Review Article Management of pulmonary embolus in pregnancy M. de Swiet Introduction
Transcription
Review Article Management of pulmonary embolus in pregnancy M. de Swiet Introduction
European Heart Journal (1999) 20, 1378–1385 Article No. euhj.1999.1584, available online at http://www.idealibrary.com on Review Article Management of pulmonary embolus in pregnancy M. de Swiet Queen Charlotte’s Hospital for Women, London, U.K. The importance of pulmonary embolus in pregnancy cannot be exaggerated. In developed countries where women no longer die from sepsis and haemorrhage, it is the leading cause of maternal mortality[1,2]. The management of pulmonary embolus in pregnancy is difficult because few internists have much experience of managing pregnant women; and few obstetricians have any experience of pulmonary embolus. In addition there is confusion about the safety of maternal investigations for the fetus, particularly when these investigations involve ionising radiation and also confusion about the effects that any maternal therapy may have on fetal well being. As in the non-pregnant state[3], pulmonary embolism is both under- and over-diagnosed in pregnancy, exposing women to the risks of further fatal pulmonary embolism and unnecessary anticoagulation, respectively. Underdiagnosis usually occurs in the scenario of breathlessness, fever and pulmonary infiltration diagnosed as pneumonia; over-diagnosis relates to ascribing all cases of chest pain and collapse to pulmonary embolus. Plethysmography has shown that veins are more distensible in pregnancy[5] and recent Doppler studies indicate that lower limb blood flow is reduced in pregnancy[6]. These effects are likely to be due to a combination of hormonal influences on the structure of vessel walls and obstruction to blood flow caused by the enlarging uterus. After delivery the effect is more marked in the veins of the left leg than the right[7] supporting the observation that in pregnancy deep vein thrombosis is much more common in the left leg. It has been known for some time that the composition of the blood changes in pregnancy probably because of high oestrogen levels. For example the levels of clotting factors II, VII, VIII, X and fibrin all increase in pregnancy[8,9]; to a certain extent, this is offset by an increase in thrombolysis[10]. However, recent interest in natural anticoagulants has shown that pregnancy also decreases some of their activities: specifically, activated protein C resistance is increased (decreased activated protein C resistance ratio) even in the absence of Factor V Leiden[11,12] and protein S levels also decrease[13]. So it is likely that changes in the composition of the blood in pregnancy relate to both an increase in clotting factors and a decrease in natural anticoagulation. Definition and pathophysiology (see also Risk Factors below) Epidemiology Introduction Although several substances such as fat and air can cause pulmonary embolus in pregnancy, this review relates to pulmonary embolus caused by blood clot, usually originating in the lower limb or pelvic veins. The differential diagnoses with amniotic fluid embolus and chorion carcinoma are also considered. The five- to sixfold increased risk of pulmonary embolus due to pregnancy[4] is due in part to changes in the composition of the blood and in part to changes in blood flow. Key Words: Pulmonary embolus, pregnancy, pregnancy complications, heparin, warfarin, low molecular weight heparin. The incidence of pulmonary embolism in pregnancy varies between 1 per 1000 and 1 per 3000 deliveries[14–16]. This degree of variation is due, at least in part, to differences in diagnostic methodology and to different obstetric practices. About 1 per 100 000 pregnant women die from pulmonary embolism[2]. The deaths are evenly distributed between the antenatal period and the postnatal period, conventionally taken as 6 weeks after delivery[2,15]. Within the antenatal period, thromboembolism occurs equally within each trimester[17]. Therefore the postnatal period is the most dangerous time in terms of deaths per week but no period of pregnancy is without risk. Revision submitted 20 January 1999, and accepted 8 February 1999. Risk factors Correspondence: Dr M. de Swiet, Queen Charlotte’s Hospital for Women, Goldhawk Road, London W6 0XG, U.K. Risk factors for pulmonary embolus in pregnancy include those acting in the non-pregnant state. For 0195-668X/99/191378+08 $18.00/0 1999 The European Society of Cardiology Review 1379 Table 1 Risk of thromboembolism per pregnancy (%) in patients who themselves have had thromboembolism or who come from families with history of thromboembolism (High