, 627 women were screened (the entire birth cohort of both study sites in the period from May 2017 to June 2017). 105 women met the requirements for inclusion in the reference group; these were addressed by the study team (acquisition). 38 of these women were included in the reference group (recruitment).

The reference group of subjects without previous cardiovascular disease or pregnancy complications examined postpartum did not differ significantly from the subjects who had had preeclampsia with or without pre-existing hypertension and/or HELLP syndrome with regard to age (p = 0.850), height (p = 0.271) and weight (p = 0.496). On the other hand, significant differences were observed in birth weight (p < 0.01), weeks of pregnancy at delivery (p < 0.01) and the rate of intrauterine growth retardation (IUGR) (p < 0.05) and section (p < 0.01). As expected, significant differences were also found in systolic (p < 0.01) and diastolic (p < 0.01) blood pressure ([Table 1]).

The majority of the patients had a form of late-onset preeclampsia appearing after 34 weeks of pregnancy, and there were no significant differences in the frequency of diagnosis between the intervention and control groups ([Table 2]).

Table 2 Frequency distribution with regard to diagnosis and time of diagnosis.

Diagnosis

Intervention group

n = 14

Control group

n = 15

The data are given as a number (percentage).

> 34 weeks

Preeclampsia

7 (50)

6 (40)

Preeclampsia with pre-existing hypertension

1 (7)

2 (13)

HELLP syndrome

3 (21)

2 (13)

≤ 34 weeks

Preeclampsia

1 (7)

1 (7)

Preeclampsia with pre-existing hypertension

0 (0)

1 (7)

HELLP syndrome

2 (14)

3 (20)

The average lowest platelet count (p = 0.971) in HELLP syndrome and the average sFlt-1/PlGF ratio (p = 0.956) did not differ significantly in these groups ([Table 3]).

Table 3 Means of the typical preeclampsia laboratory parameters.

Laboratory parameter

Intervention group

n = 14

Control group

n = 15

The data are given as mean (standard deviation).

sFlt-1: soluble Fms-like tyrosine kinase-1; PlGF: placental growth factor

Minimum platelets (Gpt/l)

77 ± 45

87 ± 33

sFlt-1/PlGF

223 ± 199

241 ± 88


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Effects and test results

The postpartum aPWV at T1 showed a marked difference between subjects who had had preeclampsia with or without pre-existing hypertension and/or HELLP syndrome and the healthy reference group ([Fig. 3]). While the average aPWV of the healthy reference group corresponded to the age class-stratified reference values of the Arterial Stiffness Collaboration Group (< 30 years 6.2 ± 0.75; 30 – 39 years 6.5 ± 1.35) [52], significantly higher pulse wave velocity and thus greater vascular age (6.5 vs. 7.5 m/s, p < 0.01) were found in the subjects with prior preeclampsia and/or HELLP syndrome.

Zoom Image
Fig. 3 Illustration of aortic pulse wave velocity in the study groups at T1 and T3.

Variance analysis (T1 vs. T3; [Table 4]) yielded significant time effects in all parameters when the control and intervention groups were compared, based on the defined criteria of significance (p < 0.05 and ηp 2 ≥ 0.10, d ≥ 0.50 and observed power ≥ 0.80), with the exception of the parameters aPWV, pPWV und AIx. Significant group or interaction effects (time × group) were not observed in this pilot study, probably due to the lack of power and the case number. However, the effect for the parameter aPWV between T1 and T3 was markedly greater in the intervention group than in the control group (d = 0.90 vs. d = 0.56). The greatest individual effects were found in the intervention group for the parameters mean arterial pressure (MAP) (d = 2.82) and systolic blood pressure (syst. BP) (d = 2.52) and in the control group for the parameter syst. BP (d = 1.76).

Table 4 Variance analysis comparison (T1 vs. T3) of the 2 preeclampsia groups.

