Background— Acute massive pulmonary embolism (PE) carries an exceptionally high mortality rate. We explored how often adjunctive therapies, particularly thrombolysis and inferior vena caval (IVC) filter placement, were performed and how these therapies affected the clinical outcome of patients with massive PE.
Methods and Results— Among 2392 patients with acute PE and known systolic arterial blood pressure at presentation, from the International Cooperative Pulmonary Embolism Registry (ICOPER), 108 (4.5%) had massive PE, defined as a systolic arterial pressure <90 mm Hg, and 2284 (95.5%) had non–massive PE with a systolic arterial pressure ≥90 mm Hg. PE was first diagnosed at autopsy in 16 patients (15%) with massive PE and in 29 patients (1%) with non–massive PE (P<0.001). The 90-day mortality rates were 52.4% (95% CI, 43.3% to 62.1%) and 14.7% (95% CI, 13.3% to 16.2%), respectively. In-hospital bleeding complications occurred in 17.6% versus 9.7% and recurrent PE within 90 days in 12.6% and 7.6%, respectively (P<0.001). In patients with massive PE, thrombolysis, surgical embolectomy, or catheter embolectomy were withheld in 73 (68%). Thrombolysis was performed in 33 patients, surgical embolectomy in 3, and catheter embolectomy in 1. Thrombolytic therapy did not reduce 90-day mortality (thrombolysis, 46.3%; 95% CI, 31.0% to 64.8%; no thrombolysis, 55.1%; 95% CI, 44.3% to 66.7%; hazard ratio, 0.79; 95% CI, 0.44 to 1.43). Recurrent PE rates at 90 days were similar in patients with and without thrombolytic therapy (12% for both; P=0.99). None of the 11 patients who received an IVC filter developed recurrent PE within 90 days, and 10 (90.9%) survived at least 90 days. IVC filters were associated with a reduction in 90-day mortality (hazard ratio, 0.12; 95% CI, 0.02 to 0.85).
Conclusions— In ICOPER, two thirds of the patients with massive PE did not receive thrombolysis or embolectomy. Counterintuitively, thrombolysis did not reduce mortality or recurrent PE at 90 days. The observed reduction in mortality from IVC filters requires further investigation.
The principal criterion to characterize acute pulmonary embolism (PE) as massive is systemic arterial hypotension.1,2 Massive PE is rare, and therefore no single physician or hospital can rely on individual experience to determine optimal management. Despite anticoagulation, the mortality rate doubles for submassive PE patients with preserved systemic arterial pressure and right ventricular dysfunction.3 The death rate is even higher in patients who present with profound hypotension due to massive PE.4 Nevertheless, there is only 1 randomized controlled trial of thrombolysis in patients with massive PE, with a total of 8 patients enrolled.5 Aggressive pharmacological therapy with thrombolysis is approved by the Food and Drug Administration and would appear beneficial at first glance, but this assumption requires further evaluation. Therefore, we studied the 108 patients with massive PE in the International Cooperative Pulmonary Embolism Registry (ICOPER).6 We focused on whether these patients received thrombolysis or placement of an inferior vena cava (IVC) filter in addition to anticoagulation.
Clinical Perspective p 582
Methods
ICOPER enrolled 2454 consecutive patients with acute PE from 52 institutions in 7 countries, from January 1995 through November 1996.6 In the present analysis, we evaluated 2392 patients with acute PE and known systolic arterial pressure at presentation. One hundred eight (4.5%) had massive PE, defined as a systolic arterial pressure <90 mm Hg, and 2284 (95.5%) had non–massive PE with a systolic arterial pressure ≥90 mm Hg. The remaining 62 patients were excluded because of unknown systolic arterial pressure at presentation.
