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27.11.2019 | Interventional

Body interventional procedures: which is the best method for CT guidance?

verfasst von: Jean-Philippe Lustig, Sébastien Aubry, Chrystelle Vidal, Lionel Pazart, Alexandre Moreau-Gaudry, Ivan Bricault

Erschienen in: European Radiology | Ausgabe 3/2020

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Abstract

Objectives

To compare sequential fluoroscopy guidance with spiral guidance in terms of safety, effectiveness, speed and radiation in interventional whole body procedures.

Methods

This study was a retrospective analysis of data from the prospective, randomised controlled, multicentre CTNAV2 study. The present analysis included 385 patients: 247 in the sequential group (SEQ) and 138 in the spiral group (SPI). Safety was assessed by the number of major complications. Effectiveness was measured according to the number of targets reached. Data on procedural time and radiation delivered to patients were also collected.

Results

There was no significant difference between the two groups (SEQ vs SPI) regarding the success rate (99.6% vs 99.3%, p = 0.680), procedural time (7 min 40 s ± 5 min 48 s vs 7 min 13 s ± 7 min 33 s, p = 0.507), or major complications (2.43% vs 5.8%, p = 0.101). Radiation dose to patients was 84% lower in the sequential group (54.8 ± 51.8 mGy cm vs 352.6 ± 404 mGy cm, p < 0.0001).

Conclusions

Sequential CT fluoroscopy-guided whole-body interventional procedures seems to be as safe, effective and fast as spiral guidance, while also yielding a significant decrease in the radiation dose to patients.

Key Points

• Sequential CT fluoroscopy and spiral acquisition are comparable in terms of safety, effectiveness and speed.

• Procedural times are comparable despite an increased number of acquisitions in sequential fluoroscopy.

• Radiation dose to patients is 84% lower in sequential fluoroscopy compared with spiral CT.

Silverman SG, Bloom DA, Seltzer SE, Tempany CM, Adams DF (1992) Needle-tip localization during CT-guided abdominal biopsy: comparison of conventional and spiral CT. AJR Am J Roentgenol 159:1095–1097CrossRef

Katada K, Anno H, Takeshita G et al (1994) Development of realtime CT fluoroscopy. Nihon Igaku Hoshasen Gakkai Zasshi 54:1172–1174PubMed

Paulson EK, Sheafor DH, Enterline DS, McAdams HP, Yoshizumi TT (2001) CT fluoroscopy–guided interventional procedures: techniques and radiation dose to radiologists. Radiology 220:161–167CrossRef

Paprottka PM, Helmberger T, Reiser MF, Trumm CG (2013) Computed tomography guidance: fluoroscopy and more. Radiologe 53:974–985CrossRef

Keat N (2001) Real-time CT and CT fluoroscopy. Br J Radiol 74:1088–1090CrossRef

Joemai RM, Zweers D, Obermann WR, Geleijns J (2009) Assessment of patient and occupational dose in established and new applications of MDCT fluoroscopy. AJR Am J Roentgenol 192:881–886CrossRef

Yueh N, Halvorsen RA Jr, Letourneau JG, Crass JR (1989) Gantry tilt technique for CT-guided biopsy and drainage. J Comput Assist Tomogr 13:182–184CrossRef

Bissoli E, Bison L, Gioulis E et al (2003) Multislice CT fluoroscopy: technical principles, clinical applications and dosimetry. Radiol Med 106:201–212PubMed

Ghaye B, Dondelinger RF, Dewe W (1999) Percutaneous CTguided lung biopsy: sequential versus spiral scanning. A randomized prospective study. Eur Radiol 9:1317–1320CrossRef

10.

Silverman SG, Tuncali K, Adams DF et al (1999) CT fluoroscopyguided abdominal interventions: techniques, results, and radiation exposure. Radiology 212:673–681CrossRef

11.

Sheafor DH, Paulson EK, Kliewer MA et al (2000) Comparison of sonographic and CT guidance techniques: does CT fluoroscopy decrease procedure time? AJR Am J Roentgenol 174:939–942CrossRef

12.

Carlson SK, Bender CE, Classic KL et al (2001) Benefits and safety of CT fluoroscopy in interventional radiologic procedures. Radiology 219:515–520CrossRef

13.

Heck SL, Blom P, Berstad A (2006) Accuracy and complications in computed tomography fluoroscopy-guided needle biopsies of lung masses. Eur Radiol 16:1387–1392CrossRef

14.

Kim GR, Hur J, Lee SM et al (2011) CT fluoroscopy-guided lung biopsy versus conventional CT-guided lung biopsy: a prospective controlled study to assess radiation doses and diagnostic performance. Eur Radiol 21:232–239CrossRef

15.

