Long-term clinical, radiological, and histological follow-up after complex ventral incisional hernia repair using urinary bladder matrix graft reinforcement: a retrospective cohort study

Bioscaffolds derived from xenogeneic extracellular matrix (ECM) have been used in numerous tissue engineering applications. The safety and efficacy of such scaffolds when used for the repair and reconstruction of numerous body tissues including musculoskeletal, cardiovascular, urogenital and integumentary structures has been shown in both preclinical animal studies and in human clinical studies. More than 200,000 human patients have been implanted with xenogeneic ECM scaffolds. These ECM scaffolds are typically prepared from porcine organs such as small intestine or urinary bladder, which are subjected to decellularization and terminal sterilization without significant loss of the biologic effects of the ECM. The composition of these bioscaffolds includes the structural and functional proteins that are part of native mammalian extracellular matrix. The three-dimensional organization of these molecules distinguishes ECM scaffolds from synthetic scaffold materials and is associated with constructive tissue remodeling instead of scar tissue. The biologic response to these xenogeneic bioscaffolds, including the immune response, is discussed herein. Copyright 2004 Elsevier B.V.

A clear definition of "complex (abdominal wall) hernia" is missing, though the term is often used. Practically all "complex hernia" literature is retrospective and lacks proper description of the population. There is need for clarification and classification to improve patient care and allow comparison of different surgical approaches. The aim of this study was to reach consensus on criteria used to define a patient with "complex" hernia.

Given the questionable long-term durability of biologic meshes, additional prosthetic options for ventral hernia repairs (VHR) in contaminated fields are necessary. Recent evidence suggests improved bacterial resistance of reduced-weight, large-pore synthetics, giving a potential mesh alternative for repair of contaminated hernias. We aimed to evaluate the clinical outcomes of 2 institutions' experience implanting lightweight polypropylene synthetic mesh in clean-contaminated and contaminated fields. Open VHRs performed with polypropylene mesh in the retro-rectus position in clean-contaminated and contaminated fields were evaluated. Primary outcomes parameters included surgical site infection, surgical site occurrence, mesh removal, and hernia recurrence. One hundred patients (50 male, 50 female) with a mean age of 60 ± 13 years and a mean body mass index (calculated as kg/m(2)) of 32 ± 9.3 met inclusion criteria. There were 42 clean-contaminated and 58 contaminated cases. The incidence of surgical site occurrence was 26.2% in clean-contaminated cases and 34% in contaminated cases. The 30-day surgical site infection rate was 7.1% for clean-contaminated cases and 19.0% for contaminated cases. There were a total of 7 recurrences with a mean follow-up of 10.8 ± 9.9 months (range 1 to 63 months). Mesh removal was required in 4 patients: 2 due to early anastomotic leaks, 1 due to stomal disruption and retraction in a morbidly obese patient, and 1 from a long-term enterocutaneous fistula. Although perhaps not yet considered standard of care in the United States, we have demonstrated favorable infection, recurrence, and mesh removal rates associated with the use of synthetic mesh in contaminated VHR. Copyright © 2013 American College of Surgeons. Published by Elsevier Inc. All rights reserved.