Methods: Medical data of a total of 68 patients ( 41 males, 27 females; mean age 38 years; range, 25 to 56 years) who were admitted to our department with the diagnosis of hyperacute or acute deep vein thrombosis between January 2013 and January 2015 were retrospectively analyzed. The patients were divided into two groups: thrombectomy without thrombolytic therapy (Group 1, n=33) and thrombectomy with thrombolytic therapy (Group 2, n=35). All patients were administered Clinical Symptom Scoring and Doppler ultrasonography at one, six, and 12 months.
Results: Clinical symptom scores were higher in Group 1 at one month (p<0.001), while there was no significant difference between the groups at six months (p=0.102). Group 1 had higher scores at 12 months (p=0.043). The complete patency rates for both groups were similar at one month (p=0.181); however, the rates were higher in Group 2 at six and 12 months (p=0.019 and p=0.002, respectively). There was no significant difference in the complete patency rates between the groups at one and six months (p=0.563 and p=0.064, respectively), while these rates were higher in Group 2 at 12 months (p=0.013). In patients with acute deep vein thrombosis, the complete patency rates were found to be higher in all control Doppler ultrasonography examinations.
Conclusion: In the treatment of both hyperacute and acute deep vein thrombosis, the addition of thrombolytic therapy to pharmacomechanical thromboaspiration improves the clinical symptoms and venous patency rates.
Standard treatment of DVT mainly includes systemic anticoagulation. The mechanism of systemic anticoagulation is to limit the progression of the thrombus and to prevent the development of pulmonary embolism. However, with anticoagulation, the complete resolution of the thrombus cannot be achieved and, in the long-term, this may result in the development of PTS.
Aggressive removal of the thrombus reduces the risk and severity of PTS. To achieve a higher venous patency, systemic thrombolysis and catheterdirected thrombolysis (CDT) have been proposed as a treatment option. In the Cochrane review, PTS was shown to be significantly lower with fibrinolysis, and it further decreased with CDT, compared to systemic thrombolysis.[4,5] However, thrombolysis is associated with a high bleeding risk.[5] To minimize the risk of bleeding complications, different mechanical thrombectomy techniques, such as pharmacomechanical thrombectomy or percutaneous aspiration thrombectomy, have been proposed as alternatives or adjunct therapies to pharmacological thrombolysis. Early thrombus removal techniques are also strongly recommended in patients with limbthreatening venous ischemia due to iliofemoral DVT; however, the recommendation for the remaining patients is weak.[6] As all of the developed techniques have their own advantages and disadvantages, complications and success rates, there is no consensus on the treatment protocol for DVT.
In this study, we aimed to evaluate the clinical and ultrasonographic long-term results of additional thrombolytic therapy to pharmacomechanical thromboaspiration in acute DVT patients.
Group 1 received pharmacomechanical thrombectomy alone using aspiration, while Group 2 received pharmacomechanical thrombectomy using aspiration + thrombolytic therapy by introducing the catheter into the iliofemoral vein at the region of thrombectomy. For pharmacomechanical thrombectomy, the Cleaner™ (Argon Medical, Dallas, USA) device was used in all patients.
