View clinical trials related to Breast Implant Infection.
Filter by:Infections following postmastectomy breast reconstruction can compromise surgical outcomes and lead to significant morbidity. The aim of this study was to determine factors associated with infection following two-stage implant-based reconstruction.
The goal of this retrospective observational trial is to compare two different devices, used in implant-based breast reconstruction, called acellular dermal matrices, which are a sort of collagen patch that integrates with the tissues of the patient and helps in contrasting the collateral effects of radiotherapy (capsular contracture, implant loss) The main questions the study aims to answer are: - is one of the two matrices better than the other? (better results with fewer complications) - is there a group of patients who benefit more than another from the use of this type of devices? - is there an adm which works better in one specific subgroup of patients? Participants have undergone mastectomy, radiotherapy and implant reconstruction with the aid of two different kinds of acellular dermal matrices. Researchers will compare patients who receive the porcine-derived adm and the patients who receive bovine-derived adm to see if there is a difference in terms of capsular contracture reduction, aestethic result and complications.
Breast implants, either cosmetic or reconstructive, are among the most common procedures performed by plastic surgeons. Bacterial infections or biofilms are implicated in the majority of breast implant complications including infection requiring explantation, capsular contracture (CC), and/or breast-implant associated anaplastic large cell lymphoma (BIA-ALCL). The research team, which has already extensively characterized bacterial pathogenesis in the urinary tract and designed non-antibiotic therapeutics to reduce the incidence of catheter-associated urinary tract infections (CAUTIs), and proposal will study bacteria-breast implant interactions and explore further the impact of the breast microbiome. The proposed research provides a greater understanding of which bacteria can colonize breast implants, their source, and how effective antibiotic pocket irrigation is at eliminating them, and begins to examine the mechanisms by which bacteria bind and colonize the implant surface. These insights will set the groundwork for developing new therapeutic agents that can disrupt the binding of certain bacteria to breast implants. Strategies that minimize problems bacteria can cause, while avoiding antibiotics, will reduce bacteria-related implant complications, limit antibiotic-related side effects, and reduce bacterial resistance.