Abstract
The risk of dying from a pulmonary embolism (PE) is estimated to be about 30% if inotropic support is required and no cardiopulmonary arrest occurs. Fibrinolysis in massive PE is regarded as a life-saving intervention, unless there is a high risk of bleeding following the use of the fibrinolytic therapy. Rivaroxaban is an oral factor Xa inhibitor, however its anticoagulation effects before or after administration of fibrinolytics in massive PE are still unknown. Two patents were admitted: 61-year-old woman with repeated syncope, and a 73-year-old woman was admitted with dyspnea and poor oral intake. Systemic arterial hypotension with radiologic confirmation led to a diagnosis of massive PE in both patients. Rivaroxaban was administered before in one, and after firbrinolytic therapy in the other. One showed similar efficacy of rivaroxaban with currently used anticoagulants after successful fibrinolysis, and the other one without antecedent administration of the fibrinolytic agent showed unfavorable efficacy of rivaroxaban.
Massive pulmonary embolism (PE) is defined by acute PE with sustained systemic arterial hypotension that is below 90 mm Hg for at least 15 minutes or requires inotropic agents1. The risk of dying of PE is estimated to be 30% if an inotropic support is required and no cardiopulmonary arrest occurs2. Fibrinolysis in massive PE is regarded as a life-saving intervention unless there is a high risk of bleeding following the use of fibrinolytic therapy3. Successful fibrinolysis reduces thrombus burden, rapidly reverses right heart failure, and leads to treatment with anticoagulation alone3.
Rivaroxaban, an oral factor Xa inhibitor and one of the new oral anticoagulants, shows effective anticoagulation within hours of administration, a fixed-dose regimen, and no need for laboratory monitoring4,5. The effect of rivaroxaban before or after administration of fibrinolytics in massive PE is still unknown since clinical trials performed with rivaroxaban excluded patients with massive PE. Here, we report on two cases of massive PE managed with fibrinolytic therapy and rivaroxaban.
A 61-year-old woman was admitted to our hospital with a 4-day history of repeated syncope. She had felt dyspnea on exertion even in daily life since the last 2 weeks. The loss of consciousness was accompanied by syncope but abnormal neurologic sign was not shown. She was never a smoker and had been on hormone replacement therapy for abnormal uterine bleeding since the last 3 months. On admission, blood pressure was 104/70 mm Hg, heart rate was 94 beat/min, respiratory rate was 20 breath/min, and body temperature was 36.8℃. All of a sudden, her blood pressure decreased to 80/40 mm Hg for over 15 minutes on the same day. The physical examination was grossly normal. Arterial blood gas analysis (aBGA) on room air was 7.442 in pH, 27.7 mm Hg in PaCO2, 51 mm Hg in PaO2, 18 mmol/L in HCO3-, and 87% in O2 saturation. Echocardiography showed right ventricular (RV) hypokinesia with a D-shaped left ventricle (LV) and pulmonary hypertension. Computed tomographic (CT) pulmonary angiogram with lower extremity CT venogram showed extensive bilateral acute PE with deep vein thrombosis (DVT) in the right lower extremity and enlarged right cardiac chambers (Figure 1). The brain CT was normal. D-dimer, N terminal-pro-brain natriuretic peptide (NT-pro-BNP), and high sensitive troponin-T was 2,923 ng/mL (range, 0-243 ng/mL), 316 pg/mL (range, 0-97.3 ng/mL), and 0.029 ng/mL (range, 0-0.015 ng/mL), respectively.
According to the known protocol3 for massive PE, a high dose of unfractionated heparin (UFH) with 10,000 U was intravenously injected once. The maintaining dose of UFH was continuously infused at the rate of at least 1,250 U/hr until the activated partial thromboplastin time (aPTT) reached 80 seconds. Then, recombinant tissue plasminogen activator (rt-PA) of 100 mg was administered via a peripheral vein for 2 hours while a high dose of UFH was withheld. The aPTT was checked every 4 hours until aPTT reached below 80 seconds. Rivaroxaban with 15 mg twice daily was administered instantly without resumption of the high dose UFH after aPTT reached below 80 seconds. Her hospital stay was 4 days. The dose of rivaroxaban was changed from 30 mg/day to 20 mg/day after 3 weeks. Two months passed and she denied dyspnea on exertion even during hard work and any bleeding complications.