The procedure was performed in the angiography laboratory in all patients. Local anesthesia was given in the region of the femoral vein located contralaterally to thrombosis. An opaque material was inserted to visualize the patency of the vena cava inferior. A vena cava filter was placed under the renal vein (Figure 1). Diluted heparin (5,000 U) was given from the catheter intravenously. The patients were instructed to lay down in a prone position. The popliteal vein was punctured with a Seldinger needle (Newtech Medical Devices New Delhi, Delhi India) under the guidance of ultrasonography. A 7F sheath was introduced and venography was, then, done by inserting the opaque material to visualize the side of the thrombus. The mechanical thrombectomy device was pushed forward from the 7F catheter and started up (Figures 2, 3). Meanwhile, a 1/10 diluted 20 mg alteplase (Actilyse, Boehringer Ingelheim Pharma GmbH & Co. KG. Biberach/Riss. Germany), as a thrombolytic agent, was given from the device port during the mechanical thrombectomy. Then, a mechanical aspiration catheter was placed to the proximal part of the thrombus location and was followed by back and forth aspiration maneuvers. Complete opening was checked with a control venography. Mechanical thrombolysis support was provided with the catheter at the side of thrombus location from the 7F sheath. Later, control venography was performed to ensure complete patency of the vein (Figure 4). The procedure was completed in Group 1. In Group 2, a catheter with holes at the distal 15 cm side was placed in the thrombosis location by the popliteal vein. Alteplase 1 mg/h was given from the catheter for 24 hours. The vena cava filter was removed 24 h after the procedure in all patients.
Figure 1: Introduction of vena cava filter.
Figure 2: Cleaner™ machine used for thrombectomy.
Figure 3: Cleaner™ machine for the removal of the thrombus.
Following the procedures, all patients were put on a low-molecular-weight heparin and warfarin treatment. After the international normalized ratio (INR) levels reached over 2, low-molecular-weight heparin was discontinued and warfarin treatment was continued, until the end of the sixth month.
Statistical analysis
Statistical analysis was performed using the
Number Cruncher Statistical System (NCSS) version
2007 software (NCSS LLC., Kaysville, Utah, USA).
Descriptive data were expressed in mean ± standard
deviation (SD) and number and frequency. Continuous
variables, except for age, were presented in median
values with the first and third quartile. The Mann-
Whitney U test was used to compare the two groups
with quantitative data. For the comparison of qualitative data, the Pearson's chi-square test and Fisher's exact
test were used. A p value of <0.05 was considered
statistically significant.
All patients (100%) included in the study had leg swelling and pain, and five patients (7.3%) had additionally rash and itching. All patients were under treatment with low-molecular-weight heparin. Deep vein thrombosis was hyperacute in 48 patients (70.5%) and acute in 20 patients (29.5%). Fortyone patients (60.2%) had DVT in the left leg and 20 patients (39.8%) in the right leg. Deep vein thrombosis affected the iliofemoral and femoral and popliteal vein in 12 patients (17.6%), the femoral and popliteal vein in 36 patients (52.9%), the iliofemoral vein alone in 20 patients (29.5%). There were no significant differences in the demographic and clinical characteristics, comorbidities and risk factors for DVT between the groups. Demographic and clinical characteristics of the patients and the risk factors for DVT are summarized in Table 1.
Localization of DVT is shown in Table 2. There was no significant difference in the localization of DVT between the groups. However, hyperacute DVT was more common in Group 1, while acute DVT was more common in Group 2 (p=0.048).
Table 2: Localization of deep vein thrombosis
No bleeding complications were seen during or after the procedure. Venous patency at one, six, and 12 months using Doppler ultrasonography (DUS) and clinical symptom scores at the predefined time points are shown in Tables 3 and 4. During the follow-up period, two patients developed a complete obstruction and warfarin treatment was re-initiated at one year. While none of the patients in Group 2 had complete obstruction after the procedure, two patients in Group 1 developed DVT in the same leg at a close time of the first year DUS control.
Table 3: Doppler ultrasonography findings and clinical symptoms at one, six, and 12 months
Table 4: Complete patency rates in patients with hyperacute and acute deep vein thrombosis
Doppler ultrasonography and clinical symptom distribution at one, six, and 12 months are given in Table 3. At one month, clinical symptom scores were significantly higher in Group 1 (p<0.001), and this difference was found to be related to swelling (p<0.001), pain (p<0.001), and restricted motion (p=0.008). At six months, pain was more common in Group 1 (p=0.045), but this complaint did not significantly affect the clinical symptom scores (p=0.102). At 12 months, the clinical symptom scores were significantly higher in Group 1 (p=0.028), and this difference was found to be related to swelling (p=0.008), pain (p=0.041), and restricted motion (p=0.043).