Control group (n = 15)

Intervention group (n = 14)

Variance analysis p (ηp 2)/observed power

T1°

T3°

d

T1°

T3°

d

Group

Time

Group × time

The data are given as ° mean ± standard deviation and significant differences are shown in bold.

d = effect size; significance level: p < 0.05 and ηp 2 ≥ 0.10, d ≥ 0.50 and observed power ≥ 0.80

AIx: augmentation index; AoPP: aortic pulse pressure; CO: cardiac output; MAP: mean arterial pressure; T: measurement time; BP: blood pressure; SEVR: subendocardial viability ratio; SV: stroke volume

Primary outcome

aPWV (m/s)

7.83 ± 1.64

7.33 ± 2.25

0.54

7.20 ± 1.11

6.36 ± 0.76

0.90

0.095 (0.100)/0.386

0.072 (0.115)/0.439

0.632 (0.009)/0.075

Secondary outcomes

pPWV (m/s)

16.0 ± 9.78

11.4 ± 3.80

0.68

11.7 ± 2.78

10.1 ± 1.82

0.70

0.069 (0.118)/0.448

0.045 (0.140)/0.526

0.311 (0.038)/0.169

AIx (%)

22.5 ± 9.27

15.7 ± 7.29

0.82

21.1 ± 13.4

15.8 ± 5.99

0.55

0.815 (0.002)/0.056

0.015 (0.200)/0.707

0.741 (0.004)/0.062

AoPP (mmHg)

58.0 ± 7.92

46.0 ± 8.09

1.50

55.4 ± 11.1

42.7 ± 5.88

1.50

0.266 (0.046)/0.195

< 0.001 (0.643)/1.000

0.824 (0.002)/0.055

CO (l/min)

7.23 ± 1.67

5.76 ± 1.10

1.06

7.16 ± 1.66

5.30 ± 1.01

1.39

0.543 (0.014)/0.091

< 0.001 (0.555)/1.000

0.493(0.018)/0.103

SEVR (%)

127 ± 38.7

150 ± 22.2

0.76

133 ± 24.0

156 ± 23.5

1.00

0.438 (0.022)/0.118

0.003 (0.280)/0.878

0.951(0.000)/0.050

SV (ml)

88.8 ± 13.1

76.4 ± 9.52

1.10

85.3 ± 12.5

71.7 ± 10.0

1.21

0.283 (0.043)/0.184

< 0.001 (0.609)/1.000

0.760 (0.004)/0.060

syst. BP (mmHg)

148 ± 10.2

127 ± 13.7

1.76

148 ± 15.5

117 ± 9.11

2.52

0.231 (0.053)/0.219

< 0.001 (0.788)/1.000

0.095 (0.100)/0.386

diast. BP (mmHg)

83.7 ± 9.30

73.7 ± 8.40

1.13

85.4 ± 8.85

68.5 ± 6.29

2.23

0.483 (0.018)/0.105

< 0.001 (0.653)/1.000

0.081 (0.108)/0.416

Pulse pressure (mmHg)

64.6 ± 8.93

52.9 ± 7.43

1.43

63.5 ± 10.8

48.8 ± 7.06

1.65

0.338 (0.035)/0.156

< 0.001 (0.653)/1.000

0.436 (0.024)/0.119

MAP (mmHg)

114 ± 8.72

97.4 ± 11.7

1.63

116 ± 9.50

90.4 ± 8.66

2.82

0.368 (0.031)/0.143

< 0.001 (0.798)/1.000

0.058 (0.131)/0.480

Performance at lactate threshold 2 mmol/l (W)

51.6 ± 10.6

60.1 ± 18.1

0.59

0.013 (0.388)/0.756

There was a high correlation between the achieved exercise frequency and performance at the 2-mmol/l lactate threshold, which acted as an indicator of basic aerobic endurance (r = 0.739). Accordingly, the increases in performance (9.36 ± 10.8 W; range: − 5 to 32 W) were greater in the intervention group the more frequent the exercise ([Fig. 4]).

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Fig. 4 Relationship between exercise frequency and the increase in performance achieved at a lactate threshold of 2 mmol/l.

