Department of Biomedical Engineering, Rutgers University, Piscataway, New Jersey, United States of America.
Department of Materials Science and Engineering, Rutgers University, Piscataway, New Jersey, United States of America.
PLoS One. 2022 Oct 25;17(10):e0276626. doi: 10.1371/journal.pone.0276626. eCollection 2022.
Osteoarthritis and rheumatoid arthritis are debilitating conditions, affecting millions of people. Both osteoarthritis and rheumatoid arthritis degrade the articular cartilage (AC) at the ends of long bones, resulting in weakened tissue prone to further damage. This degradation impairs the cartilage's mechanical properties leading to areas of thinned cartilage and exposed bone which compromises the integrity of the joint. No preventative measures exist for joint destruction. Discovering a way to slow the degradation of AC or prevent it would slow the painful progression of the disease, allowing millions to live pain-free. Recently, that the articular injection of the polyphenol epigallocatechin-gallate (EGCG) slows AC damage in an arthritis rat model. It was suggested that EGCG crosslinks AC and makes it resistant to degradation. However, direct evidence that intraarticular injection of EGCG crosslinks cartilage collagen and changes its compressive properties are not known. The aim of this study was to investigate the effects of intraarticular injection of EGCG induced biomechanical properties of AC. We hypothesize that in vivo exposure EGCG will bind and crosslink to AC collagen and alter its biomechanical properties. We developed a technique of nano-indentation to investigate articular cartilage properties by measuring cartilage compressive properties and quantifying differences due to EGCG exposure. In this study, the rat knee joint was subjected to a series of intraarticular injections of EGCG and contralateral knee joint was injected with saline. After the injections animals were sacrificed, and the knees were removed and tested in an anatomically relevant model of nanoindentation. All mechanical data was normalized to the measurements in the contralateral knee to better compare data between the animals. The data demonstrated significant increases for reduced elastic modulus (57.5%), hardness (83.2%), and stiffness (17.6%) in cartilage treated with injections of EGCG normalized to those treated with just saline solution when compared to baseline subjects without injections, with a significance level of alpha = 0.05. This data provides evidence that EGCG treated cartilage yields a strengthened cartilage matrix as compared to AC from the saline injected knees. These findings are significant because the increase in cartilage biomechanics will translate into resistance to degradation in arthritis. Furthermore, the data suggest for the first time that it is possible to strengthen the articular cartilage by intraarticular injections of polyphenols. Although this data is preliminary, it suggests that clinical applications of EGCG treated cartilage could yield strengthened tissue with the potential to resist or compensate for matrix degradation caused by arthritis.
骨关节炎和类风湿关节炎是使人虚弱的疾病,影响着数以百万计的人。骨关节炎和类风湿关节炎都会使长骨末端的关节软骨(AC)退化,导致组织脆弱,容易进一步受损。这种退化会损害软骨的机械性能,导致软骨变薄和暴露的骨区域,从而破坏关节的完整性。目前还没有针对关节破坏的预防措施。发现一种减缓 AC 退化或防止其退化的方法将减缓疾病的痛苦进展,使数百万人免受疼痛之苦。最近,关节内注射多酚表没食子儿茶素没食子酸酯(EGCG)可减缓关节炎大鼠模型中的 AC 损伤。有人认为,EGCG 交联 AC 并使其具有抗降解能力。然而,关于关节内注射 EGCG 交联软骨胶原并改变其压缩性能的直接证据尚不清楚。本研究旨在探讨关节内注射 EGCG 对 AC 生物力学特性的影响。我们假设体内暴露于 EGCG 将与 AC 胶原结合并交联,改变其生物力学特性。我们开发了一种纳米压痕技术来通过测量软骨压缩特性并量化由于 EGCG 暴露而导致的差异来研究关节软骨特性。在这项研究中,大鼠膝关节接受了一系列关节内 EGCG 注射,对侧膝关节注射生理盐水。注射后,处死动物,取出膝关节,并在解剖相关的纳米压痕模型中进行测试。所有机械数据均归一化为对侧膝关节的测量值,以便更好地比较动物之间的数据。与未接受注射的基线受试者相比,用 EGCG 处理的软骨的弹性模量(57.5%)、硬度(83.2%)和刚度(17.6%)归一化后的测量值显著增加,显著性水平为 alpha = 0.05。该数据提供了证据,表明与接受生理盐水注射的膝关节的 AC 相比,EGCG 处理的软骨产生了更强的软骨基质。这些发现意义重大,因为软骨生物力学的增加将转化为关节炎中软骨降解的抵抗力。此外,该数据首次表明,通过关节内注射多酚可以增强关节软骨。尽管这项数据是初步的,但它表明 EGCG 处理的软骨的临床应用可能会产生具有潜在抵抗力或补偿关节炎引起的基质降解的强化组织。
