Abstract
A best evidence topic in cardiac surgery was written according to a structured protocol. The question addressed was whether there is an optimal antithrombotic management for patients supported with axial-flow left ventricular assist devices (LVADs). Altogether, more than 758 papers were found using the reported search, of which 17 represented the best evidence to answer the clinical question. The authors, journal, date and country of publication, patient group studied, study type, relevant outcomes and results of these papers are tabulated. These included seven prospective and three retrospective cohort studies with a total of 538 patients with axial-flow left ventricular assist device (LVAD) (HeartMate II, Jarvik 2000, INCOR, Thoratec assist device) implanted across the world as destination therapy or bridge to transplantation. We conclude that there is a substantial alteration of the prothrombotic profile in patients with axial-flow LVADs. These abnormalities appeared to be reversible with the removal of the device and are likely to be responsible for the high incidence of non-surgical bleeding episodes reported. Warfarin seems to offer a lower thromboembolic risk compared with unfractioned heparin or low molecular weight heparin. There are reports that suggest that managing axial-flow LVAD without anticoagulation, after major bleeding complications, is possible but in all probability, these papers are subject to publication bias as poor outcomes are unlikely to have been reported. All patients with axial-flow LVAD, showed severely impaired platelet function at point of care tests. The use of warfarin (INR target 2.5), in association with aspirin at 100 mg/day, or with point-of-care tests titrated antiplatelet therapy to inhibit 70%, seems to have the best bleeding-thrombosis, and in many cases a very small dose of aspirin of 25 mg twice a day and a dose of clopidogrel of 35 mg/day, were sufficient to achieve a reduction of the maximum aggregation to less than 30%. Finally, we would like to emphasize that such recommendations are addressed only to patients with axial-flow LVAD.
Keywords: Left ventricular assist device, Oral anticoagulation, Antiplatelet agents, Antithrombotic therapy
INTRODUCTION
A best evidence topic was constructed according to a structured protocol. This is fully described in the ICVTS [1]
THREE-PART QUESTION
In [patients with axial-flow left ventricular assist device] what is [the best anticoagulation strategy] to [optimize mortality and morbidity]?
CLINICAL SCENARIO
You are at a ventricular assist device (VAD) conference and the speaker is talking about the problems that they have been having with non-surgical bleeding at their institution. You are surprised as in your institution you have not had many bleeding complications, but have had a few serious ventricular assist device (VAD) thromboses, which all required thrombolysis to resolve. You wonder what the current anticoagulation strategies are around the world and resolve to check the literature.
SEARCH STRATEGY
Medline 1950 to March 2012 using OVID interface (left ventricular assist device/or LVAD.mp.) and (antithrombotic therapy/or anticoagulation.mp.)
SEARCH OUTCOME
758 papers were found using the reported search. From these, 17 papers were identified. That provided the best evidence to answer the question. They are presented in Table 1.
Table 1:
Best evidence papers
| Author, date, journal, country Study type (level of evidence) |
Patient group | Outcomes | Key results | Comments |
|---|---|---|---|---|
| Uriel et al., 2010, J Am Coll Cardiol, USA [2] Retrospective cohort study (level 2b) |
Seventy-nine HM II were reviewed for coagulation abnormalities and bleeding events + transfusion at heart transplantation, compared with that in 69 HeartMate XVE patients | Anticoagulation protocol | Warfarin in 68.3%, aspirin in 55.7% and dipyridamole in 58.2% of the patients | High molecular weight von Willebrand factor multimers were reduced in all HM II patients; 18 of these 31 (58%) patients had bleeding |
| Bleeding and thromboembolic events during support | 44.3% had bleeding episodes with 50% experiencing an event within 2 months of implantation. Five patients had thromboembolic events: 2 CVAs, 1 popliteal artery embolism and 2 embolic events after treatment with IV IgGn | Average INR at time of bleeding was 1.67 ± 0.53 with only 2 patients with INR > 2.5. GI bleeding was the most frequent event | ||
