Comparative kinetics of polymerisation of three fibrin sealants and influence on timing of tissue adhesion.

The clinical performance of fibrin sealants may be influenced by physical properties such as elasticity, tensile strength, and ability to adhere to human tissue. These properties are related to the internal structure of the fibrin sealant that builds as it polymerises. Analysis of the minimum polymerisation time to achieve a functional fibrin clot is clinically important. Instant tissue-fibrin sealant adhesion is desirable to ensure that the fibrin sealant functions on contact and remains at the site of application without being washed away by blood or displaced by movement of the target tissue (e.g., the heart or lungs). The physical characteristics of fibrin sealants are related to the extent of fibrin cross-linking. Determination of the polymerisation rate allows calculation of the minimum time required to produce a functional clot. The adhesion characteristics to vital human tissue and kinetics of polymerisation between 20 and 300 seconds postapplication of Vivostat system patient-derived sealant have been analysed and compared to those obtained for two conventional fibrin sealants, Tissucol and Beriplast. Mathematical analysis of the experimental data revealed that polymerisation of Vivostat sealant followed first-order kinetics, whereas that of Beriplast and Tissucol followed second-order kinetics. This study demonstrates that Vivostat sealant polymerises faster than these other conventional fibrin sealants.