Drugs. Author manuscript; available in PMC 2015 Sep 2. Published in final edited form as: PMCID: PMC4558097 NIHMSID: NIHMS716228 Hypertensive disorders represent major causes of pregnancy related maternal mortality worldwide. Similar to the non-pregnant population, hypertension is the most
common medical disorder encountered during pregnancy and is estimated to occur in about 6–8% of pregnancies [1]. A recent report highlighted hypertensive disorders as one of the major causes of pregnancy-related maternal deaths in the United States, accounting for 579 of the 4693 (12.3%) maternal deaths that occurred between 1998 and 2005
[2]. In low-income and middle-income countries, preeclampsia and its convulsive form, eclampsia, are associated with 10–15% of direct maternal deaths [3]. The optimal timing and choice of therapy for hypertensive pregnancy disorders involves carefully weighing the
risk-versus-benefit ratio for each individual patient, with an overall goal of improving maternal and fetal outcomes. In this review we have compared and contrasted the recommendations in different treatment guidelines and we have outlined some newer perspectives on management. We have aimed to provide a clinically orientated guide to the drug treatment of hypertension in pregnancy. Hypertension in pregnancy includes a range of
conditions, most notably preeclampsia, a form of hypertension unique to pregnancy that occurs de novo or may be superimposed on chronic hypertension. The other forms, chronic and gestational hypertension, usually have more benign courses [1]. Preeclampsia, a pregnancy-specific disorder characterized by hypertension (≥140/90 mm Hg) and proteinuria (≥300 mg in a 24-hour urine),
affects 3–4% of all pregnancies worldwide. However, recent obstetric literature questions the importance of kidney injury (as demonstrated by proteinuria) in the diagnosis of preeclampsia, suggesting that a subclass of “non-proteinuric preeclampsia” should be added [4] or that detection of proteinuria should not be mandatory for a preeclampsia diagnosis
[5]. Risk factors include primiparity, previous preeclampsia, increased maternal body mass index (BMI) before pregnancy, ethnicity (black women are more at risk), multiple gestations, and underlying medical conditions such as renal disease and diabetes mellitus [6].
Preeclampsia is a condition that involves numerous and constant interactions among the placental, immunologic, and cardiovascular systems [7]. It is a syndrome associated with impaired early placentation and dysfunctional trophoblast development, defective placental angiogenesis, and an exaggerated maternal systemic inflammatory response
[8–11]. Risks to the fetus include premature delivery, growth retardation, and death. Treatment of severe hypertension is necessary to prevent cerebrovascular, cardiac, and renal complications in the mother. In the US the National High Blood Pressure
Education Program (NHBPEP) Working Group Report on High Blood Pressure in Pregnancy was first presented in 1990 and was most recently updated in 2000 [1]. The definition and treatment recommendations for hypertension in pregnancy, unlike those for hypertension in the general population, have not similarly evolved and vary among different organizations that provide guidance in this
area. Blood pressure levels requiring therapy in pregnancy, although somewhat different among various groups and professional societies, have been set, in general, at higher systolic and diastolic levels compared to the general population [12]. There are several reasons for this. First, there was (and still is) a relative paucity of well-designed clinical trials establishing the
benefit of treatment of mild chronic hypertension during pregnancy, typically defined in the relevant literature as a SBP 140–160 mm Hg and/or DBP 90–100 mm Hg. As a result, the current treatment approach is based on the assumption that hypertension of 4–5 months duration in a young woman without other risk factors does not increase her risk for cardiovascular disease, neither during the pregnancy nor later in life. However, there is increasing evidence that hypertension in pregnancy is an under
recognized risk factor for future cardiovascular disease (CVD). Compared with women who have had normotensive pregnancies, those who are hypertensive during pregnancy are at greater risk of cardiovascular and cerebrovascular events years after their pregnancy