risk) compared to the risk in individuals found to have thrombophilia by population screening (Low risk). (From Girling and de Swiet 1998[53]] Low risk[22] High risk families Antithrombin III[54] Protein C[56] Protein S[56] APCR[55] Pregnancy Puerperium Pregnancy Puerperium 12–60 3–10 0–6 10–14 11–33 7–19 7–22 19 3 2 0 — 0 0 6·6 — example, even within the reproductive age range, age is still an important factor: the incidence of pulmonary embolus is doubled in pregnant women aged over 35 years compared to those aged less than 35[16]; the mortality from pulmonary embolus is nearly 100 times greater in pregnant women aged over 40 years compared to those age 20 to 25 years[18]. Parity is a further risk factor, the risk increasing in those who have had more than three pregnancies independent of age[18]; so too is obesity[19]. Operative delivery increases the risk of pulmonary embolus between two and eightfold, the risk varying depending on whether Caesarean section was an emergency or elective procedure and on the method of anaesthesia: epidural block reduces the risk compared to general anaesthesia[10]. Oestrogen administration to suppress lactation is another risk factor, indeed the risk of pulmonary embolus is the main reason why other drugs such as bromocriptine are used if lactation has to be suppressed[10]. Although bed rest is assumed to be a risk factor for pulmonary embolus, the little evidence that there is suggests that this is not the case[20]. Thrombophilia is an important risk factor for pulmonary embolus in the pregnant as well as in the non-pregnant state. For example Hirsch et al.[21] found Factor V Leiden heterozygosity in 20% of cases of thromboembolism in pregnancy, whereas the prevalence in their community was of the order of 5%. However, it is difficult to estimate the risks for a given thrombophilia with precision, because they vary depending on patient selection. Also figures are usually quoted for all thromboembolism rather than for pulmonary embolism alone. For example, the risk for all thromboembolism in antithrombin III deficiency varies between 12 and 60% per pregnancy in groups of patients diagnosed because they presented at some other time with thromboembolism. However, in patients found to have the condition by population screening, the risk could be as low as 3%[22]. Figures for some other common thrombophilias are given in Table 1. Inherited and acquired thrombophilias are also important, not only because of their interaction with pregnancy to increase the risk of pulmonary embolism, but also because nearly all thrombophilias are associated with an increased risk of poor pregnancy outcome. These adverse effects, which occur independently of thromboembolism, vary from pre-eclampsia to miscarriage and intra-uterine death. Placental infarction is a frequent feature so that the mechanism is likely to involve thrombosis in the placental vessels. Natural history and prognosis In non-pregnant patients, many with pulmonary embolus die from the underlying cause rather than from recurrent embolism[23]. By contrast, pregnant women with pulmonary embolus are usually otherwise healthy. They either die suddenly and unexpectedly or they have an illness that lasts several days or weeks where the diagnosis has not been considered. This emphasizes the need for prophylaxis in some cases and above all for correct diagnosis. Although there is much concern about how to treat pulmonary embolus in pregnancy, failure of treatment once instigated is uncommon. Diagnosis and investigation Clinical The clinical features of pulmonary embolus are no different in pregnancy compared to the non-pregnant state, where a recent review suggests that 90% of those with pulmonary embolus have dyspnoea and tachypnoea i.e. the absence of these features will exclude 90% of pulmonary emboli[3]. However, breathlessness is a common feature of normal pregnancy. Women increase their ventilation by about 40% in pregnancy and there is considerable variation between women and in the same women between pregnancies, in their awareness of this increase in ventilation. Pregnant women often present with breathlessness. It is difficult to know how far to go to exclude pulmonary embolus if there are no other clinical features. Depending on the severity of the symptom in a woman who does not present acutely, chest Eur Heart J, Vol. 20, issue 19, September 1999 1380 M. de Swiet radiography and measurement of oxygen saturation at rest and on exercise or measurement of arterial blood gas tensions should suffice. Investigation Basic tests (chest radiography, electrocardiography and arterial blood gas tensions) to diagnose pulmonary embolus and to exclude