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SmartCT Soft Tissue Helical

Neuro imaging technology

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SmartCT Soft Tissue Helical creates CBCT images to help spot soft tissue changes in the Angio suite. The new protocol with dual-axis acquisition trajectory and improved reconstruction software results in images with improved image appearance compared to conventional cone beam acquisition techniques. SmartCT Soft Tissue Helical is our improved CBCT protocol for neurovascular care with a fast 8 secs trajectory, metal artifact and motion compensation algorithms to further improve image quality.

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SmartCT empowers you to easily adopt 3D imaging in the lab
SmartCT empowers you to easily adopt 3D imaging in the lab

SmartCT empowers you to easily adopt 3D imaging in the lab

Despite the advantages of 3D imaging, it can still be considered difficult to perform by many users. To take the guesswork out of 3D acquisition, SmartCT provides step-by-step guidance and visual aids during acquisition to help easily acquire 3D images. 3D imaging can enhance diagnostic accuracy [1-3], support improved treatment outcomes[4-6] and increase procedural efficiency in the interventional lab [7].

SmartCT empowers you to easily adopt 3D imaging in the lab

SmartCT empowers you to easily adopt 3D imaging in the lab
Despite the advantages of 3D imaging, it can still be considered difficult to perform by many users. To take the guesswork out of 3D acquisition, SmartCT provides step-by-step guidance and visual aids during acquisition to help easily acquire 3D images. 3D imaging can enhance diagnostic accuracy [1-3], support improved treatment outcomes[4-6] and increase procedural efficiency in the interventional lab [7].

SmartCT empowers you to easily adopt 3D imaging in the lab

Despite the advantages of 3D imaging, it can still be considered difficult to perform by many users. To take the guesswork out of 3D acquisition, SmartCT provides step-by-step guidance and visual aids during acquisition to help easily acquire 3D images. 3D imaging can enhance diagnostic accuracy [1-3], support improved treatment outcomes[4-6] and increase procedural efficiency in the interventional lab [7].
Click here for more information
SmartCT empowers you to easily adopt 3D imaging in the lab
SmartCT empowers you to easily adopt 3D imaging in the lab

SmartCT empowers you to easily adopt 3D imaging in the lab

Despite the advantages of 3D imaging, it can still be considered difficult to perform by many users. To take the guesswork out of 3D acquisition, SmartCT provides step-by-step guidance and visual aids during acquisition to help easily acquire 3D images. 3D imaging can enhance diagnostic accuracy [1-3], support improved treatment outcomes[4-6] and increase procedural efficiency in the interventional lab [7].
Control advanced 3D visualization and measurement tools at tableside​
Control advanced 3D visualization and measurement tools at tableside​

Control advanced 3D visualization and measurement tools at tableside​

Using simple tablet gestures, you can carry out advanced measurements and visualizations on the touchscreen at tableside to study the disease in great detail. SmartCT 3D images can help reveal information not apparent on DSA images. This additional information may change diagnosis, treatment planning or treatment delivery, supporting better patient outcomes[4-9]. ​

Control advanced 3D visualization and measurement tools at tableside​

Control advanced 3D visualization and measurement tools at tableside​
Using simple tablet gestures, you can carry out advanced measurements and visualizations on the touchscreen at tableside to study the disease in great detail. SmartCT 3D images can help reveal information not apparent on DSA images. This additional information may change diagnosis, treatment planning or treatment delivery, supporting better patient outcomes[4-9]. ​

Control advanced 3D visualization and measurement tools at tableside​

Using simple tablet gestures, you can carry out advanced measurements and visualizations on the touchscreen at tableside to study the disease in great detail. SmartCT 3D images can help reveal information not apparent on DSA images. This additional information may change diagnosis, treatment planning or treatment delivery, supporting better patient outcomes[4-9]. ​
Click here for more information
Control advanced 3D visualization and measurement tools at tableside​
Control advanced 3D visualization and measurement tools at tableside​

Control advanced 3D visualization and measurement tools at tableside​

Using simple tablet gestures, you can carry out advanced measurements and visualizations on the touchscreen at tableside to study the disease in great detail. SmartCT 3D images can help reveal information not apparent on DSA images. This additional information may change diagnosis, treatment planning or treatment delivery, supporting better patient outcomes[4-9]. ​
CBCT with helical acquisition​​
CBCT with helical acquisition​

CBCT with helical acquisition​

Soft Tissue CBCT protocol with helical movement improves the image quality and appearance, compared to conventional CBCT acquisition techniques, to spot soft tissue changes in the Angio suite. The asymmetrical motion of the arm during the acquisition increases the field of view(FOV) of the scan imaging parts of the brain multiple times. This increase of information, in combination with improved image reconstruction software, leads to improvements in image quality. The speed of the scan has also been increases from 20secs to 10secs to minimize the impact of patient motion for non-sedated stroke patients.

CBCT with helical acquisition​

CBCT with helical acquisition​
Soft Tissue CBCT protocol with helical movement improves the image quality and appearance, compared to conventional CBCT acquisition techniques, to spot soft tissue changes in the Angio suite. The asymmetrical motion of the arm during the acquisition increases the field of view(FOV) of the scan imaging parts of the brain multiple times. This increase of information, in combination with improved image reconstruction software, leads to improvements in image quality. The speed of the scan has also been increases from 20secs to 10secs to minimize the impact of patient motion for non-sedated stroke patients.

