Idarucizumab for Dabigatran Reversal.

BACKGROUND: Specific reversal agents for non-vitamin K antagonist oral anticoagulants are lacking. Idarucizumab, an antibody fragment, was developed to reverse the anticoagulant effects of dabigatran. METHODS: We undertook this prospective cohort study to determine the safety of 5 g of intravenous idarucizumab and its capacity to reverse the anticoagulant effects of dabigatran in patients who had serious bleeding (group A) or required an urgent procedure (group B). The primary end point was the maximum percentage reversal of the anticoagulant effect of dabigatran within 4 hours after the administration of idarucizumab, on the basis of the determination at a central laboratory of the dilute thrombin time or ecarin clotting time. A key secondary end point was the restoration of hemostasis. RESULTS: This interim analysis included 90 patients who received idarucizumab (51 patients in group A and 39 in group B). Among 68 patients with an elevated dilute thrombin time and 81 with an elevated ecarin clotting time at baseline, the median maximum percentage reversal was 100% (95% confidence interval, 100 to 100). Idarucizumab normalized the test results in 88 to 98% of the patients, an effect that was evident within minutes. Concentrations of unbound dabigatran remained below 20 ng per milliliter at 24 hours in 79% of the patients. Among 35 patients in group A who could be assessed, hemostasis, as determined by local investigators, was restored at a median of 11.4 hours. Among 36 patients in group B who underwent a procedure, normal intraoperative hemostasis was reported in 33, and mildly or moderately abnormal hemostasis was reported in 2 patients and 1 patient, respectively. One thrombotic event occurred within 72 hours after idarucizumab administration in a patient in whom anticoagulants had not been reinitiated. CONCLUSIONS: Idarucizumab completely reversed the anticoagulant effect of dabigatran within minutes. (Funded by Boehringer Ingelheim; RE-VERSE AD ClinicalTrials.gov number, NCT02104947.).

Idarucizumab Improves Outcome in Murine Brain Hemorrhage Related to Dabigatran.

Lack of specific antidotes is a major concern in intracerebral hemorrhage (ICH) related to direct anticoagulants including dabigatran (OAC-ICH). We examined the efficacy of idarucizumab, an antibody fragment binding to dabigatran, in a mouse model of OAC-ICH. Dabigatran etexilate (DE) dose-dependently prolonged diluted thrombin time and tail-vein bleeding time, which were reversed by idarucizumab. Pretreatment with DE increased intracerebral hematoma volume and cerebral hemoglobin content. Idarucizumab in equimolar dose prevented excess hematoma expansion for both DE doses. In more extensive ICH, idarucizumab significantly reduced mortality. Thus, idarucizumab prevents excess intracerebral hematoma formation in mice anticoagulated with dabigatran and reduces mortality.

Reversal of dabigatran effects in models of thrombin generation and hemostasis by factor VIIa and prothrombin complex concentrate.

BACKGROUND: The oral thrombin inhibitor dabigatran has the drawbacks that it does not have a validated antidote. Data from animal studies and plasma coagulation assays suggest that prothrombin complex concentrate (PCC) or recombinant factor VIIa (FVIIa) might reverse dabigatran anticoagulation. METHODS: Cellular elements make a significant contribution to hemostasis. Our goals were to (1) test the hypothesis that both FVIIa and a 4-factor PCC improve parameters of thrombin generation in the presence of dabigatran in a cell-based model; and (2) determine whether results in a cell-based model correlate with hemostasis in vivo. RESULTS: PCC reversed dabigatran effects on the rate, peak, and total amount of thrombin but did not shorten the lag (n = 6 experiments in triplicate). By contrast, FVIIa shortened the lag, increased the rate and peak, but did not improve total thrombin (n = 6). Effects of PCC were seen at both therapeutic and markedly supratherapeutic dabigatran levels, whereas beneficial effects of FVIIa decreased as the dabigatran level increased. The PCC effect was reproduced by adding prothrombin, factor X, and factor IX. At therapeutic dabigatran levels, both PCC and FVIIa normalized hemostasis time in a mouse saphenous vein bleeding model. CONCLUSIONS: A cell-based model reflects the effects on thrombin generation of clinically relevant levels of FVIIa and PCC in the presence of dabigatran. Enhancing the rate of thrombin generation and peak thrombin level appear to correlate best with hemostasis in vivo. The ineffectiveness of FVIIa at supratherapeutic dabigatran levels may explain conflicting reports of its efficacy in dabigatran reversal.