other conditions are well known. With regard to pregnancy, it should be noted that with modern equipment the radiation received by the fetus from a single maternal chest radiograph (CXR) is <10 ìGy[24], a trivial quantity compared to the 50 000 ìGy considered to be the upper limit with regard to danger of injury for the fetus[24]. Mothers may also be reassured by the comparison with flying: the radiation from one CXR is about the same as the extra radiation received in one transatlantic flight at the altitude flown by modern jetliners.The ECG is non-specific for the diagnosis of pulmonary embolus, even in the nonpregnant state. The lack of specificity is increased by the changes in electrical axis that occur in normal pregnancy. However features of acute right heart strain are common and specific in massive pulmonary embolus as in the non-pregnant state. Arterial blood gas values are not changed by pregnancy. However, the sample should be taken with the patient sitting. When pregnant women lie flat, the arterial oxygen tension falls by up to 2 kPa[25] for a number of reasons including ventilation/perfusion inequality and impaired venous return to the right heart. Echocardiography is an attractive option in pregnancy because of the lack of radiation. It will show a variety of abnormalities in patients with major central pulmonary embolus[3] as well as exclude other causes of collapse, in particular aortic dissection. Unfortunately this investigation may not be available when most needed in the emergency situation of the collapsed patient, particularly in isolated maternity units. Lung imaging As in the non-pregnant state, lung imaging is mandatory to confirm the abnormalities that may (or may not) have been found in the non-specific tests above. Isotope scanning is the technique that is most likely to be available. The radiation from one perfusion scan using 99m Tc-labelled macroaggregates varies between 10 and 350 ìGy[24], again well within the 50 000 ìGy permitted during pregnancy and the injected dose may be reduced still further in pregnancy[26]. Nursing mothers should not breast feed for the 15 h during which significant quantities of 99mTc are secreted in their milk[3]. It is argued that ventilation scans add little diagnostic precision[3,27]. However, even if a ventilation scan is used, this only increases the radiation by a further 40–190 ìGy[24]. Pulmonary angiography is under-used Eur Heart J, Vol. 20, issue 19, September 1999 in the non-pregnant state[3]. But the radiation from this examination is considerable (500–3740 ìGy)[24] and in pregnancy its use should be limited to patients who have collapsed where there is no confirmed diagnosis. Similar constraints apply to spiral CT scanning. By contrast magnetic resonance imaging has recently been shown to be of value in the diagnosis of pulmonary embolus. If preliminary results are confirmed this could well be the technique of choice for lung imaging in pregnancy because of the lack of radiation. The indications for leg vein imaging in suspected pulmonary embolus (indeterminate V/Q scan) in pregnancy are the same as in the non-pregnant state. However, in pregnancy in particular, ultrasound should be used rather than contrast venography because of the lack of radiation. From about 20 weeks gestation such studies should be performed in the left lateral position to avoid false-positive results caused by obstruction to venous flow from the gravid uterus[26]. Again, magnetic resonance imaging of the femoral iliac and ovarian veins[28] is likely to become very helpful. Plasma D-dimer assay has been proposed as an under-used test to exclude thromboembolism[3,29]. The levels are elevated because of activation of fibrin degradation. If this test is used in pregnancy it will need a different set of cut-off values since fibrin degradation is part of normal pregnancy. Differential diagnosis Pregnancy-specific differential diagnoses are amniotic fluid embolus and chorion carcinoma. The pathophysiology of amniotic fluid embolus is obscure. It is only likely to cause confusion in the first hours of acute vascular collapse. An important distinguishing feature is disseminated vascular coagulopathy, which is almost invariably present in amniotic fluid embolus but not in pulmonary embolus before treatment. Chorioncarcinoma can occur in pregnancy or be present for several years after delivery from a normal pregnancy or non-molar abortion. It can mimic pulmonary embolus due to the presence of tumour in pulmonary blood vessels or be a cause of pulmonary embolus. Although the association is rare it is one that should not be missed and ideally all women presenting with pulmonary