Farid Badar1, Jihyun Lee1, Xianggui Qu2, Yang Xia3. 1. Department of Physics and Center for Biomedical Research, Oakland University, Rochester, MI 48309, USA. 2. Department of Mathematics and Statistics, Oakland University, Rochester, MI 48309, USA. 3. Department of Physics and Center for Biomedical Research, Oakland University, Rochester, MI 48309, USA. Electronic address: xia@oakland.edu.
Abstract
PURPOSE: This study aimed to establish the topographical and zonal T2 patterns of multi-resolution MRI in medial tibial cartilage in a canine model of osteoarthritis (OA), initiated by the anterior cruciate ligament (ACL) transection surgery, and studied after 8-weeks and 12-weeks post-surgery. METHODS: Articular cartilage from healthy, two stages of contralateral, and of OA knees were quantitatively imaged by the MRI T2 protocols at two imaging resolutions (100 and 17.6 μm/pixel). The zonal T2 changes at five topographical locations (anterior (AMT), exterior (EMT), posterior (PMT), central (CMT) and interior (IMT) medial tibia) and subsequent two averaged regions (covered by meniscus and exposed) were analyzed. At each location, full-thickness cartilage was studied in four sub-tissue zones (superficial, transitional, upper and lower radial zones). RESULTS: Tissue degradation can be detected by measurable changes of T2, which is resolution- and orientation-dependent. T2 changes ranging from +28.82% increase (SZ, PMT) to -23.15% decrease (RZ1, AMT) in healthy to disease (8C), with the largest increase of T2 in the surface tissue. Various location-dependent patterns of degradation are found over the tibial surface, most commonly shown in early-stage OA (8C) on the anterior site, different from the posterior. Finally, the contralateral cartilage has specific degradation patterns, different from those in OA cartilage. CONCLUSIONS: This is the first quantitative and highest multi-resolution characterization of cartilage at five topographical locations over the medial tibial plateau with fine zonal resolution in an animal model of OA, which would benefit future investigation of human OA in clinics.
PURPOSE: This study aimed to establish the topographical and zonal T2 patterns of multi-resolution MRI in medial tibial cartilage in a canine model of osteoarthritis (OA), initiated by the anterior cruciate ligament (ACL) transection surgery, and studied after 8-weeks and 12-weeks post-surgery. METHODS: Articular cartilage from healthy, two stages of contralateral, and of OA knees were quantitatively imaged by the MRI T2 protocols at two imaging resolutions (100 and 17.6 μm/pixel). The zonal T2 changes at five topographical locations (anterior (AMT), exterior (EMT), posterior (PMT), central (CMT) and interior (IMT) medial tibia) and subsequent two averaged regions (covered by meniscus and exposed) were analyzed. At each location, full-thickness cartilage was studied in four sub-tissue zones (superficial, transitional, upper and lower radial zones). RESULTS: Tissue degradation can be detected by measurable changes of T2, which is resolution- and orientation-dependent. T2 changes ranging from +28.82% increase (SZ, PMT) to -23.15% decrease (RZ1, AMT) in healthy to disease (8C), with the largest increase of T2 in the surface tissue. Various location-dependent patterns of degradation are found over the tibial surface, most commonly shown in early-stage OA (8C) on the anterior site, different from the posterior. Finally, the contralateral cartilage has specific degradation patterns, different from those in OA cartilage. CONCLUSIONS: This is the first quantitative and highest multi-resolution characterization of cartilage at five topographical locations over the medial tibial plateau with fine zonal resolution in an animal model of OA, which would benefit future investigation of human OA in clinics.
Authors: K P H Pritzker; S Gay; S A Jimenez; K Ostergaard; J-P Pelletier; P A Revell; D Salter; W B van den Berg Journal: Osteoarthritis Cartilage Date: 2005-10-19 Impact factor: 6.576
Authors: Ji Hyun Lee; Farid Badar; David Kahn; John Matyas; Xianggui Qu; Christopher T Chen; Yang Xia Journal: Connect Tissue Res Date: 2014-03-21 Impact factor: 3.417
Authors: David Kahn; Daniel Mittelstaedt; John Matyas; Xiangui Qu; Ji Hyun Lee; Farid Badar; Clifford Les; Zhiguo Zhuang; Yang Xia Journal: Open Orthop J Date: 2016-11-30