# Direct Oral Anti-Xa Anticoagulants and the Future of Factor XI/FXIa Inhibition: A New Paradigm in Thrombosis Prevention

**Authors:** Francesca Futura Bernardi, Dario Bianco, Rosaria Lanzillo, Natalia Diana, Mario Scarpato, Antonio Lalli, Aniello Corallo, Consiglia Riccardi, Ugo Trama, Alessandro Perrella, Manuela Basaglia, Ada Maffettone, Pierpaolo Di Micco, Carmine Siniscalchi

PMC · DOI: 10.3390/pharmacy14010019 · Pharmacy · 2026-01-27

## TL;DR

New anticoagulants targeting factor XI may reduce bleeding risks while preventing blood clots, offering safer alternatives to current drugs.

## Contribution

This paper reviews the potential of FXI/FXIa inhibition as a novel anticoagulant strategy with reduced bleeding risks.

## Key findings

- FXI deficiency protects against thrombosis without causing significant bleeding.
- FXI inhibitors like asundexian and abelacimab show promise in clinical trials.
- FXI inhibition could offer safer anticoagulation for high-risk patients.

## Abstract

The introduction of direct oral anticoagulants (DOACs), particularly factor Xa (FXa) inhibitors, has transformed the prevention and treatment of thromboembolic events. These agents have largely replaced vitamin K antagonists across most indications due to their predictable pharmacokinetics, reduced rates of intracranial bleeding, and overall ease of use. Nevertheless, a substantial residual bleeding risk remains, particularly gastrointestinal bleeding and clinically relevant non-major bleeding in elderly, frail, or polymedicated patients. Furthermore, the management of patients with severe renal dysfunction, active cancer, especially gastrointestinal or genitourinary malignancies and those requiring complex pharmacological regimens, continues to pose significant challenges. These limitations have intensified interest in targeting earlier steps of the coagulation cascade, specifically factor XI (FXI) and its activated form (FXIa). FXI occupies a unique mechanistic position: it contributes substantially to pathological thrombosis while playing only a limited role in physiological hemostasis. Genetic, observational, and mechanistic evidence consistently demonstrates that FXI deficiency confers protection against venous thromboembolism and cardiovascular events while causing minimal spontaneous bleeding. This biological paradigm has catalyzed the development of novel FXI/FXIa inhibitors, including small-molecule agents (asundexian, milvexian) and biological therapies (abelacimab). Clinical trials such as AXIOMATIC-TKR, PACIFIC-AF, and OCEANIC-AF, and ongoing programmes including ASTER and MAGNOLIA suggest that FXI inhibition may preserve antithrombotic efficacy while substantially reducing bleeding risk. This review summarizes the current landscape of oral FXa inhibitors, outlines the biological rationale for FXI/FXIa inhibition, and discusses the evolving clinical evidence supporting what may represent the next major advance in anticoagulant therapy.

## Linked entities

- **Proteins:** F10 (coagulation factor X), F11 (coagulation factor XI)
- **Chemicals:** asundexian (PubChem CID 135206011), milvexian (PubChem CID 118277544)
- **Diseases:** venous thromboembolism (MONDO:0005399)

## Full-text entities

- **Genes:** F11 (coagulation factor XI) [NCBI Gene 2160] {aka FXI, PTA}, F10 (coagulation factor X) [NCBI Gene 2159] {aka FX, FXA}, F2 (coagulation factor II, thrombin) [NCBI Gene 2147] {aka PT, RPRGL2, THPH1}
- **Diseases:** claudication (MESH:D007383), gastrointestinal and intracranial bleeding (MESH:D006471), oncologic (MESH:D000072716), pulmonary embolism (MESH:D011655), stroke (MESH:D020521), hypercoagulability (MESH:D019851), cerebral venous thrombosis (MESH:D020767), gastrointestinal malignancies (MESH:D005770), Thromboembolic disorders (MESH:D013923), renal dysfunction (MESH:D007674), Bleeding (MESH:D006470), systemic embolism (MESH:D004617), intracranial hemorrhage (MESH:D020300), peripheral artery disease (MESH:D058729), CKD (MESH:D051436), APS (MESH:D016736), deep vein thrombosis (MESH:D020246), vascular injury (MESH:D057772), cerebrovascular diseases (MESH:D002561), cardioembolic stroke (MESH:D000083262), ACS (MESH:D000168), liver cirrhosis (MESH:D008103), ischemic (MESH:D002545), endothelial dysfunction (MESH:D014652), AF (MESH:D001281), Cancer-Associated Thrombosis (MESH:D009369), FXI deficiency (MESH:D005173), renal failure (MESH:D051437), Coagulation (MESH:D001778), intracranial bleeding (MESH:D013345), acute coronary syndrome (MESH:D054058), atherosclerosis (MESH:D050197), VTE (MESH:D054556), gastrointestinal and genitourinary tumors (MESH:D014565), Thrombosis (MESH:D013927), portal vein thrombosis (MESH:D012170), injury to (MESH:D014947), inflammation (MESH:D007249), hepatic dysfunction (MESH:D008107)
- **Chemicals:** enoxaparin (MESH:D017984), warfarin (MESH:D014859), Abelacimab (MESH:C000718976), rivaroxaban (MESH:D000069552), edoxaban (MESH:C552171), apixaban (MESH:C522181), Milvexian (MESH:C000720754), dalteparin (MESH:D017985), Anti-Xa (-)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Full text

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## Figures

1 figure with captions in the complete paper: https://tomesphere.com/paper/PMC12922082/full.md

## References

26 references — full list in the complete paper: https://tomesphere.com/paper/PMC12922082/full.md

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Source: https://tomesphere.com/paper/PMC12922082