embolus or suspected pulmonary embolus in reproductive life should have a pregnancy test and estimation of serum human chorionic gonadotropin if positive[30]. Thrombophilia testing As in the non-pregnant state, the presence or absence of thrombophilia has prognostic value relating to recurrence risk and could be used to aid decision making with regard to length of treatment. However, thrombophilia status is also important with regard to obstetric Review management since, in general, women with thrombophilia have a poorer pregnancy outcome. Unfortunately, testing for many thrombophilias is affected both by pregnancy and by anticoagulant treatment. Antiphospholipid antibodies such as anticardiolipin antibody are not affected and these should be sought in all women who have pulmonary embolus in pregnancy. At present, individual units must develop their own policies regarding the cost effectiveness of screening for other thrombophilias. Treatment Heparin, low molecular weight heparin and warfarin Anticoagulation with heparin should be the initial treatment in pregnancy. Heparin, both low molecular weight[31] and unfractionated[32] does not cross the placenta or the breast. It is therefore safe for the fetus and for the breast-fed infant. However there is considerable concern about the use of warfarin in pregnancy, chiefly for fetal reasons. One review suggests that the pooled incidence of adverse effects due to warfarin in pregnancy is 26%[33]. In the first trimester warfarin is teratogenic[34,35] and causes abnormalities of cartilage and bone formation, chondrodysplasia punctata. It also increases the risk of miscarriage. In the second and third trimester, maternal warfarin use has been associated with major fetal central nervous system abnormalities, particularly microcephaly and optic atrophy[34,35]. This is probably because warfarin, in contrast to herparin, does cross the placenta; also the fetus has a relatively immature clotting system so that a dose of warfarin which gives therapeutic anticoagulation in the mother is likely to over-anticoagulate the fetus. If the mother receives full anticoagulation with warfarin at the time of delivery, there are the fetal risks of gross retroplacental and intracerebral bleeding[34]. In addition, women bleed easily in pregnancy, particularly from the genital tract. While this risk may be no greater with full anticoagulation using warfarin than with heparin, reversal of anticoagulation is much easier with heparin treatment. For all these reasons heparin is preferred to warfarin for the treatment of pulmonary embolus for as long as the woman is pregnant. (Certain patients, such as those with artificial heart valves, heparin allergy or very active antiphospholipid syndrome may still require treatment with warfarin in pregnancy despite the fetal and maternal risks outlined above). No randomized controlled trials have been performed for the treatment of pulmonary embolus in pregnancy. However, a reasonable strategy is to use intravenous heparin aiming for activated partial thromboplastin time 1·5–2·5 times the control value for 10 days and then to change to a lower intensity subcutaneous regime. Patients can usually learn to inject themselves with relatively little difficulty. In practice 1381 10 000 units of unfractionated heparin twice daily, or now more commonly low molecular weight heparin such as enoxaparine 40 mg once daily, give adequate anticoagulation in this second phase. It is accepted that this level of anticoagulation is less than that usually obtained with warfarin maintaining the international normalized ratio at 2·0–3·0. Although it has been suggested that when administered subcutaneously, unfractionated heparin should be given twice daily in doses (presumably in excess of 10 000 units) to maintain the activated partial thromboplastin time in the normal therapeutic range[26,36], this is very difficult to achieve in practice and usually causes unacceptable bruising at the injection site. There are no comparative studies that indicate that this level of anticoagulation is necessary. Furthermore, although the aim may be to achieve an activated partial thromboplastin time ratio of 1·5, this is not necessarily achieved, leaving the patient at risk from both under-and overanticoagulation. Additional anxiety will occur should the patient need delivery or some other surgical procedure. In practice, the extra inconvenience of an adjusted dose subcutaneous heparin regime does not seem worthwhile. An alternative and more practical strategy is to use high dose subcutaneous low molecular weight heparin e.g. enoxaparine 1 mg . kg 1 every 12 h for a further 6 weeks in