Continuous Aspiration Thrombectomy in High- and Intermediate-High-Risk Pulmonary Embolism in Real-World Clinical Practice

Araszkiewicz, Aleksander; Sławek-Szmyt, Sylwia; Jankiewicz, Stanisław; Żabicki, Bartosz; Grygier, Marek; Mularek-Kubzdela, Tatiana; Krasiński, Zbigniew; Lesiak, Maciej

doi:https://doi.org/10.1155/2020/4191079

Journal of Interventional Cardiology

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Abstract Introduction Materials and Methods Results Discussion Conclusions Data Availability Conflicts of Interest Supplementary Materials References Copyright Related Articles

Clinical Study | Open Access

Volume 2020 | Article ID 4191079 | https://doi.org/10.1155/2020/4191079

Continuous Aspiration Thrombectomy in High- and Intermediate-High-Risk Pulmonary Embolism in Real-World Clinical Practice

Aleksander Araszkiewicz,¹Sylwia Sławek-Szmyt,¹Stanisław Jankiewicz,¹Bartosz Żabicki,²Marek Grygier,¹Tatiana Mularek-Kubzdela,¹Zbigniew Krasiński,³and Maciej Lesiak¹

Academic Editor: Piotr Musiałek

Received02 Apr 2020

Revised15 May 2020

Accepted06 Jul 2020

Published21 Aug 2020

Abstract

Objectives. We sought to assess the technical and clinical feasibility of continuous aspiration catheter-directed mechanical thrombectomy (CDT) in patients with high- or intermediate-high-risk pulmonary embolism (PE). Methods and Results. Fourteen patients (eight women and six men; age range: 29–71 years) with high- or intermediate-high-risk PE and contraindications to or ineffective systemic thrombolysis were prospectively enrolled between October 2018 and February 2020. The Indigo Mechanical Thrombectomy System (Penumbra, Inc., Alameda, California) was used as CDT device. Low-dose local thrombolysis (alteplase, 3–12 mg) was additionally applied in three patients. Technical and procedural success was achieved in 14 patients (100%). Complete or nearly complete clearance of pulmonary arteries was achieved in nine patients (64.3%), whereas partial clearance was achieved in five (35.7%). A significant improvement in the pre- and postprocedural patients’ clinical status was observed in the following fields (median; interquartile range): heart rate (110; 100–120/min vs. 85; 80–90/min; ), systolic blood pressure (106; 90–127 mmHg vs. 123; 110–133 mmHg; ), arterial oxygen saturation (88.5; 84.2–93% vs. 95.0; 93.8–95%, ), pulmonary artery systolic pressure (55; 44–66 mmHg vs. 42; 34–53 mmHg; ), Miller index score (21.5; 20–23 vs. 9.5; 8–13; ) and right ventricular/left ventricular ratio (1.3; 1.3–1.5 vs. 1.0; 0.9–1.0; ). No major periprocedural bleeding was detected. Conclusions. CDT is a feasible and promising technique for management of high- or intermediate-high-risk PE to decrease thrombus burden, reduce right heart strain, and improve hemodynamic and clinical status. Some patients may benefit from simultaneous local low-dose thrombolytic therapy. Nevertheless, its criteria and role in CTD-managed patients require further elucidation.

1. Introduction

Pulmonary embolism (PE) is the third leading cause of cardiovascular mortality and its occurrence is estimated at 39–115 cases/100000 inhabitants/year [1–4]. The presentation of PE may vary from asymptomatic or mild exertion disturbances (low-risk PE) treated with anticoagulants only to hemodynamic “obstructive” collapse and death (high-risk or massive PE) [5]. Systemic thrombolysis (ST) decreases mortality and improves clinical status in high-risk PE patients, but it also poses higher major bleeding risk [6]. The controversy concerns especially risk stratification and treatment in intermediate-high-risk (submassive) PE patients. Patients in this group do not have developed features of hemodynamic instability (hypotension, the need for catecholamines, disturbances, or loss of consciousness), but they have right ventricular (RV) overload characteristics, elevated markers of necrosis, and high values of Pulmonary Embolism Severity Index (PESI). In patients with intermediate-high-risk PE, ST is not indicated because the potential benefits do not outweigh the risk of serious bleeding complications [6, 7]. On the other hand, a significant percentage of intermediate-high-risk patients with PE may experience rapid hemodynamic deterioration and then the prognosis in this group is significantly worse. According to the present European and American guidelines, in the case of contraindications to ST or its failure, surgical embolectomy (SE) is recommended [5, 8]. However, a severe preoperative condition and high incidence of comorbidities as well as limited availability of “on-time” cardiac surgery result in high mortality in these patients. Due to the above conditions, risk assessment and qualification for different treatment methods should be dealt with by the institutional multidisciplinary team set-up for the treatment of PE (Pulmonary Embolism Response Team, PERT) [9–11]. Consequently, current treatment modalities such as anticoagulation (AC), ST, or SE have recently been expanded to modern transcatheter techniques, such as catheter-directed thrombolysis or mechanical catheter-directed aspiration thrombectomy (CDT) [12, 13]. The issue of choosing the catheter-directed modality determined by the mortality risk and contraindications to ST is widely discussed. Catheter-directed thrombolysis has been applied as an alternative to ST and has been shown to improve RV strain. Nonetheless, it is still associated with a relatively high bleeding risk, because of usage of thrombolytic agents [14]. As a result, CDT without thrombolytic drug administration is considered to be a promising therapeutic option [12, 13]. The present study aimed to evaluate the safety and feasibility of this approach.