|
Stern et al., 2010, J Card Surg, USA [3] Retrospective cohort study (level 2b) |
Thirty-three patients undergoing long-term LVAD implantation 20 with HM II and 13 patients with other devices (non-axial continuous-flow devices) |
Anticoagulation protocol |
heparin (intravenous or subcutaneous) from POD 3–5 followed by transition to Coumadin therapy to a target INR of 2.0–3.0 antiplatelet therapy consisted of low-dose aspirin and dipyridamole |
The authors lowered the INR target to 1.5–2.0 because of a high incidence of bleeding events |
|
Bleeding events during device support |
Eight (40%) HM II recipients suffered at least one episode of GI bleeding while no GI bleeding occurred in recipients of other devices (P = 0.012) |
In 3 patients with HM II and GI bleeding, warfarin was withheld for at least four months without any thromboembolic events |
||
|
Demirozu et al., 2011, J Heart Lung Transplant, USA [4] Case series (level 4) |
One hundred seventy-two patients who received HM II support |
Anticoagulation protocol |
Warfarin (INR 2.0–3.0), aspirin and dipyridamole |
All GI bleeding episodes were successfully managed medically |
|
Bleeding events during device support |
Thirty-two patients (19%) had GI bleeding after 63 ± 62 (range 8–241) days of support. Ten patients had GI bleeding from an AVM |
|||
|
Geisen et al., 2008, Eur J Cardiothorac Surg, Germany [5] Prospective cohort study (level 2a) |
Analysed patients with two VAD types (7 HM II; 5 Thoratec biventricular assist device) and compared them with 8 patients after heart transplantation (HTX) |
Anticoagulation protocol |
Anticoagulation for both systems was started with heparin (target PTT of 60–80 s) and changed to warfarin with a target INR of 3.0–3.5 for the Thoratec BiVAD and 2.5–3.0 for the HM II after removal of the chest drains. Platelet anti-aggregation was attained with aspirin 100 mg/day |
Small cohort. Did not comment if the abnormal coagulation pattern recorded in the VAD group translated into higher incidence of bleeding events. Transplant group received only aspirin 100 mg/day |
|
Outcome |
Large multimers were missing in all VAD patients. Collagen binding capacity and ristocetin cofactor activity were lower in VAD compared to HTX recipients |
5/6 HTX recipients displayed normal multimer pattern |
||
| Crow et al., 2010, Ann Thorac Surg, USA [6] Prospective cohort study (level 2a) |
Blood samples were collected before and after CF-LVAD implantation from 37 patients. Blood samples were analysed for vWF, platelet and collagen-binding ability | Hemostatic profile | All 37 patients exhibited significant loss of HMW vWF multimers within 30 days of CF-LVAD implantation | The presence of high-molecular-weight (HMW) vWF multimers were detected through gel electrophoresis. All CF-LVAD recipients had AvWS after LVAD placement |
|
Anticoagulation protocol |
Warfarin (INR target 1.5–2.0) and aspirin |
INR levels between bleeders and non-bleeders were similar |
||
|
Bleeding complications |
Ten of the 37 patients experienced bleeding complications after CF-LVAD placement |
The loss of HMW vWF multimers alone cannot predict bleeding risk |
||
|
Meyer et al., 2010, Circ Heart Fail, Germany [7] Prospective cohort study (level 2a) |
Twenty-six patients received axial flow LVAD (HM II) for a median support time of 4.5 months |
Hemostatic profile |
In all patients on devices, severe impairment of platelet aggregation as well as a loss of large vWF multimers were found |
A diagnosis of von Willebrand syndrome type 2 was established in all patients after LVAD implantation. Reversibility of this condition was found after removal of the device |
|
Anticoagulation protocol |
IV heparin within 24 h from implantation if chest tubes drainage < 50 ml/h. Transition to warfarin after drain removal (INR target 2.5 ± 0.5) + aspirin 100 mg/day from POD 3 |
Platelet-related hemostasis was tested with a PFA-100 with an aspirin-independent test. If patient had AvWS aspirin was stopped |
||
|
Bleeding episodes |
Incidence of 0.17 per patient-year: 8 bleeding episodes were recorded within 48 patient-years |
The total follow-up period was 48 patient-years |
||
|
Thromboembolic events |
No haemorrhagic or ischaemic CVAs. One fatal mesenteric ischaemia, two pump thrombosis (one after discontinuation of warfarin) |