patients judged to be at particularly high risk of further embolization. Although high dose low molecular weight heparin is not currently recommended for the treatment of acute pulmonary embolism in pregnancy (see below), there is no reason why it should not be used in the treatment after the first week granted that lower intensity anticoagulation has been satisfactory in current clinical practice. Whenever heparin is used for more than 2 months, patients should be warned of the risk of bone demineralization. Most patients undergo some degree of demineralization as judged by bone densitometry studies; however, the majority of these changes are reversed one year after the cessation of therapy and breast-feeding[37]. About 2% of all patients taking heparin for 3 months or more in pregnancy will have symptoms from bone fracture due to demineralization. The incidence of such symptoms may be less with low molecular weight heparin, although strictly comparative data to support this suggestion only come from animal studies. Other complications of heparin therapy such as thrombocytopoenia are very uncommon in pregnant patients even if they take heparin long term. Occasionally patients develop erythematous itchy skin rashes at the site of heparin injection, which can be so severe as to limit treatment. These rashes are presumed to be due to allergy. It is worth trying different forms of heparin, both within and between the categories of unfractionated heparin and low molecular weight heparin, but often the patients react to all preparations. The only option is then to use warfarin, notwithstanding the fetal risks. It may be possible to use intravenous heparin to cover the peripartum period, but this needs to Eur Heart J, Vol. 20, issue 19, September 1999 1382 M. de Swiet be introduced very carefully because of the obvious risk of anaphylaxis. It is possible that the risk of anaphylaxis may be reduced by given a small dose of glucocorticoid if intravenous heparin is being used[38]. The excess risk of thromboembolism associated with pregnancy continues after delivery for an ill-defined period, believed by most clinicians to be no longer than 6 weeks. Therefore, treatment for pulmonary embolus occurring in relation to pregnancy should continue until 6 weeks after delivery or until 3 months after the initial episode whichever is the longer. To manage labour and delivery, one method has been to reduce the dose of subcutaneous unfractionated heparin to 7500 units twice daily in anticipation of the contraction in circulating blood volume and to counter any bleeding risk. This reduction seems unnecessary in patients taking low molecular weight heparin in daily doses of the order of enoxaparine 40 mg[39] or fragmin 5000 units. Providing the thrombin and activated partial thromboplastin times are not prolonged by more than 5 s the patients do not bleed excessively and nor is epidural haematoma a problem[39]. If there is real concern about the risk of bleeding in patients taking unfractionated heparin, measurement of the heparin level by anti Xa assay will give further information; if the level is less than 0·4 units . ml 1 (as is almost invariably the case using the doses of unfractionated heparin mentioned above), the patient should not bleed because of heparin treatment[40]. Similar data have not yet been established for low molecular weight heparin. Since warfarin is not secreted in significant quantities in breast milk, patients may convert to warfarin after delivery even if they are breast feeding[41]. There is also no problem with either unfractionated heparin or low molecular weight heparin with regard to breast-feeding. The use of high dose low molecular weight heparin, such as enoxaparine 1 mg . kg 1 every 12 h, for the acute treatment of pulmonary embolus has recently been studied in the non-pregnant state. However, the trials that have been performed comparing high dose low molecular weight heparin with unfractionated heparin in acute thromboembolism have all compared low molecular weight heparin and near simultaneous warfarin with unfractionated heparin and similar warfarin therapies. The results of such trials cannot be extrapolated directly to pregnancy where low molecular weight heparin would be used alone. Therefore, at present high dose low molecular weight heparin is not recommended for the initial treatment of thromboembolism in pregnancy. Nevertheless the practical advantages of low molecular weight heparin are just as great if not greater for pregnant patients compared to those who are not pregnant. It is therefore likely that high dose low molecular weight heparin will be used in acute thromboembolism in pregnancy, as