2. Materials and Methods

Ninety-eight consecutive patients with acute PE were evaluated and screened by our institutional PERT between October 2018 and February 2020. Patients older than 18 years of age with proximal PE confirmed by computed tomography pulmonary angiography (CTPA) and symptoms onset within 14 days were eligible for enrollment in the present study. The severity of PE was categorized as low-risk, intermediate-low-risk, intermediate-high-risk, or high-risk in accordance with the guidelines of the European Society of Cardiology (ESC) [5, 15]. The precise PE patients risk stratification is presented on Figure 1. The details concerning organizing and functioning of our institutional PERT were published elsewhere [16]. In brief, PERT recommendation included AC therapy alone or advanced therapy defined as implementation of the AC together with some kind of invasive strategy including CDT or pharmacomechanical thrombectomy (CDT along with low dose of the thrombolysis with the alteplase), ST, SE, or venous thrombectomy (VT). All high-risk PE patients with absolute contraindications to ST or its failure (refractory circulatory collapse) who were not eligible for SE were qualified for CDT after careful assessment by PERT. Intermediate-high-risk patients with RV dysfunction confirmed by imaging (CTPA or transthoracic echocardiography) and elevated troponin concentration with concomitant: (1) systolic blood pressure (SBP) > 90 mmHg and ≤100 mmHg, (2) heart rate (HR) ≥ 110/min, or (3) arterial blood oxygen saturation (SaO₂) <90% during spontaneous breathing (atm) were closely monitored on the cardiac intensive care unit. All patients were reevaluated after 24 hours of AC therapy. If at least one of the above factors persisted, the patient was qualified for CDT. In case of clinical deterioration (sudden occurrence of one or more of the above-mentioned factors), the patient was also qualified for CDT. Exclusion criteria were pregnancy, refusal to sign the informed consent form, presence of intracardiac thrombus, diagnosed thrombophilia or severe thrombocytopenia (platelet count below 20 000 μL), history of severe or chronic pulmonary hypertension, serum creatinine concentration higher than 1.8 mg/dl, and known serious and uncontrolled sensitivity to radiographic agents (see also Supplementary material Table 1).

Among the whole study population, 14 patients with high- or intermediate-high-risk PE were qualified to perform CDT. The detailed indications to CDT in particular cases were presented in Supplementary material Table 2. Patients with intermediate-low‐risk and low‐risk PE were monitored and treated with AC according to the ESC guidelines [5, 15]. The management algorithm is presented in Figure 2.

The study protocol of this prospective observational study was in accordance with the Declaration of Helsinki and was approved by the Institutional Ethics Committee (approval number 879/19). All the patients accepted the treatment and gave an informed consent to participate in the registry (if they were unconscious, family members approved the treatment).