[13–15]. There is the concern that decreased BP in the mother may compromise uteroplacental unit perfusion and fetal circulation. With respect to antihypertensive therapy, the choice has been limited to those that have proven to be relatively safe,
have long been in clinical use, and have a side-effect profile that most obstetricians have found to be acceptable [12]. Throughout the article, where available, we have ranked the level of evidence in support for the measurement and treatment of hypertension in pregnancy. A full explanation of the ranking systems used is available in the
appendices. The guidelines for measuring blood pressure in pregnancy are outlined in table 1.Throughout this paper we will refer to blood pressure
levels that are based on clinic blood pressure measurements. There has been much discussion on using ambulatory blood pressure monitoring (ABPM) in pregnancy but international guidelines currently base diagnosis and treatment interventions on clinic measurements. Guidelines for the measurement of blood pressure in pregnancy
Classification of hypertension in pregnancy and treatment guidelinesAccording to NHBPEP and The American College of Obstetricians and Gynecologists (ACOG) practice bulletins, hypertension in pregnancy is classified as chronic hypertension, preeclampsia-eclampsia, preeclampsia superimposed upon chronic hypertension and gestational hypertension [1, 21, 17]. Chronic hypertension is defined as BP ≥140/90mm Hg before pregnancy or <20th week of gestation or use of antihypertensive medication before pregnancy. Preeclampsia-eclampsia is a pregnancy-specific disorder that occurs after 20 weeks gestation. Eclampsia is the convulsive form of preeclampsia and affects 0.1% of all pregnancies. Preeclampsia can also occur superimposed upon chronic hypertension. Gestational hypertension is defined as new onset BP ≥140 mmHg systolic or 90 mmHg diastolic on at least two occasions, at least 6 h apart, after 20 weeks gestation, in the absence of proteinuria. This category encompasses women with preeclampsia who have not yet developed proteinuria, those with transient hypertension, if BP returns to normal by 12 weeks postpartum, and women with chronic hypertension, if BP elevation persists after 12 weeks. The NHBPEP guidelines state that in pregnancy normal or acceptable blood pressure is SBP≤140 and DBP≤90 mmHg, mild hypertension SBP 140 to 150 or DBP 90 to 109 mmHg and severe hypertension ≥ 160 systolic or ≥110 diastolic mmHg[1]. NHBPEP advises that antihypertensive medication might be safely withheld in women with a history of chronic hypertension, and recommend restarting treatment at > 150–160 mmHg SBP and/or 100–110 mmHg DBP, or in the presence of LVH or renal insufficiency [1]. In preeclampsia, antihypertensive therapy can be withheld unless there is persistent DBP 105–110 mmHg or higher (III-C). ACOG Practice Bulletins recommend that antihypertensive therapy be used for women with a history of chronic hypertension who develop severe hypertension in pregnancy, for maternal benefit and that treatment of uncomplicated mild hypertension is not beneficial [21, 17]. The American College of Obstetricians and Gynecologists (ACOG) recently convened a task force on hypertension in pregnancy and have provided an up to date statement with recommendations on treatment of hypertension in pregnancy [22]. They recommend that for women with mild gestational hypertension or preeclampsia (SBP < 160mmHg or DBP < 110 mmHg), antihypertensives are not recommended (the quality of this evidence is moderate and the strength of this recommendation is qualified). For women with preeclampsia and sustained SBP ≥ 160 mmHg or DBP ≥ 110 mmHg, antihypertensive therapy is recommended (the quality of this evidence is moderate and the strength of this recommendation is strong). In pregnant women with chronic hypertension and no end-organ damage, no antihypertensive therapy is needed if SBP <160 mmHg or DBP < 105 mmHg (the quality of this evidence is low and the strength of this recommendation is qualified). In pregnant women with chronic hypertension who are on antihypertensive therapy, BP should be maintained between 120/80 mmHg and 160/105 mmHg (the quality of this evidence is low and the strength of this recommendation is qualified). Other international societies and organizations have different definitions and levels at which therapy should be initiated and these are also presented in table 2. These recommendations come from the Society of Obstetricians and Gynaecologists of Canada (SOGC), the European Society of Hypertension /European Society of Cardiology (ESH/ESC); the National Institute for Health and Clinical Excellence (NICE) UK and the Society of Obstetric Medicine of Australia and New Zealand (SOMANZ). Table 2Guidelines for diagnosis and treatment of Hypertensive Disorders of Pregnancy (adapted from Moser M et al, 2012)