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Feasibility analysis

266 out of the total of 364 exercise appointments (73%) were kept. Each of the 14 subjects in the intervention group took part in at least 50% of the appointments for exercise training. With regard to the intervention group a statistically (p = 0.013) and clinically significant (d = 0.59) increase in ergometer performance at the 2-mmol/l lactate threshold was observed (T1: 51.6 ± 10.6 vs. T3: 60.1 ± 18.1; [Table 4]). Depending on the exercise frequency and intensity (cut-off: ≥ 80%, n = 7), higher performance in watts was seen at the 2-mmol/l lactate threshold when the baseline and final tests were compared (difference in the groups: 18 W vs. 1 W, p = 0.002). Moreover, greater exercise frequency and intensity implied a tendency to lower PWV and thus to decreasing arterial stiffness (6.0 vs. 6.6 m/s, p = 0.099).

All patients availed of the postpartum nutritional counselling in the form of lifestyle changes advised by the study doctors when patients were recruited to the study and on hospital discharge. Only 11 subjects in the intervention group took part 6 weeks postpartum in the first individual DGE-based nutritional counselling session with nutritional analysis, which was conducted by a certified dietitian. 22 of the 28 appointments (79%) for individual DGE-based nutritional counselling (excluding the nutritional counselling in the form of advice on lifestyle changes on recruitment to the study) were kept. Patients who attended both DGE-based nutritional counselling session performed 10 watts more on average on the bicycle ergometer at the conclusion of the intervention than those who had taken part only in the nutritional counselling in the form of lifestyle change advised on the occasion of hospital discharge (14 vs. 4 W, p = 0.04). Lower aPWV and therefore improved arterial stiffness were also seen in patients who had two individual DGE-based nutritional counselling sessions compared with only one session (6.1 vs. 6.7 m/s, p = 0.06).


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Dropouts

A total of 5 subjects in the intervention group and 4 subjects in the control group dropped out of the study on their own motivation in all cases. While dealing with grief because of the postpartum death of the baby was the main reason for dropping out in one case, there were organisational or structural problems (physical distance, excessive demands with the child, language and cultural barrier) including in motivation in the other 8 cases. No dropout was indicated medically. All dropouts occurred between 6 weeks and 32 weeks postpartum.


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Discussion

The increasing incidence of preeclampsia in western industrial nations (including because of the steadily increasing average age of pregnant women), increased life expectancy and consequently the sequelae of preeclampsia for lifelong cardiovascular risk are important reasons for focussing scientific research on the secondary and tertiary prophylaxis of cardiovascular events after preeclampsia [6], [53], [54], [55], [56]. The “window to future health” within pregnancy – acting like a cardiac stress test – makes possible secondary prevention if indicated of cardiovascular disease in women who have had hypertensive disorders of pregnancy such as preeclampsia and HELLP syndrome.

An important difficulty in secondary and tertiary prophylaxis is represented by the apparent recovery of a majority of patients who feel hardly any symptoms at the end of the postpartum period and who are also liable to be distracted from their own health because of caring for their infant, with the change in their role from that of a pregnant woman to that of a mother. In reality, only about a quarter of women who have had preeclampsia are prepared to take part in an additional exercise/sport unit at least once a week if it is left up to them (surveyed 6 months postpartum) [57]. In addition, it was apparent that 27 of 78 surveyed patients did sport less frequently after the index event (preeclampsia) than before the pregnancy (increase in frequency in only 6 of 78 patients). Available studies show that unaffected women can be motivated to more physical activity by convincing information about health aspects [58]. In this study, in addition to consistent advice in the pre-discharge discussion with these patients, involvement of a midwife in the exercise setting subsequently laid an effective foundation for good adherence of the subjects to the aerobic basic endurance exercise. Ensuring care of the newborn baby and the possibility of discussing delivery-related problems with the midwife thus acted as a reassuring factor. In future studies to confirm the results of this study, inclusion of such an exercise programme in midwivesʼ clinics in conjunction with postnatal exercise classes is worth considering for women who have had hypertensive disorders of pregnancy and could further enhance the already considerable value of the midwives beyond delivery, for instance with regard to subsequent pregnancies. The psychosocial peer group contacts that take place in these postnatal classes are also of value. Socioeconomic aspects can be latent reasons for a) lack of exercise compliance and b) for rejection of general lifestyle changes and should be investigated in detail. Future studies should therefore focus, among other things, on the evaluation of reasons for dropping out of the study and also on the development of alternative possibilities for patients who cannot follow the exercise training because of exclusion criteria. Only in this way can secondary and tertiary prevention concepts be devised that also offer solutions for women in precarious social or familial situations.