Inclusion criteria for ICOPER were acute PE diagnosed by the attending physician within 31 days of symptom onset or major PE first discovered by autopsy. There were no exclusion criteria. The diagnosis of PE was accepted without independent review if confirmed by high-probability lung scan, pulmonary angiography, venous ultrasound of the leg veins in the presence of a high clinical suspicion of PE, or necropsy. The diagnosis of concomitant deep vein thrombosis was accepted when objectively confirmed by phlebography or venous ultrasound. Echocardiography was recommended but not mandated in ICOPER, and echocardiographic examinations were not centrally adjudicated. Right ventricular hypokinesis was defined as moderate or severe systolic hypokinesis of the right ventricular free wall by qualitative assessment. Left ventricular ejection fraction was obtained from the baseline echocardiogram. ICOPER did not issue guidelines for the management of the registered patients. The administration of anticoagulation or thrombolysis and the use of embolectomy and placement of IVC filters were decided entirely by site physicians. Site investigators performed 90-day follow-up by telephone interview, and follow-up was completed in 2343 (98%) of the 2392 patients included in this analysis. Completed case report forms were sent to and analyzed by the Data Coordinating Center, CINECA, Bologna, Italy. Institutional ethics committee approval was obtained from the participating hospitals.
We used the Mann-Whitney test for comparisons of continuous variables between patients with massive and non–massive PE and the χ2 test or Fisher exact test for comparisons of nominal variables. These tests were also used to explore differences between the patients with massive PE who did and did not receive systemic intravenous thrombolysis. The Kaplan-Meier estimator and log-rank test were used to estimate the cumulative probability of overall and cardiovascular death at 90 days in the groups. Cardiovascular mortality was defined as death from PE, acute myocardial infarction, stroke, or sudden cardiac death. The Cox proportional hazard model was used to calculate the univariate hazard ratio (HR) of clinical variables for predicting 90-day mortality in the defined groups. All reported probability values are 2 tailed.
Results
Comparison of Patients With Massive and Non–Massive PE
Age (64±17 versus 62±17 years) and gender (41% versus 45% men) were similar in patients with massive and non–massive PE, respectively (Table 1). PE was first diagnosed at autopsy in 16 (15%) of the patients with massive PE and in 29 (1%) of the patients with non–massive PE (P<0.001). Among the 1096 patients who underwent baseline echocardiography within 24 hours of PE diagnosis, right ventricular hypokinesis was present in 62% of the patients with massive PE compared with 39% of the patients with non–massive PE. Right heart thrombi were more often found in patients with massive PE (10% versus 4%). Patients with massive PE more often had congestive heart failure (22% versus 10%), reduced left ventricular ejection fraction of <40% (15% versus 6%), and renal dysfunction (15% versus 5%). Cancer rates were similar in both groups (21% versus 22%). Concomitant deep vein thrombosis was less often diagnosed in patients with massive PE (32% versus 50%).
TABLE 1. Patient Characteristics (n=2392)
Massive PE (n=108)
Non–Massive PE (n=2284)
P
Data are numbers of patients with percentages in parentheses unless otherwise specified. LV indicates left ventricular.
*Intravenous or subcutaneous unfractionated heparin or subcutaneous low-molecular-weight heparin.
†One patient underwent both catheter embolectomy and thrombolysis.
‡One patient underwent surgical embolectomy for failed thrombolysis.