2.1. Catheter-Directed Thrombectomy

Common femoral venous access was obtained by placing 6F vascular sheath. The intravenous bolus of 5000 IU of unfractionated heparin (UFH) was administered unless absolute contraindications were present. The main pulmonary artery was catheterized by using a pigtail diagnostic catheter, and an initial pulmonary angiogram was performed to demonstrate the location and extent of thrombi in pulmonary arteries (see Figure 3). Then, pulmonary arterial pressure (PAP) was measured according to the current guidelines [17]. Subsequently, a 115 cm, 8F CDT catheter (Indigo CAT8 XTORQ; Penumbra, Alameda, California) was advanced through a 90 cm, 8F Flexor sheath (Cook; Bloomington, Indiana) to perform procedure. A direct-aspiration first-pass technique was performed purposefully to attach a large thrombus to the catheter tip by suction and then pull it out through the sheath. If the first-pass technique was ineffective, a separator wire was repeatedly passed through the thrombus to break it up and simplify aspiration. Occasionally, a Judkins right coronary diagnostic catheter or multipurpose catheter was used to facilitate access to the lobar or segmental arteries and then were replaced by the Indigo CAT8 XTORQ catheter. The decision to terminate the intervention was at operator’s discretion after careful evaluation of hemodynamic parameters (restoration of the SBP≥100 mmHg, HR < 100/min), improvement of SaO₂ ≥ 92%, practicable clot burden reduction, and total amount of aspirated blood (should not exceed 300 ml) [18–20]. An additional low dose (1 mg per hour per patient through 6–12 hours) of the thrombolytic drug alteplase was administered to patients with an assessed angiographic clot burden reduction below <50%. If PE symptoms onset was within 12–14 day prior the procedure, a low dose (3 mg) of alteplase per patient was applied through a perforated angioplasty balloon as an introduction to CDT in order to better prepare the thrombus for aspiration (a hybrid strategy). All procedures were performed by two experienced interventional cardiologists (AA and SJ). After CDT, UFH or low molecular weight heparin (LMWH) in weight-adjusted dose were continued for 24–48 hours depending on clinical state, and then direct oral anticoagulant was introduced at physician’s discretion.

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(b)

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2.2. Data Collection and Study Endpoints

The recorded data included demographics, personal medical history, clinical findings (presenting symptoms, hemodynamic and pulmonary status, along with echocardiographic results taken before and 24 hours after the procedure), and outcomes (including major procedure-related complications or bleeding events).

Technical success was defined as targeted placement of the devices, initiation of aspiration thrombectomy, and obtaining the embolic material. The clinical endpoints of the study were defined as follows: (1) clinical improvement during CDT procedure (change in SBP, HR and SaO₂); (2) improvement of PAPs during the CDT procedure; (3) reduction in vascular obstruction in the angiography measured at the end of CDT with Miller Index score [21]; (4) change in right ventricle (RV) strain in echocardiography measured 24 hours after the procedure; (5) death caused by PE (RV failure) during index hospitalization or follow-up period; (6) death of any cause during index hospitalization or follow-up period; (7) CDT-related major adverse events (major bleeding, pulmonary vascular injury). See also Supplementary material Table 3.

To assess the extent of angiographic reduction in thrombus burden, pulmonary angiograms performed before and immediately after the procedure were reviewed by two independent observers. To quantify the degree of pulmonary arterial obstruction, the Miller index score was calculated as described previously [21]. The reduction of thrombus burden was classified as complete clearance (>90% reduction in Miller index score), nearly complete (50%–90% clearance), or partial (<50% clearance).

An independent cardiologist qualitatively assessed right heart strain with echocardiography, measuring right ventricular/left ventricular (RV/LV) ratio, tricuspid annular plane systolic excursion (TAPSE), RV and LV diameter, and systolic wave.

Bleeding events were classified according to Valve Academic Research Consortium-2 guidelines criteria published elsewhere [22]. Life-threatening (disabling) bleeding was defined as bleeding into critical organ or causing hypovolemic shock or drop in hemoglobin concentration more than 5 g/dL. Major bleeding was defined as bleeding causing drop in hemoglobin concentration more than 3 g/dL, but not fulfilling the criteria of life-threatening bleeding. Clinically significant bleedings which did not fullfill the criteria of life-threatening and major bleeding were categorized as minor bleedings (such as access site hematoma) [22]. The Charlson Comorbidity Index score was also calculated for each patient [23]. All survived patients were evaluated on out-patient follow-up visit one month and three months after CDT procedure.

2.3. Statistical Analysis

Patient characteristics are expressed as absolute and percentage frequencies for categorical variables and median and interquartile range (IQR) for continuous variables. The normality distribution was assessed with the Shapiro-Wilk test. Continuous variables were compared using depending Student’s t-test or Wilcoxon signed-rank as appropriate. A two-tailed alpha of 0.05 was considered statistically significant. Statistical analysis was performed using Statistica 13.7 version (StatSoft, Inc., Tulsa, Oklahoma, USA).