A high level of intrinsic patient motivation also remains crucial, and this is inevitably linked with the care and current health of the baby and sometimes multiple babies or when she already has older children to care for.

This study in a group of women who had had severe hypertensive disorders of pregnancy (preeclampsia with or without previous hypertension and/or HELLP syndrome) showed for the first time that:

  • There is a high level of willingness to take part actively in aerobic basic endurance exercise in conjunction with nutritional counselling,

  • Aerobic basic endurance exercise (intervention) can reduce arterial stiffness as a biomarker for the risk of cardiovascular disease.

In the control group, a biological vascular age corresponding to that of the healthy population at least 10 years older was shown 32 weeks after delivery, while the subjects in the intervention group showed a pulse wave velocity corresponding to the biological vascular age of the healthy population of the same age (comparison in [Table 4] and reference values [52]). An increase in PWV of 1 m/s corresponds to a risk increase of 15% for cardiovascular morbidity and events [59].

The results of this pilot study confirm the hypothesis of the short- and medium-term effect of a regular exercise intervention to reduce vascular stiffness and hence the cardiovascular risk at least to the level of the healthy population of the same age following preeclampsia with or without previous hypertension and/or HELLP syndrome. Nevertheless, the success of the intervention appears to depend crucially on starting promptly after the end of the puerperium and continuing for at least 6 months as, by contrast, Scholten et al. [14] with a similar intervention for only 12 weeks starting 6 months postpartum were unable to show any improvement in the vascular status of women with previous preeclampsia.

If the preventive effects of the aerobic basic endurance exercise are perpetuated, women in the intervention group would not develop cardiovascular disease or, if they did, would at least do so much later. This would result in a gain for the overall population from the health and economic points of view. For instance, estimates of the annual costs of disease and absence from work due to lack of exercise and the resulting cardiovascular disease in Germany alone amount to up to 21 billion Euro [60], [61].

The results are an impetus to initiate a larger multicentre, randomised, complex interventional study, which should also look at an evaluation of other risk factors/biomarkers in addition to standardising the sports and nutritional medicine setting. Only a long-term follow-up study can confirm the improved outcome, similar to the Framingham study.

Applying the results to the standard care of women with preeclampsia with or without previous hypertension and/or HELLP syndrome requires calculations of cost-effectiveness, which take into account, on the one hand, how much the exercise units cost and the adherence of the participating women and, on the other hand, what reduction in morbidity can be expected and how much can be saved from the cost of treating cardiovascular disease.

The results are limited by a high dropout rate (24%). As regards the high dropout rate, based on the justified reasons given by the subjects, the possibility of taking part in basic aerobic endurance training, nutritional counselling, medical diagnostics and health education close to home should be considered in further studies.

Studies also confirm that a healthy diet, as promoted in a lifestyle intervention, is associated with higher costs and hence with socioeconomic status [62], [63], [64]. Socioeconomic reasons are therefore also decisive for participation in an exercise programme and for switching diet. Their importance and thus the underlying dropouts must be recorded more intensively in future so that an equal-opportunity risk reduction can be achieved, independent of socioeconomic status.

As regards the achieved exercise effects, especially with reference to the non-significant interaction effects, adaptation of the load parameters of the exercise intervention should be considered and the exercise should be intensified if appropriate. Because of a lack of evidence and out of ethical considerations, a comparatively moderate exercise programme was conceived initially.

