Pre-clinical assay of the tissue integration and mechanical adhesion of several types of cyanoacrylate adhesives in the fixation of lightweight polypropylene meshes for abdominal hernia repair

Characterization and in vivo evaluation of a fabricated absorbable poly(vinyl alcohol)-based hernia mesh

The most widely taken medical approach toward hernia repair involves the implementation of a prosthetic mesh to cover the herniated site and reinforce the weakened area of the abdominal wall. Biodegradable meshes can serve as biocompatible grafts with a low risk of infection. However, their major complication is associated with a high rate of degradation and hernia recurrence. We proposed a facile and cost-effective method to fabricate a poly(vinyl alcohol)-based mesh, using the solution casting technique. The inclusion of zinc oxide nanoparticles, citric acid, and three cycles of freeze-thaw were intended to ameliorate the mechanical properties of poly(vinyl alcohol). Several characterization, cell culture, and animal studies were conducted. Swelling and water contact angle measurements confirmed good water uptake capacity and wetting behavior of the final mesh sample. The synthesized mesh acquired a high mechanical strength of 52.8 MPa, and its weight loss was decreased to 39 %. No cytotoxicity was found in all samples. In vivo experiments revealed that less adhesion and granuloma formation, greater tissue integration, and notably higher neovascularization rate were resulted from implanting this fabricated hernia mesh, compared to commercial Prolene® mesh. Furthermore, the amount of collagen deposition and influential growth factors were enhanced when rats were treated with the proposed mesh instead of Prolene®.

Prosthetic meshes for hernia repair: State of art, classification, biomaterials, antimicrobial approaches, and fabrication methods

Worldwide, hernia repair represents one of the most frequent surgical procedures encompassing a global market valued at several billion dollars. This type of surgery usually requires the implantation of a mesh that needs the appropriate chemical, physical and biological properties for the type of repair. This review thus presents a description of the types of hernias, current hernia repair methods, and the state of the art of prosthetic meshes for hernia repair providing the most important meshes used in clinical practice by surgeons working in this area classified according to their biological or chemical nature, morphology and whether bioabsorbable or not. We emphasise the importance of surgical site infection in herniatology, how to deal with this microbial problem, and we go further into the future research lines on the production of advanced antimicrobial meshes to improve hernia repair and prevent microbial infections, including multidrug-resistant strains. A great deal of progress has been made in this biomedical field in the last decade. However, we are still far from an ideal antimicrobial mesh that can also provide excellent integration to the abdominal wall, mechanical performance, low visceral adhesion and minimal inflammatory or foreign body reactions, among many other problems.

Antibacterial polypropylene mesh fixation with a cyanoacrylate adhesive improves its response to infection

BACKGROUND

Antibacterial meshes for hernia repair seek to avoid infection in the patient. As these biomaterials are especially prone to bacteria settling at their sutured borders, this study examines whether the use of a cyanoacrylate tissue adhesive could improve mesh behavior at the fixation zones.

METHODS

First, antibacterial polypropylene meshes were prepared by soaking in 0.05% chlorhexidine, and the response of n-hexyl cyanoacrylate to contamination with Staphylococcus aureus ATCC25923 was assessed in vitro. Then, in a preclinical model, partial defects (5 x 3 cm) were created in the abdominal wall of 18 New Zealand White rabbits and repaired with mesh to establish the following 3 study groups: (1) mesh without chlorhexidine fixed with cyanoacrylate, (2) antibacterial mesh fixed with sutures, and (3) antibacterial mesh fixed with cyanoacrylate (n = 6 each). The implants were inoculated with 10⁶ CFU/mL of S aureus. At 14 days after surgery, bacterial adhesion to the implant and its integration within host tissue were determined through microbiological, histological and immunohistochemical procedures.

RESULTS

As observed in vitro, the cyanoacrylate gave rise to a 1.5-cm bacteria-free margin around the prosthetic mesh. In vivo, the tissue adhesive prevented bacterial adhesion to the fixation zones, reducing infection of chlorhexidine-free meshes and optimizing the efficacy of the antibacterial meshes compared with those fixed with sutures.

CONCLUSION

These findings indicated that cyanoacrylate fixation does not affect mesh integration into the host tissue. Likewise, the antibacterial behavior and tissue response of a chlorhexidine-treated polypropylene mesh is improved when cyanoacrylate is used for its fixation.

Two Polyurethane Adhesives for PVDF Fixation Show Superior Biocompatibility in a Rat Model

BACKGROUND

The current standard for open and laparoscopic repair of incisional hernia consist of an abdominal wall augmentation by mesh implantation. However, the ideal fixation method of the prothesis material remains under discussion, due to potential complications of conventional fixation methods such as chronic abdominal pain or intestinal obstruction. As the use of adhesive based mesh fixation is an option of growing interest, the aim of this experimental study was to investigate the strength and biocompatibility of two newly developed polyurethane-based adhesives in comparison to a cyanoacrylatic adhesive, which is currently in clinical use.

METHODS

Two experimental polyurethane/urea-based adhesives (Adhesive-A and Adhesive-B) were compared to a conventional cyanoacrylatic adhesive and an untreated control group. Biomechanical testing was carried out using a pull-out test in uniaxial tensile mode, while biocompatibility assessment was performed in a rat model with 40 Sprague-Dawley rats receiving a subcutaneous implanted PVDF mesh fixed by the corresponding adhesive. Histological and immunohistochemical analysis by a Tissue FAXS system examined the tissue integration of the mesh/adhesive combination and characterized the foreign body reaction.

RESULTS

Biomechanical testing of the mesh/adhesive combinations showed a minimal strength of 15.08 N without a significant difference between the groups. Cellular penetration into the mesh/adhesive interface was significantly improved after application of polyurethane adhesives and Adhesive-A showed a significantly lower migration of CD68 positive cells to the adhesive sites compared to cyanoacrylate after 7 days.

CONCLUSION

The developed polyurethane-based adhesives are a promising alternative with sufficient adhesive strength and superior short-term biocompatibility to cyanoacrylate.

Preparation and Performances of Warp-Knitted Hernia Repair Mesh Fabricated with Chitosan Fiber

In this paper, warp-knitted knitted fabrics with chitosan fibers for ventral hernia repair were fabricated with three kinds of structures. The properties of chitosan fiber, yarns, and fabrics were tested. The results demonstrated that the properties of a mesh fabricated with 1-0/1-2/2-3/2-1// structure were slightly better than those of other fabrics. The mechanical properties of the three produced fabrics were weak. However, the results demonstrated that chitosan meshes have many advantages, such as excellent hygroscopicity, and thermal and antimicrobial properties, which makes them one of the best materials for ventral hernia repair. The findings have theoretical and practical significance for the industrial uses of chitosan in ventral hernia repair.