Weighting-Based Deep Ensemble Learning for Recognition of Interventionalists' Hand Motions During Robot-Assisted Intravascular Catheterization

Robot-assisted intravascular interventions have evolved as unique treatments approach for cardiovascular diseases. However, the technology currently has low potentials for catheterization skill evaluation, slow learning curve, and inability to transfer experience gained from manual interventions. Th...

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Bibliographic Details
Published inIEEE transactions on human-machine systems Vol. 53; no. 1; pp. 215 - 227
Main Authors Omisore, Olatunji Mumini, Akinyemi, Toluwanimi Oluwadara, Du, Wenjing, Duan, Wenke, Orji, Rita, Do, Thanh Nho, Wang, Lei
Format Journal Article
LanguageEnglish
Published New York IEEE 01.02.2023
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Catheterization
Deep learning
Electromyography
Ensemble learning
Feature extraction
hand motion classification
In vitro methods and tests
Intubation
Learning curves
Machine learning
Manuals
Motion perception
Motion segmentation
Navigation
Recognition
Robot sensing systems
robot- assisted navigation
robotic catheterization
Robots
surface electro- myography (sEMG) control
Surgery
Weighting
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Summary:Robot-assisted intravascular interventions have evolved as unique treatments approach for cardiovascular diseases. However, the technology currently has low potentials for catheterization skill evaluation, slow learning curve, and inability to transfer experience gained from manual interventions. This study proposes a new weighting-based deep ensemble model for recognizing interventionalists' hand motions in manual and robotic intravascular catheterization. The model has a module of neural layers for extracting features in electromyography data, and an ensemble of machine learning methods for classifying interventionalists' hand gestures as one of the six hand motions used during catheterization. A soft-weighting technique is applied to guide the contributions of each base learners. The model is validated with electromyography data recorded during in-vitro and in-vivo trials and labeled as many-to-one sequences. Results obtained show the proposed model could achieve 97.52% and 47.80% recognition performances on test samples in the in-vitro and in-vivo data, respectively. For the latter, transfer learning was applied to update weights from the in-vitro data, and the retrained model was used for recognizing the hand motions in the in-vivo data. The weighting-based ensemble was evaluated against the base learners and the results obtained shows it has a more stable performance across the six hand motion classes. Also, the proposed model was compared with four existing methods used for hand motion recognition in intravascular catheterization. The results obtained show our model has the best recognition performances for both the in-vitro and in-vivo catheterization datasets. This study is developed toward increasing interventionalists' skills in robot-assisted catheterization.
ISSN:2168-2291
2168-2305
DOI:10.1109/THMS.2022.3226038