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Main Authors: Lan, Bangyu, Abayazid, Momen, Verdonschot, Nico, Stramigioli, Stefano, Niu, Kenan
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2403.05879
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author Lan, Bangyu
Abayazid, Momen
Verdonschot, Nico
Stramigioli, Stefano
Niu, Kenan
author_facet Lan, Bangyu
Abayazid, Momen
Verdonschot, Nico
Stramigioli, Stefano
Niu, Kenan
contents In Total Knee Replacement Arthroplasty (TKA), surgical robotics can provide image-guided navigation to fit implants with high precision. Its tracking approach highly relies on inserting bone pins into the bones tracked by the optical tracking system. This is normally done by invasive, radiative manners (implantable markers and CT scans), which introduce unnecessary trauma and prolong the preparation time for patients. To tackle this issue, ultrasound-based bone tracking could offer an alternative. In this study, we proposed a novel deep learning structure to improve the accuracy of bone tracking by an A-mode ultrasound (US). We first obtained a set of ultrasound dataset from the cadaver experiment, where the ground truth locations of bones were calculated using bone pins. These data were used to train the proposed CasAtt-UNet to predict bone location automatically and robustly. The ground truth bone locations and those locations of US were recorded simultaneously. Therefore, we could label bone peaks in the raw US signals. As a result, our method achieved sub millimeter precision across all eight bone areas with the only exception of one channel in the ankle. This method enables the robust measurement of lower extremity bone positions from 1D raw ultrasound signals. It shows great potential to apply A-mode ultrasound in orthopedic surgery from safe, convenient, and efficient perspectives.
format Preprint
id arxiv_https___arxiv_org_abs_2403_05879
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Deep Learning based acoustic measurement approach for robotic applications on orthopedics
Lan, Bangyu
Abayazid, Momen
Verdonschot, Nico
Stramigioli, Stefano
Niu, Kenan
Signal Processing
Machine Learning
Robotics
In Total Knee Replacement Arthroplasty (TKA), surgical robotics can provide image-guided navigation to fit implants with high precision. Its tracking approach highly relies on inserting bone pins into the bones tracked by the optical tracking system. This is normally done by invasive, radiative manners (implantable markers and CT scans), which introduce unnecessary trauma and prolong the preparation time for patients. To tackle this issue, ultrasound-based bone tracking could offer an alternative. In this study, we proposed a novel deep learning structure to improve the accuracy of bone tracking by an A-mode ultrasound (US). We first obtained a set of ultrasound dataset from the cadaver experiment, where the ground truth locations of bones were calculated using bone pins. These data were used to train the proposed CasAtt-UNet to predict bone location automatically and robustly. The ground truth bone locations and those locations of US were recorded simultaneously. Therefore, we could label bone peaks in the raw US signals. As a result, our method achieved sub millimeter precision across all eight bone areas with the only exception of one channel in the ankle. This method enables the robust measurement of lower extremity bone positions from 1D raw ultrasound signals. It shows great potential to apply A-mode ultrasound in orthopedic surgery from safe, convenient, and efficient perspectives.
title Deep Learning based acoustic measurement approach for robotic applications on orthopedics
topic Signal Processing
Machine Learning
Robotics
url https://arxiv.org/abs/2403.05879