Reversal agents in development for the new oral anticoagulants.

The new oral anticoagulants have many advantages over vitamin K antagonists, but they are still associated with a troublesome incidence of major bleeding. Additionally, the absence of a reversal agent for the new oral anticoagulants is a barrier to their more widespread use. Currently, there are 3 potential reversal agents in development: idarucizumab is a humanized murine monoclonal antibody fragment directed specifically at dabigatran; andexanet alfa is a recombinant modified decoy factor Xa that binds to factor Xa inhibitors; and PER977 is a small molecule that binds to factor Xa and IIa inhibitors and to heparin-based anticoagulants through charge interaction. These agents have undergone phase I clinical testing, appear to be well tolerated in healthy volunteers, and are effective in neutralizing their respective targets. All 3 are currently undergoing or entering into a phase II or III clinical study. This article reviews the available data for idarucizumab, andexanet alfa, and PER977.

Novel thrombin and factor Xa inhibitors: challenges to reversal of their anticoagulation effects.

PURPOSE OF REVIEW: Warfarin has been the sole oral anticoagulant used in the management of thromboembolic disorders for over 60 years. Target-specific oral anticoagulants (TSOAs) have recently emerged as alternatives to warfarin, because they do not require laboratory monitoring. Nevertheless, with the rising use of TSOAs, there is growing concern among clinicians regarding management of bleeding in patients taking them. Unlike warfarin, there is no antidote or reversal agent for TSOAs. This review summarizes recent developments and attempts to provide a systematic approach to patients on TSOAs presenting with bleeding complications. RECENT FINDINGS: Currently, data involving clinical management of TSOAs are limited and primarily based on ex-vivo or animal models using hemostatic agents with uncertain implications in bleeding patients. There is a pressing need for randomized clinical trials evaluating the safety and efficacy of hemostatic agents. SUMMARY: Without evidence-based guidelines for TSOA management, appropriate patient care requires an understanding of TSOA pharmacology, their effect on coagulation tests and, hence, a correct interpretation of test results, as well as a systematic approach to bleeding complications.

Managing new oral anticoagulants in the intensive care unit.

Warfarin has been the mainstay of oral anticoagulation for more than half a century. Within the last several years, 2 new classes of oral anticoagulants have been introduced as potential alternatives to warfarin for certain indications. The oral direct thrombin inhibitor, dabigatran, and 2 factor Xa inhibitors, rivaroxaban and apixaban, are the newest agents approved for use in the United States. These agents have been studied in various areas including stroke prophylaxis in atrial fibrillation, prevention and treatment of venous thromboembolism, and for reduction of ischemic events following acute coronary syndromes. While these agents do not require routine monitoring of international normalized ratio, these agents may be more challenging to reverse than traditional warfarin therapy. The following review will focus on describing the areas where the new oral anticoagulant agents have been studied, the basic pharmacologic characteristics of each agent, and how to appropriately manage the reversal of these agents when indicated.

Pharmacologic interventions for reversing the effects of oral anticoagulants.

PURPOSE: To describe the pharmacologic agents and strategies used for urgent reversal of warfarin and the target-specific oral anticoagulants dabigatran, rivaroxaban, and apixaban. SUMMARY: To reverse the anticoagulant effects of warfarin in patients who are bleeding or need surgery, exogenous vitamin K (phytonadione) may be used in combination with another, shorter-acting intervention, such as fresh frozen plasma (FFP), prothrombin complex concentrate (PCC), recombinant factor VIIa, or activated PCC (aPCC). Three-factor PCC contains factors II, IX, and X in an inactivated form, and four-factor PCC also includes factor VII in an inactivated form. No four-factor PCC products are available in the United States, but aPCC, which contains the same four factors with factor VII provided in an activated form, is available. The intervention depends on the International Normalized Ratio, presence of bleeding, and need for and timing of surgery. Research suggests that clotting factor concentrates are more effective than FFP alone for warfarin reversal. These products also may be useful for reversing the effects of target-specific oral anticoagulants, but limited efficacy and safety data are available to support their use. The risks and benefits associated with these products need to be weighed before their use for reversal of dabigatran, rivaroxaban, or apixaban. Additional clinical data are needed to clearly define the role of concentrated clotting factor products in reversal and to determine the optimal clotting factor concentrate product and dose for urgent reversal of oral anticoagulation. CONCLUSION: Phytonadione and clotting factor concentrates appear to have a role for reversal of warfarin, and limited evidence suggests that clotting factor concentrates could have a role in reversal of target-specific oral anticoagulants in an emergency situation.

