Abstract
There is little reported on the efficacy and safety of direct oral anticoagulants (DOACs) in morbid obesity after venous thromboembolism (VTE).
In this observational study, patients were followed up after intermediate- or high-risk pulmonary embolism (PE) at the University of Rochester Pulmonary Hypertension Clinic 2–4 months after the initial event. All patients had echocardiography and V/Q imaging regardless of symptoms. Outcomes of interest were the rates of recurrent VTE, thrombus resolution and development of chronic thromboembolic pulmonary hypertension (CTEPH) in patients with morbid obesity treated with a DOAC compared to treatment with vitamin K antagonists and to non-morbidly obese patients after PE. Using the electronic medical record, recurrent events were assessed up to 12 months after the event.
107 patients (body mass index (BMI)>40 kg·m−2, n=32; BMI 30–39.9 kg·m−2, n=39; BMI<30 kg·m−2, n=36) attended follow-up appointments after treatment for PE. A DOAC was used in 70 patients (BMI>40 kg·m−2, n=19; BMI 30–39.9 kg·m−2, n=27; BMI<30 kg·m−2, n=24). There were no recurrent events within the first 12 months of initial diagnosis based on symptoms and imaging in any patient. There was no difference in rate of residual unmatched perfusion defect with DOACs or conventional anticoagulation (49% versus 49%). This finding remained in the subset of morbidly obese patients (47% versus 50%). For the overall cohort, there was no difference in the rate of CTEPH development based on anticoagulation with a DOAC (5% versus 8% with warfarin). There were no major bleeding complications with a DOAC.
DOAC therapy appears to be effective and safe in morbid obesity even after intermediate- or high-risk PE.
Abstract
Direct oral anticoagulants appear to be safe and effective in the management of acute pulmonary embolism in morbidly obese patients https://bit.ly/2J1unqn
Introduction
Direct oral anticoagulants (DOACs) used for the treatment of venous thromboembolism (VTE) have been available for almost a decade and are recommended over vitamin K antagonist therapy in the treatment of VTE [1, 2]. There are two classes of DOACs currently approved for treatment of VTE: direct thrombin inhibitors (dabigatran [3]) and direct Xa inhibitors (rivaroxaban [4], apixaban [5] and edoxapan [6]). However, despite the clear advantages, DOACs are not often used in morbidly obese patients. The International Society of Thrombosis and Haemostasis (ISTH) recommends against DOAC use in patients with a body mass index (BMI)≥40 kg·m−2 or weight>120 kg because of the lack of available safety and efficacy data. Further, if they are used, the ISTH recommends checking anti-Xa levels [7], even though therapeutic ranges have not been established for any DOAC. Interestingly, BMI and weight were not exclusionary criteria in any of the DOAC trials, and there is no evidence that DOAC therapy is ineffective in morbidly obese patients. Unfortunately, this ISTH consensus has led many providers to avoid DOAC therapy in morbid obesity, and these patients are frequently treated with warfarin despite the significant challenges in achieving therapeutic levels [8].
With the growing obesity epidemic, almost 40% of US adults are considered obese [9] and ∼7% are considered morbidly obese with a BMI≥40 kg·m−2 [10]. Obesity is not only an independent risk factor for VTE [11–13] but is also associated with an increased risk for recurrent VTE [14]. Morbid obesity is even more prevalent among hospitalised patients (one estimate of 16% [15]), many of whom are likely to require some anticoagulation therapy during hospitalisation. Therefore, an effective and easy to manage anticoagulation strategy in this population is critical to decrease their risk for long-term complications, including recurrent VTE. Our institutional approach to intermediate- and high-risk pulmonary embolism (PE) [16] includes programmatic follow-up for the majority of patients, many of whom are morbidly obese. We thus had an opportunity to address disease recurrence among people treated with DOACS and we performed a single-centre study observing the efficacy and safety of DOAC and warfarin therapy. In particular, we explicitly compared morbidly obese with obese and non-obese patients.