In further subgroup analysis, Group 1 and 2 treatment protocols were compared between the hyperacute and acute DVT patients according to clinical symptoms and symptom scoring at one, six, and 12 months (Table 4). In patients with hyperacute DVT, the first month symptom scoring scores were higher in Group 1 due to swelling (p=0.001), pain (p=0.007), and restricted motion (p=0.014), while there was no difference at six and 12 months. In patients with acute thrombosis, clinical symptom scores were higher in Group 1 with swelling (p=0.011), pain (p=0.011), edema (p=0.002), and restricted motion (p=0.011). At six months, these variables were found to be higher in Group 1, while at 12 months, the clinical symptom scores were still higher in Group 1 (p=0.002) with swelling (p=0.002), pain (p=0.002), and restricted motion (p=0.007) (Table 4).
None of the patients had a total occlusion at one and six months, although two patients had a total occlusion at 12 months. To increase the statistical significance, the patients were further classified based on the severity of the stenosis or occlusion. The patients who had narrowing less 50% or more than 50% had Grade 1 or 2 occlusion, respectively, and a total occlusion was categorized as Grade 3. The patients with complete patency formed a different group. Accordingly, there was no significant difference in the complete patency rates between the groups (p=0.181). In contrast to this finding, venous patency, as measured by DUS, was found to be significantly higher than the controls in Group 2 at six and 12 months (p=0.019 and p=0.002, respectively) (Figure 2). The complete patency rates using DUS at one, six and 12 months were also compared by further analysis between the patients with hyperacute and acute DVT (Table 5). While there was no significant difference in the complete patency rates between the two groups in patients with acute DVT at one and six months (p=0.563 and p=0.064, respectively), these rates were higher in Group 2 (p=0.013). In the patients with acute DVT, the complete patency rates were found to be higher in all control DUS examinations.
If left untreated, the clinical status of 25% of patients with DVT may deteriorate, while symptoms resolve in 20%, and stable condition is observed in 55%.[7,8] About half of the patients not receiving appropriate treatment may develop relapsing DVT.[7,8]
Catheter-directed thrombolysis is performed by the infusion of thrombolytic agents through an infusion catheter placed directly into a venous thrombus. Vedantham et al.[9] demonstrated a greater than 50% reduction in thrombus burden in more than 90% of patients. In a recent randomized-controlled trial, CDT was associated with an absolute risk reduction of 14% for PTS at 24 months, compared to anticoagulation alone. Complete lysis of the thrombus may take several days, and patients should be followed in the intensive care unit, which increases the hospital stay and the costs.
Pharmacomechanical thrombolysis uses a mechanical device which delivers the thrombolytic agent and produces thrombus fragmentation and/or thrombus aspiration.[10,11] In previous reports using the mechanical thrombectomy devices, the primary technical success rate ranged from 83 to 100%.[10] However, in about half of the patients, thrombolytic therapy was added due to incomplete results. In our study, we administered thrombolytic therapy to all of our patients and achieved complete patency in all patients at the end of the procedure. The Peripheral Use of AngioJet™ Rheolytic Thrombectomy with a Variety of Catheter Lengths (PEARL) registry was a prospective multi-center study which included 329 patients with lower extremity DVT. One-third of the patients had only pharmacomechanical thrombectomy and had complete thrombus resolution; even in the patients who needed lytic therapy, the infusion time was significantly shorter in the AngioJet™ group.[11] The patency rate at one year was reported to be 83%. Small series and retrospective studies comparing pharmacomechanical thrombectomy and CDT also showed that similar efficacy could be achieved by pharmacomechanical thrombectomy without the costs of intensive care unit monitoring and shortened hospital stays,[12] and that PTS could be reduced with pharmacomechanical thrombectomy at one year.[13]
The procedural success and patency rates of our study are comparable with previous studies. However, when we compared the patency rates at one year, we found that the addition of thrombolytic therapy improved the long-term patency. We also compared the symptom status of the patients, which was done previously in only few studies. Cakir et al.[14] demonstrated that percutaneous aspiration thrombectomy with stenting when needed improved the clinical symptom status, compared to anticoagulation alone. The PEARL registry also demonstrated significant improvement in the quality of life with pharmacomechanical thrombectomy. The symptom status of our patients in both hyperacute and acute DVT were improved in both groups at the end of one month. Improvement of symptoms was also permanent in acute DVT; however, it was not significant in the hyperacute DVT group. Although complete patency rates were higher in hyperacute DVT patients, combination therapy still improved the quality of life in acute DVT patients.