Prosch H, Stadler A, Schilling M et al (2012) CT fluoroscopyguided vs. multislice CT biopsy mode-guided lung biopsies: accuracy, complications and radiation dose. Eur J Radiol 81:1029–1033CrossRef

16.

Nawfel RD, Judy PF, Silverman SG et al (2000) Patient and personnel exposure during CT fluoroscopy-guided interventional procedures. Radiology 216:180–184CrossRef

17.

Kirchner J, Kickuth R, Laufer U et al (2002) CT fluoroscopyassisted puncture of thoracic and abdominal masses: a randomized trial. Clin Radiol 57:188–192CrossRef

18.

Froelich JJ, Ishaque N, Regn J et al (2002) Guidance of percutaneous pulmonary biopsies with real-time CT fluoroscopy. Eur J Radiol 42:74–79CrossRef

19.

Kloeckner R, dos Santos DP, Schneider J et al (2013) Radiation exposure in CT-guided interventions. Eur J Radiol 82:2253–2257CrossRef

20.

Rouchy RC, Moreau-Gaudry A, Chipon E et al (2017) Evaluation of the clinical benefit of an electromagnetic navigation system for CT-guided interventional radiology procedures in the thoracoabdominal region compared with conventional CT guidance (CTNAV II): study protocol for a randomised controlled trial. Trials 18:306. https://doi.org/10.1186/s13063-017-2049-6 CrossRefPubMedPubMedCentral

21.

Sacks D, McClenny TE, Cardella JF, Lewis CA (2003) Society of Interventional Radiology clinical practice guidelines. J Vasc Interv Radiol 14:S199–S202CrossRef

22.

Leng S, Christner JA, Carlson SK et al (2011) Radiation dose levels for interventional CT procedures. AJRAmJ Roentgenol 197:W97–W103CrossRef

23.

Mellenberg DE, Sato Y, Thompson BH, Warnock NG (1999) Personnel exposure rates during simulated biopsies with a realtime CT scanner. Acad Radiol 6:687–690CrossRef

24.

Moulin B, Tselikas L, de Baère T et al (2019) CT guidance assisted by electromagnetic navigation system for percutaneous fixation by internal cemented screws (FICS). Eur Radiol 12:6243s–6247s

25.

Faiella E, Frauenfelder G, Santucci D et al (2018) Percutaneous low-dose CT-guided lung biopsy with an augmented reality navigation system: validation of the technique on 496 suspected lesions. Clin Imaging 49:101–105CrossRef

26.

Schubert T, Jacob AL, Pansini M et al (2013) CT-guided interventions using a free-hand, optical tracking system: initial clinical experience. Cardiovasc Intervent Radiol 36:1055–1062CrossRef

27.

Hiraki T, Kamegawa T, Matsuno T et al (2019) Robotic needle insertion during computed tomography fluoroscopy-guided biopsy: prospective first-in-human feasibility trial. Eur Radiol 42:74–77

28.

Sarti M, BrehmerWP GSB (2012) Low-dose techniques in CTguided interventions. Radiographics 32:1109–1119CrossRef

29.

Chintapalli KN, Montgomery RS, Hatab M et al (2012) Radiation dose management: part 1, minimizing radiation dose in CT-guided procedures. AJR Am J Roentgenol 198:W347–W351CrossRef

30.

Lucey BC, Varghese JC, Hochberg A et al (2007) CT-guided intervention with low radiation dose: feasibility and experience. AJR Am J Roentgenol 188:1187–1194CrossRef

31.

Dixon RG, Ogden K (2010) Optimizing dose in computed tomographic guided procedures. Tech Vasc Interv Radiol 13:172–175CrossRef

32.

Adiga S, Athreya S (2014) Safety, efficacy, and feasibility of an ultra-low dose radiation protocol for CT-guided percutaneous needle biopsy of pulmonary lesions: initial experience. Clin Radiol 69:709–714CrossRef

Titel: Body interventional procedures: which is the best method for CT guidance?
verfasst von: Jean-Philippe Lustig
Sébastien Aubry
Chrystelle Vidal
Lionel Pazart
Alexandre Moreau-Gaudry
Ivan Bricault
Publikationsdatum: 27.11.2019
Verlag: Springer Berlin Heidelberg
Erschienen in: European Radiology / Ausgabe 3/2020
Print ISSN: 0938-7994
Elektronische ISSN: 1432-1084
DOI: https://doi.org/10.1007/s00330-019-06490-4

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Body interventional procedures: which is the best method for CT guidance?

Abstract

Objectives

Methods

Results

Conclusions

Key Points

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Abstract

Objectives

Methods

Results

Conclusions

Key Points

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