Deep learning generated lower extremity radiographic measurements are adequate for quick assessment of knee angular alignment and leg length determination

Holden Archer; Seth Reine; Shuda Xia; Louis Camilo Vazquez; Oganes Ashikyan; Parham Pezeshk; Ajay Kohli; Yin Xi; Joel E Wells; Allan Hummer; Matthew Difranco; Avneesh Chhabra

doi:10.1007/s00256-023-04502-5

Deep learning generated lower extremity radiographic measurements are adequate for quick assessment of knee angular alignment and leg length determination

Skeletal Radiol. 2024 May;53(5):923-933. doi: 10.1007/s00256-023-04502-5. Epub 2023 Nov 15.

Authors

Holden Archer¹, Seth Reine¹, Shuda Xia¹, Louis Camilo Vazquez¹, Oganes Ashikyan¹, Parham Pezeshk¹, Ajay Kohli¹, Yin Xi¹, Joel E Wells², Allan Hummer³, Matthew Difranco³, Avneesh Chhabra^{4

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Affiliations

¹ University of Texas Southwestern Medical Center, 5323 Harry Hines Blvd, Dallas, TX, 75390, USA.
² Baylor, Scott, & White, Dallas, TX, USA.
³ IB Lab GmbH, Zehetnergasse 6/2/2, 1140, Vienna, Austria.
⁴ University of Texas Southwestern Medical Center, 5323 Harry Hines Blvd, Dallas, TX, 75390, USA. avneesh.chhabra@utsouthwestern.edu.
⁵ Adjunct Faculty, Johns Hopkins University, Baltimore, MD, USA. avneesh.chhabra@utsouthwestern.edu.
⁶ University of Dallas, Richardson, TX, USA. avneesh.chhabra@utsouthwestern.edu.
⁷ Walton Centre for Neurosciences, Liverpool, UK. avneesh.chhabra@utsouthwestern.edu.

PMID: 37964028
DOI: 10.1007/s00256-023-04502-5

Abstract

Purpose: Angular and longitudinal deformities of leg alignment create excessive stresses across joints, leading to pain and impaired function. Multiple measurements are used to assess these deformities on anteroposterior (AP) full-length radiographs. An artificial intelligence (AI) software automatically locates anatomical landmarks on AP full-length radiographs and performs 13 measurements to assess knee angular alignment and leg length. The primary aim of this study was to evaluate the agreements in LLD and knee alignment measurements between an AI software and two board-certified radiologists in patients without metal implants. The secondary aim was to assess time savings achieved by AI.

Methods: The measurements assessed in the study were hip-knee-angle (HKA), anatomical-tibiofemoral angle (aTFA), anatomical-mechanical-axis angle (AMA), joint-line-convergence angle (JLCA), mechanical-lateral-proximal-femur-angle (mLPFA), mechanical-lateral-distal-femur-angle (mLDFA), mechanical-medial-proximal-tibia-angle (mMPTA), mechanical-lateral-distal-tibia- angle (mLDTA), femur length, tibia length, full leg length, leg length discrepancy (LLD), and mechanical axis deviation (MAD). These measurements were performed by two radiologists and the AI software on 164 legs. Intraclass-correlation-coefficients (ICC) and Bland-Altman analyses were used to assess the AI's performance.

Results: The AI software set incorrect landmarks for 11/164 legs. Excluding these cases, ICCs between the software and radiologists were excellent for 12/13 variables (11/13 with outliers included), and the AI software met performance targets for 11/13 variables (9/13 with outliers included). The mean reading time for the AI algorithm and two readers, respectively, was 38.3, 435.0, and 625.0 s.

Conclusion: This study demonstrated that, with few exceptions, this AI-based software reliably generated measurements for most variables in the study and provided substantial time savings.

Keywords: Artificial intelligence; Deep learning; Knee deformities; Leg length discrepancy; Radiographs.

MeSH terms

Artificial Intelligence
Deep Learning*
Femur
Humans
Knee Joint
Leg
Lower Extremity
Osteoarthritis, Knee*
Retrospective Studies
Tibia