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CC BY-NC-ND 4.0 · Journal of Clinical Interventional Radiology ISVIR 2020; 4(02): 122-124
DOI: 10.1055/s-0040-1705265
Short Communication

XperCT Sharpening Reconstruction for Cone-Beam Computed Tomography Guided Lung and Bone Interventions

Christopher M. Murphy
1   Division of Interventional Radiology, Department of Radiology, Seattle Children’s Hospital, Seattle, Washington, United States
,
L. Ray Ramoso
1   Division of Interventional Radiology, Department of Radiology, Seattle Children’s Hospital, Seattle, Washington, United States
,
Eric J. Monroe
1   Division of Interventional Radiology, Department of Radiology, Seattle Children’s Hospital, Seattle, Washington, United States
› Institutsangaben
Funding None.
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Abstract

C-arm cone-beam computed tomography (CBCT) is a valuable tool for three-dimensional navigation and mapping in the interventional radiology suite owing to its flexible gantry positioning, real-time three-dimensional volume acquisition, and reduced contrast and radiation use. Reports of CBCT-guided bone and lung interventions are relatively infrequent, however, possibly due in part to the lack of dedicated bone and lung reconstruction algorithms and concerns regarding insufficient lesion conspicuity. Two cases of an ad hoc intraprocedural CBCT sharpening reconstruction are presented in this article.


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Keywords

CBCT - interventional radiology - osteoid osteoma - ablation - biopsy

Introduction

C-arm cone beam computed tomography (CBCT) has been shown to have significant utility for procedural guidance.[1] [2] However, the adoption of CBCT as an adjunctive imaging modality in some arenas has been slowed by image quality limits and concerns over radiation dosing.[3] Particularly in artifact-prone areas such as lung and bone, limits in image detail may encourage the operator to prefer standard computed tomography (CT), ultrasound, magnetic resonance imaging (MRI), or fluoroscopic guidance. Early experience, however, suggests that CBCT provides effective image guidance for bone[4] and lung interventions.[5] [6] [7]

Recent advances in commercially available CBCT systems promise to improve image quality through reduction of noise, decreased radiation exposure,[4] and artifact mitigation. The use of CBCT in guidance for pediatric procedures is likely to increase with reduced radiation dose and improved image detail. Accordingly, this technical report provides a demonstration of improved bone and lung lesion detection in pediatric patients using the Philips XperCT with XperGuide navigation (Philips) where dedicated bone and lung reconstruction algorithms are not yet commercially available. This novel combination of built-in reconstruction algorithms provides increased lesion conspicuity in a sample set of pediatric osteoid osteomas and lung nodules. Evaluation of these algorithms may provide opportunities for further research and use of CBCT in the interventional setting.


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Technique

Written informed consent was obtained from the patients’ parents after a discussion of risks, benefits, and alternatives of the procedure. Planning and procedural imaging were performed in a Philips FD20 angiography suite (aSi detector with CsI scintillator, 40 × 30 cm detector) with Allura Clarity image optimization. A planning CBCT was performed through the body, with no lateral collimation and limited z-axis coverage for the region known to contain the target lesion based on prior imaging. Using the XperCT workstation interface, “New Reconstruction” is selected. The reconstruction volume size is reduced to include the target lesion and percutaneous access route. Preset algorithms of “Stent” and “BMI Noise Reduction” are selected with a 512 × 512 matrix. The reconstructed image set is then used to plan and perform the procedure with navigational overlay.


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Case 1

A 17-year-old male presenting with debilitating pain in the right foot and ankle, partially relieved by nonsteroidal anti-inflammatory medications, underwent successful CBCT-guided percutaneous needle access and microwave ablation ([Fig. 1]). Fluoroscopy time and air kerma were 3.4 minutes and 13 mGy, respectively.

Zoom Image
Fig. 1 A 17-year-old male presented with right cuboid osteoid osteoma. Axial cone-beam computed tomography images (a) before and (b) after the sharpening reconstruction demonstrate the osteoid osteoma (white arrow) as well as the resultant increase in the surrounding trabecular detail.