One pump thrombosis was successfully treated with lepirudin |
||
|
Mortality |
One died due to mesenteric ischaemia 4 months after implantation; 1 died due to sepsis after 40 months |
|||
|
Jennings et al., 2011, J Thorac Cardiovasc Surg, USA [8] Prospective cohort study (level 2a) |
Sixteen patients (average age: 53 years; 62% Afro-American; 81% male; 31% bridge-to-transplant). Followed up to 1-year post-LVAD implantation (HeartMate II) |
Time to within the therapeutic international normalized ratio (INR) range (2.0–3.0) |
Average: 51% (range 22–88%). Significantly worse than the control group: the overall clinic population (68%). The VAD population was 17% above and 32% below the therapeutic range |
Small study. Suggests that HM II patients may spend less time in their target INR range than the overall anticoagulation clinic population |
|
Bleeding and thromboembolic events |
No outpatient bleeding episodes. One patient had a transient ischaemic attack (INR 1.6) |
|||
| Slaughter et al., 2011, Int J Artif Organs, USA [9] Prospective cohort study (level 2a) |
Thirty-four HF patients supported by a HM II axial flow LVAD implanted for destination therapy (DT). 31 M, 3 F, supported by LVAD for 30–723 days average 268 days | Anticoagulation protocol Platelet adhesion markers |
Coumadin (0–8 mg daily dose) and aspirin (0–325 mg daily dose) The soluble P-selectin marker was within normal platelet activity limits for all end points |
Despite high shear stresses associated with a high-speed axial flow pump, the HM II had no discernable effect on platelet activation, independently of length of support, antiplatelet and anticoagulation regimens |
|
John et al., 2008, J Thorac Cardiovasc Surg, USA [10] Case series (level 4) |
Forty-five patients (mean age 57.24 ± 14.2 years) underwent implantation of the HeartMate II; 30 bridge-to-transplantation therapy, 7 DT, and 8 device exchange for a failed XVE left ventricular assist device |
Anticoagulation |
IV heparin 12–24 h after HM II implantation or at the point that thoracostomy tube drainage is less than 50 ml/h; Warfarin (from POD 3–5) with INR target 2.0–3.0 for the first 14 patients and 1.5–2.0 for the others; aspirin from POD 2–3 at 81 mg/day |
Single-center analysis. However, as a result of significant GI bleeding among the first 14 patients, they stopped using postoperative heparin and lowered the INR to 1.5–2.0 |
|
Average monthly INR range |
Forty-one had a mean INR of less than 2.0; of those 41 patients, 21 had a mean INR of less than 1.6 |
|||
|
Incidences of bleeding |
Of the first 14 patients, 4 had GI bleeding and 1 pericardial tamponade (5/14; 35.7%). Of the remaining 31 patients who received only warfarin, 4 had GI bleeding, (4/31; 12.9%) |
Because of recurrent GI bleeding episodes, 4 patients discontinued warfarin for about 4 months without any thromboembolic events |
||
|
Device thrombus |
One suspected pump thrombus (INR, 1.3 at the time of presentation) |
No thrombolytic therapy was used |
||
| Attisani et al., 2010, J Artif Organs, Italy [11] Case series (level 4) |
Twelve patients (10 males, 35–60 years old) with acute or end stage heart failure received the INCOR LVAD system as a bridge-to-transplantation. Mean follow-up was 10 months (cumulative 4.9 years) | Anticoagulation protocol | Heparin and warfarin: IV heparin was used until POD 4 (PTT 60–80 s). IV heparin was stopped when INR was over 2.2 The INR target was 2.8–3.2. Double antiplatelet therapy with aspirin and clopidogrel was started between the second and the fifth POD | Small cohort. Stimulators of platelet aggregation used in the test were arachidonic acid (AA), ADP, epinephrine and collagen. There were no cases of aspirin or clopidogrel resistance |
|
Conditions to introduce antiplatelet therapy |
Platelet count over 100 000/ml. The target was to obtain a reduction of the maximum aggregation (MA)/20% with AA,/50% with epinephrine and /30% with ADP. Collagen acted as a control and should not be suppressed (MA over 50%) |
In 9 cases (82%), the effective dose of aspirin was 25 mg twice a day, and in 2 (18%) it was 50 mg twice a day. In 10 cases (90%), the effective dose of clopidogrel was 35 mg/day, and in only one case, 75 mg/day |
||
|
Major and minor bleeding |
Three (25%) cases of early postoperative mediastinal bleeding |
No episodes of major bleeding occurred during the follow-up period |