Age, mean±SD, y
64±17
62±17
0.12
Age >70 y
43 (40)
818 (36)
0.40
Men
44 (41)
1024 (45)
0.40
Systolic pressure, mean±SD, mm Hg
75±10
131±23
<0.001
Heart rate, mean±SD, bpm
117±28
98±21
<0.001
Days from symptom onset to diagnosis, mean±SD
(1.2± 2.1)
(4.1±5.9)
<0.001
Chest pain
41 (40)
1127 (50)
0.06
Dyspnea
86 (81)
1876 (82)
0.77
Syncope
41 (39)
271 (12)
<0.001
Cough
10 (9)
483 (21)
0.003
Hemoptysis
2 (2)
160 (7)
0.040
Right ventricular hypokinesis
38/61 (62)
405/1035 (39)
0.001
Right heart thrombus
6/62 (10)
44/1052 (4)
0.042
LV ejection fraction <40%
13/88 (15)
104/1777 (6)
0.001
Concomitant deep vein thrombosis
34/105 (32)
1150/2276 (50)
<0.001
Cancer
23 (21)
510 (22)
0.79
Ongoing cancer chemotherapy
7 (7)
122 (5)
0.60
Prior deep vein thrombosis
16 (16)
468 (21)
0.19
Prior PE
4 (4)
207 (9)
0.08
Chronic lung disease
20 (19)
277 (12)
0.050
Congestive heart failure
23 (22)
230 (10)
<0.001
Trauma within 2 mo
15 (14)
251 (11)
0.35
Creatinine >2.0 mg/dL
16 (15)
107 (5)
<0.001
Therapy
Thrombolysis
33 (36)
266 (12)
<0.001
Heparin*
102 (94)
2,208 (97)
0.21
Vitamin K antagonist
57 (53)
1,779 (78)
<0.001
IVC filter
11 (12)
227 (10)
0.59
Catheter thrombectomy
1 (1)†
14 (<1)
0.50
Surgical embolectomy
3 (3)‡
11 (<1)
0.02
No reperfusion therapy
73 (68)
1999 (88)
<0.001
The 90-day mortality rates were 52.4% (95% CI, 43.3% to 62.1%) and 14.7% (95% CI, 13.3% to 16.2%) in patients with massive and non–massive PE, respectively (Figure 1). PE was the cause of death in 62.5% of the patients with massive PE and in 34.0% of the patients with non–massive PE (Table 2). In-hospital bleeding complications occurred in 17.6% versus 9.7%, and recurrent PE was detected within 90 days in 12.6% and 7.6%, respectively, in patients with massive versus non–massive PE (P<0.001).
Figure 1. Overall mortality (A) (log-rank P<0.001) and cardiovascular mortality (B) (log-rank P<0.001) in 108 patients with massive PE and in 2284 patients with non–massive PE.
TABLE 2. Adverse Events
Massive PE (n=108)
Non–Massive PE (n=2284)
P
Data are numbers of patients with percentages in parentheses.
Deaths at 90 d
56 (51.9)
332 (14.5)
<0.001
Cause of death
PE
35 (62.5)
119 (34.0)
Sudden cardiac death
6 (10.7)
39 (11.1)
Cancer
2 (3.6)
73 (20.9)
Respiratory failure
3 (5.4)
45 (12.9)
Stroke
3 (5.4)
7 (2.0)
Hemorrhage
…
10 (2.9)
Myocardial infarction
…
5 (<1)
Other
7 (12.5)
52 (14.9)
Recurrent PE at 90 d
13 (12.6)
171 (7.6)
0.09
Any in-hospital bleeding
19 (17.6)
221 (9.7)
0.007
Intracranial bleeding
2 (2.0)
11 (0.5)
0.11
Gastrointestinal bleeding
7 (7.0)
48 (2.2)
0.011
Genitourinary bleeding
2 (2.0)
21 (1.0)
0.27
Retroperitoneal bleeding
…
10 (0.4)
1.00
Any transfusion
17 (17.0)
175 (8.0)
0.002
Drop in hematocrit ≥10%
12 (12.1)
142 (6.5)
0.031
Adjunctive Therapies
Thrombolysis, surgical embolectomy, or percutaneous catheter embolectomy was withheld in 73 patients (68%). Thrombolysis was administered in 33 patients, surgical embolectomy in 3, and catheter embolectomy in 1. Age (64±13 versus 64±19 years) and sex (39% versus 41% men) were similar between the patients who did and did not receive thrombolysis, respectively (Table 3). Among the 61 patients who underwent baseline echocardiography, right ventricular hypokinesis was more common (85%) among those who received thrombolysis compared with the no-thrombolysis group (44%) (P=0.001). In patients who received thrombolysis, cancer was less often present (6% versus 28%), and prior deep vein thrombosis (38% versus 6%) or prior PE (13% versus none) was more often present.
TABLE 3. Characteristics of Massive PE Patients With and Without Thrombolysis
Thrombolysis (n=33)
No Thrombolysis (n=75)
P
Data are numbers of patients with percentages in parentheses. LV indicates left ventricular.
