Applying machine learning methods to enable automatic customisation of knee replacement implants from CT data

Burge, Thomas A.; Jeffers, Jonathan R.T.; Myant, Connor

doi:10.1038/s41598-023-30483-5

Cited by 5 publications

(5 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…As highlighted by recent reports, these trends support the notion that the landscape is steadily shifting towards a point where CAD processes can be fully automated or derived from a simple sketch, scan or photograph supplied by the user. 83 This highlights a growing challenge in design engineering where future users cannot rely on graphical interfaces but must instead be proficient in computer programming to drive automation. Current CAD packages would also require users to spend an unrealistic amount of time to accurately model the multi-scale heterogeneity and complexity of artificial cells, especially if nanofeatures such as lipids, proteins, and nucleic acids were to be included.…”

Section: Computer Aided Design Of Artificial Cells and Tissuesmentioning

confidence: 99%

Towards skin-on-a-chip for screening the dermal absorption of cosmetics

Govey-Scotland,

Johnstone,

Myant

et al. 2023

Lab Chip

View full text Add to dashboard Cite

show abstract

Section: Computer Aided Design Of Artificial Cells and Tissuesmentioning

confidence: 99%

Towards skin-on-a-chip for screening the dermal absorption of cosmetics

Govey-Scotland,

Johnstone,

Myant

et al. 2023

Lab Chip

View full text Add to dashboard Cite

show abstract

“…In recent years, deep learning (DL) approaches have been developed to generate automatic segmentation of various bone structures in CT imaging, which can alleviate user interaction. [6][7][8] The aim of this study is to automate segmentation tasks in the knee prosthesis displacement analysis by Kievit et al using DL. This is another step towards reducing the amount of user interaction and therefore observer variation in knee prosthesis displacement analysis.…”

Section: Introductionmentioning

confidence: 99%

Towards automation in non-invasive measurement of knee implant displacement

Magg,

ter Wee,

Buijs

et al. 2024

Medical Imaging 2024: Computer-Aided Diagnosis

View full text Add to dashboard Cite

Non-invasive measurement of knee implant loosening is important to provide a diagnostic tool for patients with recurrent complaints after a total knee arthroplasty (TKA). Displacement measurements are currently estimated between tibial implant and bone using a loading device, CT imaging and an advanced 3D image analysis workflow. However, user interaction is required within each step of this workflow, especially in the segmentation of implant and bone, increasing the complexity of this task and affecting its reproducibility. A deep learning-based segmentation model can alleviate the workload by increasing automation and reducing the variability of manual segmentation. In this work, we propose a segmentation algorithm for the tibial implant and tibial bone cortex. The automatically obtained segmentations are then introduced in the displacement calculation workflow and four displacement measurements are calculated, namely mean target registration error (mTRE), maximum total point motion (MTPM), magnitude of translation and rotation. Results show that the parameter distributions are similar to the manual approach, with intra-class correlation values ranging from 0.96 to 0.99 for the different displacement measurements. Moreover, the methodological error has a smaller or comparable distribution, showing the feasibility to increase automation in knee implant displacement assessment.

show abstract

“…These individualized patient's specific implants, created from cross-sectional imaging of the lower limb, are designed with the triple target to respect the patient's anatomy, minimize bone cuts, and restore the most physiological joint kinematics possible [5,7]. The incorporation of machine learning in the automatic customization process has further contributed to the accuracy and success of CIM TKR [18], where these prosthesis are now available for primary as well as for revision hinged arthroplasty [19][20][21].…”

Section: Introductionmentioning

confidence: 99%

“…Although their potential clinical benefits is not well established in literature [ 11 , 16 ], recent investigation of the new ORIGIN® CIM prosthesis showed significant improvement in various clinical and patient-reported outcomes including the Knee Society Score (KSS), range of motion, and the Forgotten Joint Score (FJS) at 1-year follow-up [ 17 ]. These individualized patient’s specific implants, created from cross-sectional imaging of the lower limb, are designed with the triple target to respect the patient's anatomy, minimize bone cuts, and restore the most physiological joint kinematics possible [ 5 , 7 ].The incorporation of machine learning in the automatic customization process has further contributed to the accuracy and success of CIM TKR [ 18 ], where these prosthesis are now available for primary as well as for revision hinged arthroplasty [ 19 – 21 ].…”

Section: Introductionmentioning

confidence: 99%

Customized‐individually‐made origin® implants in total knee arthroplasty allow a reliable solution for accurate reproduction of planned implant positioning

Sajan,

Moussa,

Lefèvre

et al. 2023

J. exp. orthop.

View full text Add to dashboard Cite

Purpose To evaluate the accuracy and reproducibility of a patient-specific, customized individually made (CIM) total knee replacement (TKR) using the ORIGIN® prosthesis. Methods This was a prospective study conducted at a University Hospital from January 15, 2019, to April 30, 2021. The study included patients planned for an ORIGIN® CIM TKR procedure. Exclusion criteria included revision surgery, severe deformity, stiffness, or laxity. Evaluations were carried out using computed tomography scans performed 8 weeks preoperatively and 6 weeks postoperatively. The primary outcome measurements were the preoperative, planned, and postoperative CT scan alignment measurements including the Hip-Knee-Ankle (HKA) angle, mechanical Medial Distal Femoral articular surface Angle (mMDFA, distal alpha angle), Posterior Distal femoral articular surface angle (PDFA, posterior alpha angle), mechanical Medial Proximal Tibial articular surface Angle (mMPTA, beta angle) and posterior proximal tibial angle (PPTA). Secondary outcomes included the accuracy of implant positioning with percentage of outliers at 2° and 3° Results The study encompassed 51 knees from 50 patients with mean age of 68.1 (SD = 8.89). The overall HKA angle deviated by -0.93° [95% CI: -1.45; -0.43], and the PDFA angle by -0.61° [95% CI: -1.07; -0.15], while the mMPTA exceeded planned values by 1.00° [95% CI: 0.57; 1.43]. The 3° outliers rate ranged from 3.9% for the mMPTA to 7.8% for the HKA alignment, with no outliers in mMDFA and PPTA. Similarly, the 2° outliers rate ranged from 15.7% for both the PDFA angle and mMPTA to 19.6% for the HKA alignment. The Bland–Altman plots further emphasized the precision of planned and post-operative angles across all measurements. Conclusion The CIM TKR showed high accuracy and reproducibility, closely matching preoperative planning. The weakest accuracy at 3°-outliers is in the reproduction of the HKA alignment at 92.2% (range for all angle: 92.2–100%). Similarly, the weakest accuracy at 2°-outliers is in the reproduction of the HKA alignment at 80.4% (range for all angles: 80.4–92.2%).

show abstract

Applying machine learning methods to enable automatic customisation of knee replacement implants from CT data

Cited by 5 publications

References 33 publications

Towards skin-on-a-chip for screening the dermal absorption of cosmetics

Towards skin-on-a-chip for screening the dermal absorption of cosmetics

Towards automation in non-invasive measurement of knee implant displacement

Customized‐individually‐made origin® implants in total knee arthroplasty allow a reliable solution for accurate reproduction of planned implant positioning

Contact Info

Product

Resources

About