使用深度学习分割骨骼和软骨测量3英里跑步后胫股关节软骨的应变及恢复情况。

Tibiofemoral cartilage strain and recovery following a 3-mile run measured using deep learning segmentation of bone and cartilage.

作者信息

Bradley Patrick X, Kim-Wang Sophia Y, Blaisdell Brooke S, Riofrio Alexie D, Collins Amber T, Heckelman Lauren N, Obunadike Eziamaka C, Widmyer Margaret R, Paranjape Chinmay S, Crook Bryan S, Lad Nimit K, Sutter Edward G, Mann Brian P, Spritzer Charles E, DeFrate Louis E

机构信息

Department of Mechanical Engineering and Materials Science, Duke University, United States.

Department of Orthopaedic Surgery, Duke University School of Medicine, United States.

出版信息

Osteoarthr Cartil Open. 2024 Dec 5;7(1):100556. doi: 10.1016/j.ocarto.2024.100556. eCollection 2025 Mar.

DOI:10.1016/j.ocarto.2024.100556

PMID:39802079

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11720442/

Abstract

OBJECTIVE

We sought to measure the deformation of tibiofemoral cartilage immediately following a 3-mile treadmill run, as well as the recovery of cartilage thickness the following day. To enable these measurements, we developed and validated deep learning models to automate tibiofemoral cartilage and bone segmentation from double-echo steady-state magnetic resonance imaging (MRI) scans.

DESIGN

Eight asymptomatic male participants arrived at 7 a.m., rested supine for 45 min, underwent pre-exercise MRI, ran 3 miles on a treadmill, and finally underwent post-exercise MRI. To assess whether cartilage recovered to its baseline thickness, participants returned the following morning at 7 a.m., rested supine for 45 min, and underwent a final MRI session. These images were used to generate 3D models of the tibia, femur, and cartilage surfaces at each time point. Site-specific tibial and femoral cartilage thicknesses were measured from each 3D model. To aid in these measurements, deep learning segmentation models were developed.

RESULTS

All trained deep learning models demonstrated repeatability within 0.03 mm or approximately 1 % of cartilage thickness. The 3-mile run induced mean compressive strains of 5.4 % (95 % CI = 4.1 to 6.7) and 2.3 % (95 % CI = 0.6 to 4.0) for the tibial and femoral cartilage, respectively. Furthermore, both tibial and femoral cartilage thicknesses returned to within 1 % of baseline thickness the following day.

CONCLUSIONS

The 3-mile treadmill run induced a significant decrease in both tibial and femoral cartilage thickness; however, this was largely ameliorated the following morning.

摘要

目的

我们试图测量在进行3英里跑步机跑步后即刻胫股关节软骨的变形情况，以及次日软骨厚度的恢复情况。为了能够进行这些测量，我们开发并验证了深度学习模型，以从双回波稳态磁共振成像（MRI）扫描中自动分割胫股关节软骨和骨骼。

设计

八名无症状男性参与者于上午7点到达，仰卧休息45分钟，进行运动前MRI检查，在跑步机上跑3英里，最后进行运动后MRI检查。为了评估软骨是否恢复到基线厚度，参与者于次日上午7点返回，仰卧休息45分钟，并进行最后一次MRI检查。这些图像用于生成每个时间点胫骨、股骨和软骨表面的3D模型。从每个3D模型中测量特定部位的胫骨和股骨软骨厚度。为了辅助这些测量，开发了深度学习分割模型。

结果

所有经过训练的深度学习模型在0.03毫米以内或约为软骨厚度的1%范围内具有可重复性。3英里跑步分别导致胫骨和股骨软骨的平均压缩应变达到5.4%（95%置信区间=4.1%至6.7%）和2.3%（95%置信区间=0.6%至4.0%）。此外，胫骨和股骨软骨厚度在次日均恢复到基线厚度的1%以内。

结论

3英里跑步机跑步导致胫骨和股骨软骨厚度显著降低；然而，在次日上午这种情况在很大程度上得到了改善。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d628/11720442/7695f54b182d/gr1.jpg

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使用深度学习分割骨骼和软骨测量3英里跑步后胫股关节软骨的应变及恢复情况。

Tibiofemoral cartilage strain and recovery following a 3-mile run measured using deep learning segmentation of bone and cartilage.

作者信息

机构信息

出版信息

OBJECTIVE

DESIGN

RESULTS

CONCLUSIONS

目的

设计

结果

结论

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