Principles and Clinical Application of Dual-energy Computed Tomography in the Evaluation of Cerebrovascular Disease

Principles and Clinical Application of Dual-energy Computed Tomography in the Evaluation of Cerebrovascular Disease

Dual-energy computed tomography (DECT) simultaneously acquires images at two X-ray energy levels, at both high- and low-peak voltages (kVp). The material attenuation difference obtained from the two X-ray energies can be processed by software to analyze material decomposition and to create additiona...

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Bibliographic Details
Published in:Journal of clinical imaging science Vol. 6; no. 1; p. 27
Main Authors: Hsu, Charlie, Kwan, Gigi, Singh, Dalveer, Pratap, Jit, Watkins, Trevor
Format: Journal Article
Language:English
Published: United States Wolters Kluwer - Medknow Publications 01-01-2016
Scientific Scholar
Medknow Publications & Media Pvt Ltd
Subjects:
Review
Artifacts
atherosclerotic
plaque
intracranial hemorrhages
multidetector computed tomography
carotid stenosis
cerebrovascular disorders
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Summary:Dual-energy computed tomography (DECT) simultaneously acquires images at two X-ray energy levels, at both high- and low-peak voltages (kVp). The material attenuation difference obtained from the two X-ray energies can be processed by software to analyze material decomposition and to create additional image datasets, namely, virtual noncontrast, virtual contrast also known as iodine overlay, and bone/calcium subtraction images. DECT has a vast array of clinical applications in imaging cerebrovascular diseases, which includes: (1) Identification of active extravasation of iodinated contrast in various types of intracranial hemorrhage; (2) differentiation between hemorrhagic transformation and iodine staining in acute ischemic stroke following diagnostic and/or therapeutic catheter angiography; (3) identification of culprit lesions in intra-axial hemorrhage; (4) calcium subtraction from atheromatous plaque for the assessment of plaque morphology and improved quantification of luminal stenosis; (5) bone subtraction to improve the depiction of vascular anatomy with more clarity, especially at the skull base; (6) metal artifact reduction utilizing virtual monoenergetic reconstructions for improved luminal assessment postaneurysm coiling or clipping. We discuss the physical principles of DECT and review the clinical applications of DECT for the evaluation of cerebrovascular diseases.
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This review article has been previously presented as a poster at the European Congress of Radiology 2016: Hsu CC, Singh D, Kwan GN, Pratap J (2016). Principles and Clinical Application of Dual-Energy CT in the Evaluation of Cerebrovascular Disease. doi: 10.1594/ecr2016/C-0811.
ISSN:2156-7514
2156-5597
2156-7514
DOI:10.4103/2156-7514.185003