Avatrombopag, a new tool for the management of thrombocytopenia in patients undergoing medical procedures

Submission: 31.5.2022 Application for Prizes: 31.5.2022 Registration: 10.9.2022 Online-Registrierung https://sgg-sgvc-sasl.unibas.ch/ registration-online.php Schweizer Gastroenterologie 1 · 2022 39 Hier steht eine Anzeige.

In two recent trials including patients with advanced chronic liver disease and severe thrombocytopenia, those receiving avatrombopag in advance showed higher platelet counts and less need for transfusion or rescue therapy on the procedure day compared with placebo recipients. The most frequent side effects were nausea, headache, fever, abdominal pain, fatigue, and edema.
In patients with advanced chronic liver disease (ACLD) complex changes in the hemostatic system occur, including modifications in the synthesis of pro-and anticoagulant proteins, alterations of fibrinolysis, and significant functional changes in platelets, as well as decreased numbers. Thrombocytopenia, i.e., platelet counts below 150 × 10 9 /l, affects 64-84% of patients with cirrhosis and an estimated 1% of them have platelet counts < 50 × 10 9 /l [1,2]. There is currently no clear evidence for the optimal platelet threshold that reduces the bleeding risk in patients with ACLD who undergo an invasive procedure. Although the clinical practice guidelines of several scientific societies advise ensuring a minimum of 30-50 × 10 9 /l platelets before at-risk invasive procedures [3][4][5], other recent recommendations do not include any threshold and support an individualized approach to patients with severe thrombocytopenia before procedures [6]. A procedure is considered high risk if major bleeding is expected in >1.5% of patients or if even minor bleeding is likely to result in permanent organ damage or death (. Table 1; [6]). In patients with severe thrombocytopenia, a prudent risk assessment policy advocates taking appropriate measures before high-risk invasive procedures to potentially decrease bleeding and the use of blood-derived products in the peri-procedural period. Prophylactic and therapeutic options include platelet transfusions and exceptionally other measures such as splenic artery embolization, splenectomy, transjugular in- trahepatic portosystemic shunts, or medical treatments that may be prothrombotic such as recombinant activated factor VII or prothrombin complex concentrates.
Platelet transfusion has until recently been considered the treatment of choice to increase platelet number in patients with ACLD and severe thrombocytopenia undergoing high-risk procedures. Up to 10% of platelet concentrate recipients develop transfusion-related complications including fever, allergic reactions, transfusion purpura, infections, volume overload, and acute transfusionassociated lung injury. In patients with ACLD, the number of platelets at 10 min after transfusion increases by an average of only 12 × 10 9 /l, in comparison with 30 × 10 9 /l in non-cirrhotic patients. Moreover, the transfused platelets are eliminated much more rapidly, so that their hemostatic effect is marginal and lasts no more than 12 h [7]. As the volume of a platelet transfusion unit is around 250-300 ml and each 100 ml of plasma increases the portal pressure by an estimated 1.4 mm Hg in patients with cirrhosis, the transfusion of more than two platelet units could increase the circulating volume and portal pressure by more than 7 mm Hg, significantly increasing the risk of bleeding [8]. In addition to hemodilution, increased platelet destruction and splenic sequestration, in patients with ACLD, reduced hepatic synthesis of thrombopoietin, the main regulator of platelet production by megakaryocytes, also plays a relevant role in the pathophysiology of thrombocytopenia [9]. Therefore, owing to the limitations of platelet transfusion, the risks involved, and the relative scarcity of this component as a therapeutic resource, alternative options for procedural prophylaxis of thrombocytopenia in patients with ACLD are greatly needed.
Thrombopoietin receptor agonists (TPO-RA), including romiplostim, eltrombopag, avatrombopag, and lusutrombopag, promote the growth and differentiation of megakaryocytes and their precursors by mimicking the action of TPO.
The ADAPT-1 and ADAPT-2 trials examined avatrombopag versus placebo in a total of 435 patients with thrombocytopenia (platelets ≤ 50 × 10 9 /l) and ACLD undergoing invasive procedures with a bleeding risk that would require a platelet transfusion [10]. The primary endpoint was the proportion of patients who did not require a platelet transfusion or rescue procedure for bleeding after randomization, and up to 7 days following the scheduled procedure. Patients were randomized 2:1 into two cohorts to receive avatrombopag or placebo according to their mean platelet count at baseline. Those with platelets < 40 × 10 9 /l received 60 mg avatrombopag once daily orally for 5 days, whereas patients with platelets 40 to < 50 × 10 9 /l received 40 mg for the same period. Platelet counts increased with a peak effect between days 10 and 13 and returned to baseline levels by day 35. The main results were that 67% of patients in the low baseline platelet count group and 88% of those in the high basal platelet count group achieved the primary endpoint, compared with 29% and 36% with placebo (. Fig. 1). As a consequence of the personalized dosing scheme, only 1.1% of avatrombopag-treated patients achieved platelet counts > 200 × 10 9 /l, thereby avoiding the risk of thrombosis. Indeed, only one avatrombopag-treated patient (with a maximum platelet count below 100 × 10 9 /l) developed portal vein thrombosis and two placebo-treated patients developed thromboembolic events. The overall safety profile was similar for avatrombopag and placebo and main side effects included abdominal pain, dyspepsia, nausea, pyrexia, dizziness, and headache. The design of these studies limited the ability to show a difference in the rates of bleeding between the avatrombopag and placebo treatment groups, because patients in both treatment arms were eligible to receive platelet transfusions. However, despite several limitations due to the number of patients included, these studies consistently show the efficacy and safety of avatrombopag in increasing the proportion of patients with thrombocytopenia associated with ACLD undergoing a procedure who did not require a platelet transfusion or rescue procedure for bleeding.
Avatrombopag has been recently approved in Switzerland for ACLD patients with severe thrombocytopenia undergoing invasive procedures [11]. It does not require dietary restrictions and has not been associated with portal vein thrombosis, with apparently insignificant drug interactions. Moreover, avatrombopag is expected to be cost-saving while reducing the need for prophylactic platelet transfusions [12].
In conclusion, although more real-life data will be required to confirm the findings from these studies, the availability of avatrombopag will likely promote the adoption of new clinical practice standards to optimize the care of thrombocytopenic patients with ACLD undergoing a scheduled invasive procedure.