Age, mean±SD, y
64±13
64±19
0.95
Age >70 y
13 (39)
33 (44)
0.66
Men
13 (39)
31 (41)
0.85
Systolic pressure, mean±SD, mm Hg
73±9
76±10
0.20
Heart rate, mean±SD, bpm
119±22
116±30
0.65
Right ventricular hypokinesis
23/27 (85)
15/34 (44)
0.001
Right heart thrombus
4/28 (14)
2/34 (6)
0.26
LV ejection fraction <40%
3/29 (10)
10/59 (17)
0.41
Concomitant deep vein thrombosis
13 (41)
21 (28)
0.23
Cancer
2 (6)
21 (28)
0.010
Prior deep vein thrombosis
12 (38)
4 (6)
<0.001
Prior PE
4 (13)
…
0.002
Chronic lung disease
3 (9)
17 (23)
0.09
Congestive heart failure
4 (12)
19 (26)
0.12
Trauma within 2 mo
4 (12)
11 (15)
0.72
Creatinine >2.0 mg/dL
7 (21)
9 (12)
0.22
In-hospital bleeding
8 (24)
11 (15)
0.23
Recurrent PE at 90 d
4 (12)
9 (12)
0.99
Thrombolytic therapy did not reduce 90-day mortality (HR, 0.79; 95% CI, 0.44 to 1.43; P=0.44). The 90-day mortality rates were 46.3% (95% CI, 31.0% to 64.8%) in patients with thrombolytic therapy and 55.1% (95% CI, 44.3% to 66.7%) in patients without thrombolysis (Figure 2).
Figure 2. Overall mortality (A) (log-rank P=0.40) and cardiovascular mortality (B) (log-rank P=0.34) in 35 patients with massive PE who received reperfusion therapy and in 73 patients with massive PE who did not receive reperfusion therapy.
In-hospital bleeding complications occurred often in both the thrombolysis and no-thrombolysis groups (24% and 15%), and recurrent PE at 90 days was equal (12% for both). Recurrent PE was a predictor of 90-day mortality both in patients with thrombolytic therapy (HR, 6.71; 95% CI, 1.81 to 24.81; P=0.004) and in those without thrombolytic therapy (HR, 2.39; 95% CI, 1.09 to 5.21; P=0.029).
The 11 massive PE patients who received an IVC filter were younger than the massive PE patients without IVC filter placement (Table 4). None of the patients who received an IVC filter developed recurrent PE within 90 days, and 10 (90.9%) survived 90 days (Figure 3). In contrast, 13 of 97 patients without an IVC filter (13.4%) developed recurrent PE within 90 days, and 55 (56.7%) of the 97 survived 90 days. IVC filters were associated with a reduction in 90-day mortality (HR, 0.12; 95% CI, 0.02 to 0.85; P=0.002).
TABLE 4. Characteristics of Massive PE Patients With and Without IVC Filter
IVC Filter (n=11)
No IVC Filter (n=97)
P
Data are numbers of patients with percentages in parentheses. LV indicates left ventricular.
Age, mean±SD, y
50±15
66±17
0.003
Age >70 y
1 (9)
45 (46)
0.023
Men
8 (73)
36 (37)
0.048
Systolic pressure, mean±SD, mm Hg
81±2
75±10
0.006
Heart rate, mean±SD, bpm
138±33
115±26
0.01
Right ventricular hypokinesis
3/4 (75)
35/57 (61)
1.00
Right heart thrombus
1/4 (25)
5/58 (9)
0.34
LV ejection fraction <40%
1/8 (12)
12/80 (12)
1.00
Concomitant deep vein thrombosis
7 (64)
27 (29)
0.36
Cancer
4 (36)
19 (20)
0.24
Prior deep vein thrombosis
2 (18)
14 (15)
0.68
Prior PE
1 (9)
3 (3)
0.38
Chronic lung disease
2 (18)
18 (19)
1.00
Congestive heart failure
1 (9)
22 (23)
0.45
Trauma within 2 mo
1 (9)
14 (14)
1.00
Creatinine >2.0 mg/dL
1 (9)
15 (16)
1.00
In-hospital bleeding
4 (36)
15 (16)
0.10
Recurrent PE at 90 d
…
13 (14)
0.35
Figure 3. Overall mortality (A) (log-rank probability value 0.006) and cardiovascular mortality (B) (log-rank P=0.005) in 11 patients with massive PE who received an IVC filter and in 97 patients with massive PE who did not receive an IVC filter.