Methods
This was an initially retrospective and subsequently prospective observational cohort study evaluating imaging and clinical outcomes after inpatient management for an intermediate- or high-risk PE at the University of Rochester Medical Center, NY, USA, between November 2016 and June 2019. The study protocol (00003058) was approved by the University of Rochester Medical Center Institutional Review Board. Beginning in August 2017, at the time of hospital discharge for an acute intermediate- or high-risk PE [16], all patients with estimated survival >1 year (based on the assessment of the discharging physician) were offered follow-up at our Pulmonary Hypertension Association-accredited Comprehensive Care Center. We scheduled a V/Q scan, echocardiogram and office visit to assess for PE resolution or recurrent thrombosis. PE on initial computed tomography angiography was classified as saddle, main, lobar or segmental depending on the location of the most proximal clot. Ventilation perfusion scans were performed using 30 mCi of aerosolised technetium (Tc)-99m-diethylene-triamine-pentaacetate followed by intravenous administration of 2–4 mCi Tc-99m-macroaggregated albumin. Six standard projections were obtained for both sets of images using a large field of view dual-head γ-camera fitted with general purpose parallel hole collimators, for a minimum of 100 000 counts per ventilation image and 500 000 counts per perfusion image. Residual unmatched perfusion defects at follow-up were defined as mismatched or partly mismatched segmental ventilation–perfusion defects. Board-certified cardiologists using standardised criteria [17] interpreted the echocardiograms. The pulmonary hypertension physicians (D.J.L. and R.J.W.) made clinical and functional assessments. Once patients were optimised in regards to apparent volume status, those in whom pre-capillary pulmonary hypertension (PH) could be expected were referred for right heart catheterisation (RHC) with angiography to assess for chronic thromboembolic pulmonary hypertension (CTEPH) after ≥3 months of appropriate anticoagulation. Patients were classified as having confirmed CTEPH based on the haemodynamic definition in the 5th World Symposium on Pulmonary Hypertension [18] in the presence of perfusion defects with angiography. Patients were classified as having “suspected CTEPH” if the clinical assessment strongly suggested CTEPH but patients declined catheterisation for sensible reasons like advanced neurological disease (dementia).
Statistical analysis
Variables are expressed as mean±sd or median (interquartile range). Non-parametric testing was performed with Mann–Whitney and Kruskal–Wallis testing using SAS 9.4 (SAS Institute Inc., Cary, NC, USA). Statistical significance was defined as p<0.05.
Results
Of 122 patients, 107 attended follow-up appointments at our PH clinic 2–4 months after management of acute intermediate- or high-risk PE. Patient demographics and presentation are shown in tables 1 and 2. Of the 15 that were not followed up, two died before their scheduled appointment because of complications related to malignancy (not VTE or bleeding mediated), eight were never scheduled and five did not keep their appointments. For the 13 patients not seen in the clinic, electronic medical record evidence showed them to be alive and without evidence of recurrent pulmonary emboli or major bleeding. The majority of patients who were followed up were obese with an average BMI of 35.7 kg·m−2 (table 1); 32 patients had a BMI≥40 kg·m−2 (morbid obesity) and 39 patients had a BMI of 30–39 kg·m−2 (obese) (table 1). The most common treatment during hospitalisation was anticoagulation with heparin (either unfractionated or low-molecular weight), while 28% received advanced therapies (e.g. thrombolytics, table 2). At discharge, 67% of patients were prescribed a DOAC and 26% were prescribed warfarin (table 2).
Baseline demographics
Clinical information at presentation and during hospitalisation
Recurrent events and residual perfusion defect
Between hospital discharge and 6 months after the index event, no patients had diagnostic evidence for recurrent PE or deep vein thrombosis. At follow-up, 68 patients who were taking DOACs and 35 taking warfarin or low-molecular weight heparin had V/Q testing regardless of symptoms (four patients were evaluated without V/Q imaging). 50 patients (49%) had residual unmatched perfusion defects. There was no difference between patients treated with a DOAC or with conventional anticoagulation (33 out of 68 (49%) versus 17 out of 35 (49%), p=0.99). Similarly, there was no difference in the rate of residual unmatched perfusion defects in the subset of morbidly obese patients treated with a DOAC or conventional anticoagulation (9 (47%) versus 6 (50%), p=0.99, table 3).
Clinical assessment 2–4 months after pulmonary embolus
CTEPH
At follow-up, 59 patients (55%) reported self-limited activity because of breathlessness. Based on symptoms and imaging concerning for CTEPH, CTEPH was diagnosed in eight out of 11 patients who underwent RHC after the requisite 3 months of anticoagulation. One patient was directly referred for CTEPH surgery after index hospitalisation without being seen in clinic, giving a total of nine patients diagnosed with CTEPH (table 3). RHC and angiography were recommended in 11 patients who declined testing because of preference or severe cognitive impairment. Including these patients who declined testing resulted in an estimated prevalence of confirmed or suspected CTEPH after intermediate- or high-risk PE of >15% (15–20 patients) (table 3).
There was no difference in the rate of confirmed CTEPH whether patients were treated with DOACs or conventional anticoagulation (4 (6%) versus 4 (11%), p=0.45). There was no difference in the rate of confirmed CTEPH in morbid obesity when comparing DOACs with conventional anticoagulation (1 (5%) versus 1 (8%), p=0.99, table 3). Even assuming that all patients who were recommended for further testing had CTEPH, patients with morbid obesity treated with a DOAC did not have a higher rate of CTEPH than those treated with conventional anticoagulation therapy (2 (11%) versus 5 (41%), p=0.06). There was no difference in the rate of CTEPH in the obese and non-obese patients based on type of anticoagulation.
