Bioengineered visible polymeric mesh to enhance urogynaecological health

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Abstract

Pelvic floor disorders, including pelvic organ prolapse and stress urinary incontinence, are prevalent health concerns, affecting approximately 50% of females over their lifetime, with about 75% of women over 65 years of age being impacted. Traditional surgical interventions, such as transvaginal mesh implants, have led to numerous complications, resulting in their prohibition in several countries. This study introduces an innovative composite mesh designed to mitigate these issues by combining polymethylmethacrylate and thermoplastic polyurethane, further enhanced with iodine-doped carbon nanoparticles to enable visibility via medical imaging. The mesh is coated with 2-methacryloyloxyethyl phosphorylcholine polymer to prevent protein adsorption and promote tissue regeneration. In vitro studies showed high cell viability and low protein adsorption, indicating excellent biocompatibility. Implantation of mesh (with or without iodine) in mice revealed no adverse effects on overall animal health. Mouse spleen weight (an indicator of inflammation) was similar between groups; however, levels of some cytokines (i.e., IL-10, IL-17A and GM-CSF) were elevated following implantation of iodinated mesh in mice suggesting that further refinement of the composite mesh is required. Analysis of the fecal microbiome, which is correlated with physiological states, showed that sham and iodinated mesh implant groups maintained consistent microbial profiles with stable diversity (richness and evenness) measures over time. In contrast, the non-iodinated mesh group exhibited decreased species richness post mesh implantation, likely due to a distinct starting microbiome composition prior to implantation. This research is envisaged to contribute to a safer and more effective solution for treating pelvic floor disorders, providing non-invasive post-implantation monitoring and enhanced mechanical compatibility of surgical mesh with native tissue. Our findings demonstrate that this composite mesh possesses mechanical properties that closely mimic human tissue, ensuring biocompatibility, strength, and flexibility without stimulating significant inflammatory or foreign body responses.

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