What does this research mean for the field?

Haemostatic sprays significantly improve bleeding control and patient outcomes in surgical and trauma settings compared to conventional methods. Novelty: ClaimNovelty.SYNTHESIS. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

To analyze the development, mechanisms, and clinical applications of emerging haemostatic sprays.

March 7, 2026Open Access

Emerging haemostatic sprays: From material design to clinical translation

Key Points

To analyze the development, mechanisms, and clinical applications of emerging haemostatic sprays.
Reviewed existing haemostatic sprays and their commercial products.
Conducted a comparative analysis of material design and mechanisms of action.
Evaluated clinical applications and performance outcomes of different haemostatic agents.
Haemostatic sprays significantly reduce bleeding and improve outcomes in various clinical settings.
New biomaterials show promise in enhancing effectiveness and safety in bleeding management.
Various pre-clinical sprays offer innovative solutions for complex hemorrhage management.

Abstract

Haemostatic sprays have emerged as a transformative class of topical agents for the rapid control of bleeding in surgery, trauma, and endoscopy, particularly in settings where conventional approaches such as suturing, cauterisation, or mechanical compression are impractical. Delivered in a non-contact and conformal manner, these systems enable efficient coverage of irregular, deep, and non-compressible bleeding sites. Their haemostatic action arises from synergistic biochemical and physical mechanisms, including activation of the coagulation cascade, plasma absorption driven concentration of clotting factors, and formation of adhesive or barrier-type matrices at the wound surface. Commercial and non-commercial products such as Hemospray®, PuraStat®, Raplixa™, Ankaferd Blood-Stopper®, EndoClot®, OOZFIX™, and CMCS-COHA have demonstrated clinically meaningful reductions in bleeding, improved procedural visibility, and favourable patient outcomes across gastrointestinal, surgical, and trauma indications. Alongside these, a rapidly expanding portfolio of pre-clinical sprayable biomaterials spanning mineral, polysaccharide, protein, peptide, hydrogel, and nano-engineered platforms offers new opportunities to address unmet needs in non-compressible and complex haemorrhage. This review provides a comprehensive and integrated analysis of haemostatic sprays, covering material classes, mechanisms of action, clinical applications, and translational performance. Key challenges, including tissue irritation, thromboembolic risk, impaired visualisation, and limitations in adhesion or durability, are critically examined, together with emerging strategies to improve biocompatibility, targeting accuracy, and suitability for pre-hospital or low-resource settings. By synthesizing current clinical evidence with advances in biomaterial design and spray-delivery technologies, this review defines the present capabilities of haemostatic sprays and outlines a roadmap for their next-generation development. These innovations are poised to further enhance the safety, speed, and effectiveness of bleeding control in modern surgical and emergency care. Commercial and pre-clinical haemostatic sprays: applications, formulations and mechanism overview. • Reviews material design principles driving performance of emerging haemostatic sprays • Compares clinical products with next-generation bioengineered spray platforms • Links spray chemistry and structure to haemostasis, adhesion, and wound healing • Summarises advances in hydrogels, polysaccharides, clays and nano-enabled systems • Outlines translational challenges and design rules for future haemostatic sprays

Emerging haemostatic sprays: From material design to clinical translation

Key Points

Abstract

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