Improving the adhesion, flexibility, and hemostatic efficacy of a sprayable polymer blend surgical sealant by incorporating silica particles

Daristotle, John L.; Zaki, Shadden T.; Lau, Lung W.; Torres, Leopoldo; Zografos, Aristotelis; Srinivasan, Priya; Ayyub, Omar B.; Sandler, Anthony D.

doi:10.1016/j.actbio.2019.04.015

Cited by 42 publications

(34 citation statements)

References 55 publications

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“…To determine the potential immune response to the fast-degrading components of the PSTA, we employed an intraperitoneal space implantation mouse model that can be used to evaluate fibrosis. , Surprisingly, PSTAs composed exclusively of PLCL produced fewer cases of fibrotic adhesions to the fat pads at 3 and 10 days than those that incorporated PLGA (Figure B). In the context of implanted materials, fibrosis may occur either (1) due to chronic inflammation in response to the implanted material or (2) due to acute inflammation from the wound healing response to surgical trauma that inhibits fibrinolysis. − …”

Section: Resultsmentioning

confidence: 99%

Pressure-Sensitive Tissue Adhesion and Biodegradation of Viscoelastic Polymer Blends

Daristotle

Zaki

Lau

et al. 2020

ACS Appl. Mater. Interfaces

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Viscoelastic blends of biodegradable polyesters with low and high molecular weight distributions have remarkably strong adhesion (significantly greater than 1 N/cm2) to soft, wet tissue. Those that transition from viscous flow to elastic, solidlike behavior at approximately 1 Hz demonstrate pressure-sensitivity yet also have sufficient elasticity for durable bonding to soft, wet tissue. The pressure-sensitive tissue adhesive (PSTA) blends produce increasingly stronger pull-apart adhesion in response to compressive pressure application, from 10 to 300 s. By incorporating a stiffer high molecular weight component, the PSTA exhibits dramatically improved burst pressure (greater than 100 kPa) when used as a tissue sealant. The PSTA’s biodegradation mechanism can be switched from erosion (occurring primarily over the first 10 days) to bulk chemical degradation (and minimal erosion) depending on the chemistry of the high molecular weight component. Interestingly, fibrosis toward the PSTA is reduced when fast-occurring erosion is the dominant biodegradation mechanism.

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Section: Resultsmentioning

confidence: 99%

Pressure-Sensitive Tissue Adhesion and Biodegradation of Viscoelastic Polymer Blends

Daristotle

Zaki

Lau

et al. 2020

ACS Appl. Mater. Interfaces

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“…[ 8 ] Although these biomaterials can adhere to tissue surfaces and achieve wound closure, they are associated with the issues of long curing time, weak adhesive strength, and great chance of infectious contaminations. Recently, novel tissue adhesives, for instance, polyethylene glycols (PEG)‐based tissue adhesives, [ 9,10 ] other polymeric hydrogel adhesives, [ 11–13 ] and composite hydrogel adhesives, [ 14 ] have also been developed with enhanced tissue adhesion and shortened gelation time. However, toxic initiator/crosslinking agent, complicated preparation process, and limited degradation have restricted their clinical applications.…”

Section: Introductionmentioning

confidence: 99%

Liquid Bandage Harvests Robust Adhesive, Hemostatic, and Antibacterial Performances as a First‐Aid Tissue Adhesive

Yao

Liu

et al. 2020

Adv Funct Materials

140

134

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Massive bleeding and wound infection after tissue trauma are the major dangerous factors of casualties in disasters; hence, first-aid supplies that can greatly achieve wound closure and effectively control the hemorrhage and infection are urgently needed. Although existing tissue adhesives can adhere to the tissue surfaces and achieve rapid wound closure, most of them have limited hemostatic and antibacterial capacities, making them unsuitable as the first-aid tissue adhesives. In this study, inspired by the inherent hemostatic and antibacterial capacities of chitosan and the excellent tissue integration capacity originating from a Schiff base reaction, liquid bandage (LBA), an in situ imine crosslinking-based photoresponsive chitosan hydrogel (NB-CMC/CMC hydrogel), is developed for emergency wound management. Upon UV irradiation, o-nitrobenzene in modified carboxymethyl chitosan (CMC) converts to o-nitrosobenzaldehyde that subsequently crosslinks with amino groups on tissue surface, which endows the LBA with superior tissue adhesive performance. LBA's hemostatic and antibacterial properties can be tuned by the mass ratio of NB-CMC/CMC. Moreover, it exhibits satisfactory biocompatibility, biodegradability, and the capability to enhance wound healing process. This study sheds new light on the development of a multifunctional hydrogel-based first-aid tissue adhesive that can achieve robust tissue adhesion, effectively control bleeding, prevent bacterial infection, and promote wound healing.

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“…To prevent complications associated with bleeding, current surgical toolboxes offer solutions for wound management based on hemostatic gauzes, tissue adhesives, and sealants . Surgical materials promote blood coagulation using hemostatic biomaterials that can also provide adhesion to tissue surfaces . Apart from bleeding wounds, hemostatic materials could provide improved treatment strategies for vascular hemorrhaging via endovascular embolization, where blood vessels are filled with a biomaterial to avoid tissue rupture.…”

Section: Introductionmentioning

confidence: 99%

Engineered Hemostatic Biomaterials for Sealing Wounds

et al. 2022

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Hemostatic biomaterials show great promise in wound control for the treatment of uncontrolled bleeding associated with damaged tissues, traumatic wounds, and surgical incisions. A surge of interest has been directed at boosting hemostatic properties of bioactive materials via mechanisms triggering the coagulation cascade. A wide variety of biocompatible and biodegradable materials has been applied to the design of hemostatic platforms for rapid blood coagulation. Recent trends in the design of hemostatic agents emphasize chemical conjugation of charged moieties to biomacromolecules, physical incorporation of blood-coagulating agents in biomaterials systems, and superabsorbing materials in either dry (foams) or wet (hydrogel) states. In addition, tough bioadhesives are emerging for efficient and physical sealing of incisions. In this Review, we highlight the biomacromolecular design approaches adopted to develop hemostatic bioactive materials. We discuss the mechanistic pathways of hemostasis along with the current standard experimental procedures for characterization of the hemostasis efficacy. Finally, we discuss the potential for clinical translation of hemostatic technologies, future trends, and research opportunities for the development of next-generation surgical materials with hemostatic properties for wound management.

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Improving the adhesion, flexibility, and hemostatic efficacy of a sprayable polymer blend surgical sealant by incorporating silica particles

Cited by 42 publications

References 55 publications

Pressure-Sensitive Tissue Adhesion and Biodegradation of Viscoelastic Polymer Blends

Pressure-Sensitive Tissue Adhesion and Biodegradation of Viscoelastic Polymer Blends

Liquid Bandage Harvests Robust Adhesive, Hemostatic, and Antibacterial Performances as a First‐Aid Tissue Adhesive

Engineered Hemostatic Biomaterials for Sealing Wounds

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