Right ventricular recovery
At the time of acute presentation, the majority of patients (63%) had moderate or severe right ventricle enlargement without differences between obese and non-obese patients (table 2). At follow-up, 106 patients had an echocardiogram: 69 treated with a DOAC (19 morbidly obese) and 37 treated with conventional warfarin or enoxaparin anticoagulation (13 morbidly obese) (table 3). In total, 97 patients had a normal or mildly enlarged right ventricle, and nine had a moderately enlarged right ventricle (table 3). 102 patients had normal or mildly reduced right ventricular function, and four had moderately reduced function (table 3).
There was no difference in the rate of having a normal or mildly enlarged right ventricle at follow-up when comparing DOACs to conventional therapy (63 (92%) versus 34 (92%), table 3). 18 (95%) morbidly obese patients treated with a DOAC had a normal or mildly enlarged right ventricle at follow-up compared to 12 (92%) morbidly obese patients treated with warfarin or enoxaparin (table 3). Similarly, there were no differences between the obese and non-obese groups.
There was no difference in the rate of recovery in right ventricular function (normal or mildly reduced at follow-up) comparing DOACs to conventional anticoagulation (68 (99%) versus 34 (92%)). 18 of 19 (95%) morbidly obese patients treated with DOACs had normal or mildly impaired right ventricular function while 11 of 13 (84%) treated with conventional anticoagulation had a normal or mildly impaired right ventricle (p=0.55).
N-terminal pro-brain natriuretic peptide and 6-min walk assessment
At follow-up, 55 patients had their levels of N-terminal pro-brain natriuretic peptide (NT-proBNP) assessed because of breathlessness or signs of heart failure: 22 morbidly obese (13 on DOAC therapy and nine on conventional therapy), 18 obese (10 on DOAC therapy and eight on conventional therapy) and 15 non-obese (10 on DOAC therapy and five on conventional therapy). Owing to staffing limitations, only 58 patients completed a 6-min walk test (6MWT) regardless of symptoms, 16 of whom were morbidly obese (nine on DOAC therapy and seven on conventional therapy).
There was no difference in NT-proBNP when comparing patients treated with DOAC therapy and patients treated with conventional therapy (97 pg·mL−1 versus 167 pg·mL−1, p=0.13), for the entire cohort. There was no difference in NT-proBNP based on DOAC versus conventional therapy in morbid obesity (97 pg·mL−1 versus 183 pg·mL−1, p=0.19). There was no difference in 6MWT distance based on DOAC versus conventional therapy (399 m versus 338 m, p=0.09), for the entire cohort or for the three subgroups based on BMI.
Bleeding
There were two patients on non-DOAC therapy with bleeding complications that required intervention. One morbidly obese patient treated with warfarin developed haematuria in the setting of an elevated international normalised ratio and required hospitalisation. Another morbidly obese patient developed a spontaneous retroperitoneal bleed on low-molecular weight heparin that required hospitalisation. No patients on DOAC therapy were hospitalised owing to bleeding complications. One morbidly obese patient required a dose reduction from 20 mg to 10 mg of rivaroxaban because of gingival bleeding in the setting of poor dentition. The bleeding stopped and there were no further complications at this dose.
Discussion
In an observational cohort of higher-risk PE patients, DOAC therapy in morbidly obese patients was not associated with an increased risk of recurrent VTE compared to warfarin anticoagulation therapy within 6 months of management of acute PE, and these higher-risk patients had similar recovery of right ventricle function on DOAC therapy as those treated with warfarin (even among morbidly obese patients). This work is strengthened by the rigorous follow-up and imaging acquisition in almost all patients regardless of symptoms.
Fixed-dose DOAC therapies have greatly simplified management of acute PE by preventing recurrent VTE without the need for laboratory monitoring and the associated effort to make warfarin dose adjustments. For patients, the “real-world” rates of bleeding are low [19], and there is relatively little concern for drug–diet or drug–drug interactions [20]. The initial concern about using fixed-dose DOAC therapy in morbid obesity was understandable. Both unfractionated and low-molecular weight heparin are weight-based drugs, and vitamin K antagonist doses are typically higher in morbid obesity [8]. Theoretically, it would make sense that morbidly obese patients would require higher doses of DOAC therapy based on a fixed dose diluted in a larger volume of distribution, but limited pharmacokinetic and pharmacodynamic studies evaluating DOAC in morbid obesity suggest weight does not influence dosing [21–25]. Furthermore, there is no clear relationship between drug levels and clinical outcomes like VTE recurrence or bleeding [3–6]. No therapeutic range of Xa inhibition is established for DOAC. Given the difficulty in achieving therapeutic levels with warfarin [8], having a simplified option could decrease recurrent events.
