XMR guided cardiac electrophysiology study and radio frequency ablation

A A Amini; A Manduca; S Hegde; G Sanchez-Ortiz; D Rueckert; R Razavi; D L G Hill

XMR guided cardiac electrophysiology study and radio frequency ablation

A A Amini (Editor), A Manduca (Editor), S Hegde, G Sanchez-Ortiz, D Rueckert, R Razavi, D L G Hill

Research output: Chapter in Book/Report/Conference proceeding › Conference paper

11 Citations (Scopus)

Abstract

Introduction: XMR systems are a new type of interventional facility in which patients can be rapidly transferred between x-ray and MR systems on a floating table. We have previously developed a technique to register MR and x-ray images obtained from such systems. We are carrying out a programme of XMR guided cardiac electrophysiology study (EPS) and radio frequency ablation (RFA). Aim: The aim of our work was to apply our registration technology to XMR guided EPS/RFA in order to integrate anatomical, electrophysiological and motion information. This would assist in guidance and allow us to validate and refine electromechanical models. Method: Registration of the imaging modalities was achieved by a combination of system calibration and real-time optical tracking. Patients were initially imaged using MR imaging. An SSFP volume scan of the heart was acquired for anatomical information, followed by tagged scans for motion information. The patients were then transferred to the x-ray system. Tracked biplane x-ray images were acquired while electrical measurements were made from catheters placed in the heart. The relationship between the MR and x-ray images was determined. The MR volume scan of the heart was segmented and the tagged scans were analysed using a non-rigid registration algorithm to compute motion. The position of catheters was reconstructed within the MR cardiac anatomy. The anatomical, electrophysiological, and motion information were displayed in the same coordinate system. Simulations of electrical depolarisation and contraction were performed using electromechanical models of the myocardium. Results: We present results for 2 initial cases. For patient 1, a contact mapping system was used for the EPS and for patient 2, a non-contact mapping system was used. Conclusions: Our XMR registration technique allows the integration of anatomical, electrophysiological, and motion information for patients undergoing EPS/RFA. This integrated approach has assisted in interventional guidance and has been used to validate electromechanical models of the myocardium.

Original language	English
Title of host publication	PRO BIOMED OPT IMAG
Place of Publication	BELLINGHAM
Publisher	Spie-Int Society Optical Engineering
Pages	10 - 21
Number of pages	12
ISBN (Print)	0-8194-5282-3
Publication status	Published - 2004
Event	Medical Imaging 2004 Conference - San Diego, CA Duration: 1 Jan 2004 → …

Publication series

Name	PROGRESS IN BIOMEDICAL OPTICS AND IMAGING

Conference

Conference	Medical Imaging 2004 Conference
City	San Diego, CA
Period	1/01/2004 → …

Cite this

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title = "XMR guided cardiac electrophysiology study and radio frequency ablation",

abstract = "Introduction: XMR systems are a new type of interventional facility in which patients can be rapidly transferred between x-ray and MR systems on a floating table. We have previously developed a technique to register MR and x-ray images obtained from such systems. We are carrying out a programme of XMR guided cardiac electrophysiology study (EPS) and radio frequency ablation (RFA). Aim: The aim of our work was to apply our registration technology to XMR guided EPS/RFA in order to integrate anatomical, electrophysiological and motion information. This would assist in guidance and allow us to validate and refine electromechanical models. Method: Registration of the imaging modalities was achieved by a combination of system calibration and real-time optical tracking. Patients were initially imaged using MR imaging. An SSFP volume scan of the heart was acquired for anatomical information, followed by tagged scans for motion information. The patients were then transferred to the x-ray system. Tracked biplane x-ray images were acquired while electrical measurements were made from catheters placed in the heart. The relationship between the MR and x-ray images was determined. The MR volume scan of the heart was segmented and the tagged scans were analysed using a non-rigid registration algorithm to compute motion. The position of catheters was reconstructed within the MR cardiac anatomy. The anatomical, electrophysiological, and motion information were displayed in the same coordinate system. Simulations of electrical depolarisation and contraction were performed using electromechanical models of the myocardium. Results: We present results for 2 initial cases. For patient 1, a contact mapping system was used for the EPS and for patient 2, a non-contact mapping system was used. Conclusions: Our XMR registration technique allows the integration of anatomical, electrophysiological, and motion information for patients undergoing EPS/RFA. This integrated approach has assisted in interventional guidance and has been used to validate electromechanical models of the myocardium.",

author = "Amini, {A A} and A Manduca and S Hegde and G Sanchez-Ortiz and D Rueckert and R Razavi and Hill, {D L G}",

year = "2004",

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series = "PROGRESS IN BIOMEDICAL OPTICS AND IMAGING",

publisher = "Spie-Int Society Optical Engineering",

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note = "Medical Imaging 2004 Conference ; Conference date: 01-01-2004",