In the patients with non–massive PE, 90-day survival rates were 79.3% (95% CI, 74.3% to 84.1%) in patients with thrombolysis and 86.1% (95% CI, 84.5% to 87.5%) in patients without thrombolysis (HR, 1.56; 95% CI, 1.16 to 2.10; P=0.003); 90-day survival rates were 79.1% (95% CI, 73.2% to 83.9%) in patients with an IVC filter and 86.0% (95% CI, 84.5% to 87.5%) in those without an IVC filter (HR, 1.50; 95% CI, 1.10 to 2.04; P=0.009).
Discussion
We found that certain comorbidities were associated with massive rather than non–massive PE: congestive heart failure, renal dysfunction, and reduced left ventricular systolic ejection fraction. One third of the massive PE patients had no echocardiographic right ventricular hypokinesis; at least in some of these patients, cardiopulmonary comorbidities may have been the main cause of hemodynamic instability. Massive PE was associated more often with right heart thrombi (10%) than non–massive PE (4%). This finding is important because echocardiographic evidence of right heart thrombi in the setting of massive PE may change the treatment plan from thrombolysis to surgical embolectomy.
Since the conclusion of ICOPER, chest CT has virtually replaced lung scanning for diagnosing PE at most hospitals,7 resulting in more rapid and accurate diagnosis. Rapid diagnosis of massive PE is crucial to initiate potentially life-saving therapy. Chest CT is not only useful to diagnose PE and assess clot burden but helps to identify patients with right ventricular enlargement who are at increased risk of early death.8,9
We were surprised to find that two thirds of the patients with massive PE did not receive any adjunctive therapy such as thrombolysis or embolectomy. Unfortunately, we were not able to explore the reasons for withholding thrombolysis or embolectomy. The 15% missed massive PEs can only partly explain the omission of therapy. Therefore, it remains hypothetical whether thrombolysis or embolectomy was actively withheld or simply not considered. It is likely that neither surgical embolectomy nor percutaneous catheter thrombectomy was available in most of the participating hospitals. However, this does not explain the omission of thrombolysis.
At first glance, it seemed surprising and counterintuitive that thrombolysis did not improve survival. That thrombolysis patients more frequently than no-thrombolysis patients had right ventricular hypokinesis raises the possibility that these patients had more severe PE. However, in some patients thrombolysis was probably contraindicated because of severe comorbidities despite massive PE. Because most deaths after thrombolysis occurred in the first few days, we hypothesize that many of the patients had suffered irreversible cardiogenic shock and multisystem organ failure due to prolonged systemic arterial hypotension and that thrombolysis was administered too late. We recognize that no definite conclusion about the efficacy of thrombolysis in massive PE can be drawn from the ICOPER because (1) the patients with and without thrombolysis may not have been comparable because of the nonrandomized design and (2) the relatively small number of patients yielded wide CIs of the mortality estimates.
Patients in shock because of acute myocardial infarction do poorly with thrombolysis alone. To maximize the likelihood of survival, they usually require mechanical intervention with insertion of an intra-aortic balloon pump followed by percutaneous coronary intervention or coronary artery bypass grafting.10,11 By analogy, thrombolysis alone might fail to rescue a substantial proportion of patients with massive PE, even though the Food and Drug Administration has approved thrombolysis for massive PE. Their survival may depend on rapid transfer to a specialized vascular center skilled in surgical or catheter embolectomy. This strategy of rapid referral to specialty hospitals is often used to manage complicated acute myocardial infarction or trauma patients.
With a closely coordinated multidisciplinary PE management program, 1-year survival after surgical embolectomy can be as high as 86%.12 In 35 (74%) of 47 massive PE patients at Brigham and Women’s Hospital, surgical embolectomy was performed before the development of decompensated cardiogenic shock.13 Catheter thrombectomy is especially useful in the presence of an increased bleeding risk or if surgical embolectomy is not available or feasible.1 Since the introduction of novel percutaneous interventional thrombectomy devices, such as the Aspirex PE catheter thrombectomy device (Straub Medical)14 or the Angiojet Xpeedior device (Possis),15 the spectrum of interventional approaches to treat massive PE has broadened. The Food and Drug Administration has assigned Humanitarian Use Device status for the Aspirex PE catheter device to treat patients with massive PE in whom thrombolysis is contraindicated.