Furthermore, pharmacomechanical thrombectomy with thrombolysis can be done effectively even in patients with symptoms lasting longer than 14 days with high success, low complication, and good long-term results.[15] In their study, Baran et al.[16] implemented direct thrombolytic infusion to 85 patients diagnosed with iliofemoral acute DVT. The number of patients who achieved complete patency after intervention was 75 (88.2%), whereas in the other 10 patients (11.8%) achieved partial patency. During follow-up, recurrent venous thrombi were observed in nine patients. At 12 months, 68 patients were reached, and the number of patients with complete patency was 42 (61.7%) and the number of partial patency was 26 (38.3%). Comparing these results to our study findings, it is likely to consider that pharmacomechanical thrombectomy practice is superior, when only it is practiced with the aim of catheter-use thrombolysis.[16] In another study, Tayfur et al.[17] included 30 patients with acute iliofemoral DVT, and only pharmacomechanical thrombolysis was implemented. At the end of the first year, the venous patency rate was almost at the same rate with our patient group who underwent additional thrombolytic and pharmacomechanical thrombolysis.
However, the Acute Venous Thrombosis: Thrombus Removal with Adjunctive Catheter-Directed Thrombolysis (ATTRACT) study, which was presented at the 2017 Society of Interventional Radiology meeting, did not support the data previously published. In the aforementioned study, data on the long-term effects of pharmacomechanical CDT showed that 46.7% of the patients who received interventional therapy and 48.2% of the patients who received anticoagulation alone developed PTS (p=0.56). Due to these controversial results, although early interventional therapy seems to have more promising results, we conclude that there is still controversy in the treatment protocol for the patients with DVT.
Our study results demonstrated that the addition of a 24-h fixed-dose thrombolytic therapy to pharmacomechanical thrombectomy using aspiration increased the patency rates and improved the clinical symptoms at 12 months. Although there was no significant difference in clinical symptom status in the hyperacute patient group, we observed a significant improvement in the acute DVT group. According to the patency rates, the patients with hyperacute DVT had higher patency rates (95.2%) than acute DVT patients (71.4%). These results suggest that early and aggressive treatment increase the success of DVT treatment.
Nonetheless, there are some limitations to our study mainly including the retrospective nature of the study and small sample size. In addition, the lack of major bleeding in our study can be attributed to the fact that our study population was relatively young with a small sample size. Therefore, we recommend further large-scale studies to confirm these findings.
In conclusion, there is no consensus in the treatment protocol for patients with deep vein thrombosis. To the best of our knowledge, this is the first study to compare the long-term effects of pharmacomechanical thrombectomy using aspiration and additional fixed dose thrombolytic therapy in the treatment of deep vein thrombosis. In addition, the results of our study demonstrate that, in the treatment of deep vein thrombosis, the addition of low-dose thrombolytic therapy for 24 h to pharmacomechanical thrombectomy using aspiration improves the clinical symptoms and venous patency rates at one year without any increase in bleeding complications.
Declaration of conflicting interests
The authors declared no conflicts of interest with respect to
the authorship and/or publication of this article.
Funding
The authors received no financial support for the research
and/or authorship of this article.
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