3. Results

Among all PERT patients, 51 (52%) were categorized as intermediate-high-risk and 19 (19.4%) as high-risk PE (see Figure 1). Fourteen patients underwent CDT (8 female and 6 male). Among these patients, 5 high-risk PE patients were qualified for CDT on the basis of absolute contraindication to ST and refractory circulatory collapse, and 9 intermediate-high PE patients were qualified for the CDT procedure because of coexistence of persistent RV dysfunction with tachycardia HR ≥ 110/min, SBP<100 mmHg, and SaO₂ < 90% (4 patients) or persistent RV dysfunction with concomitant tachycardia ≥ 110/min and SaO₂ < 90% (5 patients). The median age of patients who underwent CDT was 56 years (range: 29–71 years) and median body mass index was 26.8 kg/m² (IQR: 23.9–29.7 kg/m²). Baseline clinical, echocardiographic, and laboratory characteristics are summarized in Table 1.

Technical success was achieved in all 14 (100%) patients. The median duration of CDT procedure was 72 minutes (IQR: 60–100 minutes) and the median blood loss was 300 ml (IQR: 290–320 ml). Complete reduction in thrombus burden was achieved in 2 patients (14.3%), nearly complete in seven patients (50%) and partial in five (35.7%) patients. The pharmacomechanical treatment (CDT along with local thrombolysis) was implemented in three patients, including two patients with saddle thrombus and the clot clearance <50% as a supplement after CDT (these patients received a total dose of 6 mg of alteplase). In one patient with the longest duration of PE symptoms, a hybrid strategy was applied. The precise data are shown in Table 2. No patient died because of RV insufficiency. There was a significant clinical status improvement after CDT. The median HR significantly decreased from median 110/min to 85/min (), while median SBP increased from 106 mmHg to 123 mmHg immediately after CDT (). Blood SaO₂ also significantly increased after CDT, from median 88.5% baseline to median 95% after CDT ().

The PAP significantly decreased immediately after the procedure. The median change in systolic PAP was 10.5 mmHg (IQR: 7–17 mmHg), while the median change in mean PAP was 6.5 mmHg (IQR: 5–8.5 mmHg), respectively. The median Miller index score before CDT was 21.5 (IQR: 20–23), while after CDT median Miller index score was 9.5 (IQR: 8–13)().

In all cases, RV/LV ratio (median 1.3 before CDT vs. median 1.0 after CDT, ) and TAPSE (median 16 mm before CDT vs. median 20 mm after CDT, ) significantly improved 24 hours after the procedure. The detailed data are presented in Table 3 and Figure 4.

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(b)

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Figure 4

Hemodynamic and echocardiographic outcomes before and after CDT. CDT = catheter-directed mechanical aspiration thrombectomy, LV = left ventricle, RV = right ventricle, and TAPSE = tricuspid annular plane systolic excursion. (a) Change in systolic arterial pressure. (b) Change in mean pulmonary arterial pressure. (c) Change in Miller index score. (d) Change in right ventricular/left ventricular ratio. (e) Change in tricuspid annular plane systolic excursion. (f) Change in arterial blood saturation.

One patient died (43-year-old female patient after >60 min; cardiopulmonary resuscitation before admission; CTD performed on extracorporeal circulation support) due to irreversible brain injury and pneumonia, two days after the procedure. No life-threating or major bleeding related to the CTD procedure was observed. We observed minor bleedings, limited inguinal hematoma in two (14.3%) patients after the procedure. No interventions were necessary in those patients. Two patients required red blood cells transfusion during hospitalization period (both of them had moderate anemia at baseline due to neoplastic disease or previous surgery which was unrelated to CDT).

4. Discussion

The results of our small observational study suggest that CDT might be an alternative or supplemental to standard management, especially in patients with contraindications to ST or SE. The CDT approach allows removing thrombi from the pulmonary arteries without the additional risks posed by thrombolysis or cardiac surgery [12, 13]. Early treatment restoring patency of occluded pulmonary arteries seems to be the crucial factor affecting mortality in high-risk PE. The efficient clot removal improves the patient’s condition and alleviates the symptoms in intermediate-high-risk patients. Possibly, the reduction of thrombotic material burden may also decrease the probability of postembolic disease including chronic thromboembolic pulmonary hypertension. According to the current ESC guidelines, shock or systemic hypotension is an accepted indication for urgent thrombolysis in patients with acute PE and also the therapy of choice in case of deterioration in previously hemodynamically stable patients [5–7]. Surgical or endovascular thrombectomy can be an option in selected cases. The guidelines suggest also the endovascular approach as an alternative for SE in patients with unsuccessful ST or contraindication to thrombolytic therapy [5]. In intermediate-high-risk PE patients, ST may pose the bleeding risk that overweighs potential benefits [7]. On the other hand, the decision on thrombolysis or surgical therapy is often taken too late, and hemodynamic deterioration in this group of patients is associated with high mortality.