||
|
Major and minor thromboembolic events |
The rate of major and minor events was 0.09 and 0.2 per patient-year respectively |
|||
|
Meuris et al., 2007, Artif Organs, Belgium [12] Case series (level 4) |
Ten patients with end-stage HF treated with INCOR LVAD as bridge-to-transplantation and kept on a long-term regime of low molecular weight heparin (LMWH) and antiplatelet therapy |
Anticoagulation protocol |
No anticoagulation during the first 12 h postoperatively. Thereafter, IV heparin (PTT60–80 s). As soon as the chest drains were removed and total platelet count was above 100 000/ml: aspirin at 80 mg two times daily; clopidogrel at 75 mg daily; and dipyridamole 75 mg three times daily. As soon as the patients were moved to the regular ward, the intravenous heparin was replaced by subcutaneous LMWHs at a therapeutic level of 1 mg/kg, twice daily |
Effectiveness of the low molecular weight regime was monitored through measurement of antifactor Xa activity (base and peak levels). Antiplatelet therapy was monitored through weekly platelet function tests. No oral anticoagulation was given at any time |
|
Bleeding events |
One patient had a fatal late intestinal bleeding |
|||
|
Thromboembolic events |
Five minor TIA. Four Thrombus-related pump dysfunction. One severe stroke with concomitant intracranial bleeding fatal to the patient |
|||
|
Copeland et al., 2011, Artif Organs, USA [13] Case series (level 4) |
Twenty-eight children, ages 1 month to 16 years. Eighteen LVAD, 7 BIVAD and 3 total artificial hearts, implanted for 3–107 days (mean 27) |
Anticoagulation protocol |
Heparin IV was started once chest tube drainage was <0.5 ml/kg/h . Dipyridamole was started immediately postoperatively IV at 0.1 mg/kg/h in children <6 years old, 50 mg (age 6–10 years) or 100 mg (>10 years) every 6 h. Aspirin was started at 2–10 mg/kg/min after plt > 150 000 mm3. Dosage was increased in larger children by 162–325 mg for each 100 000 plt above 150 000. Pentoxifylline 400 mg × 3/daily was used in >6-years old |
VAD anticoagulation is more difficult in children. 20/28 (71%) were discharged from the hospital. Antiplatelet effect assessed with thromboelastography (TEG), platelet aggregation studies |
|
Deaths |
Eight deaths (29%): 4 embolic, 1 graft failure, 2 anoxic brain damage and 1 postexplant heart failure |
|||
|
Thromboembolic and bleeding complication |
Six reoperations for bleeding (21%); 7 strokes (25%) and 3 visceral emboli (11%) |
|||
| Saito et al., 2001, Eur J Cardiothorac Surg, UK [14] Prospective cohort study (level 2a) |
Animal study. The Terumo continuous flow left ventricular assist system (T-ILVAS; a centrifugal pump with a magnetically suspended impeller) was implanted into 6 sheep |
Anticoagulation & outcome All animals appeared completely normal for up to 210 days. At speeds between 1500 and 2000 rev/min the device pumped up to 8 l/min capturing all mitral flow |
No anticoagulation was given after implantation | All animals were electively euthanized between 3 and 7 months postoperatively. The T-ILVAS successfully supported the systemic circulation without anticoagulation for up to 210 days |
|
Complications |
There were no major complications: pump failure, thromboembolism, haemorrhage or driveline infection |
One embolus was found in a sectioned kidney |
||
|
Pereira et al., 2010, Interact CardioVasc Thorac Surg, USA [15] Case report (level 4) |
Two patients in whom recurrent GI bleeding during LVAD support with axial left ventricular assist device |
Thromboembolic complications |
None |
Discontinuation of anti-thrombotic regimen for a year or more |
|
Steinlechner et al., 2009, Ann Thorac Surg, Austria [16] Prospective cohort study (level 2a) |
Platelet function was assessed in 12 LVAD outpatients and 12 healthy matched volunteers using TEG platelet mapping, thromboelastometry, PFA-100 and a whole blood aggregometre (multiplate) |
Anticoagulation protocol |
Warfarin with INR target 2.5–3.5. Aspirin 100 mg/day |
Multimodal antiplatelet monitoring with TEG ROTEM and the PFA-100 and multiplate showed impaired platelet function in patients with LVAD |
|
Hemostatic profile |
Although antigen levels of von Willebrand factor were 80% higher in patients (P < 0.001), von Willebrand factor-ristocetin was subnormal in 5 of 12 patients. Ristocetin-induced aggregation was also threefold higher in volunteers (P < 0.001) |
