Dual energy CT

Changed by Andrew Murphy, 5 Jul 2016

Updates to Article Attributes

Body was changed:

Show markup changes

Dual energy CTexplores the different attenuation properties of matter at two energy levels. A lower KvP is associated with increase photoelectric interactions especially in substances with higher atomic number such as iodine and calcium. The attenuation value at two different energies within a voxel can subsequently be analysis using material decomposition technique and post processing of images can provide additional diagnostic value compared to single energy conventional CT.

Imaging protocol and post processing

Currently available 1^st and 2^nd generation Dual energy scanners include 64 slice DECT (Siemens Definition System) and 128 slice DECT (Siemens Flash Definition System).

Two x-ray source, tube A (140 KvP) and tube B (80 KvP or 100KvP) with an angular offset of 90 degrees. Tube A maintains full field of view, however, the FOV for tube B is limited to 26 and 30 cm (Siemens Definition ~~System~~ System and Siemens ~~Flash~~ Flash Definition ~~System~~ System respectively). The radiation dose for DECT is equivalent or less than conventional CT technique.

The acquired images are then automatically ~~reconstructed~~ reconstructed to three separate image sets: 80 kVp, 140 kVp and mixed 80:140 kVp image with weighting factor of 0.4 (40% image information from the 80 kVp image and 60% information from the 140 kVp image). The weighting factors can be adjusted, to achieve the desirable effect. The 80 kvP images have higher contrast attenuation but ~~intrinsically lower~~ intrinsically lower SNR ratio and smaller FOV. The 140 KvP ~~images~~ images have lower contrast ~~attenuation~~ attenuation better SNR and full FOV.

Material decomposition can be further performed on a dedicated workstation to create different image setting including iodine map (virtual contrast image), iodine subtraction (virtual non-contrast ~~image~~ image) and bone mask (bone and calcium subtraction). A further perfusion blood volume colour coded images can be created by using a gray or colour scale. This perfusion blood volume images reflect the lung perfusion at a single time point thus they are only a surrogate perfusion images.

Clinical applications

DECT aortogram- potential to eliminate need for pre ~~contrast~~-contrast image.¹.
DECT aortogram in surveillance of EVAR improves detection of ~~Endoleaks.~~endoleaks ⁴.
~~Suboptimal~~suboptimal contrast injection/triggering- 80 KvP image can be used to improve ~~contrast~~ contrast resolution on either DECT aortogram or DECT pulmonary angiogram studies.².
DECT can reduce volume of contrast injection as 80KvP image improves contrast resolution.².
80 KvP image may have potential to improve subsegmental pulmonary artery perfusion and distal pulmonary embolus detection.².
~~Perfusion~~perfusion blood volume map can be used to identified the segmental or subsegmental areas of lung affected by pulmonary embolus. Review of lung window is paramount as other lung pathology- atelectasis, cardiac motion or ~~strak~~streak artefact can all cause perfusion defects.³.
~~Perfusion~~perfusion of pulmonary nodules and nodes.
~~Subtraction~~subtraction of overlying calcium and bone.

~~For patient information please refer to http://www.insideradiology.com.au/pages/view.php?T_id=128#.VC3W7OsrK_8~~