Recently, other percutaneous modalities have also garnered an interest because of their ability for restoration of pulmonary perfusion without significant increase in bleeding risk. These involve a variety of system including not only thrombus aspiration, but also mechanical fragmentation or mechanical or ultrasound-assisted thrombus fragmentation with local administration of a small dose of thrombolytics [24–29].

Despite the rapid development of transcatheter techniques, limited data are available on the efficacy and safety of this therapy, and experience is based on a small number of single-arm observational studies or case series. So far, only a few studies on the use of Indigo Penumbra CDT in PE patients have been published [18, 30–32]. Al-Hakim et al. used Indigo to treat six patients with submassive PE and a contraindication to thrombolysis [31]. They found significant reduction in systolic PAP, RV/LV ratio, Miller index, and CT obstructive index. There were no procedural or periprocedural complications. Pieraccini et al. treated 18 patients with massive (8/18) or submassive (10/18) PE [32]. Technical and procedural success was achieved in all patients; however, four patients died during index hospitalization (mostly because of serious comorbidities). Nevertheless, the authors showed a significant improvement in the pre- and postprocedural RV/LV ratio, pulmonary SaO₂, heart rate, PAP, and Miller index score [32]. In another similar study, Ciampi-Dopazo et al. presented the results of treatment in 18 patients with PE [18]. The procedure was considered a technical success in 17 patients (94.4%) and a clinical success in 15 (83.3%); three patients died. Two patients died of massive PE, and one died due to submassive PE. Echocardiography showed significant improvements in RV size, TAPSE, and systolic wave. Two patients who received previous systemic fibrinolytic agents experienced intracranial bleeding, and abdominal bleeding developed in one patient [18]. In our series, we achieved also high rate of the technical and clinical success. All the patients who survived had fast and significant clinical improvement. We have achieved improvements in RV strain markers, significant reduction in PAPs, and improved echocardiographic and even electrocardiographic markers as we reported previously [33].

Mechanical thrombectomy with the Indigo system has several important limitations. The first one is the risk of peripheral embolization. During the procedure, it is possible to shift embolic material from large main or lobar pulmonary arteries to the numerous segmental arteries resulting in an increase in pulmonary vascular resistance and rapid clinical deterioration instead of improvement. One should take care of axial position of the catheter and continue the procedure in distal arteries until the flow is restored [33]. The next problem is blood loss following the extensive and long-lasting procedure. In our center, we stopped the treatment if the loss exceeded 300–350 ml. Another limitation of thrombectomy with the Indigo system is the difficulty in removing a large and long thrombus originating, for example, from the iliac vein. The catheter diameter (8F) is usually too small in this case. Although a large-bore device (FlowTriever) that mechanically engages thrombus was lastly proposed for such clinical scenarios, the system in not currently available outside the United States [26]. In our group, we used pharmacomechanical treatment in three patients (in two patients as a supplement after CDT, and in one patient as an introduction to CDT in order to facilitate thrombus for aspiration). Despite the possibility of rheolytic thrombectomy for the large clot removal with AngioJet catheter, it should not be used in initial PE treatment because of safety concerns [13].

In case of large thrombus fragmentation, partial thrombectomy should be performed, and in the absence of absolute contraindications, local low-dose thrombolytic therapy (e.g., alteplase 1 mg/h for 6–12 hours) might be also applied. In our group, we obtained no complete removal of thrombi in up to 80% of patients. However, we obtained partial or complete clearance in over 60%. This indicates that even partial success of thrombectomy can lead to rapid and effective hemodynamic and clinical improvement, as long as it is supplemented with anticoagulation, which remains the basis of PE treatment. Even partial improvement of pulmonary flow can restore sufficient cardiac output and reverse RV strain.

We found Indigo system especially effective in patients with thrombi in lobar and segmental arteries. These patients constitute the majority of our study group. In our opinion, saddle or central PE should be treated with SE unless bigger devices like FlowTriever are available [26].

