Risk factors

1. What factors increase risk of VTE during pregnancy?

Virchow’s triad of hemostasis, endothelial injury, and hypercoagulability has long been recognized as risk factors for VTE. All of these elements are present in pregnancy.

Venous stasis begins as early as the first trimester and progressively increases throughout the pregnancy. Causes of the increased stasis include progesterone‐induced venodilation, venous compression by the gravid uterus, and pulsatile compression of the left iliac vein by the right iliac artery [10]. Vascular injury occurs during the birth process and may be exacerbated by operative vaginal delivery.

Pregnancy is a time of significant physiologic changes in the maternal coagulation status. Activated protein C resistance increases and protein S activity is decreased. These changes and the elevated concentrations of fibrinogen and factors V, VIII, IX, and X all lead to increased thrombin production [11]. Concurrently, fibrinolysis is decreased by increased activity of plasminogen activator inhibitors type 1 and type 2 as well as decreased activity of tissue plasminogen activator [12].

Many factors have been shown to increase the risk of VTE in pregnancy (Table 34.1) [13]. The greatest risk for VTE in pregnancy is a personal history of prior VTE. In fact, 15–25% of VTEs in pregnancy are recurrences [14]. Thrombophilias are the next largest risk group accounting for 20–50% of VTEs occurring in pregnancy [15–17]. Other risk factors include increased parity, infection, operative vaginal delivery, cesarean delivery, smoking, obesity, cancer, and surgery [7, 16, 18–22].

A number of inherited thrombophilias increase the risk of developing VTE during pregnancy (Table 34.2) [23]. The American College of Chest Physicians (ACCP) considers Factor V Leiden (FVL), Prothrombin G20210A, and antithrombin deficiency (ATD) major risk factors while Protein C and S deficiencies are minor risk factors for VTE in pregnancy.

FVL is the thrombophilia most commonly encountered by obstetricians. Its prevalence is highest in Caucasians of European decent with carrier frequencies estimated at 5–9% and is less common among those of Asian and African descent [24]. Only about 1% of women with FVL mutations are homozygous and they tend have to have a higher incidence of VTE [25, 26]. Retrospective data demonstrates heterozygous carriers of FVL have a 5–10‐fold relative risk for VTE during pregnancy, and it is present in 43% of pregnant women with their first thrombotic event [27, 28, 29, 30]. Among heterozygotes without a family or personal history of thrombosis, the risk of VTE is only 0.25%. For patients with a family or personal history of VTE, the risk may be as high as 10% [28]. One large multicenter prospective National Institute of Child Health and Human Development (NICHD) study looked at 4885 gravid patients without a personal history of thrombotic event. Of the 134 FVL carriers, there was no increased risk of VTE [31].

The second most prevalent inherited thrombophilia is Prothrombin G20210A (PGM), which leads to elevated prothrombin levels. Among European Caucasians the carrier prevalence is 2–4%. Similar to FVL, PGM is less common in those of Asian and African descent [24, 25]. Studies have shown a wide range in the carrier frequency among women having their first VTE during pregnancy with rates ranging from 3.8% to 31% [27, 30]. Women who are carriers of PGM without a personal or family history of VTE appear to have a low risk (0.37%) of VTE during pregnancy; however, that risk increases to over 10% for those with prior VTE or for family history of VTE. The probability appears to be higher for those who are homozygous for PGM mutation, but the available data is limited [30]. Even without a prior history of VTE FVL and PGM compound heterozygotes have a much higher risk (4.6%) of a VTE during pregnancy and puerperium even without a prior history [27].

Less common but more thrombogenic than FVL or PGM is ATD. Many mutations have been identified at the antithrombin gene loci, which lead to a wide spectrum of phenotypes. Type I disease is a quantitative disorder while type II is a qualitative dysfunction. Type I is less common, comprising only 12% of the cases of ATD, but it is much more thrombogenic, accounting for 80% of symptomatic cases. In contrast to FVL and PGM the prevalence of ATD in highest in Asian populations with some groups having a prevalence of up to 2–5%, while among Caucasian Europeans it is estimated at 0.02–1.15% [24, 32]. The risk of VTE in pregnancy can be high with ATD, but there is large variability among phenotypes. Robertson reported an OR 4.69 for VTE in pregnancy [26]. Retrospective studies have estimated the odds ratio for the more thrombogenic type 1 disease to be 282 compared to a much smaller risk with type II disease (OR 28) [33, 13]. It is estimated that the lifetime risk of VTE in those with type I disease is 50% [34]. One case series of 63 untreated women with type 1 ATD who went through pregnancy without anticoagulation found 18% had a thrombotic complication during pregnancy and additional 33% had a VTE postpartum [35].

Protein C is an anticoagulant responsible for the deactivation of factor Va and factor VIIIa thereby inhibiting clot formation [25]. Deficiencies in protein C synthesis or function are found in 0.2–0.3% of those with European ancestry and is more common in those of Asian and African descent [24]. Protein C deficiency is moderately pro‐thrombogenic during pregnancy. The risk is likely proportional to the deficiency of substrate and/or function. Zotz et al. found the relative risk of a first VTE in pregnancy to be RR 3.0 if using <73% of normal protein C activity as the cutoff and RR 13.0 if using <50% as the cutoff in a case control study [28]. A review of available retrospective case controlled studies showed a modest risk of VTE (OR 4.76) in patients with hereditary protein C deficiency [26].

Protein S accelerates activated protein C’s disruption of factors Va and VIIIa, ultimately suppressing thrombin formation. It is a less common than protein C deficiency with a prevalence of 0.03–0.13% in the Caucasian European population. Due to the infrequency of protein S deficiency there are limited studies regarding its risks during pregnancy. Robertson’s review of available case controlled studies showed an OR 3.19 of VTE and pregnancy [26]. Conard et al.’s evaluation of 44 pregnancies in 17 patients with congenital protein S deficiency showed no thrombosis during pregnancies without anticoagulation, but had five post‐partum thrombotic events (17%) [35].

Diagnosis

1. 2. What is the best method of diagnosing VTE in pregnancy?

PE

Clinical symptoms

Symptoms of PE include shortness of breath, chest pain, hypoxia, tachycardia, cough, tachypnea, hemoptysis, hypotension, and syncope [40, 41]. Among 38 pregnant women diagnosed with acute PE the most common findings were tachycardia (65%), dyspnea (63%), tachypnea (57%), pleuritic chest pain (55%), cough (24%), and sweating (18%) [42].

Imaging

Diagnostic testing for PE has changed over the years. Originally, pulmonary angiography was considered the gold standard. The ventilation‐perfusion scan replaced pulmonary angiography because of the invasive nature of the test and associated complications. In more recent years, CT pulmonary angiography has become more common and outside of pregnancy is usually the diagnostic test of choice.

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