Throughout the past few years, hernia incidence has remained at a high level worldwide, with more than 20 million people requiring hernia surgery each year. Synthetic hernia meshes play an important role, providing a microenvironment that attracts and harbors host cells and acting as a permanent roadmap for intact abdominal wall reconstruction. Nevertheless, it is still inevitable to cause not-so-trivial complications, especially chronic pain and adhesion. In long-term studies, it was found that the complications are mainly caused by excessive fibrosis from the foreign body reaction (FBR) and infection resulting from bacterial colonization. For a thorough understanding of their complex mechanism and providing a richer background for mesh development, herein, we discuss different clinical mesh products and explore the interactions between their structure and complications. We further explored progress in reducing mesh complications to provide varied strategies that are informative and instructive for mesh modification in different research directions. We hope that this work will spur hernia mesh designers to step up their efforts to develop more practical and accessible meshes by improving the physical structure and chemical properties of meshes to combat the increasing risk of adhesions, infections, and inflammatory reactions. We conclude that further work is needed to solve this pressing problem, especially in the analysis and functionalization of mesh materials, provided of course that the initial performance of the mesh is guaranteed.
Carbon nanotube (CNT) is exhibited outstanding electrical, mechanical, and structural properties. CNT yarn is widely used in textile structures as multifunctional yarn and is suitable as strain sensor. Here, use two methods for braiding CNT yarn into rope to make sensing ropes. The properties of CNT yarn and different ropes were tested, then according to the result the best method was chosen for the preparation of sensing rope. Results show the CNT yarn have enough strength to be used in braiding process, CNT embedded rope structure has more stable sensing property than CNT braided rope structure. The rope has approximately ≥7% resistance change ratio per 10% strain, so the embedded rope structure is the optimal structure for sensing rope. The sensing rope will help to improve the development of strain sensor in textile structure.
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