Some previous studies reported a close correlation of early PE mortality with patients’ age and comorbidities [34, 35]. The multimorbidity assessed by Charlson Comorbidity Index, which comprises among others myocardial infarction, chronic lung disease, malignancy, or renal failure, was found to be the most important prognostic factor of in-hospital death for patients with acute PE [35]. In present study the median Charlson Comorbidity Index was 2 (IQR: 1–3) which indicates that PE patients were moderately ill prior to PE occurrence. The most frequent concomitant diseases were obesity, arterial hypertension, and malignancy.

The present study is burdened by several limitations. One of the study limitations is its observational nature, which may also be considered as a strong point and reflects the real-life nature of the study. The study included a small number of patients from a single center. Despite the statistical significance observed in variables after intervention, the small number of studied patients limits the extrapolation of these results.

5. Conclusions

Continuous aspiration mechanical thrombectomy with Indigo system is a feasible and promising technique for management of high- and intermediate-high-risk PE to decrease thrombus burden, reduce right heart strain, and improve hemodynamic and clinical status. Some patients, such as those with a severe clinical course and a particularly large initial thrombus burden or those with a large residual clot burden, may benefit from an additional, local, low-dose thrombolytic therapy. Further studies are needed to define clinical and angiographic scenarios for the hybrid strategy.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Supplementary Materials

Table 1: inclusion and exclusion criteria for CDT procedure. Table 2: clinical presentation of study patients, indications to CDT, and PE risk classification. Table 3: the clinical endpoints of the study. (Supplementary Materials)