Drug treatment of hypertension in pregnancyAccording to NHBPEP methyldopa, labetalol, beta blockers (other than atenolol), slow release nifedipine, and a diuretic in pre-existing hypertension are considered as appropriate treatment [1]. If a woman’s blood pressure is well controlled on an agent pre-pregnancy she may continue it during pregnancy, with the exception of angiotensin-converting enzyme inhibitors and angiotensin II receptor blockers. If restarting drug therapy in women with chronic hypertension, methyldopa is recommended as first line therapy. For emergency treatment in preeclampsia, IV hydralazine, labetalol and oral nifedipine can be used [1]. The ACOG Practice Bulletins also recommend that methyldopa and labetalol are appropriate first-line agents and beta-blockers and angiotensin-converting enzyme inhibitors are not recommended [21, 17]. In current practice, antihypertensive medications other than methyldopa and hydralazine are being used more often in pregnancy (Table 3), and particularly in patients for whom BP control cannot be achieved with these agents, or in the presence of intolerable side effects. Table 3Recommended management options for treating hypertension in pregnancy
The drug treatments for severe acute hypertension in preeclampsia are highlighted in figure 1. [1]. Severe hypertension in preeclampsia being defined as ≥160 mm Hg systolic, ≥105 mm Hg diastolic, or both. Drug treatments and regimens for severe hypertension in preeclampsia [1] * The NHBPEP Working Group recommend the use of sodium nitroprusside in rare cases of hypertension not responding to the previously mentioned drugs, or clinical findings of hypertensive encephalopathy, or both Profiles of recommended drug therapies
Centrally acting α2-adrenergic agonistsMethyldopa is a centrally acting α2-adrenergic receptor agonist. It inhibits vasoconstriction via a central mechanism by reducing catecholamine release [28]. It decreases central sympathetic outflow, decreasing systemic vascular resistance without decreasing cardiac output [27]. The side effects of methyldopa include fatigue, depression, poor sleep and decreased salivation. Dose independent adverse effects include elevated liver enzymes in up to 5% of women and some patients can develop a positive antinuclear antigen or antiglobulin (Coombs’) test although a clinical haemolytic anaemia is rare [29, 27]. It has been suggested that methyldopa should be avoided in women with a prior history of depression, because of the possible increased risk of postnatal depression [30]. Methyldopa has a long history of use in pregnancy and does not appear teratogenic [27]. Methyldopa has a record of safety in pregnancy, as established by follow-up studies in the 1980’s of children exposed to the drug in utero [31]. More recent studies indicate that in hypertensive pregnancy disorders, treatment with methyldopa does not affect the maternal uterine artery Doppler pulsatility and resistance indices, suggesting that it does not impair uteroplacental circulation and consequent fetal growth [32]. The doses of methyldopa recommended in pregnancy are similar to those used in non-pregnant patients [33]. Clonidine is a centrally acting adrenergic agonist. It works as an antihypertensive agent by stimulating α-2 adrenergic receptors in the brainstem thereby decreasing central adrenergic output [34]. It acts on both peripheral and central α-2 adrenergic receptors to decrease the cardiac output, systemic vascular resistance, systolic blood pressure and heart rate [35]. Clonidine is similar to methyldopa with regards to safety and efficacy [35]. It is generally used as a third-line agent for multidrug control of refractory hypertension [29]. According to the Food and Drug Administration (FDA) methyldopa is a Class B drug and clonidine is a Class C drug. According to either the World Health Organization and/or Thomson lactation ratings methyldopa is usually compatible with breast milk and clonidine has possible breast milk effects. Peripherally acting adrenergic-receptor antagonistsLabetalol a non-selective β-blocking agent with vascular α-1-receptor blocking