The current consensus guidelines from ISTH [7] and the European Society of Cardiology [26] both caution against using DOAC therapy for patients with a BMI>40 kg·m−2; if DOACs are used, these documents recommend measuring anti-Xa activity despite the fact that no therapeutic range has been established. The American Society of Hematology does not address morbid obesity in their 2018 VTE guidelines [27]. Papers being published today still caution against DOAC use in morbidly obese patients owing to the lack of clinical data, with calls for prospective trials to be completed before DOAC use can be recommended in this population [28–30]. However, at least one meta-analysis found no reduction in efficacy in the registration trials when looking at obese versus non-obese patients [31]. To the best of our knowledge, there are no active clinical trials evaluating DOAC therapy for VTE in morbid obesity (clinicaltrials.gov, October 2020).
The majority of patients included in the original DOAC clinical trials were low-risk VTE and not obese. However, it is important to note that neither BMI nor weight was an exclusionary criterion in the registration trials. A meta-analysis determined that 20% of participants in the registration trials were “high body weight” at randomisation (either >100 kg or >90 kg) [31]. None of the registration trials reported event rates specifically in morbid obesity, but they did report no differences in recurrent events in the high body weight groups treated with DOAC versus conventional therapy [3–6].
Recurrent VTE events often occur within 3–6 months at a rate of 4%–8% [32, 33] and typically present in a similar manner as the index event [34, 35]. With obesity being a risk factor for initial [11–13] and recurrent [14] VTE, if effective anticoagulation was not provided, the observed VTE recurrence rate would likely be much higher than the reported baseline of ∼4%–8%. We did not observe an elevated recurrence rate in our cohort. There is evolving retrospective data on the efficacy of DOAC therapy in morbid obesity. Kushnir et al. [36] used single-centre chart review and determined a 2% risk for recurrent VTE in 366 morbidly obese (BMI>40 kg·m−2) patients with any DOAC-treated VTE event. Using two US claims databases, Spyropoulos et al. [37] found a similar rate of risk of recurrent thrombotic events in morbid obesity. Although both studies relied on coding, their findings are real-world evidence that DOACs are effective in morbid obesity. We do not know if some of their recurrent VTE could have been unrecognised CTEPH or chronic clot.
We complement these larger studies with rigorous clinical follow-up and detailed chart review including echocardiogram, V/Q scan and RHC. We did not observe any recurrent PE within the first year in any patient, regardless of weight group or type of anticoagulation. We were able to differentiate CTEPH from recurrent PE. Furthermore, we did not observe any difference in the resolution of thrombotic disease on perfusion lung scanning, and DOAC-treated patients were just as likely to achieve right ventricle recovery (an indirect measure that the pulmonary circulation is no longer obstructed) after higher-risk PE. Our numbers are small, but DOACs did not appear to leave patients at higher risk for CTEPH. None of the registration clinical trials reported rates of CTEPH development, and given the large numbers of patients involved, CTEPH would be expected in some patients. Our data strengthen a growing body of literature supporting the clinical efficacy of DOAC therapy in morbid obesity because none of the previously reported studies detailed follow-up data on imaging and physiological recovery.
There are limitations to our study. We have data on a small number of morbidly obese patients on DOAC therapy that took 2 years to collect. However, given that this is a high-risk group, DOAC failure with recurrent events should have been observed. Our data are observational and anticoagulation was chosen based on the preference of the discharging attending physician and patient. Peak and trough drug concentrations were not measured, and we have no measurements of anti-Xa levels. We only included patients who had an intermediate- or high-risk PE. We did not include atrial fibrillation in our analysis and therefore our results may not be applicable to patients with BMI>40 kg·m−2 and atrial fibrillation.
In conclusion, we found that DOAC therapy does not put patients with morbid obesity at higher risk for recurrent VTE after intermediate- or high-risk PE compared to warfarin anticoagulation; we observed similar outcomes in obese and non-obese patients. Perfusion lung scanning did not suggest a difference in the rate of thrombus resolution, and echocardiography suggested similar rates of right ventricular recovery regardless of anticoagulation choice. In patients with PE, we believe that the available evidence makes DOAC therapy a reasonable option even in morbid obesity; we propose prospective clinical trials to address this directly.
Footnotes
Author contributions: D.J. Lachant, C. Bach, A. Fe, R.J. White and N.A. Lachant all contributed to the study design, analysis of the results and writing the manuscript, and approved the manuscript.
Conflict of interest: D.J. Lachant has nothing to disclose.
Conflict of interest: C. Bach has nothing to disclose.
Conflict of interest: A. Fe has nothing to disclose.
Conflict of interest: R.J. White has nothing to disclose.
Conflict of interest: N.A. Lachant has nothing to disclose.
- Received August 4, 2020.
- Accepted November 17, 2020.
- Copyright ©ERS 2021
This article is open access and distributed under the terms of the Creative Commons Attribution Non-Commercial Licence 4.0.
References
