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DOI: 10.1055/a-1586-2733
Phantom study for comparison between computed tomography- and C-Arm computed tomography-guided puncture applied by residents in radiology
Article in several languages: English | deutsch Supported by: Deutsche Röntgengesellschaft e. V. (Forscher-für-die-Zukunft)
Abstract
Purpose Comparison of puncture deviation and puncture duration between computed tomography (CT)- and C-arm CT (CACT)-guided puncture performed by residents in training (RiT).
Methods In a cohort of 25 RiTs enrolled in a research training program either CT- or CACT-guided puncture was performed on a phantom. Prior to the experiments, the RiT’s level of training, experience playing a musical instrument, video games, and ball sports, and self-assessed manual skills and spatial skills were recorded. Each RiT performed two punctures. The first puncture was performed with a transaxial or single angulated needle path and the second with a single or double angulated needle path. Puncture deviation and puncture duration were compared between the procedures and were correlated with the self-assessments.
Results RiTs in both the CT guidance and CACT guidance groups did not differ with respect to radiologic experience (p = 1), angiographic experience (p = 0.415), and number of ultrasound-guided puncture procedures (p = 0.483), CT-guided puncture procedures (p = 0.934), and CACT-guided puncture procedures (p = 0.466). The puncture duration was significantly longer with CT guidance (without navigation tool) than with CACT guidance with navigation software (p < 0.001). There was no significant difference in the puncture duration between the first and second puncture using CT guidance (p = 0.719). However, in the case of CACT, the second puncture was significantly faster (p = 0.006). Puncture deviations were not different between CT-guided and CACT-guided puncture (p = 0.337) and between the first and second puncture of CT-guided and CACT-guided puncture (CT: p = 0.130; CACT: p = 0.391). The self-assessment of manual skills did not correlate with puncture deviation (p = 0.059) and puncture duration (p = 0.158). The self-assessed spatial skills correlated positively with puncture deviation (p = 0.011) but not with puncture duration (p = 0.541).
Conclusion The RiTs achieved a puncture deviation that was clinically adequate with respect to their level of training and did not differ between CT-guided and CACT-guided puncture. The puncture duration was shorter when using CACT. CACT guidance with navigation software support has a potentially steeper learning curve. Spatial skills might accelerate the learning of image-guided puncture.
Key Points:
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The CT-guided and CACT-guided puncture experience of the RiTs selected as part of the program “Researchers for the Future” of the German Roentgen Society was adequate with respect to the level of training.
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Despite the lower collective experience of the RiTs with CACT-guided puncture with navigation software assistance, the learning curve regarding CACT-guided puncture may be faster compared to the CT-guided puncture technique.
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If the needle path is complex, CACT guidance with navigation software assistance might have an advantage over CT guidance.
Citation Format
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Meine TC, Hinrichs JB, Werncke T et al. Phantom study for comparison between computed tomography- and C-Arm computed tomography-guided puncture applied by residents in radiology. Fortschr Röntgenstr 2022; 194: 272 – 280
Publication History
Received: 21 February 2021
Accepted: 27 July 2021
Article published online:
18 November 2021
© 2021. Thieme. All rights reserved.