Blocking direct inhibitor bleeding.

In this issue of Blood, Schiele et al report the development of a monoclonal antibody that reverses the anticoagulant effect of the direct thrombin inhibitor dabigatran.

A specific antidote for dabigatran: functional and structural characterization.

Dabigatran etexilate is a direct thrombin inhibitor and used widely as an anticoagulant for the prevention of stroke in patients with atrial fibrillation. However, anticoagulation therapy can be associated with an increased risk of bleeding. Here, we present data on the identification, humanization, and in vitro pharmacology of an antidote for dabigatran (aDabi-Fab). The X-ray crystal structure of dabigatran in complex with the antidote reveals many structural similarities of dabigatran recognition compared with thrombin. By a tighter network of interactions, the antidote achieves an affinity for dabigatran that is ~350 times stronger than its affinity for thrombin. Despite the structural similarities in the mode of dabigatran binding, the antidote does not bind known thrombin substrates and has no activity in coagulation tests or platelet aggregation. In addition we demonstrate that the antidote rapidly reversed the anticoagulant activity of dabigatran in vivo in a rat model of anticoagulation. This is the first report of a specific antidote for a next-generation anticoagulant that may become a valuable tool in patients who require emergency procedures.

Treatment of acute stroke in patients on dabigatran: a survey of US stroke specialists.

BACKGROUND: There are no guidelines for thrombolysis in stroke patients taking dabigatran, or dabigatran reversal strategies in patients with ICH. We sought to assess how vascular neurologists plan to care for these patients. METHODS: An Internet-based questionnaire was sent to US board-certified vascular neurologists. Case scenarios for patients on dabigatran with acute ischemic stroke or ICH were presented; questions assessed preferred treatment strategies. RESULTS: In all, 221 vascular neurologists responded. For a typical ischemic stroke patient eligible for intravenous (IV) tissue plasminogen activator (tPA) except for use of dabigatran (time of last dose unknown), 49% would not treat with tPA regardless of PTT, 28% would treat if PTT was normal, 9% would treat if PTT was less than 40 seconds, and 4% would treat regardless of PTT. Even more variability in responses was seen when presented with a normal PTT but variable times from last dabigatran dose. Between 8%-14% of respondents were not sure what they would do. For catheter-based thrombolysis, 25% indicated they would treat with IV tPA but would prefer catheter thrombolysis, 30% would use IV tPA and consider catheter thrombolysis as for any patient, 36% would only use catheter thrombolysis, and 9% would not use IV tPA or catheter thrombolysis. For a patient with dabigatran-associated ICH, 73% said they would attempt reversal of dabigatran with the following modalities: FFP 53%; factor VIIa 24%; prothrombin complex concentrates 61%; platelet transfusion 7%; and hemodialysis 24%. CONCLUSIONS: There is a remarkable lack of consensus among vascular neurologists regarding the assessment and treatment of acute stroke patients on dabigatran.

Reversal of dabigatran anticoagulation by prothrombin complex concentrate (Beriplex P/N) in a rabbit model.

BACKGROUND: One limitation of the direct thrombin inhibitor dabigatran is the lack of specific antidotes that allow acute bleeding events to be managed or urgent interventional procedures performed. Prothrombin complex concentrates (PCCs) have served as a standard treatment for the reversal of coumarin anticoagulation. OBJECTIVES: This study was designed to determine in an animal model whether a PCC (Beriplex P/N) can effectively reverse the effects of dabigatran. An additional objective was to evaluate markers of dabigatran-associated bleeding diathesis. METHODS: Anesthetized rabbits were treated with 0.4 mg kg(-1) dabigatran followed by PCC doses of 20, 35 or 50 IU kg(-1) or placebo. After a standardized kidney incision, volume of blood loss and time to hemostasis were determined. RESULTS: From an initial mean of 29 mL, blood loss progressively declined by 5.44 mL with a 95% confidence interval (CI) of 2.21-8.67 mL per 10 IU kg(-1) increment in PCC dose (P = 0.002). At a PCC dose of 50 IU kg(-1) blood loss was fully normalized. Increasing PCC doses shortened the median time to hemostasis from 20.0 to 5.7 min (P < 0.001). The rate of hemostasis was nearly trebled with each 10 IU kg(-1) increment in PCC dose (rate ratio, 2.89; CI, 1.64-5.09). CONCLUSIONS: In this animal study, PCC showed potential as an agent for reversing the effects of dabigatran. Further investigation is warranted.