The reduction in pulse wave velocity in the control group (d = 0.54) corresponds to the physiological effect and must be included in the interpretation of the effect in the intervention group. Morris et al. showed that there was a physiological reduction in arterial stiffness in normotensive women to pre-conception levels 14 months postpartum [65]. Yuan et al. [60] also demonstrated this 20 months postpartum in large arteries and described remodelling of the carotid artery in pregnancy and recovery in the postpartum period. Mersich et al. [61] found a physiological reduction in arterial stiffness both in normotensive women and in women with preeclampsia 3 months postpartum compared with the 3rd trimester. Foo et al. [62] observed this effect as a partial remission of endothelial dysfunction. However, women with disease did not reach pre-pregnancy levels [66]. In a 10-year follow-up increased arterial stiffness was found in the previously hypertensive pregnant women compared with the healthy reference group [30]. Reference levels of the general physiological reduction in arterial stiffness after pregnancy with and without hypertensive disorders of pregnancy must also be the basis in further studies for evaluating individual targeted exercise [67].

The validity of this study is limited by the small case number, which is too low to allow conclusions about influencing factors such as pre-existing hypertension, IUGR, multiple pregnancies and previous infertility treatments, which were represented heterogeneously in the intervention and control groups. Subgroup analyses were not possible but would have to be planned in subsequent studies with larger case numbers. The influence of pre-existing hypertension, in particular, should be studied separately as a cardiovascular risk factor involving pre-existing vascular modelling, as the pathogenesis of superimposed preeclampsia is possibly altered. With this diagnosis, pre-conception lifestyle intervention might very probably be more effective in influencing arterial stiffness than postpartum intervention. The absence of a risk reduction for IUGR and superimposed preeclampsia when aspirin is taken in accordance with guidelines (starting < 16 weeks) in women with pre-existing hypertension appears to support the hypothesis [68].


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Conclusion

The study confirms the feasibility and the great importance of lifestyle intervention with aerobic basic endurance exercise starting 6 weeks postpartum. The intervention shows a significant clinical effect by reducing arterial stiffness to the level of the general population. An optimal setting in an interdisciplinary team that includes varied midwife-supported care (incl. pelvic floor exercises, psychosocial support) beyond childbirth appears decisive for good adherence and the associated success of cardiovascular risk reduction as well as timely intervention for at least 6 months.

Before this intervention can be included in the standard of care and prevention, follow-up studies must confirm these results and the medium-term effects on cardiovascular risk.

ClinicalTrials.gov Identifier: NCT02754778


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Conflict of Interest/Interessenkonflikt

The authors declare that they have no conflict of interest./Die Autorinnen/Autoren geben an, dass kein Interessenkonflikt besteht.

Acknowledgements

Particular thanks to midwives Julia Böhme, Marie Bastian, Franziska Bremer, Hedwig Weiher and medical student Christin Descher for their generous assistance during the intervention and to Prof. Andreas Wienke for his statistical advice.


Correspondence/Korrespondenzadresse

Dr. Marcus Riemer
Martin-Luther-Universität Halle-Wittenberg
Universitätsklinik für Geburtshilfe und Pränatalmedizin Halle
Ernst Grube Straße 40
06120 Halle
Germany   

Publication History

Received: 06 July 2020

Accepted after revision: 31 December 2020

Article published online:
09 August 2021

© 2021. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commecial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/)

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Rüdigerstraße 14, 70469 Stuttgart, Germany


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Fig. 1 Definition criteria according to S1 guideline 015/018: Diagnosis and treatment of hypertensive disorders of pregnancy (as of 12/2013) [45].
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Fig. 2 Flow chart for the different study phases.
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Fig. 3 Illustration of aortic pulse wave velocity in the study groups at T1 and T3.
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Fig. 4 Relationship between exercise frequency and the increase in performance achieved at a lactate threshold of 2 mmol/l.
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Abb. 1 Definitionskriterien nach S1-Leitlinie 015/018: Diagnostik und Therapie hypertensiver Schwangerschaftserkrankungen (Stand 12/2013) [45].
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Abb. 2 Flussdiagramm für die verschiedenen Studienphasen.
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Abb. 3 Darstellung der aortalen Pulswellengeschwindigkeit der untersuchten Gruppen bei MZP 1 und MZP 3.
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Abb. 4 Beziehung zwischen der Trainingshäufigkeit und der erzielten Leistungssteigerung an der Laktatschwelle 2 mmol/l.