collagen adenosine diphosphate closure times were 2.5-fold longer in patients than in volunteers (P < 0.001), and 50% of patients had maximal collagen adenosine diphosphate closure time values |
||
|
Tsukui et al., 2007, J Thorac Cardiovasc Surg, USA [17] Retrospective cohort study (level 2b) |
Sixty-four patients with LVAD: 22 HeartMate; 5 HM II; 19 Thoratec LVAD; 13 Novacor. 60 patients underwent BiVAD implantation with 57 Thoratec BiVADs and 3 HM LVAD + Thoratec RVAD |
Anticoagulation |
In all VAD implantation except with the HeartMate anticoagulation was started with dextran 40% at 25 ml/h 6 h after admission to the ICU if bleeding was less than 100 ml/h. Subsequently, heparin was started PTT 40–51 s for the first 72 h then PTT of 42–62 seconds. Warfarin was introduced on postoperative day (POD) 10 INR 2.5–3.5. Aspirin 81–325 mg and/or clopidogrel 75 mg daily was started 48 h after implantation |
The risk of cerebrovascular accident (CVA) increases with a longer LVAD support period. Infection may activate platelet function and predispose the patient to a CVA. Antiplatelet dose was adjusted to maintain MA at TEG between 60 and 70 mm |
|
CVAs |
31 patients (25%) had 48 CVAs. 60% of CVAs occurred within 4 months after implantation |
42% of CVAs occurred in patients with infections |
||
|
Actuarial freedom from cerebrovascular accident at 6 months |
75, 64, 63 and 33% with the HeartMate, Thoratec BVAD, Thoratec LVAD and Novacor, respectively |
PTT: partial thromboplastin time; BVAD: biventricular assist device; ADP: adenosine diphosphate; POD: post operative day.
RESULTS
Uriel et al. [2], in a retrospective analysis of 79 patients with axial-flow LVAD, anticoagulated with a combination of warfarin, aspirin and dipyridamole, reported an incidence of gastrointestinal (GI) bleeding events of 44.3%. Anticoagulant use was not statistically different between bleeders and non-bleeders, with an average INR at time of bleeding of 1.67 ± 0.53.
Stern et al. [3] similarly reported an incidence of GI bleeding of 40% in the HeartMate II (HM II) axial-flow LVAD, group versus 0% in the pulsatile one. The anticoagulation protocol consisted of a low-dose of aspirin and dipyridamole and warfarin (INR of 2.0–3.0). Interestingly, 3 bleeding patients uneventfully withheld warfarin for about four months.
Demirozu et al. [4], in a large series of 172 patients, supported with HM II and anticoagulated with warfarin aspirin and dipyridamole, reported a GI bleeding rate of 32%. They demonstrated the presence of an arteriovenous malformation in 31% of the bleeding patients.
Geisen et al. [5] demonstrated that their axial-flow LVAD patients developed impaired coagulation secondary to acquired von Willebrand syndrome (AvWS).
Crow et al. [6], in a multicenter prospective study, investigated the impact of continuous flow LVAD support on the haemostatic profile in 37 patients. All LVAD recipients developed AvWS after the device implantation, but only 10 had bleeding complications. The anticoagulation protocol consisted of warfarin (INR target 1.5–2.0) and aspirin. INR levels between bleeders and non-bleeders were similar. Point of care test for the evaluation of platelet function was not used. They conclude that the loss of high-molecular-weight von Willebrand factor multimers alone cannot predict bleeding risk.
Meyer et al. [7] showed the reversibility of AvWS in 26 patients supported with axial-flow LVAD implanted as bridge to transplantation after the removal of the device. During LVAD support they reported an incidence of bleeding of 0.17 per patient-year using warfarin (INR target 2.5 ± 0.5) and Aspirin 100 mg/day. If a patient was diagnosed with AvWS, aspirin was stopped. One patient had fatal mesenteric ischaemia. Platelet function analyser showed severe impairment in all patients on LVAD support.
Jennings et al. [8] reported that their outpatient HM II cohort (16 patients) spent 32% of the average time below the therapeutic INR range (2.0–3.0) with only one incidence of TIA and no incidence of GI bleeding episodes. The authors did not comment about antiplatelet therapy.
Slaughter et al. [9], showed that, despite high shear stresses associated with a high-speed axial flow pump, there was no effect on platelet activation, independently of length of support, antiplatelet and anticoagulation regimens used.