capabilities is widely used in pregnancy [26]. Fetal growth restriction and low placental weight in patients (with essential hypertension) have been associated with the use of atenolol during the second trimester [36], but not with other β-blocking agents, such as labetalol (an α and β-blocker), which is used frequently for the treatment of severe acute hypertension during pregnancy, and has shown equivalent efficacy and better tolerability compared to hydralazine [37]. Side effects include fatigue, lethargy, exercise intolerance, sleep disturbance and bronchoconstriction have been reported [26]. β-blockers are not associated with teratogenicity [26]. In a review of antihypertensive drug therapy for mild-to-moderate hypertension during pregnancy, β-blockers appear to be more effective than methyldopa in limiting episodes of severe hypertension in women with hypertensive disorders of pregnancy [38]. However, at the same time, this review showed no evidence of a difference in the risks of preeclampsia, neonatal death, preterm birth, or small-for-gestational-age (SGA) babies. Prazosin is an α 1-blocker that selectively blocks post-synaptic α 1-adrenoceptors, producing a decrease in total peripheral resistance (and a reflex increase in sympathetic tone) [27]. It is considered as a second-line agent by SOMANZ [19] but is not recommended by SOGC [16]. Prazosin has a useful role in chronic renal disease complicating pregnancy. It is associated with postural hypotension and palpitations. Fetal growth restriction and low placental weight in patients (with essential hypertension) have been associated with the use of atenolol during the second trimester [36], but not with other β-blocking agents, such as labetalol (an alpha and beta blocker), which is used frequently for the treatment of severe acute hypertension during pregnancy, and has shown equivalent efficacy and better tolerability compared to hydralazine [37]. The benefits and concerns of antihypertensive agents are outlines in table 2. According to FDA labetalol is a Class C drug. It may be associated with a risk of fetal bradycardia and neonatal hypoglycemia. According to either the World Health Organization and/or Thomson lactation ratings methyldopa is usually compatible with breast milk. Atenolol is an FDA Class D drug. It is not recommended due to risk of IUGR and is not recommended if breast-feeding. Calcium channel blockersOral nifedipine and verapamil are frequently seen as second line agents used for the treatment of hypertension in pregnancy. They do not appear to be teratogenic [39]. Calcium channel blockers (CCBs) inhibit the influx of calcium ions to vascular smooth muscle, resulting in arterial vasodilation; nifedipine act predominantly on the vasculature and verapamil acts primarily on the heart [27] [28]. Side effects of CCB use in the mother include tachycardia, palpitations, peripheral edema, headaches and facial flushing [40]. According to FDA nifedipine and verapamil are Class C drugs. With all CCBs, there is a risk of interactions with magnesium, resulting in profound hypotension. Nifedipine and verapamil are usually compatible with breast milk. Direct vasodilatorsHydralazine is now predominantly used intravenously for the treatment of severe hypertension in pregnancy. Hydralazine selectively relaxes arteriolar smooth muscle. Adverse effects include headache, nausea, flushing, and palpitations. It does not appear teratogenic. There have been reports of neonatal thrombocytopenia, rare cases of a pyridoxine-responsive polyneuropathy with chronic use, and drug-induced lupus [41]. However, there is evidence that intravenous labetalol or oral nifedipine are preferable first-line agents compared to intravenous hydralazine in severe hypertension in pregnancy [37]. Sodium nitroprusside is rarely used in pregnancy and is reserved for life-threatening severe hypertension [42]. Adverse effects include cyanide and thiocyanate toxicity and also the risk of cardio-neurogenic syncope. Hydralazine is an FDA Class C drug. It is usually compatible with breast-feeding. DiureticsThe use of diuretic therapy during pregnancy remains controversial, primarily due to theoretical concerns about reduced plasma volume. In a randomized trial of women with chronic hypertension in pregnancy, the use of diuretics reduced plasma volume, but was not associated with adverse pregnancy outcomes [43]. Women on maintenance diuretic therapy prior to pregnancy can be continued on this regimen, unless