In ICOPER patients with massive PE, IVC filters appeared to reduce recurrent PE and mortality at 90 days. These findings should be interpreted with caution because of the small percentage of patients (10%) who received an IVC filter. Although we found no differences in comorbidities except younger age in patients who received an IVC filter, selection bias is likely and makes it difficult to compare the outcome of the filter and no-filter patients. IVC filter placement has been found to reduce recurrent PE but not mortality in patients with non–massive PE.16 Further studies should be performed before a definitive recommendation is made. Since the conclusion of ICOPER, the use of IVC filters in patients with venous thromboembolism has increased substantially.17
In conclusion, the principal findings of this ICOPER analysis of massive PE are that (1) thrombolysis or embolectomy was withheld in two thirds of the patients and (2) thrombolysis did not appear to reduce mortality. These findings imply that there is a need for improved multidisciplinary collaboration to optimize the in-hospital management of patients with acute massive PE, involving vascular medicine specialists, intensive care or emergency medicine specialists, interventional cardiologists/radiologists, and cardiovascular surgeons.
Acknowledgments
Disclosures
None.
CLINICAL PERSPECTIVE
Among 2392 patients with acute pulmonary embolism (PE) and known systolic arterial blood pressure at presentation from the International Cooperative Pulmonary Embolism Registry (ICOPER), 108 (4.5%) had massive PE, defined as a systolic arterial pressure <90 mm Hg, and 2284 (94.5%) had non–massive PE with a systolic arterial pressure ≥90 mm Hg. PE was first diagnosed at autopsy in 16 patients (15%) with massive PE and in 29 patients (1%) with non–massive PE (P<0.001). The 90-day mortality rates were 52.4% (95% CI, 43.3% to 62.1%) and 14.7% (95% CI, 13.3% to 16.2%), respectively. Thrombolysis, catheter thrombectomy, or surgical embolectomy was withheld in two thirds (68%) of the patients with massive PE, and thrombolysis did not appear to reduce mortality (hazard ratio, 0.79; 95% CI, 0.44 to 1.43; P=0.44) in these patients. These findings imply that there is an urgent need for improved multidisciplinary collaboration to optimize the in-hospital management of patients with acute massive PE, involving vascular medicine specialists, intensive care or emergency medicine specialists, interventional cardiologists, and cardiovascular surgeons.
Footnote
Guest Editor for this article was Kim M. Fox, MD.
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Received September 30, 2005; revision received October 28, 2005; accepted November 11, 2005.
Authors
Affiliations
NilsKucher, MD
From the Cardiovascular Division, Department of Medicine, University Hospital Zurich, Zurich, Switzerland (N.K.); CINECA, Bologna, Italy (E.R., M.D.R.); and Cardiovascular Division, Department of Medicine, Brigham and Women’s Hospital, Harvard Medical School, Boston, Mass (S.Z.G.).
From the Cardiovascular Division, Department of Medicine, University Hospital Zurich, Zurich, Switzerland (N.K.); CINECA, Bologna, Italy (E.R., M.D.R.); and Cardiovascular Division, Department of Medicine, Brigham and Women’s Hospital, Harvard Medical School, Boston, Mass (S.Z.G.).
From the Cardiovascular Division, Department of Medicine, University Hospital Zurich, Zurich, Switzerland (N.K.); CINECA, Bologna, Italy (E.R., M.D.R.); and Cardiovascular Division, Department of Medicine, Brigham and Women’s Hospital, Harvard Medical School, Boston, Mass (S.Z.G.).
From the Cardiovascular Division, Department of Medicine, University Hospital Zurich, Zurich, Switzerland (N.K.); CINECA, Bologna, Italy (E.R., M.D.R.); and Cardiovascular Division, Department of Medicine, Brigham and Women’s Hospital, Harvard Medical School, Boston, Mass (S.Z.G.).
Correspondence to Samuel Z. Goldhaber, MD, Cardiovascular Division, Brigham and Women’s Hospital, 75 Francis St, Boston, MA 02115. E-mail [email protected]
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