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Case 2

A 5-year-old female with a history of a right renal Wilms tumor post chemotherapy, resection, and flank radiation presented with a persistent subcentimeter left upper lobe ground-glass opacity lung nodule. Image-guided wire localization was requested to facilitate wedge resection and determine the ongoing treatment regimen. CBCT-guided wire localization was performed successfully ([Fig. 2]), followed by wedge resection demonstrating focal necrosis with histiocytic inflammation consistent with prior tumor and no active malignancy. Fluoroscopy time and air kerma were 2.1 minutes and 22 mGy, respectively.

Zoom Image
Fig. 2 A 5-year-old female presented with an indeterminate left upper lobe pulmonary nodule. Axial cone-beam computed tomography images (a) before and (b) after the sharpening reconstruction demonstrate the lesion (white arrow) as well as the resultant increase in the surrounding parenchymal detail.

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Discussion

The field of application of CBCT is expanding as additional improvements in noise and artifact reduction are producing higher quality images. Improved operator ergonomics, real-time volumetric reconstructions, and comodal overlays provide the interventionalist an increasingly accurate and immediate description of the procedural landscape. In pediatrics, dose-reducing techniques have been shown to preserve image quality while reducing total radiation exposure.[2] In pediatric osteoid osteomas, CBCT has demonstrated similar technical and clinical success, reduced radiation dose, and increased total room utilization time compared with conventional CT guidance.[4] Similarly, reports have demonstrated reduced lung radiation doses in simulated pediatric lung interventions,[6] with successful use in adult lung biopsies for guidance.[7] Published data on use of CBCT in the pediatric lung interventions are comparatively limited.

The primary limitation to the adoption of CBCT in diagnostic and procedural arenas is image quality.[3] While flat-panel detectors offer comparable spatial resolution to standard CT, characteristic artifacts and noise can limit detail in reconstructions.[1] Methods to produce detailed imaging while minimizing radiation or contrast exposure in both pediatric and adult interventional procedures would be highly beneficial. Currently, commercially available systems such as Philips XperCT provide several postacquisition reconstruction options to mitigate noise and artifact in specific imaging scenarios.

This technical report demonstrates improvement in lesion detail in example cases of pediatric lung and bone lesions through a combination of two previously developed CBCT reconstruction routines. Noted incidentally, the adaptive filtering and multipass reconstruction algorithms employed were initially developed for the reduction of artifacts in high-attenuation areas (obese patients and metallic implants).[8] Their combined effect has been shown in our series to improve visibility of lesions as compared with standard CBCT reconstructions, without additional radiation or contrast exposure. Further exploration of the interaction between these filtering algorithms on pediatric lung and bone CBCT acquisitions, including interobserver variability assessment, is needed.


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Conclusion

Until dedicated reconstruction algorithms become commercially available, the ad hoc image sharpening algorithm presented may increase lesion conspicuity and operator confidence during CBCT-guided bone and lung interventions.


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Conflicts of Interest

None.

Acknowledgments

None.

  • References

  • 1 Wallace MJ, Kuo MD, Glaiberman C, Binkert CA, Orth RC, Soulez G. Technology Assessment Committee of the Society of Interventional Radiology. Three-dimensional C-arm cone-beam CT: applications in the interventional suite. J Vasc Interv Radiol 2009; 20 (Suppl. 07) S523-S537
    CrossrefPubMedGoogle Scholar
  • 2 Acord M, Shellikeri S, Vatsky S. et al. Reduced-dose C-arm computed tomography applications at a pediatric institution. Pediatr Radiol 2017; 47 (13) 1817-1824
    CrossrefPubMedGoogle Scholar
  • 3 Hu YH, Fueglistaller R, Myronakis M. et al. Physics considerations in MV-CBCT multi-layer imager design. Phys Med Biol 2018; 63 (12) 125016
    CrossrefPubMedGoogle Scholar
  • 4 Perry BC, Monroe EJ, McKay T, Kanal KM, Shivaram G. Pediatric percutaneous osteoid osteoma ablation: CONE-beam CT with fluoroscopic overlay versus conventional CT guidance. Cardiovasc Intervent Radiol 2017; 40 (10) 1593-1599
    CrossrefPubMedGoogle Scholar
  • 5 Shivaram GM, Gill AE, Monroe EJ, Koo KS, Hawkins CM. Cone-beam computed tomography guidance with navigational overlay for percutaneous lung nodule biopsy. Pediatr Radiol 2018; 8: 1-5
    PubMedGoogle Scholar
  • 6 Ben-Shlomo A, Cohen D, Bruckheimer E. et al. Comparing effective doses during image-guided core needle biopsies with computed tomography versus C-arm cone beam CT using adult and pediatric phantoms. Cardiovasc Intervent Radiol 2016; 39 (05) 732-739
    CrossrefPubMedGoogle Scholar
  • 7 Hwang HS, Chung MJ, Lee JW, Shin SW, Lee KS. C-arm cone-beam CT-guided percutaneous transthoracic lung biopsy: usefulness in evaluation of small pulmonary nodules. AJR Am J Roentgenol 2010; 195 (06) W400-7
    CrossrefPubMedGoogle Scholar
  • 8 Prell D, Kalender WA, Kyriakou Y. Development, implementation and evaluation of a dedicated metal artefact reduction method for interventional flat-detector CT. Br J Radiol 2010; 83 (996) 1052-1062
    CrossrefPubMedGoogle Scholar