they develop premonitory signs of preeclampsia, such as proteinuria. At that point, some physicians would opt to stop diuretic medications, due to the concern that, with the lower plasma volume characteristic of preeclampsia, the use of diuretics may further aggravate the hypovolemic state, stimulate the renin–angiotensin system, and worsen hypertension [44]. The 2000 NHBPEP Working Group Report, however, recognized that the major concern for the use of diuretics in pregnancy is primarily theoretical, as supporting evidence for their deleterious effects is lacking. Thiazides are FDA Class B drugs. They may cause volume contraction and electrolyte abnormalities but rare with small doses. Diuretics may reduce milk production [29]. Spironolactone is not recommended due to potential fetal antiandrogen effects. Renin Angiotensin System drugsAngiotensin converting enzyme (ACE) inhibitors and angiotensin II receptor blockers (ARB) are contraindicated in pregnancy due to their association with adverse fetal effects [45]. ACE inhibitors are labelled FDA class C for the first trimester of pregnancy, and FDA class D for the second and third trimesters. Current clinical practiceAs discussed in earlier sections there are several guidelines and recommendations available to practitioners treating hypertension in pregnancy. These however may not always reflect clinical practice. Two recent reviews give us a reflection of actual drug therapy being used in hypertension in pregnancy. Table 4 summarizes drug therapy currently being used in clinical practise to treat very high blood pressure in pregnancy. Table 4Drug therapy for the treatment of very high blood pressure in pregnancy
There is further evidence of the increasing use of antihypertensives in pregnancy. A review of outpatient antihypertensive medication use during pregnancy in a Medicaid population was performed from 2000 to 2006 [47]. They noted that the prevalence of antihypertensive use both in the first trimester and in pregnancy overall increased during this period by approximately 50%; by the end nearly 5% of all pregnancies were exposed to antihypertensive therapy [47]. The authors reported significant variation in the range of antihypertensive drugs used across all trimesters of pregnancy and in the approach to the management of patients entering pregnancy on antihypertensive medication. There were study limitations but a significant number of women taking antihypertensives prior to pregnancy were kept on their same drug and not switched to one of the preferred agents. Beta-blockers, thiazides, and calcium channel blockers were often used as first line agents. Drugs used for the prevention of preeclampsia/eclampsiaMagnesium sulphate and other anticonvulsants for preeclampsiaIn a Cochrane review of treatment of women with preeclampsia, magnesium sulphate more than halves the risk of eclampsia, and probably reduces maternal death [48]. In women with eclampsia, magnesium sulphate reduces the risk ratio of maternal death and of recurrence of seizures, compared with diazepam. Antiplatelet agents and preeclampsiaA review of 59 trials, involving 37,560 women, found low doses of aspirin reduced the risk of preeclampsia by 17%, the risk of fetal or neonatal deaths by 14%, and the relative risk of preterm births by 8% [49]. Doses up to 75 mg appear to be safe. Guidelines from the ESH/ESC suggest that women at high risk of preeclampsia (from hypertension in a previous pregnancy, CKD, autoimmune disease such as systemic lupus erythematosus, or antiphospholipid syndrome, type 1 or 2 diabetes or chronic hypertension) or with more than one moderate risk factor for preeclampsia (first pregnancy, age >40 years, pregnancy interval of >10 years, BMI >35 kg/m2 at first visit, family history of preeclampsia and multiple pregnancy), may be advised to take 75mg of aspirin daily from 12 weeks until the birth of the baby, provided that they are at low risk of gastrointestinal haemorrhage [23]. Similarly the UK NICE guidelines advise woman to take aspirin 75 mg/day from 12 weeks until birth if they have at least two moderate risk factors (as listed above) or at least one high risk factor (as listed above) for preeclampsia exists [25]. They state that this is an unlicensed indication and that informed consent should be taken. There is support for the use of low-dose aspirin before 16 weeks with investigators suggesting the possibility that because normally the transformation of uterine spiral arteries