}

TY - CHAP

T1 - XMR guided cardiac electrophysiology study and radio frequency ablation

AU - Hegde, S

AU - Sanchez-Ortiz, G

AU - Rueckert, D

AU - Razavi, R

AU - Hill, D L G

A2 - Amini, A A

A2 - Manduca, A

PY - 2004

Y1 - 2004

N2 - Introduction: XMR systems are a new type of interventional facility in which patients can be rapidly transferred between x-ray and MR systems on a floating table. We have previously developed a technique to register MR and x-ray images obtained from such systems. We are carrying out a programme of XMR guided cardiac electrophysiology study (EPS) and radio frequency ablation (RFA). Aim: The aim of our work was to apply our registration technology to XMR guided EPS/RFA in order to integrate anatomical, electrophysiological and motion information. This would assist in guidance and allow us to validate and refine electromechanical models. Method: Registration of the imaging modalities was achieved by a combination of system calibration and real-time optical tracking. Patients were initially imaged using MR imaging. An SSFP volume scan of the heart was acquired for anatomical information, followed by tagged scans for motion information. The patients were then transferred to the x-ray system. Tracked biplane x-ray images were acquired while electrical measurements were made from catheters placed in the heart. The relationship between the MR and x-ray images was determined. The MR volume scan of the heart was segmented and the tagged scans were analysed using a non-rigid registration algorithm to compute motion. The position of catheters was reconstructed within the MR cardiac anatomy. The anatomical, electrophysiological, and motion information were displayed in the same coordinate system. Simulations of electrical depolarisation and contraction were performed using electromechanical models of the myocardium. Results: We present results for 2 initial cases. For patient 1, a contact mapping system was used for the EPS and for patient 2, a non-contact mapping system was used. Conclusions: Our XMR registration technique allows the integration of anatomical, electrophysiological, and motion information for patients undergoing EPS/RFA. This integrated approach has assisted in interventional guidance and has been used to validate electromechanical models of the myocardium.

AB - Introduction: XMR systems are a new type of interventional facility in which patients can be rapidly transferred between x-ray and MR systems on a floating table. We have previously developed a technique to register MR and x-ray images obtained from such systems. We are carrying out a programme of XMR guided cardiac electrophysiology study (EPS) and radio frequency ablation (RFA). Aim: The aim of our work was to apply our registration technology to XMR guided EPS/RFA in order to integrate anatomical, electrophysiological and motion information. This would assist in guidance and allow us to validate and refine electromechanical models. Method: Registration of the imaging modalities was achieved by a combination of system calibration and real-time optical tracking. Patients were initially imaged using MR imaging. An SSFP volume scan of the heart was acquired for anatomical information, followed by tagged scans for motion information. The patients were then transferred to the x-ray system. Tracked biplane x-ray images were acquired while electrical measurements were made from catheters placed in the heart. The relationship between the MR and x-ray images was determined. The MR volume scan of the heart was segmented and the tagged scans were analysed using a non-rigid registration algorithm to compute motion. The position of catheters was reconstructed within the MR cardiac anatomy. The anatomical, electrophysiological, and motion information were displayed in the same coordinate system. Simulations of electrical depolarisation and contraction were performed using electromechanical models of the myocardium. Results: We present results for 2 initial cases. For patient 1, a contact mapping system was used for the EPS and for patient 2, a non-contact mapping system was used. Conclusions: Our XMR registration technique allows the integration of anatomical, electrophysiological, and motion information for patients undergoing EPS/RFA. This integrated approach has assisted in interventional guidance and has been used to validate electromechanical models of the myocardium.

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M3 - Conference paper

SN - 0-8194-5282-3

T3 - PROGRESS IN BIOMEDICAL OPTICS AND IMAGING

SP - 10

EP - 21

BT - PRO BIOMED OPT IMAG

PB - Spie-Int Society Optical Engineering

CY - BELLINGHAM

T2 - Medical Imaging 2004 Conference

Y2 - 1 January 2004

ER -

XMR guided cardiac electrophysiology study and radio frequency ablation

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