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Mechanisms of vascular invasion after cartilage injury and potential engineering cartilage treatment strategies.

Zitong ZhaoXiaoxian SunPeng-Cheng TuJianchao GuiYang GuoYafeng ZhangMengmin LiuLining WangXinyu ChenLin SiGuangguang LiYa-Lan Pan
Published in: FASEB journal : official publication of the Federation of American Societies for Experimental Biology (2024)
Articular cartilage injury is one of the most common diseases in orthopedic clinics. Following an articular cartilage injury, an inability to resist vascular invasion can result in cartilage calcification by newly formed blood vessels. This process ultimately leads to the loss of joint function, significantly impacting the patient's quality of life. As a result, developing anti-angiogenic methods to repair damaged cartilage has become a popular research topic. Despite this, tissue engineering, as an anti-angiogenic strategy in cartilage injury repair, has not yet been adequately investigated. This exhaustive literature review mainly focused on the process and mechanism of vascular invasion in articular cartilage injury repair and summarized the major regulatory factors and signaling pathways affecting angiogenesis in the process of cartilage injury. We aimed to discuss several potential methods for engineering cartilage repair with anti-angiogenic strategies. Three anti-angiogenic tissue engineering methods were identified, including administering angiogenesis inhibitors, applying scaffolds to manage angiogenesis, and utilizing in vitro bioreactors to enhance the therapeutic properties of cultured chondrocytes. The advantages and disadvantages of each strategy were also analyzed. By exploring these anti-angiogenic tissue engineering methods, we hope to provide guidance for researchers in related fields for future research and development in cartilage repair.
Keyphrases
  • tissue engineering
  • extracellular matrix
  • endothelial cells
  • case report
  • vascular endothelial growth factor
  • signaling pathway
  • risk assessment
  • current status
  • climate change
  • human health
  • single molecule