more experience is gained in other situations such as in the management of patients with artificial heart valves. It is also likely that, as in the non-pregnant state, high dose low molecular weight heparin will first be used in patients with acute Eur Heart J, Vol. 20, issue 19, September 1999 deep vein thrombosis rather than acute pulmonary embolism. Thrombolysis There is published information on about 30 women treated with thrombolytic agents in pregnancy, massive pulmonary embolus being the indication in about one third[42]. Streptokinase was the agent used most frequently. Streptokinase (and probably other thrombolytic drugs) does not cross the placenta because of its high molecular weight. However in the mother, bleeding is the major side effect, usually from the genital tract and often severe; the overall incidence of bleeding is about 8%[42]. Because of the risk of bleeding, thrombolysis should not be used routinely in pregnancy, but reserved for those who are haemodynamically unstable, particularly with regard to systemic hypotension. It would not be appropriate to extrapolate directly from studies in non-pregnant patients[43] using echocardiographic variables as criteria for thrombolytic treatment. Because of the risk of bleeding, thrombolytic treatment should not be used at the time of delivery unless it appears that the patient is likely to die. Surgical procedures Procedures such as embolectomy are only occasionally indicated in pregnancy; one obvious situation would be massive pulmonary embolus immediately after delivery when thrombolysis should not be used. However, in most maternity units thrombolytic treatment or even transvenous catheter fragmentation or embolectomy[44] are more likely to be available. Caval filters Filters have been used in pregnancy[45] but controversy about the place of interrupt devices[46,47] is just as great with regard to patients who are pregnant, if not more so. Concerns that are specific to pregnancy are that free floating clot in the inferior vena cava before delivery may be ‘liberated’ at delivery, thus causing further pulmonary embolus, and fear for the fetus because of the additional radiation that is necessary for the placement of these devices. At present, interrupt devices should only be placed where recurrent pulmonary embolus has occurred despite adequate anticoagulation or where patients cannot receive conventional anticoagulant treatment. Prophylaxis Although the subject of thromboprophylaxis is too general to be within the remit of this review, Review thromboprophylaxis in pregnancy in women who have previously had an episode of thromboembolism is a specific problem, which should be addressed here. Again there are no randomized trials to aid the clinician. The following guidelines are suggested because they are practical and because in general they have been successful[10,39,48]. In women who have had thromboembolism in the past, the recurrence risk in pregnancy has been estimated to be about 12% whatever the circumstances of the original clot and independent of risk factors such as thrombophilia[49]. However, this study from 1974 was a postal survey and no record was made of the method of ascertainment of the subsequent episode. Recurrence was probably over-diagnosed and the true recurrence risk is probably less than 12%. Subsequent incidence studies have been confounded by the use of some form of prophylaxis. Granted the risk and granted the safety for the fetus of maternal subcutaneous heparin therapy it is tempting to recommend this throughout pregnancy for all at risk of recurrence of thromboembolism. However, the risks of bone demineralization and other heparin-induced side effects, plus the inconvenience of at least daily injections make such a blanket recommendation inadvisable. Instead, patients may be categorized as high and low risk for recurrence[10]. Low risk patients are those who have only had one previous episode of thromboembolism (pulmonary embolism or deep vein thrombosis) no matter what the original circumstances and who have no other high risk factors. High risk patients have had more than one episode or have thrombophilia or a family history of thromboembolism, suggesting that they may have undiagnosed thrombophilia. Low risk patients should take low dose aspirin, say 75 mg once daily from as soon as pregnancy has been confirmed until delivery. Meta-analysis of many trials in medical, surgical and orthopaedic (but not pregnant) patients, indicates that aspirin reduces the incidence of deep-vein thrombosis and pulmonary embolus by at least 50%[50]. The safety of low dose aspirin has been demonstrated in the numerous large randomized