Intestinal anastomotic leaking, which involves the discharge of chemically aggressive, non‐sterile fluids into the abdomen, remains one of the most dreaded postoperative complications of abdominal surgery. Depending on the site and the patient condition, incidence ranging between 4% and 21% and mortality rates up to 27% are reported. Currently available surgical sealants only poorly address the issue, especially since most commonly used fibrin glues fail due to insufficient adhesion and chemical instability. Here, a chemically highly resistive, leak‐tight, and mucoadhesive hydrogel sealant, which is grafted on the surface of the intestinal wall using a mutually interpenetrating network that traverses hydrogel and tissue is presented. In contrast to clinically used fibrin‐based sealants (including Tachosil), the developed adhesive poly(acrylamide‐methyl acrylate‐acrylic acid) patch does not degrade and exhibits strong tissue adhesion even when exposed to intestinal fluid. The biocompatible hydrogel patch effectively seals anastomotic leaks in ex vivo intestinal models, greatly surpassing commercial sealants (time to patch‐failure >24 h compared to 5 min for commonly used Tachosil). Importantly, the developed adhesive patch paves the way for the application of both mechanically and chemically robust sealants suitable for the treatment and prevention of intestinal leaks.
Acne vulgaris associated with Propionibacterium acnes (P. acnes) remains one of the most common skin diseases, while lacking of effective and non-resistant treatments. Graphene inclusing graphene oxide (GO) and reduced graphene oxide (rGO) have been triggering abundant attentions due to their astonishing performances in multi research areas. Here, the GO and rGO suspensions with different concentrations and sizes against P. acnes were investigated. The higher the concentration while the smaller the size distribution led to the better the antibacterial performance. And the loss of viability of P. acnes can surprisely achieve 72% under a 100 μg 10 000 mesh rGO existed which was induced by physical puncture and oxidative stress. Furthermore, the physiological activities of P. acnes will reduce the GO to rGO which further accelerate its death. This study will provide a rapid, effective and non-resistant method for the treatment of acne.
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