Reversal of rivaroxaban and dabigatran by prothrombin complex concentrate: a randomized, placebo-controlled, crossover study in healthy subjects.

BACKGROUND: Rivaroxaban and dabigatran are new oral anticoagulants that specifically inhibit factor Xa and thrombin, respectively. Clinical studies on the prevention and treatment of venous and arterial thromboembolism show promising results. A major disadvantage of these anticoagulants is the absence of an antidote in case of serious bleeding or when an emergency intervention needs immediate correction of coagulation. This study evaluated the potential of prothrombin complex concentrate (PCC) to reverse the anticoagulant effect of these drugs. METHODS AND RESULTS: In a randomized, double-blind, placebo-controlled study, 12 healthy male volunteers received rivaroxaban 20 mg twice daily (n=6) or dabigatran 150 mg twice daily (n=6) for 2½ days, followed by either a single bolus of 50 IU/kg PCC (Cofact) or a similar volume of saline. After a washout period, this procedure was repeated with the other anticoagulant treatment. Rivaroxaban induced a significant prolongation of the prothrombin time (15.8±1.3 versus 12.3±0.7 seconds at baseline; P<0.001) that was immediately and completely reversed by PCC (12.8±1.0; P<0.001). The endogenous thrombin potential was inhibited by rivaroxaban (51±22%; baseline, 92±22%; P=0.002) and normalized with PCC (114±26%; P<0.001), whereas saline had no effect. Dabigatran increased the activated partial thromboplastin time, ecarin clotting time (ECT), and thrombin time. Administration of PCC did not restore these coagulation tests. CONCLUSION: Prothrombin complex concentrate immediately and completely reverses the anticoagulant effect of rivaroxaban in healthy subjects but has no influence on the anticoagulant action of dabigatran at the PCC dose used in this study. Clinical Trial Registration- URL: http://www.trialregister.nl. Unique identifier: NTR2272.

Indirect regulation of the intestinal H+-coupled amino acid transporter hPAT1 (SLC36A1).

A H(+)-coupled amino acid transporter has been characterised functionally at the brush border membrane of the human intestinal cell line Caco-2. This carrier, hPAT1 (human Proton-coupled Amino acid Transporter 1) or SLC36A1, has been identified recently at the molecular level and hPAT1 protein is localised to the brush border membrane of human small intestine. hPAT1 transports both amino acids (e.g., beta-alanine) and therapeutic agents (e.g., D-cycloserine). In human Caco-2 cells, hPAT1 function (H(+)/amino acid symport) is associated with a decrease in intracellular pH (pH(i)), which selectively activates the Na(+)/H(+) exchanger NHE3, and thus maintains pH(i) and the driving force for hPAT1 function (the H(+) electrochemical gradient). This study provides the first evidence for regulation of hPAT1 function. Activation of the cAMP/protein kinase A pathway in Caco-2 cell monolayers either using pharmacological tools (forskolin, 8-br-cAMP, [(11,22,28)Ala]VIP) or physiological activators (the neuropeptides VIP and PACAP) inhibited hPAT1 function (beta-alanine uptake) at the apical membrane. Under conditions where NHE3 is inactive (the absence of Na(+), apical pH 5.5, the presence of the NHE3 inhibitor S1611) no regulation of beta-alanine uptake is observed. Forskolin and VIP inhibit pH(i) recovery (NHE3 function) from beta-alanine-induced intracellular acidification. Immunocytochemistry localises NHERF1 (NHE3 regulatory factor 1) to the apical portion of Caco-2 cells where it will interact with NHE3 and allow PKA-mediated phosphorylation of NHE3. In conclusion, we have shown that amino acid uptake via hPAT1 is inhibited by activators of the cAMP pathway indirectly through inhibition of NHE3 activity.