by trophoblasts is completed by 16–20 weeks and this is abnormal in preeclampsia; early use of aspirin may be beneficial [50] [51]. Antioxidants for preventing preeclampsiaIt has been demonstrated that supplementation with vitamin C (at a dose of 1000 mg daily) and vitamin E (at a dose of 400 IU daily) do not reduce the rates of either serious adverse outcomes of pregnancy-associated hypertension or preeclampsia among low-risk, nulliparous women [52]. Calcium supplementation for preventing hypertensive disordersA review of calcium supplementation during pregnancy for preventing hypertensive disorders concluded that calcium supplementation appears to approximately halve the risk of preeclampsia, reduce the risk of preterm birth, and the rare occurrence of the composite outcome: ‘death or serious morbidity’ [53]. Of note, most of the women in these trials had a low calcium diet and were supplemented with at least 1 g of calcium daily. However, the evidence for added calcium in the prevention of hypertensive disorders is conflicting [54]. Other agentsFish oil supplementation and vitamin and nutrient supplements appear to have no benefit in the prevention of hypertensive disorders [55]. Other management options such as the use of corticosteroids, plasma volume expansion, or interventions such as rest or exercise, have not been validated [3]. Steroid therapy is recommended only for lung maturation [16, 19, 25]. Currently, several interventional trials for hypertension in pregnancy are in progress, with further information on these trials being available at ClinicalTrials.gov and the WHO International Clinical Trials Registry Platform. These include the Control of Hypertension in Pregnancy Study trial [56], the Goal-directed Therapy in Pregnant Women at High Risk of Developing Preeclampsia trial (therapeutic intervention, nifedipine vs. labetalol), the Labetalol vs. Magnesium Sulfate (MgSO4) for the Prevention of Eclampsia Trial and the Antihypertensive Treatment in Stable Pregnant Women with Severe Preeclampsia. Results from these trials may further enhance our treatment therapies for hypertension in pregnancy. Novel therapeutic targets and emerging treatmentsAngiogenesisDysregulation of angiogenesis appears to play a key role in the pathogenesis of preeclampsia. Placental cystathionine γ-lyse (CSE) expression is reduced in preeclampsia, leading to reduced plasma levels of the pro-angiogenic gaseous vasodilator, hydrogen sulfide (H2S) and increased sFlt-1 [57]. Targeting CSE/H2S activity may be a potential therapy pending additional studies. AminopeptidasesAminopeptidases, such as placental leucine aminopeptidase (P-LAP) and aminopeptidase A (APA) do not cross the placental barrier. In the pregnant, spontaneously hypertensive rat, APA acts as an antihypertensive agent, degrading vasoactive peptides, and as a result, normalizes blood pressure [58]. The role of aminopeptidases as potential therapeutic agents is being investigated. Heme oxygenase 1A recent study examined heme oxygenase 1 (HO-1) induction in a rat model of placental ischemia [59]. George et al, suggest two potential pathways through which HO-1 acts, namely, normalization of angiogenic balance in the placenta, and reduction in oxidative stress. Both pathways are potential targets for treatment in preeclampsia. MarinobufageninUddin et al, and others, have investigated the role of marinobufagenin (MBG), a cardiotonic steroid, and its antagonist resibufogenin (RBG), in experimental animal models of preeclampsia [60]. This group has demonstrated that in a rat model of preeclampsia, MBG inhibits first trimester cytotrophoblast cell function and that urinary excretion of MBG is elevated prior to the development of hypertension and proteinuria. MBG also causes hypoxia and ischemia leading to an imbalance of pro- and anti-angiogenic factors. RBG, when given early in pregnancy, prevented the development of hypertension, proteinuria, and intrauterine growth restriction. G protein-coupled receptor (GPCR) targetsThere is potential for investigation of novel GPCR-based therapies in preeclampsia, including calcitonin receptor-like receptor / receptor activity modifying protein 1 complexes, the angiotensin AT1, 2 and Mas receptors, and the relaxin receptor RXFP1 [61]. Inhibitors of the enzyme poly ADP ribose polymerase (PARP)In states of increased oxidative stress, such as diabetes, overstimulation of PARP leads to endothelial dysfunction and PARP inhibitors have been shown to