ABSTRACT
Traumatic arthritis (TA) is one of the common diseases of bone and joint caused by trauma. The main pathological changes are degeneration of articular cartilage and secondary hyperplasia and ossification of cartilage. The main clinical manifestations are joint pain and dysfunction of movement. Its pathogenesis is still unclear. At present, the treatment of TA is based mainly on symptoms rather than etiology, including physical therapy, drug treatment, surgical treatment, etc. Conservative treatment (physical therapy, drug treatment) can only alleviate short-term pain, and the long-term effect is not satisfactory. Thus, patients with middle and late TA tend to choose surgical treatment. At present, the surgical treatment of TA includes arthroscopic debridement, arthrodesis, cartilage repair, osteotomy, artificial joint replacement, 3D printing technology, etc. There are differences in the postoperative efficacy. This article reviews the current situation of surgical treatment for TA.
ABSTRACT
BACKGROUND: Poly(glycerol sebacate) holds excellent and good biocompatibility, flexibility and degradability, which is widely used in soft tissue replacement and tissue engineering, drug delivery carrier, wound dressing, and bone-cartilage regeneration. OBJECTIVE: To summarize the research progress in the optimal synthesis and medical application of poly(glycerol sebacate) and its composites. METHODS: PubMed, Elsevier, CNKI and WanFang databases were retrieved. The key words were “poly(glycerol sebacate), synthesis, cardiac muscle, blood vessels, nerves, skin, drug delivery carrier, wound dressing, bone regeneration” in English and Chinese, respectively. Finally, 43 articles eligible for the inclusion criteria were obtained. RESULTS AND CONCLUSION: In recent years, poly(glycerol sebacate) has attracted much attention because of its many excellent properties. Many basic scientific studies and animal experiments have confirmed that it is suitable for tissue engineering. Conventional poly(glycerol sebacate) curing process requires high temperature, high vacuum and long duration, which prevents the polymer from binding directly to cells or temperature-sensitive molecules, resulting in some limitations in its application. The composite scaffold material synthesized with a variety of other materials can make up for the corresponding shortcomings of its application in myocardial and vascular tissue engineering, drug delivery carrier, nerve guiding materials, skin and wound dressing, and bone-cartilage tissue engineering. At present, most of the studies on poly(glycerol sebacate) composites focus on the cytobiology level, and few studies focus on the mechanism of action in vivo. Further study may develop an important material for tissue replacement.