References

M. Turetz, A. Sideris, O. Friedman, N. Triphathi, and J. Horowitz, “Epidemiology, pathophysiology, and natural history of pulmonary embolism,” Seminars in Interventional Radiology, vol. 35, no. 2, pp. 92–98, 2018.
View at: Publisher Site | Google Scholar
G. E. Raskob, P. Angchaisuksiri, A. N. Blanco et al., “Thrombosis: a major contributor to global disease burden,” Arteriosclerosis, Thrombosis, and Vascular Biology, vol. 34, no. 11, pp. 2363–2371, 2014.
View at: Publisher Site | Google Scholar
S. B. Buller, J. B. Geske, P. Kathuria et al., “Analysis of national trends in admissions for pulmonary embolism,” Chest, vol. 150, no. 1, pp. 35–45, 2016.
View at: Publisher Site | Google Scholar
W. Huang, R. J. Goldberg, F. A. Anderson, C. I. Kiefe, and F. A. Spencer, “Secular trends in occurrence of acute venous thromboembolism: the Worcester VTE study (1985–2009),” The American Journal of Medicine, vol. 127, no. 9, pp. 829–839, 2014.
View at: Publisher Site | Google Scholar
S. V. Konstantinides, G. Meyer, C. Becattini et al., “2019 ESC Guidelines for the diagnosis and management of acute pulmonary embolism developed in collaboration with the European Respiratory Society (ERS),” European Heart Journal, vol. 41, no. 4, pp. 543–603, 2020.
View at: Publisher Site | Google Scholar
S. Chatterjee, A. Chakraborty, I. Weinberg et al., “Thrombolysis for pulmonary embolism and risk of all-cause mortality, major bleeding, and intracranial hemorrhage: a meta-analysis,” Journal of the American Medical Association, vol. 311, no. 23, pp. 2414–2421, 2014.
View at: Publisher Site | Google Scholar
G. Kadakia, E. Vicaut, T. Danays et al., “Fibrinolysis for patients with intermediate-risk pulmonary embolism,” New England Journal of Medicine, vol. 370, no. 15, pp. 1402–1411, 2014.
View at: Publisher Site | Google Scholar
P. D. Stein and F. Matta, “Thrombolytic therapy in unstable patients with acute pulmonary embolism: saves lives but underused,” The American Journal of Medicine, vol. 125, no. 5, pp. 465–470, 2012.
View at: Publisher Site | Google Scholar
T. Provias, D. M. Dudzinski, M. R. Jaff et al., “The Massachusetts general hospital pulmonary embolism response team (MGH PERT): creation of a multidisciplinary program to improve care of patients with massive and submassive pulmonary embolism,” Hospital Practice, vol. 42, no. 1, pp. 31–37, 2014.
View at: Publisher Site | Google Scholar
C. Kabrhel, R. Rosovsky, R. Channick et al., “A multidisciplinary pulmonary embolism response team: initial 30-month experience with a novel approach to delivery of care to patients with submassive and massive pulmonary Embolism,” Chest, vol. 150, no. 2, pp. 384–393, 2016.
View at: Publisher Site | Google Scholar
A. Araszkiewicz, M. Kurzyna, G. Kopeć et al., “Expert opinion on the creating and operating of the regional pulmonary embolism response teams (PERT): polish PERT initiative,” Cardiology Journal, vol. 26, no. 6, pp. 623–632, 2019.
View at: Publisher Site | Google Scholar
J. Schultz, A. Andersen, C. Kabrhel, and J. E. Nielsen-Kudsk, “Catheter-based therapies in acute pulmonary embolism,” EuroIntervention, vol. 13, no. 14, pp. 1721–1727, 2018.
View at: Publisher Site | Google Scholar
J. Giri, A. K. Sista, I. Weinberg et al., “Interventional therapies for acute pulmonary embolism: current status and principles for the development of novel evidence: a scientific statement from the American heart association,” Circulation, vol. 140, no. 20, pp. e774–e801, 2019.
View at: Publisher Site | Google Scholar
N. Kucher, P. Boekstegers, O. J. Müller et al., “Randomized, controlled trial of ultrasound-assisted catheter-directed thrombolysis for acute intermediate-risk pulmonary embolism,” Circulation, vol. 129, no. 4, pp. 479–486, 2014.
View at: Publisher Site | Google Scholar
S. V. Konstantinides, A. Torbicki, G. Agnelli et al., “2014 ESC guidelines on the diagnosis and management of acute pulmonary embolism,” European Heart Journal, vol. 35, no. 43, pp. 3033–3069, 2014.
View at: Google Scholar
S. Sławek-Szmyt, S. Jankiewicz, A. Smukowska-Gorynia et al., “Implementation of a regional multidisciplinary pulmonary embolism response team: PERT-POZ initial 1-year experience,” Kardiologia Polska, vol. 78, no. 4, pp. 300–310, 2020.
View at: Publisher Site | Google Scholar
M. Kurzyna, A. Araszkiewicz, P. Błaszczak et al., “Summary of recommendations for the haemodynamic and angiographic assessment of the pulmonary circulation: joint statement of the polish cardiac society’s working group on pulmonary circulation and association of cardiovascular interventions,” Kardiologia Polska, vol. 73, no. 1, pp. 63–68, 2015.
View at: Publisher Site | Google Scholar
J. J. Ciampi-Dopazo, J. M. Romeu-Prieto, M. Sánchez-Casado et al., “Aspiration thrombectomy for treatment of acute massive and submassive pulmonary embolism: initial single-center prospective experience,” Journal of Vascular and Interventional Radiology, vol. 29, no. 1, pp. 101–106, 2018.
View at: Publisher Site | Google Scholar
Z. Devcic and W. Kuo, “Percutaneous pulmonary embolism thrombectomy and thrombolysis: technical tips and tricks,” Seminars in Interventional Radiology, vol. 35, no. 2, pp. 129–135, 2018.