be of benefit [62]. A recent investigation has demonstrated a protective effect of a PARP inhibitor, preventing the development of both endothelial dysfunction and hypertension, in a rat model of preeclampsia [62]. GasotransmittersNitric oxide, a potent vasodilator that mediates endothelium-dependent relaxation, has been linked to endothelial dysfunction in preeclampsia [63]. Carbon monoxide, nitric oxide and hydrogen sulphide are endogenously generated gaseous transmitters known as, gasotransmitters. In preclinical animal models, the therapeutic use of CO gas and CO-releasing molecules demonstrated anti-inflammatory properties and cardiovascular protective effects [64]. These gaseous molecules may have a potential role in the therapeutics for several diseases, including cardiovascular disease and preeclampsia, although their instability and potential toxicity are significant drawbacks. PodocytesDerangements of podocytes and podocyte-specific proteins are implicated in preeclampsia. There is evidence of an association between dysregulated pro-angiogenic factors, hypertension, and podocyte injury. Further investigation focusing on the mechanism of podocyte injury and detachment may identify novel therapeutic targets. These are only a few of the more recent potential therapeutic targets under investigation. Perspectives in ManagementOver the last decade, new evidence has emerged, both with respect to the pathophysiology of preeclampsia and the benefits of early hypertension treatment in the general population, which may affect the management of hypertensive pregnant patients. The notion that pregnant women with chronic hypertension are at low risk for cardiovascular complications within the short duration of pregnancy may be in question given the current trend towards advanced maternal age at first pregnancy. These women may have other cardiovascular risk factors, such as obesity or hyperlipidemia, and/or signs of target organ hypertensive damage. In addition, modern methods of assisted reproduction (such as in vitro fertilization) have enabled women with CVD risk factors that are associated with decreased fertility (such as diabetes mellitus and renal disease) to conceive. In these women, treatment of hypertension of even a short duration, may improve their cardiovascular risks, especially in view of recent studies in the general population showing an important correlation between the time taken to achieve goal BP and clinical outcomes, namely better outcome with earlier and more effective treatment [65, 66]. Finally, recent studies have indicated that cerebral vascular events in women with severe preeclampsia and eclampsia may occur when SBP exceeds 150 mm Hg, and called for a paradigm shift, by recommending antihypertensive therapy when the SBP reaches or exceeds 155–160 mm Hg [67]. Indeed, most investigators agree that antihypertensive therapy in the peripartum period should be initiated when the DBP approaches 100 mm Hg, or for a blood pressure ≥ 150/100 mm Hg [68]. As abrupt decreases in BP may adversely affect uteroplacental perfusion, treatment of hypertension mandates close maternal and fetal monitoring as the BP is lowered. The ultimate therapeutic goal is to prevent maternal complications without compromising fetal wellbeing. AcknowledgmentsThe project described was supported by the award number P50AG44170 from the National Institute on Aging (Vesna D. Garovic). AppendicesAppendix 1The NHBPEP Working Group Report on High Blood Pressure in Pregnancy reviewed and classified studies providing evidence supporting their recommendations. They used the following explanatory symbols and appended them to some of their references and to some of their citations [1]. M- Meta-analysis; an analysis of a compendium of experimental studies; Ra- Randomized controlled studies Re- Retrospective analyses; case-control studies F- Prospective follow-up; cohort studies X- Cross sectional population studies Pr- Previous review or position statements C- Clinical interventions (nonrandomized). Appendix 2: ACOG evidence baseI: Evidence obtained from at least one properly randomized controlled trial II-1: Evidence from well-designed controlled trials without randomization II-2: Evidence from well-designed cohort or case-control studies, preferably from more than one centre or research group II-3: Evidence obtained from multiple time series with or without the intervention. Dramatic results in uncontrolled experiments could also be regarded as