Abstract

Irrigation and débridement are frequently utilized in the management of surgical infections, but even with aggressive débridement, it is difficult to remove all the suture material from the tissues and retained suture material may harbor bacteria and/or biofilm. The degree to which barbed or braided sutures may differentially influence the risk of infection has not been defined in a well-controlled animal model. We compared braided and barbed monofilament sutures after irrigation of an infected mouse air pouch model to determine whether the suture type influenced the effectiveness of the irrigation. After irrigation of infected pouches, sutures were compared for (1) bacterial adherence and bacterial retention; (2) qualitative and quantitative pouch thickness and cellular density; and (3) quantitative biofilm formation. Soft tissue air pouches were created on the backs of 60 female, mature 10-week-old BALB/cJ mice by sequentially introducing air into the subcutaneous tissue and allowing the pouch to mature. The pouches were inoculated with Staphylococcus aureus and braided or barbed monofilament sutures were implanted. Pouch irrigation was performed Day 7 after suture implantation. Suture segments were collected before and after irrigation. After euthanasia on Day 14, pouch tissues with residual suture segments were collected for analysis: microbiologic analysis done using optical density as a measure of the concentration of bacteria in the culture (the larger concentration indicates higher number of bacteria) and histologic evaluation of the pouch tissues were semiquantitative, whereas environmental scanning electron microscopy (ESEM) and confocal analyses of the biofilm and bacteria on the sutures were qualitative. Histologic evaluation of pouch tissue showed all groups had inflammatory responses. Quantitatively microbiology showed no difference in bacterial number calculated from the optical density (OD) values between the two suture materials at any time point in the irrigation group. In the no-irrigation group, for the Day 7 time point, mean (± SD) OD was greater in the barbed than the OD in the braided sutures (0.52 ± 0.12 versus 0.37 ± 0.16, mean difference 0.43 [95% confidence interval, 0.08-0.13]; p = 0.007). Qualitatively, ESEM showed more bacterial retention by braided sutures before and after irrigation. Confocal imaging of the sutures demonstrated penetration of biofilm into the interstices of braided sutures and less adhesion in barbed monofilament sutures. The quantification of the biomass showed no differences between groups at all time points (before-irrigation biomass was 11.2 ± 9.3 for braided versus 5.2 ± 4.7 for barbed sutures, p = 0.196; and after-irrigation biomass was 7.2 ± 7.5 for braided versus 3.3 ± 4.3 for barbed suture, p = 0.259). All sutures can retain bacteria and biofilm, but it is rarely possible to remove all suture material at the time of irrigation to treat infection. After an irrigation procedure, qualitatively braided sutures appeared to harbor more bacteria and to retain more biofilm than barbed monofilaments. When saline irrigation was used to simulate infection treatment in an infected mouse air pouch model, bacteria/biofilm was not completely eliminated from either braided or barbed monofilament sutures. The irrigation appeared to clear more bacteria and biofilm from the monofilament despite having barbs. Unfortunately, current technologies do not allow direct quantitative comparisons of biofilm retention. Clinicians should be aware that in the face of infection, any retained sutures may harbor bacteria despite irrigation.

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