Belinda Adamson

Incisional herniation induces decreased abdominal wall compliance via oblique muscle atrophy and fibrosis.

Objective:The purpose of this study is to measure abdominal wall myopathic histologic and mechanical changes during incisional herniation and its effect on incisional hernia repairs. Summary Background Data:Unloaded skeletal muscles undergo characteristic atrophic changes, including change in fiber type composition, decreased cross-sectional area, and pathologic fibrosis. We hypothesize that these atrophic changes decrease muscle elastic properties and may contribute to the high laparotomy wound failure rate observed following incisional hernia repair. Methods:A rat model of chronic incisional hernia formation was used. Failing midline laparotomy incisions developed into incisional hernias. Controls were uninjured and sham laparotomy (healed) groups. Internal oblique muscles were harvested for fiber typing, measurement of cross-sectional area, collagen deposition, and mechanical analysis. Mesh hernia repairs were performed on a second group of rats with chronic incisional hernias or acute anterior abdominal wall myofascial defects. Results:The hernia group developed lateral abdominal wall shortening and oblique muscle atrophy. This was associated with a change in the distribution of oblique muscle fiber types, decreased cross-sectional area, and pathologic fibrosis consistent with myopathic disuse atrophy. These muscles exhibited significant decreased extensibility and increased stiffness. The healed (sham) laparotomy group expressed an intermediate phenotype between the uninjured and hernia groups. Recurrent hernia formation was most frequent in the chronic hernia model, and hernia repairs mechanically disrupted at a lower force compared with nonherniated abdominal walls. Conclusions:The internal oblique muscles of the abdominal wall express a pattern of changes consistent with those seen in chronically unloaded skeletal muscles. The internal oblique muscles become fibrotic during herniation, reducing abdominal wall compliance and increasing the transfer of load forces to the midline wound at the time of hernia repair.

Role of glutathione redox dysfunction in diabetic wounds

We propose that diabetic foot ulcers and diabetic mouse wounds have insufficient glutathione to maintain correct cellular redox potential. Therefore, tissue samples from the wound edge of diabetic foot ulcers, diabetic mice wounds and nondiabetic mice wounds were obtained. Levels of glutathione, cysteine, and mixed protein disulfide were determined and topical application of esterified glutathione in carboxymethylcellulose or carboxymethylcellulose alone was applied to the mice wounds. Diabetic foot ulcer mean glutathione levels were 150.6 pmol/mg in the controls and 53.4 pmol/mg at the wound edge (p < 0.05), while mean cysteine levels were 22.3 pmol/mg in the control and 10.5 pmol/mg at the wound edge (p < 0.05). The mixed protein disulfide levels were elevated in the wounds (14.6 pmol/mg), but not in the control (6.9 pmol/mg) (p < 0.05). The glutathione levels were lower in the diabetic mouse wounds (155 pmol/mg) than the nondiabetic mouse wounds (205 pmol/mg) (p=0.04). The diabetic mouse treated with carboxymethylcellulose alone healed slower (19.5 ± 2.2 days) than the nondiabetic mouse DM (11.5 ± 0.5 days) (p < 0.001). The diabetic mouse that received topical glutathione healed significantly faster (12.5 ± 0.8 days) than the carboxymethylcellulose‐treated mice (19.5 ± 2.2 days) (p < 0.001). Glutathione levels in the diabetic mouse (26.0 pmol/mg) were lower than in the nondiabetic mouse (311.7 pmol/mg) (p < 0.05) after glutathione treatment. In the glutathione‐treated diabetic mouse, the oxidized glutathione was higher (26.7%) than in the nondiabetic mouse (9.9%) (p=0.05). These data suggest that cellular redox dysfunction and lower glutathione levels are present in diabetic foot ulcers and diabetic mouse wounds.

Fascial fibroblast kinetic activity is increased during abdominal wall repair compared to dermal fibroblasts

Abdominal wall fascial wound healing failure is a common clinical problem for general surgeons, manifesting in early postoperative fascial dehiscence as well as delayed development of incisional hernias. We previously reported that abdominal wall fascial incisions normally recover breaking strength faster than simultaneous dermal incisions in a rodent model. The accelerated fascial repair was associated with greater fibroblast cellularity within fascial wounds and increased wound collagen deposition. The current study was designed to determine whether accelerated fascial healing is the result of increased fascial fibroblast kinetic activity as measured by a more efficient fibroblast phenotype for binding to and remodeling a collagen matrix. Using a new model of abdominal wall repair, fibroblast cell cultures were developed from uninjured and wounded fascia and compared to dermal fibroblasts in order to define the fibroproliferative kinetic properties of abdominal wall fibroblasts. Fascial wound fibroblasts produced a more efficient and greater overall collagen lattice compaction compared to dermal fibroblasts. Acute fascial wound fibroblasts also showed enhanced cell proliferation compared to dermal fibroblasts but no significant differences in collagen production when normalized to cell number. These results suggest that fascial fibroblasts express distinct acute repair phenotypes and therefore a specific mechanism for fascial repair following injury.