trials e.g. CLASP (Collaborative Studies of Low Dose Aspirin in Pregnancy)[51] where aspirin has been tested for the prevention of pre-eclampsia. At delivery, patients should take subcutaneous heparin[52] either unfractionated heparin 7500 units twice daily, or low molecular weight heparin such as enoxaparine 40 mg once daily, until at least the first week after delivery, and then either continue heparin for a further 5 weeks or switch to warfarin[48]. High-risk patients take subcutaneous heparin in doses as above rather than aspiring as soon as pregnancy is confirmed. Management at delivery and thereafter is as for low risk patients[39]. The safety of these regimes with regard to delivery, epidural block and breast feeding has already been discussed. Patients who are taking the high risk regime should be warned of the risk of bone demineralization. Individual risk factors and patients’ wishes should also be considered e.g. an otherwise low risk woman aged 1383 45 years should probably be treated with the high risk regime. Logistics As already indicated, none of the recommendations given for therapy and prophylaxis of pulmonary embolus in pregnancy have been established on the basis of clinical trial. It is therefore particularly difficult to be dogmatic granted the inevitable wide variety of opinions and clinical experience between different countries. However, the guidelines suggested above are derived from clinical practice and they have been found to work well. They should therefore form a framework, which can be adapted both in accordance with others’ clinical experience and as a consequence of clinical trials, which will eventually be performed. Conclusions and recommendations Diagnosis 1. Take samples for blood gas analysis with the patient sitting 2. Do not rely on axis changes in the electrocardiogram 3. Consider echocardiography 4. Chest X-ray and lung scan are safe in pregnancy 5. The diagnosis must be confirmed by lung imaging 6. Lung scan or magnetic resonance imaging are preferred to pulmonary angiography 7. Exclude chorioncarcinoma Treatment 1. Warfarin should usually be avoided in the treatment of pulmonary embolism in pregnancy 2. Use full anticoagulation with intravenous heparin for the first 10 days 3. Subsequent treatment should be with subcutaneous heparin either unfractionated heparin or low molecular weight heparin 4. Subcutaneous heparin does not need to be dose adjusted 5. Labour, surgical procedures and epidural block are safe providing that the thrombin time, activated partial thromboplastin time and platelet count are normal 6. Continue treatment for 6 weeks after delivery 7. Consider switching to warfarin one week after delivery 8. Warfarin is safe when mothers are breast feeding 9. Thrombolysis is the most practical rescue therapy for the patient who is haemodynamically unstable following pulmonary embolus. Prophylaxis 1. Low-risk patients have only had a single episode of previous thromboembolism with no other high-risk factors. Eur Heart J, Vol. 20, issue 19, September 1999 1384 M. de Swiet 2. High-risk patients have had previous multiple episodes or have had at least one previous episode and have documented thrombophilia or a family history or thromboembolism. 3. Treat low risk patients with aspirin 75 mg once daily from when pregnancy is confirmed to delivery. Then switch to subcutaneous heparin, either unfractionated heparin 7500 units twice daily or low molecular weight heparin e.g. enoxaparine 40 mg once daily. One week after delivery consider switching to warfarin. 4. Treat high risk patients as low risk except that they should take subcutaneous heparin from as soon as pregnancy is diagnosed. Conflict of interest Dr de Swiet has been supported with research and travel grants by Rhône-Poulenc Rorer. References [1] Koonin LM, Atrash HK, Lawson HW, Smith JC. Maternal mortality surveillance, United States, 1979–1986. MMWR CDC Suveill Summ 1991; 40 (SS-2): 1–13. [2] Report on Confidential Enquiries into Maternal Deaths in the United Kingdom 1994–96. HMSO, 1998. [3] British Thoracic Society Standards of Care Committee. Thorax 1997; 52 (Suppl 4): S1–24. [4] NIH 1986. Prevention of venous thrombosis and pulmonary embolism. NIH Consensus Development. JAMA 1986; 256: 744–9. [5] Clarke-Pearson DL, Jelovsek FR. Alterations of occlusive cuff impedance plethysmography results in the obstetric patient. Surgery 1981; 89: 594–8. [6] Macklon NS, Greer IA, Bowman AW. An ultrasound study of gestational and postural changes in the deep venous system of the leg in pregnancy. Br J Obstet Gynaecol 1997; 104: 191–7. [7] Macklon NS, Greer IA. 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