光学相干断层扫描检测亚临床创伤性软骨损伤。
Optical coherence tomography detection of subclinical traumatic cartilage injury.
机构信息
Cartilage Restoration Laboratory, Department of Orthopaedic Surgery, University of Pittsburgh School of Medicine, Pittsburgh, PA, USA.
出版信息
J Orthop Trauma. 2010 Sep;24(9):577-82. doi: 10.1097/BOT.0b013e3181f17a3b.
OBJECTIVES
Posttraumatic arthritis is a major cause of disability. Current clinical imaging modalities are unable to reliably evaluate articular cartilage damage before surface breakdown, when potentially reversible changes are occurring. Optical coherence tomography (OCT) is a nondestructive imaging technology that can detect degenerative changes in articular cartilage with an intact surface. This study tests the hypothesis that OCT detects acute articular cartilage injury after impact at energy levels resulting in chondrocyte death and microstructural changes, but insufficient to produce macroscopic surface damage.
METHODS
Bovine osteochondral cores underwent OCT imaging and were divided into a control with no impact or were subjected to low (0.175 J) or moderate (0.35 J) energy impact. Cores were reimaged with OCT after impact and the OCT signal intensity quantified. A ratio of the superficial to deep layer intensities was calculated and compared before and after impact. Chondrocyte viability was determined 1 day after impact followed by histology and polarized microscopy.
RESULTS
Macroscopic changes to the articular surface were not observed after low and moderate impact. The OCT signal intensity ratio demonstrated a 27% increase (P = 0.006) after low impact and a 38% increase (P = 0.001) after moderate impact. Cell death increased by 150% (P < 0.001) and 200% (P < 0.001) after low and moderate energy impacts, respectively. When compared with unimpacted controls, both Mankin histology and David-Vaudey polarized microscopy scores increased (P = 0.036 and P = 0.002, respectively) after moderate energy impact.
CONCLUSIONS
This study shows that OCT detects acute cartilage changes after impact injury at levels insufficient to cause visible damage to the articular surface but sufficient to cause chondrocyte death and microscopic matrix damage. This finding supports the use of OCT to detect microstructural subsurface cartilage damage that is poorly visualized with conventional imaging.
目的
创伤后关节炎是导致残疾的主要原因。目前的临床影像学手段无法可靠地评估关节软骨在表面破裂之前的损伤,而此时可能会发生潜在的可逆性变化。光学相干断层扫描(OCT)是一种非破坏性成像技术,可检测到具有完整表面的关节软骨退行性变化。本研究检验了这样一个假设,即 OCT 可以检测到导致软骨细胞死亡和微观结构变化但不足以产生宏观表面损伤的能量水平下撞击后急性关节软骨损伤。
方法
牛骨软骨标本进行 OCT 成像,并分为未受撞击的对照组或接受低(0.175 J)或中(0.35 J)能量撞击的实验组。撞击后再次进行 OCT 成像,并对 OCT 信号强度进行定量分析。计算并比较撞击前后浅层和深层 OCT 信号强度比。撞击后 1 天测定软骨细胞活力,随后进行组织学和偏光显微镜检查。
结果
低能量和中能量撞击后关节表面没有观察到宏观变化。OCT 信号强度比显示,低能量撞击后增加了 27%(P = 0.006),中能量撞击后增加了 38%(P = 0.001)。低能量和中能量撞击后,细胞死亡分别增加了 150%(P < 0.001)和 200%(P < 0.001)。与未撞击的对照组相比,中能量撞击后 Mankin 组织学和 David-Vaudey 偏光显微镜评分均升高(P = 0.036 和 P = 0.002)。
结论
本研究表明,OCT 可检测到不足以导致关节表面可见损伤但足以导致软骨细胞死亡和微观基质损伤的撞击后急性软骨变化。这一发现支持使用 OCT 检测常规成像难以可视化的亚表面软骨微观结构损伤。
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