View at: Publisher Site | Google Scholar
C. Marcelin, S. D’Souza, Y. Le Bras et al., “Mechanical thrombectomy in acute thrombosis of dialysis arteriovenous fistulae and grafts using a vacuum-assisted thrombectomy catheter: a multicenter study,” Journal of Vascular and Interventional Radiology, vol. 29, no. 7, pp. 993–997, 2018.
View at: Publisher Site | Google Scholar
G. A. H. Miller, G. C. Sutton, I. H. Kerr, R. V. Gibson, and M. Honey, “Comparison of streptokinase and heparin in treatment of isolated acute massive pulmonary embolism,” British Medical Journal, vol. 2, no. 5763, pp. 681–684, 1971.
View at: Publisher Site | Google Scholar
A. P. Kappetein, S. J. Head, P. Généreux et al., “Updated standardized endpoint definitions for transcatheter aortic valve implantation: the valve academic research consortium-2 consensus document (VARC-22),” European Journal of Cardio-Thoracic Surgery, vol. 42, no. 5, pp. 45–60, 2012.
View at: Publisher Site | Google Scholar
M. E. Charlson, P. Pompei, K. L. Ales, and C. R. MacKenzie, “A new method of classifying prognostic comorbidity in longitudinal studies: development and validation,” Journal of Chronic Diseases, vol. 40, no. 5, pp. 373–383, 1987.
View at: Publisher Site | Google Scholar
J. Stępniewski, G. Kopeć, W. Magoń, D. Sobczyk, P. Musiałek, and P. Podolec, “Ultrasound-assisted, catheter-directed, low-dose thrombolysis for the treatment of acute intermediate-high risk pulmonary embolism,” Polish Archives of Internal Medicine, vol. 128, no. 6, pp. 394-395, 2018.
View at: Publisher Site | Google Scholar
M. Roik, D. Wretowski, A. Łabyk et al., “Initial experience of pulmonary embolism response team with percutaneous embolectomy in intermediate-high- and high-risk acute pulmonary embolism,” Kardiologia Polska, vol. 77, no. 2, pp. 228–231, 2019.
View at: Publisher Site | Google Scholar
T. Tu, C. Toma, V. F. Tapson et al., “A prospective, single-arm, multicenter trial of catheter-directed mechanical thrombectomy for intermediate-risk acute pulmonary embolism: the FLARE study,” JACC: Cardiovascular Interventions, vol. 12, no. 9, pp. 859–869, 2019.
View at: Publisher Site | Google Scholar
P. P. Mohan, J. J. Manov, F. Contreras, M. E. Langston, M. H. Doshi, and G. Narayanan, “Ultrasound-assisted catheter-directed thrombolysis for submassive pulmonary embolism,” Vascular and Endovascular Surgery, vol. 52, no. 3, pp. 195–201, 2018.
View at: Publisher Site | Google Scholar
M. A. Langston, J. A. Guirola, W. T. Kuo et al., “Catheter-directed aspiration thrombectomy and low-dose thrombolysis for patients with acute unstable pulmonary embolism: prospective outcomes from a PE registry,” International Journal of Cardiology, vol. 287, pp. 106–110, 2019.
View at: Publisher Site | Google Scholar
G. Piazza, B. Hohlfelder, M. R. Jaff et al., “A prospective, single-arm, multicenter trial of ultrasound-facilitated, catheter-directed, low-dose fibrinolysis for acute massive and submassive pulmonary embolism: the SEATTLE II study,” JACC: Cardiovascular Interventions, vol. 8, no. 10, pp. 1382–1392, 2015.
View at: Publisher Site | Google Scholar
M. Roik, D. Wretowski, M. Machowski, M. Ciurzyński, M. Krakowian, and P. Pruszczyk, “Successful treatment of intermediate-high-risk pulmonary embolism with aspiration thrombectomy: first experience in Poland,” Kardiologia Polska, vol. 76, no. 9, p. 1381, 2018.
View at: Publisher Site | Google Scholar
R. Al-Hakim, A. Bhatt, and J. F. Benenati, “Continuous aspiration mechanical thrombectomy for the management of submassive pulmonary embolism: a single-center experience,” Journal of Vascular and Interventional Radiology, vol. 28, no. 10, pp. 1348–1352, 2017.
View at: Publisher Site | Google Scholar
M. Pieraccini, S. Guerrini, E. Laiolo et al., “Acute massive and submassive pulmonary embolism: preliminary validation of aspiration mechanical thrombectomy in patients with contraindications to thrombolysis,” CardioVascular and Interventional Radiology, vol. 41, no. 12, pp. 1840–1848, 2018.
View at: Publisher Site | Google Scholar
A. Araszkiewicz, S. Jankiewicz, S. Sławek-Szmyt et al., “Rapid clinical and haemodynamic improvement in a patient with intermediate-high risk pulmonary embolism treated with transcatheter aspiration thrombectomy,” Advances in Interventional Cardiology, vol. 15, no. 4, pp. 497-498, 2019.
View at: Publisher Site | Google Scholar
M. Trystuła and M. Pąchalska, “Comorbidities and health-related quality of life following revascularization for asymptomatic critical internal carotid artery stenosis treated with carotid endarterectomy or angioplasty with stenting,” Medical Science Monitor : International Medical Journal of Experimental and Clinical Research, vol. 25, pp. 4734–4743, 2019.
View at: Publisher Site | Google Scholar
A. C. C. Ng, V. Chow, A. S. C. Yong, T. Chung, and L. Kritharides, “Prognostic impact of the Charlson comorbidity index on mortality following acute pulmonary embolism,” Respiration, vol. 85, no. 5, pp. 408–416, 2013.
View at: Publisher Site | Google Scholar

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Copyright © 2020 Aleksander Araszkiewicz et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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