Electromagnetic Tracking for Deep Liver Targets: A preliminary feasibility study

Electromagnetic tracking is a core platform technology in the navigation and visualisation of image-guided procedures. The technology provides high tracking accuracy in non-line-of-sight environments, allowing instrument navigation in locations where optical tracking is not feasible. EMT can be bene...

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Veröffentlicht in:	International journal for computer assisted radiology and surgery 2019-04
Hauptverfasser:	Hinds, Stephen, Jaeger, Herman Alexander, Burke, Richard, O’sullivan, Brodie, Keane, Joseph, Trauzettel, Fabian, Marques, Bruno, Cotin, Stéphane, Bird, Brian, Leira, Hakon, Langø, Thomas, Cantillon-Murphy, Pádraig
Format:	Artikel
Sprache:	eng
Schlagworte:	Cancer Computer Science Electronics Engineering Sciences Life Sciences Medical Imaging
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container_title	International journal for computer assisted radiology and surgery
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creator	Hinds, Stephen Jaeger, Herman Alexander Burke, Richard O’sullivan, Brodie Keane, Joseph Trauzettel, Fabian Marques, Bruno Cotin, Stéphane Bird, Brian Leira, Hakon Langø, Thomas Cantillon-Murphy, Pádraig
description	Electromagnetic tracking is a core platform technology in the navigation and visualisation of image-guided procedures. The technology provides high tracking accuracy in non-line-of-sight environments, allowing instrument navigation in locations where optical tracking is not feasible. EMT can be beneficial in applications such as percutaneous radiofrequency ablation for the treatment of hepatic lesions where the needle tip may be obscured due to difficult liver environments (e.g subcutaneous fat or ablation artefacts). Advances in the field of EMT include novel methods of improving tracking system accuracy, precision and error compensation capabilities, though such system-level improvements cannot be readily incorporated in current therapy applications due to the ‘blackbox’ nature of commercial tracking solving algorithms.This paper defines a software framework to allow novel EMT designs, and improvements become part of the global design process for image-guided interventions. An exemplary framework is implemented in the Python programming language and demonstrated with the open-source Anser EMT system. The framework is applied in the preclinical setting though targeted liver ablation therapy on an animal model.The developed framework was tested with the Anser EMT electromagnetic tracking platform. Liver tumour targeting was performed using the tracking framework with the CustusX navigation platform using commercially available electromagnetically tracked needles. Ablation of two tumours was performed with a commercially available ablation system. Necropsy of the tumours indicated ablations within 5 mm of the tumours.
doi_str_mv	10.1007/s11548-019-01983-5
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The technology provides high tracking accuracy in non-line-of-sight environments, allowing instrument navigation in locations where optical tracking is not feasible. EMT can be beneficial in applications such as percutaneous radiofrequency ablation for the treatment of hepatic lesions where the needle tip may be obscured due to difficult liver environments (e.g subcutaneous fat or ablation artefacts). Advances in the field of EMT include novel methods of improving tracking system accuracy, precision and error compensation capabilities, though such system-level improvements cannot be readily incorporated in current therapy applications due to the ‘blackbox’ nature of commercial tracking solving algorithms.This paper defines a software framework to allow novel EMT designs, and improvements become part of the global design process for image-guided interventions. An exemplary framework is implemented in the Python programming language and demonstrated with the open-source Anser EMT system. The framework is applied in the preclinical setting though targeted liver ablation therapy on an animal model.The developed framework was tested with the Anser EMT electromagnetic tracking platform. Liver tumour targeting was performed using the tracking framework with the CustusX navigation platform using commercially available electromagnetically tracked needles. Ablation of two tumours was performed with a commercially available ablation system. 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subjects	Cancer Computer Science Electronics Engineering Sciences Life Sciences Medical Imaging
title	Electromagnetic Tracking for Deep Liver Targets: A preliminary feasibility study
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