A 73-year-old woman was admitted to our hospital with a 1-month history of dyspnea and poor oral intake. She had felt mild dyspnea on exertion without progression since last year. The aggravation of dyspnea on exertion started 1 month ago. She had a disability in walking because an event of cerebral hemorrhage occurred 2 years ago and an event of cerebral infarction occurred 1 year ago. She was never a smoker and was on medication due to hypertension for 2 years. On admission, blood pressure was 100/60 mm Hg, heart rate was 81 beat/min, respiratory rate was 18 breath/min, body temperature was 36.4℃. Her blood pressure decreased to 80/50 mm Hg and lasted over 1 hour on the next day. aBGA on room air was 7.505 in pH, 23.1 mm Hg in PaCO2, 64.6 mm Hg in PaO2, 17.8 mmol/L in HCO3-, and 94.8% in O2 saturation. Echocardiography showed RV hypokinesia with a D-shaped LV and pulmonary hypertension. A CT pulmonary angiogram with a lower extremity CT venogram showed massive bilateral PE with lung infarction and DVT in the right superficial femoral vein extending to the popliteal vein (Figure 2). A brain CT showed an old infarction sequelae in the right frontal lobe, basal ganglia and cerebellum. D-dimer, NT-pro-BNP, and high sensitive troponin-T were 1,190 ng/mL (range, 0-243 ng/mL), 17,481 pg/mL (range, 0-97.3 ng/mL), and 0.036 ng/mL (range, 0-0.015 ng/mL), respectively. Since previous intracranial hemorrhage is one of the major contraindications to the use of fibrinolytic therapy, high dose UFH alone was administered instead of a fibrinolytic agent. On the day following the high dose UFH injection, dyspnea was much improved in spite of no change in hemodynamic parameters. High dose UFH was replaced with rivaroxaban 15 mg twice daily. After 3 days of medication with rivaroxaban alone, the dyspnea was worsened and repeated aBGA on oxygen 6 L/min with an oxygen mask with a reservoir bag was 7.455 in pH, 19.3 mm Hg in PaCO2, 54.3 mm Hg in PaO2, 13.3 mmol/L in HCO3-, and 90.7% in O2 saturation. A high dose of UFH was administered again after the rivaroxaban was stopped for 4 days. Dyspnea was slightly improved without a change in the thrombus burden on follow-up CT scan and hemodynamic parameters (Figure 2). We assumed that reversal of the RV failure outweighed the increased bleeding following fibrinolytic therapy. On the next day, rt-PA with 100 mg was administered via a peripheral vein for 2 hours while a high dose of UFH was withheld. Dyspnea was much improved without major bleeding complications and hemodynamic parameters showed marked improvement (Figure 3). She has been taking warfarin after fibrinolytic therapy and denied dyspnea on exertion.
The major determinant regarding favorable treatment outcome in these cases was whether a fibrinolytic agent was administered to patients with massive PE. A successful fibrinolysis, which reduces thrombotic burden and reverses RV failure, could lead to effective treatment following rivaroxaban alone and shorten the hospital stay (case no. 1). Initial treatment with rivaroxaban without fibrinolysis in massive PE failed to relieve RV failure (case no. 2). The effect of rivaroxaban as a first line drug in massive PE showed an unfavorable outcome.
In case 2, there was a major contraindication to the use of fibrinolysis owing to a previous intracranial hemorrhage. The relative risk of systemic fibrinolytic therapy is 3.5 within 35 days for major bleeding and 7 for intracranial bleeding2. At the time of diagnosis, high dose UFH was administered since the risk of increased bleeding following fibrinolysis outweighs the benefits of a rapid resolution to massive PE. Subsequent failures to relieve RV pressure overload with anticoagulant, such as rivaroxaban and high dose UFH, required escalation of therapy such as fibrinolysis because the benefits of a rapid resolution to PE outweigh the risk of increased bleeding following fibrinolysis.
In the case of massive PE with major contraindications to fibrinolysis, alternative treatment, such as catheter-assisted thrombus removal or surgical pulmonary embolectomy, is recommended if appropriate expertise and resources are available2. The reasons why alternative treatment was not chosen were a slight improvement in symptoms after administration of anticoagulants and less probability it would progress to a cardiovascular collapse.
We report two cases with massive PE that successfully reverse RV failure with fibrinolytictherapy. In view of the administration of rivaroxaban in patients with massive PE, one showed similar efficacy of rivaroxaban with currently used anticoagulants after administration of the fibrinolytic agent while the other one without antecedent administration of a fibrinolytic agent showed unfavorable efficacy of rivaroxaban.
References
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