Accuracy Considerations in Image-guided Cardiac Interventions: Experience and Lessons Learned

Overview

Journal Int J Comput Assist Radiol Surg

Publisher Springer

Specialties General Surgery
Radiology

Date 2011 Jun 15

PMID 21671097

Citations 11

Authors

Cristian A Linte

Pencilla Lang

Maryam E Rettmann

Daniel S Cho

David R Holmes 3rd

Richard A Robb

Terry M Peters

Affiliations

Soon will be listed here.

Abstract

Motivation: Medical imaging and its application in interventional guidance has revolutionized the development of minimally invasive surgical procedures leading to reduced patient trauma, fewer risks, and shorter recovery times. However, a frequently posed question with regard to an image guidance system is "how accurate is it?" On one hand, the accuracy challenge can be posed in terms of the tolerable clinical error associated with the procedure; on the other hand, accuracy is bound by the limitations of the system's components, including modeling, patient registration, and surgical instrument tracking, all of which ultimately impact the overall targeting capabilities of the system.

Methods: While these processes are not unique to any interventional specialty, this paper discusses them in the context of two different cardiac image guidance platforms: a model-enhanced ultrasound platform for intracardiac interventions and a prototype system for advanced visualization in image-guided cardiac ablation therapy.

Results: Pre-operative modeling techniques involving manual, semi-automatic and registration-based segmentation are discussed. The performance and limitations of clinically feasible approaches for patient registration evaluated both in the laboratory and in the operating room are presented. Our experience with two different magnetic tracking systems for instrument and ultrasound transducer localization is reported. Ultimately, the overall accuracy of the systems is discussed based on both in vitro and preliminary in vivo experience.

Conclusion: While clinical accuracy is specific to a particular patient and procedure and vastly dependent on the surgeon's experience, the system's engineering limitations are critical to determine whether the clinical requirements can be met.

Citing Articles

Impact of cardiac and respiratory motion on the 3D accuracy of image-guided interventions on monoplane systems.

Bertsche D, Metze P, Schneider L, Vernikouskaya I, Rasche V Int J Comput Assist Radiol Surg. 2023; 19(2):367-374.

PMID: 37477817 PMC: 11341615. DOI: 10.1007/s11548-023-02998-9.

Shape Reconstruction Processes for Interventional Application Devices: State of the Art, Progress, and Future Directions.

Sahu S, Sozer C, Rosa B, Tamadon I, Renaud P, Menciassi A Front Robot AI. 2021; 8:758411.

PMID: 34869615 PMC: 8640970. DOI: 10.3389/frobt.2021.758411.

Technical and clinical study of x-ray-based surface echo probe tracking using an attached fiducial apparatus.

Bodart L, Ciske B, Le J, Reilly N, Deano R, Ewer S Med Phys. 2021; 48(5):2528-2542.

PMID: 33608930 PMC: 8152800. DOI: 10.1002/mp.14790.

Technical Note: On Cardiac Ablation Lesion Visualization for Image-guided Therapy Monitoring.

Linte C, Camp J, Rettmann M, Haemmerich D, Aktas M, Huang D Proc SPIE Int Soc Opt Eng. 2019; 10576.

PMID: 31213732 PMC: 6581517. DOI: 10.1117/12.2322523.

Therapeutic Systems and Technologies: State-of-the-Art Applications, Opportunities, and Challenges.

Almekkawy M, Chen J, Ellis M, Haemmerich D, Holmes D, Linte C IEEE Rev Biomed Eng. 2019; 13:325-339.

PMID: 30951478 PMC: 7341980. DOI: 10.1109/RBME.2019.2908940.

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