this type of evidence III: Opinions of respected authorities, based on clinical experience, descriptive studies, or reports of expert committees Recommendations are provided and graded according to the following categories: Level A. Recommendations are based on good and consistent scientific evidence Level B. Recommendations are based on limited or inconsistent scientific evidence Level C. Recommendations are based primarily on consensus and expert opinion. Appendix 3Key to evidence statements and grading of recommendations, using the ranking of the Canadian Task Force on Preventive Health Care Quality of Evidence Assessment* Classification of Recommendations† I: Evidence obtained from at least one properly randomized controlled trial II-1: Evidence from well-designed controlled trials without randomization II-2: Evidence from well-designed cohort (prospective or retrospective) or case-control studies, preferably from more than one centre or research group II-3: Evidence obtained from comparisons between times or places with or without the intervention. Dramatic results in uncontrolled experiments (such as the results of treatment with penicillin in the 1940s) could also be included in this category III: Opinions of respected authorities, based on clinical experience, descriptive studies, or reports of expert committees A. There is good evidence to recommend the clinical preventive action B. There is fair evidence to recommend the clinical preventive action C. The existing evidence is conflicting and does not allow making a recommendation for or against use of the clinical preventive action; however, other factors may influence decision-making D. There is fair evidence to recommend against the clinical preventive action E. There is good evidence to recommend against the clinical preventive action I. There is insufficient evidence (in quantity or quality) to make a recommendation; however, other factors may influence decision-making *The quality of evidence reported in these guidelines has been adapted from the Evaluation of Evidence criteria described in the Canadian Task Force on Preventive Health Care. †Recommendations included in these guidelines have been adapted from the Classification of Recommendations criteria described in the Canadian Task Force on Preventive Health Care. Appendix 3Explanation of the class of recommendations and levels of evidence used by the ESH/ESC, European Society of Hypertension /European Society of Cardiology Classes of recommendations Class I Evidence and/or general agreement that a given treatment or procedure is beneficial, useful, effective. (Is recommended/is indicated). Class II: Conflicting evidence and/or a divergence of opinion about the usefulness/efficacy of the given treatment or procedure. Class IIa: Weight of evidence/opinion is in favour of usefulness/efficacy. (Should be considered). Class IIb: Usefulness/efficacy is less well established by evidence/opinion. (May be considered). Class III Evidence or general agreement that the given treatment or procedure is not useful/effective, and in some cases may be harmful. (Is not recommended). Levels of Evidence Level of evidence A- Data derived from multiple randomized clinical trials or meta-analyses. 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[PubMed] [Google Scholar] What blood pressure medication is safe during pregnancy?Treating high blood pressure in pregnancy
For the initial treatment of high blood pressure in pregnancy, these are the most commonly used and recommended medications: Labetalol (Normodyne, Trandate) Nifedipine (Procardia, Adalat) Methyldopa (Aldomet)
Can you have a safe pregnancy with high blood pressure?High blood pressure treatment in pregnancy is safe, prevents maternal heart risks | American Heart Association.
Can blood pressure medication cause birth defects?Babies whose mothers took ACE inhibitors in their first trimester were more than twice as likely to be born with serious heart and brain problems than those not exposed to any blood pressure-lowering medicines, a large study in Tennessee found. Other types of blood pressure drugs did not raise the risk to babies.
Does blood pressure medicine affect unborn baby?Older data suggested that antihypertensive drugs might reduce blood flow to the uterus, causing fetal growth restriction. But new research has shown that treating non-severe hypertension is safe for pregnant patients and their babies.
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