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Development of an In Situ Printing System With Human Platelet Lysate-Based Bio-Adhesive to Treat Corneal Perforations

Jingjing You, Hannah Frazer, Sepidar Sayyar, Zhi Chen, Xiao Liu, Adam Taylor, Benjamin Filippi, Stephen Beirne, Innes Wise, Constantinos Petsoglou, Chris Hodge, Gordon G. Wallace, Gerard Sutton

2022Translational Vision Science & Technology13 citationsDOIOpen Access PDF

Abstract

Purpose: Corneal perforation is a clinical emergency that can result in blindness. Currently corneal perforations are treated either by cyanoacrylate glue which is toxic to corneal cells, or by using commercial fibrin glue for small perforations. Both methods use manual delivery which lead to uncontrolled application of the glues to the corneal surface. Therefore, there is a need to develop a safe and effective alternative to artificial adhesives. Methods: Previously, our group developed a transparent human platelet lysate (hPL)-based biomaterial that accelerated corneal epithelial cells healing in vitro. This biomaterial was further characterized in this study using rheometry and adhesive test, and a two-component delivery system was developed for its application. An animal trial (5 New Zealand white rabbits) to compare impact of the biomaterial and cyanoacrylate glue (control group) on a 2 mm perforation was conducted to evaluate safety and efficacy. Results: The hPL-based biomaterial showed higher adhesiveness compared to commercial fibrin glue. Treatment rabbits had lower pain scores and faster recovery, despite generating similar scar-forming structure compared to controls. No secondary corneal ulcer was generated in rabbits treated with the bio-adhesive. Conclusions: This study reports an in situ printing system capable of delivering a hPL-based, transparent bio-adhesive and successfully treating small corneal perforations. The bio-adhesive-treated rabbits recovered faster and required no additional analgesia. Translational Relevance: The developed in situ hPL bio-adhesives treatment represents a new format of treating corneal perforation that is easy to use, allows for accurate application, and can be a potentially effective and pain relief treatment.

Topics & Concepts

CyanoacrylateBiomaterialFibrin gluePerforationAdhesiveCorneal perforationBiomedical engineeringMedicineCorneaSurgeryPlatelet lysateOphthalmologyMaterials sciencePathologyNanotechnologyMesenchymal stem cellLayer (electronics)PunchingMetallurgyCorneal Surgery and TreatmentsSurgical Sutures and AdhesivesOcular Surface and Contact Lens
Development of an In Situ Printing System With Human Platelet Lysate-Based Bio-Adhesive to Treat Corneal Perforations | Litcius