-Dual energy CT explores the different attenuation properties of matter at two energy levels. A lower KvP is associated with increase photoelectric interactions especially in substances with higher atomic number such as iodine and calcium. The attenuation value at two different energies within a voxel can subsequently be analysis using material decomposition technique and post processing of images can provide additional diagnostic value compared to single energy conventional CT.<h5>Imaging protocol and post processing</h5>Currently available 1st and 2nd generation Dual energy scanners include 64 slice DECT (Siemens Definition System) and 128 slice DECT (Siemens Flash Definition System).Two x-ray source, tube A (140 KvP) and tube B (80 KvP or 100KvP) with an angular offset of 90 degrees. Tube A maintains full field of view, however, the FOV for tube B is limited to 26 and 30 cm (Siemens Definition System and Siemens Flash Definition System respectively). The radiation dose for DECT is equivalent or less than conventional CT technique.The acquired images are then automatically reconstructed to three separate image sets: 80 kVp, 140 kVp and mixed 80:140 kVp image with weighting factor of 0.4 (40% image information from the 80 kVp image and 60% information from the 140 kVp image). The weighting factors can be adjusted, to achieve the desirable effect. The 80 kvP images have higher contrast attenuation but intrinsically lower SNR ratio and smaller FOV. The 140 KvP images have lower contrast attenuation better SNR and full FOV. Material decomposition can be further performed on a dedicated workstation to create different image setting including iodine map (virtual contrast image), iodine subtraction (virtual non-contrast image) and bone mask (bone and calcium subtraction). A further perfusion blood volume colour coded images can be created by using a gray or colour scale. This perfusion blood volume images reflect the lung perfusion at a single time point thus they are only a surrogate perfusion images. <h5>Clinical applications</h5><ul>
~~-<li>DECT aortogram- potential to eliminate need for pre contrast image.1~~
+Dual energy CT explores the different attenuation properties of matter at two energy levels. A lower KvP is associated with increase photoelectric interactions especially in substances with higher atomic number such as iodine and calcium. The attenuation value at two different energies within a voxel can subsequently be analysis using material decomposition technique and post processing of images can provide additional diagnostic value compared to single energy conventional CT.<h5>Imaging protocol and post processing</h5>Currently available 1st and 2nd generation Dual energy scanners include 64 slice DECT (Siemens Definition System) and 128 slice DECT (Siemens Flash Definition System).Two x-ray source, tube A (140 KvP) and tube B (80 KvP or 100KvP) with an angular offset of 90 degrees. Tube A maintains full field of view, however, the FOV for tube B is limited to 26 and 30 cm (Siemens Definition System and Siemens Flash Definition System respectively). The radiation dose for DECT is equivalent or less than conventional CT technique.The acquired images are then automatically reconstructed to three separate image sets: 80 kVp, 140 kVp and mixed 80:140 kVp image with weighting factor of 0.4 (40% image information from the 80 kVp image and 60% information from the 140 kVp image). The weighting factors can be adjusted, to achieve the desirable effect. The 80 kvP images have higher contrast attenuation but intrinsically lower SNR ratio and smaller FOV. The 140 KvP images have lower contrast attenuation better SNR and full FOV. Material decomposition can be further performed on a dedicated workstation to create different image setting including iodine map (virtual contrast image), iodine subtraction (virtual non-contrast image) and bone mask (bone and calcium subtraction). A further perfusion blood volume colour coded images can be created by using a gray or colour scale. This perfusion blood volume images reflect the lung perfusion at a single time point thus they are only a surrogate perfusion images. <h5>Clinical applications</h5><ul>
+<li>DECT aortogram- potential to eliminate need for pre-contrast image 1.</li>
+<li>DECT aortogram in surveillance of EVAR improves detection of endoleaks 4.
~~-<li>DECT aortogram in surveillance of EVAR improves detection of Endoleaks.4 ~~
~~-</li>~~
~~-<li>Suboptimal contrast injection/triggering- 80 KvP image can be used to improve contrast resolution on either DECT aortogram or DECT pulmonary angiogram studies.2 ~~
~~-</li>~~
~~-<li>DECT can reduce volume of contrast injection as 80KvP image improves contrast resolution.2 </li>~~
~~-<li>80 KvP image may have potential to improve subsegmental pulmonary artery perfusion and distal pulmonary embolus detection.2 </li>~~
-<li>Perfusion blood volume map can be used to identified the segmental or subsegmental areas of lung affected by pulmonary embolus. Review of lung window is paramount as other lung pathology- atelectasis, cardiac motion or strak artefact can all cause perfusion defects.3
~~-</li>~~
~~-<li>Perfusion of pulmonary nodules and nodes.</li>~~
~~-<li>Subtraction of overlying calcium and bone. </li>~~
~~-</ul>For patient information please refer to http://www.insideradiology.com.au/pages/view.php?T_id=128#.VC3W7OsrK_8 ~~
+<li>suboptimal contrast injection/triggering- 80 KvP image can be used to improve contrast resolution on either DECT aortogram or DECT pulmonary angiogram studies 2.</li>
+<li>DECT can reduce volume of contrast injection as 80KvP image improves contrast resolution 2. </li>
+<li>80 KvP image may have potential to improve subsegmental pulmonary artery perfusion and distal pulmonary embolus detection 2. </li>
+<li>perfusion blood volume map can be used to identified the segmental or subsegmental areas of lung affected by pulmonary embolus. Review of lung window is paramount as other lung pathology- atelectasis, cardiac motion or streak artefact can all cause perfusion defects 3.</li>
+<li>perfusion of pulmonary nodules and nodes.</li>
+<li>subtraction of overlying calcium and bone. </li>
+</ul>

Sections changed:

Imaging Technology
Radiography

ADVERTISEMENT: Supporters see fewer/no ads

{"current_user":null,"inclusions":[{"imageId":8585892,"studyId":32120,"caseSlug":"dual-energy-ct-thorax-technique-and-application-2","caption":"Case 1: dual energy CT chest ","thumbnail":"https://prod-images-static.radiopaedia.org/images/8585892/0a2346f848a0259bb2041f0e28f450_big_gallery.jpg","isStack":false,"diagnosticCertainty":"not_applicable"},{"imageId":15948293,"studyId":42070,"caseSlug":"endoleak-type-ii-after-evar-on-dual-energy-ct-1","caption":"Case 2: endovascular aneurysm repair","thumbnail":"https://prod-images-static.radiopaedia.org/images/15948293/8345d3e1d08b26a1f2ab913a5fdeec_big_gallery.jpeg","isStack":false,"diagnosticCertainty":null},{"imageId":52890734,"studyId":91634,"caseSlug":"scaphoid-fracture-dual-energy-ct","caption":"Case 3: bone edema","thumbnail":"https://prod-images-static.radiopaedia.org/images/52890734/899cc3f41e0d4092d8f96e282c5fd9_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"confirmed_substantiated"},{"imageId":52948038,"studyId":91978,"caseSlug":"post-thrombectomy-iodine-extravasation-in-ischemic-stroke-dect","caption":"Case 4: post-thrombectomy iodine extravasation","thumbnail":"https://prod-images-static.radiopaedia.org/images/52948038/742226e947d41875b2ddffd4afb596_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"confirmed_substantiated"},{"imageId":41232712,"studyId":70062,"caseSlug":"polyarticular-foot-gout-on-dual-energy-ct","caption":"Case 5: polyarticular foot gout","thumbnail":"https://prod-images-static.radiopaedia.org/images/41232712/16fba1a7ab0f9b1ca1246a737d6f6a_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"confirmed_substantiated"},{"imageId":54364852,"studyId":102842,"caseSlug":"normal-dual-energy-chest-ct-angiography-with-pulmonary-embolism-protocol","caption":"Case 6: iodine map for pulmonary perfusion","thumbnail":"https://prod-images-static.radiopaedia.org/images/54364852/IMAGE_018-189_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"not_applicable"},{"imageId":54708474,"studyId":104595,"caseSlug":"pulmonary-embolism-spectral-ctpa-1","caption":"Case 7a: perfusion defects on spectral CTPA","thumbnail":"https://prod-images-static.radiopaedia.org/images/54708474/CT_PULMONARY_ANGIOGRAM_0163_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"confirmed_substantiated"},{"imageId":54710603,"studyId":104595,"caseSlug":"pulmonary-embolism-spectral-ctpa-1","caption":"Case 7b: perfusion defects on spectral CTPA","thumbnail":"https://prod-images-static.radiopaedia.org/images/54710603/CT_PULMONARY_ANGIOGRAM_20210324_100235_big_gallery.jpeg","isStack":false,"diagnosticCertainty":"confirmed_substantiated"},{"imageId":54710204,"studyId":104597,"caseSlug":"pulmonary-embolism-on-suboptimal-ctpa-spectral-low-monoe","caption":"Case 8: suboptimal CTPA, saved by spectral low monoE","thumbnail":"https://prod-images-static.radiopaedia.org/images/54710204/CT_PULMONARY_ANGIOGRAM_0150_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"confirmed_substantiated"},{"imageId":55228800,"studyId":107732,"caseSlug":"normal-spectral-ctpa","caption":"Case 9: normal spectral CTPA","thumbnail":"https://prod-images-static.radiopaedia.org/images/55228800/CT_PULMONARY_ANGIOGRAM_0049_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"not_applicable"},{"imageId":53457117,"studyId":95871,"caseSlug":"impacted-neck-of-femur-fracture","caption":"Case 10: bone marrow edema due to fracture of the femoral neck","thumbnail":"https://prod-images-static.radiopaedia.org/images/53457117/export--275819550_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"confirmed_substantiated"},{"imageId":63190266,"studyId":140168,"caseSlug":"coronary-cta-dual-energy-3","caption":"Case 11: VMI - 40 keV","thumbnail":"https://prod-images-static.radiopaedia.org/images/63190266/ddc06785e810e68f9c7b2914b667fc4ebf3ab169b20c65880798c5d1c281494d_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"confirmed_substantiated"},{"imageId":63217269,"studyId":138908,"caseSlug":"multivessel-coronary-artery-disease","caption":"Case 11: VMI coronary artery disease","thumbnail":"https://prod-images-static.radiopaedia.org/images/63217269/9313482c125abf54554ab3d53791ce157b10ae826940b47019547e07184787cd_big_gallery.jpeg","isStack":true,"diagnosticCertainty":"confirmed_substantiated"}],"ddx_inclusions":[],"lang":"us"}

Updating… Please wait.

Unable to process the form. Check for errors and try again.

Thank you for updating your details.

Dual energy CT

Updates to Article Attributes

Imaging protocol and post processing

Clinical applications

Articles

By Section:

By System:

Cases

Radiopaedia.org