Distinct 3-Dimensional Morphologies of Arthritic Knee Anatomy Exist: CT-Based Phenotyping Offers Outlier Detection in Total Knee Arthroplasty.

IF 4.3 1区医学 Q1 ORTHOPEDICS

Journal of Bone and Joint Surgery, American Volume Pub Date : 2025-08-29 DOI:10.2106/JBJS.24.01466

Joshua J Woo, Sayyida S Hasan, Yibin B Zhang, Danyal H Nawabi, Cory L Calendine, Andrew J Wassef, Antonia F Chen, Viktor E Krebs, Prem N Ramkumar

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引用次数: 0

Abstract

Background: There is no foundational classification that 3-dimensionally characterizes arthritic anatomy to preoperatively plan and postoperatively evaluate total knee arthroplasty (TKA). With the advent of computed tomography (CT) as a preoperative planning tool, the purpose of this study was to morphologically classify pre-TKA anatomy across coronal, axial, and sagittal planes to identify outlier phenotypes and establish a foundation for future philosophical, technical, and technological strategies.

Methods: A cross-sectional analysis was conducted using 1,352 pre-TKA lower-extremity CT scans collected from a database at a single multicenter referral center. A validated deep learning and computer vision program acquired 27 lower-extremity measurements for each CT scan. An unsupervised spectral clustering algorithm morphometrically classified the cohort. The optimal number of clusters was determined through elbow-plot and eigen-gap analyses. Visualization was conducted through t-stochastic neighbor embedding, and each cluster was characterized. The analysis was repeated to assess how it was affected by severe deformity by removing impacted parameters and reassessing cluster separation.

Results: Spectral clustering revealed 4 distinct pre-TKA anatomic morphologies (18.5% Type 1, 39.6% Type 2, 7.5% Type 3, 34.5% Type 4). Types 1 and 3 embodied clear outliers. Key parameters distinguishing the 4 morphologies were hip rotation, medial posterior tibial slope, hip-knee-ankle angle, tibiofemoral angle, medial proximal tibial angle, and lateral distal femoral angle. After removing variables impacted by severe deformity, the secondary analysis again demonstrated 4 distinct clusters with the same distinguishing variables.

Conclusions: CT-based phenotyping established a 3D classification of arthritic knee anatomy into 4 foundational morphologies, of which Types 1 and 3 represent outliers present in 26% of knees undergoing TKA. Unlike prior classifications emphasizing native coronal plane anatomy, 3D phenotyping of knees undergoing TKA enables recognition of outlier cases and a foundation for longitudinal evaluation in a morphologically diverse and growing surgical population. Longitudinal studies that control for implant selection, alignment technique, and applied technology are required to evaluate the impact of this classification in enabling rapid recovery and mitigating dissatisfaction after TKA.

Level of evidence: Prognostic Level II. See Instructions for Authors for a complete description of levels of evidence.

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不同的三维形态的关节炎膝关节解剖存在：基于ct的表型提供异常检测全膝关节置换术。

背景：在术前计划和术后评估全膝关节置换术（TKA）时，没有基本的三维特征关节炎解剖分类。随着计算机断层扫描（CT）作为术前规划工具的出现，本研究的目的是通过冠状面、轴状面和矢状面对tka前的解剖结构进行形态学分类，以识别异常表型，并为未来的哲学、技术和技术策略奠定基础。方法：对从单个多中心转诊中心的数据库中收集的1352张tka前下肢CT扫描进行横断面分析。经过验证的深度学习和计算机视觉程序为每次CT扫描获得27个下肢测量值。一种无监督谱聚类算法对队列进行形态计量分类。通过肘形图和特征间隙分析确定最佳簇数。通过t随机邻居嵌入进行可视化，并对每个聚类进行表征。通过去除影响参数和重新评估聚类分离，重复分析以评估严重畸形对其的影响。结果：光谱聚类显示4种不同的tka前解剖形态（18.5%为1型，39.6%为2型，7.5%为3型，34.5%为4型）。类型1和类型3有明显的异常值。区分4种形态的关键参数是髋关节旋转、胫骨后内侧斜度、髋关节-膝关节-踝关节角、胫股角、胫骨内侧近端角和股骨外侧远端角。在去除受严重畸形影响的变量后，二次分析再次显示了4个具有相同区分变量的不同聚类。结论：基于ct的表型分析将关节炎膝关节解剖结构的3D分类建立为4种基本形态，其中1型和3型代表26%接受TKA的膝关节的异常值。与先前的分类强调原生冠状面解剖不同，接受TKA的膝关节的3D表型可以识别异常病例，并为在形态学多样化和不断增长的手术人群中进行纵向评估奠定基础。需要纵向研究控制种植体选择、对准技术和应用技术，以评估这种分类对TKA后快速恢复和减轻不满的影响。证据等级：预后II级。有关证据水平的完整描述，请参见作者说明。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Bone and Joint Surgery, American Volume 医学-外科

CiteScore

8.90

自引率

7.50%

发文量

660

审稿时长

1 months

期刊介绍： The Journal of Bone & Joint Surgery (JBJS) has been the most valued source of information for orthopaedic surgeons and researchers for over 125 years and is the gold standard in peer-reviewed scientific information in the field. A core journal and essential reading for general as well as specialist orthopaedic surgeons worldwide, The Journal publishes evidence-based research to enhance the quality of care for orthopaedic patients. Standards of excellence and high quality are maintained in everything we do, from the science of the content published to the customer service we provide. JBJS is an independent, non-profit journal.