Georg Thieme Verlag KG
Rüdigerstraße 14, 70469 Stuttgart, Germany
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References
- 1 Helmberger T, Martí-Bonmatí L, Pereira P. et al. Radiologists’ leading position in image-guided therapy. Insights Imaging 2013; 4: 1-7
- 2 Ahmed M, Brace CL, Lee FT. et al. Principles of and Advances in Percutaneous Ablation. Radiology 2011; 258: 351-369
- 3 Goldberg SN, Gazelle GS, Mueller PR. Thermal Ablation Therapy for Focal Malignancy: A Unified Approach to Underlying Principles, Techniques, and Diagnostic Imaging Guidance. American Journal of Roentgenology 2000; 174: 323-331
- 4 Zhao G, Shi X, Sun W. et al. Factors affecting the accuracy and safety of computed tomography-guided biopsy of intrapulmonary solitary nodules ≤30 mm in a retrospective study of 155 patients. Experimental and Therapeutic Medicine 2017; 13: 1986-1992
- 5 Charboneau JW, Reading CC, Welch TJ. CT and sonographically guided needle biopsy: current techniques and new innovations. American Journal of Roentgenology 1990; 154: 1-10
- 6 Silverman SG, Tuncali K, Adams DF. et al. CT Fluoroscopy-guided Abdominal Interventions: Techniques, Results, and Radiation Exposure. Radiology 1999; 212: 673-681
- 7 Sarti M, Brehmer WP, Gay SB. Low-Dose Techniques in CT-guided Interventions. RadioGraphics 2012; 32: 1109-1119
- 8 Racadio JM, Babic D, Homan R. et al. Live 3D Guidance in the Interventional Radiology Suite. American Journal of Roentgenology 2007; 189: W357-W364
- 9 Braak SJ, van Strijen MJL, van Es HW. et al. Effective Dose during Needle Interventions: Cone-beam CT Guidance Compared with Conventional CT Guidance. Journal of Vascular and Interventional Radiology 2011; 22: 455-461
- 10 Busser WMH, Braak SJ, Fütterer JJ. et al. Cone beam CT guidance provides superior accuracy for complex needle paths compared with CT guidance. BJR 2013; 86: 20130310
- 11 Jin KN, Park CM, Goo JM. et al. Initial experience of percutaneous transthoracic needle biopsy of lung nodules using C-arm cone-beam CT systems. Eur Radiol 2010; 20: 2108-2115
- 12 Choo JY, Park CM, Lee NK. et al. Percutaneous transthoracic needle biopsy of small (≤1 cm) lung nodules under C-arm cone-beam CT virtual navigation guidance. Eur Radiol 2013; 23: 712-719
- 13 Higashihara H, Osuga K, Onishi H. et al. Diagnostic accuracy of C-arm CT during selective transcatheter angiography for hepatocellular carcinoma: comparison with intravenous contrast-enhanced, biphasic, dynamic MDCT. Eur Radiol 2012; 22: 872-879
- 14 Braak SJ, van Melick HHE, Onaca MG. et al. 3D cone-beam CT guidance, a novel technique in renal biopsy—results in 41 patients with suspected renal masses. Eur Radiol 2012; 22: 2547-2552
- 15 Lee WJ, Chong S, Seo JS. et al. Transthoracic fine-needle aspiration biopsy of the lungs using a C-arm cone-beam CT system: diagnostic accuracy and post-procedural complications. BJR 2012; 85: e217-e222
- 16 Hwang HS, Chung MJ, Lee JW. et al. C-Arm Cone-Beam CT-Guided Percutaneous Transthoracic Lung Biopsy: Usefulness in Evaluation of Small Pulmonary Nodules. American Journal of Roentgenology 2010; 195: W400-W407
- 17 Gosling AF, Kendrick DE, Kim AH. et al. Simulation of carotid artery stenting reduces training procedure and fluoroscopy times. Journal of Vascular Surgery 2017; 66: 298-306
- 18 Prenner SB, Wayne DB, Sweis RN. et al. Simulation-based education leads to decreased use of fluoroscopy in diagnostic coronary angiography. Catheter Cardiovasc Interv 2018; 91: 1054-1059
- 19 Bundesärztekammer A der deutschen Ä. (Muster-)Weiterbildungsordnung 2018. Im Internet (Stand: 01.08.2020): 2020 https://www.bundesaerztekammer.de/fileadmin/user_upload/downloads/pdf-Ordner/Weiterbildung/20200428_MWBO_2018.pdf
- 20 Abi-Jaoudeh N, Kruecker J, Kadoury S. et al. Multimodality image fusion-guided procedures: technique, accuracy, and applications. Cardiovasc Intervent Radiol 2012; 35: 986-998
- 21 Abi-Jaoudeh N, Fisher T, Jacobus J. et al. Prospective Randomized Trial for Image-Guided Biopsy Using Cone-Beam CT Navigation Compared with Conventional CT. J Vasc Interv Radiol 2016; 27: 1342-1349
- 22 Wiedenbauer G, Jansen-Osmann P. Manual training of mental rotation in children. Learning and Instruction 2008; 18: 30-41