Address for correspondence

Eric J. Monroe, MD
Division of Interventional Radiology, Department of Radiology, Seattle Children’s Hospital
4800 Sand Point Way NE, M/S R-5417, Seattle, WA 98105
United States   

Publikationsverlauf

Artikel online veröffentlicht:
14. April 2020

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Thieme Medical and Scientific Publishers Private Ltd.
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  • References

  • 1 Wallace MJ, Kuo MD, Glaiberman C, Binkert CA, Orth RC, Soulez G. Technology Assessment Committee of the Society of Interventional Radiology. Three-dimensional C-arm cone-beam CT: applications in the interventional suite. J Vasc Interv Radiol 2009; 20 (Suppl. 07) S523-S537
    CrossrefPubMedGoogle Scholar
  • 2 Acord M, Shellikeri S, Vatsky S. et al. Reduced-dose C-arm computed tomography applications at a pediatric institution. Pediatr Radiol 2017; 47 (13) 1817-1824
    CrossrefPubMedGoogle Scholar
  • 3 Hu YH, Fueglistaller R, Myronakis M. et al. Physics considerations in MV-CBCT multi-layer imager design. Phys Med Biol 2018; 63 (12) 125016
    CrossrefPubMedGoogle Scholar
  • 4 Perry BC, Monroe EJ, McKay T, Kanal KM, Shivaram G. Pediatric percutaneous osteoid osteoma ablation: CONE-beam CT with fluoroscopic overlay versus conventional CT guidance. Cardiovasc Intervent Radiol 2017; 40 (10) 1593-1599
    CrossrefPubMedGoogle Scholar
  • 5 Shivaram GM, Gill AE, Monroe EJ, Koo KS, Hawkins CM. Cone-beam computed tomography guidance with navigational overlay for percutaneous lung nodule biopsy. Pediatr Radiol 2018; 8: 1-5
    PubMedGoogle Scholar
  • 6 Ben-Shlomo A, Cohen D, Bruckheimer E. et al. Comparing effective doses during image-guided core needle biopsies with computed tomography versus C-arm cone beam CT using adult and pediatric phantoms. Cardiovasc Intervent Radiol 2016; 39 (05) 732-739
    CrossrefPubMedGoogle Scholar
  • 7 Hwang HS, Chung MJ, Lee JW, Shin SW, Lee KS. C-arm cone-beam CT-guided percutaneous transthoracic lung biopsy: usefulness in evaluation of small pulmonary nodules. AJR Am J Roentgenol 2010; 195 (06) W400-7
    CrossrefPubMedGoogle Scholar
  • 8 Prell D, Kalender WA, Kyriakou Y. Development, implementation and evaluation of a dedicated metal artefact reduction method for interventional flat-detector CT. Br J Radiol 2010; 83 (996) 1052-1062
    CrossrefPubMedGoogle Scholar

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Zoom Image
Fig. 1 A 17-year-old male presented with right cuboid osteoid osteoma. Axial cone-beam computed tomography images (a) before and (b) after the sharpening reconstruction demonstrate the osteoid osteoma (white arrow) as well as the resultant increase in the surrounding trabecular detail.
Zoom Image
Fig. 2 A 5-year-old female presented with an indeterminate left upper lobe pulmonary nodule. Axial cone-beam computed tomography images (a) before and (b) after the sharpening reconstruction demonstrate the lesion (white arrow) as well as the resultant increase in the surrounding parenchymal detail.