John et al. [10], in their series of 45 patients supported with HM II, successfully reduced the intensity of anticoagulation (avoiding postoperative heparin infusion, decreasing the therapeutic INR to 1.5–2.0 and introducing aspirin at 81 mg/day from post op day 2–3), without any increase in thromboembolic events.
Attisani et al. [11] successfully used a platelet aggregation test (PAT) to reduce the dose of antiplatelet in 14 patients supported with the INCOR LVAD and anticoagulated with warfarin (INR target 2.8–3.2). They showed that 82% required a dose of aspirin of 25 mg twice a day and 90% a dose of clopidogrel of 35 mg/day, to reduce the maximum aggregation <30%. They reported no GI bleeding episodes and a rate of major and minor thromboembolic events of 0.09 and 0.2 per patient-year, respectively.
Meuris et al. [12], in 10 patients supported with the INCOR LVAD implanted as bridge-to-transplantation, suggested the use of the low molecular weight heparin (LMWH) (1 mg/Kg twice daily) and triple antiplatelet therapy (aspirin at 80 mg two times daily; clopidogrel at 75 mg daily; and dipyridamole 75 mg three times daily) as an alternative to oral anticoagulants. PAT was used to reduce platelet aggregation levels to at least 30%. They reported 1 severe stroke with concomitant fatal intracranial bleeding and 4 Thrombus-related pump dysfunction.
Copeland et al. [13], similarly in children with LVAD used IV heparin associated with point-of-care titrate antiplatelet therapy consisting of: Aspirin 2–10 mg/kg/min increased in larger children by 162–325 mg for each 100 000 platelets above 150 000; dipyridamole, IV at 0.1 mg/kg/h in children <6 years old, 50 mg (age 6–10 years) or 100 mg (>10 years) by mouth every 6 h; pentoxifylline 400 mg per os three times daily(age > 6). This experience was worrisome, with 20% incidence of reoperation for bleeding and 25% of stroke (2 fatal).
Saito et al. [14], in an animal model, successfully supported the systemic circulation with continuos flow LVAD without any anticoagulation up to 210 days.
Pereira et al. [15] reported 2 axial-flow LVAD patients who stopped anti-thrombotic therapy for more than a year because of recurrent GI bleeding episodes, without any thrombotic complications.
Steinlechner et al. [16], simultaneously used thrombelastography (TEG), rotation thromboelastometry (ROTEM), platelet function analyser (PFA-100) and multiplate, on 12 patients supported with continuous flow LVAD. They showed markedly impaired platelet function independently from the effect of the anticoagulation therapy with warfarin (INR target 2.5–3.5) and aspirin 100 mg/day.
Tsukui et al. [17], in a retrospective analysis of 124 patients with axial-flow LVAD and biventricular assist device (BIVAD) anticoagulated with warfarin (INR 2.5–3.5) and aspirin (81–325 mg/day) e/o clopidogrel 75 mg/day to maintain the maximum amplitude (MA) on the TEG between 60–70 mm, reported 25% of cerebrovascular accidents (CVAs), 42% happening in patients with infections. The mean MA in the presence of infection (63.6 mm) was higher than that in the absence of infection (60.7 mm) (P = 0.0309).
CLINICAL BOTTOM LINE
There is a substantial alteration of the prothrombotic profile in patients with axial-flow LVADs. These abnormalities appeared to be reversible with the removal of the device and are likely to be responsible for the high incidence of non-surgical bleeding episodes reported. Warfarin seems to offer a lower thromboembolic risk compared with unfractioned heparin or LMWH. There are reports that suggest that managing axial-flow LVAD without anticoagulation, after major bleeding complications, is possible, but in all probability these papers are subject to publication bias as poor out-comes are unlikely to have been reported. All patients with axial-flow LVAD showed severely impaired platelet function at point of care tests. The use of warfarin (INR target 2.5), in association with aspirin at 100 mg/day, or with point-of-care tests titrated antiplatelet therapy to inhibit 70%, seems to have the best bleeding-thrombosis, and in many cases a very small dose of aspirin of 25 mg twice a day and a dose of clopidogrel of 35 mg/day, were sufficient to achieve a reduction of the maximum aggregation to less than 30%. Finally, we would like to emphasize that such recommendations are addressed only to patients with axial-flow LVAD.
Conflict of interest: none declared.
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