CBCT with helical acquisition​

Soft Tissue CBCT protocol with helical movement improves the image quality and appearance, compared to conventional CBCT acquisition techniques, to spot soft tissue changes in the Angio suite. The asymmetrical motion of the arm during the acquisition increases the field of view(FOV) of the scan imaging parts of the brain multiple times. This increase of information, in combination with improved image reconstruction software, leads to improvements in image quality. The speed of the scan has also been increases from 20secs to 10secs to minimize the impact of patient motion for non-sedated stroke patients.
Click here for more information
CBCT with helical acquisition​​
CBCT with helical acquisition​

CBCT with helical acquisition​

Soft Tissue CBCT protocol with helical movement improves the image quality and appearance, compared to conventional CBCT acquisition techniques, to spot soft tissue changes in the Angio suite. The asymmetrical motion of the arm during the acquisition increases the field of view(FOV) of the scan imaging parts of the brain multiple times. This increase of information, in combination with improved image reconstruction software, leads to improvements in image quality. The speed of the scan has also been increases from 20secs to 10secs to minimize the impact of patient motion for non-sedated stroke patients.
Automatic motion compensation for neuro helical​​
Automatic motion compensation for neuro helical​​

Automatic motion compensation for neuro helical​​

The Automatic motion compensation algorithm is a Helical Soft Tissue option, which the physician can use to salvage a CBCT soft tissue scan during which the patient had moved. During stroke procedures, the patient is not always sedated, and this often results in significant head motion, affecting the value of the 3D scan and often requiring a second scan. The automatic motion compensation algorithm takes the original scan and re-runs the reconstruction software to generate an improved volume.

Automatic motion compensation for neuro helical​​

Automatic motion compensation for neuro helical​​
The Automatic motion compensation algorithm is a Helical Soft Tissue option, which the physician can use to salvage a CBCT soft tissue scan during which the patient had moved. During stroke procedures, the patient is not always sedated, and this often results in significant head motion, affecting the value of the 3D scan and often requiring a second scan. The automatic motion compensation algorithm takes the original scan and re-runs the reconstruction software to generate an improved volume.

Automatic motion compensation for neuro helical​​

The Automatic motion compensation algorithm is a Helical Soft Tissue option, which the physician can use to salvage a CBCT soft tissue scan during which the patient had moved. During stroke procedures, the patient is not always sedated, and this often results in significant head motion, affecting the value of the 3D scan and often requiring a second scan. The automatic motion compensation algorithm takes the original scan and re-runs the reconstruction software to generate an improved volume.
Click here for more information
Automatic motion compensation for neuro helical​​
Automatic motion compensation for neuro helical​​

Automatic motion compensation for neuro helical​​

The Automatic motion compensation algorithm is a Helical Soft Tissue option, which the physician can use to salvage a CBCT soft tissue scan during which the patient had moved. During stroke procedures, the patient is not always sedated, and this often results in significant head motion, affecting the value of the 3D scan and often requiring a second scan. The automatic motion compensation algorithm takes the original scan and re-runs the reconstruction software to generate an improved volume.
Metal artifact reduction algorithm for CBCT ​​
Metal artifact reduction algorithm for CBCT ​​

Metal artifact reduction algorithm for CBCT ​​

SmartCT Soft Tissue Helical includes a metal artifact reduction algorithm. Imaging a patient with coils from previous treatments and/or dental replacements can result in significant artifacts in the form of dark and bright streaks on the image. These artifacts can limit confident diagnosis when assessing soft tissue changes in the brain. The metal artifact reduction algorithm processes the volume with the goal of removing the artifacts and improving image quality.​

Metal artifact reduction algorithm for CBCT ​​

Metal artifact reduction algorithm for CBCT ​​
SmartCT Soft Tissue Helical includes a metal artifact reduction algorithm. Imaging a patient with coils from previous treatments and/or dental replacements can result in significant artifacts in the form of dark and bright streaks on the image. These artifacts can limit confident diagnosis when assessing soft tissue changes in the brain. The metal artifact reduction algorithm processes the volume with the goal of removing the artifacts and improving image quality.​

Metal artifact reduction algorithm for CBCT ​​

SmartCT Soft Tissue Helical includes a metal artifact reduction algorithm. Imaging a patient with coils from previous treatments and/or dental replacements can result in significant artifacts in the form of dark and bright streaks on the image. These artifacts can limit confident diagnosis when assessing soft tissue changes in the brain. The metal artifact reduction algorithm processes the volume with the goal of removing the artifacts and improving image quality.​
Click here for more information
Metal artifact reduction algorithm for CBCT ​​
Metal artifact reduction algorithm for CBCT ​​

Metal artifact reduction algorithm for CBCT ​​

SmartCT Soft Tissue Helical includes a metal artifact reduction algorithm. Imaging a patient with coils from previous treatments and/or dental replacements can result in significant artifacts in the form of dark and bright streaks on the image. These artifacts can limit confident diagnosis when assessing soft tissue changes in the brain. The metal artifact reduction algorithm processes the volume with the goal of removing the artifacts and improving image quality.​
  • SmartCT empowers you to easily adopt 3D imaging in the lab
  • Control advanced 3D visualization and measurement tools at tableside​
  • CBCT with helical acquisition​​
  • Automatic motion compensation for neuro helical​​
See all features
SmartCT empowers you to easily adopt 3D imaging in the lab
SmartCT empowers you to easily adopt 3D imaging in the lab

SmartCT empowers you to easily adopt 3D imaging in the lab

Despite the advantages of 3D imaging, it can still be considered difficult to perform by many users. To take the guesswork out of 3D acquisition, SmartCT provides step-by-step guidance and visual aids during acquisition to help easily acquire 3D images. 3D imaging can enhance diagnostic accuracy [1-3], support improved treatment outcomes[4-6] and increase procedural efficiency in the interventional lab [7].

SmartCT empowers you to easily adopt 3D imaging in the lab

SmartCT empowers you to easily adopt 3D imaging in the lab
Despite the advantages of 3D imaging, it can still be considered difficult to perform by many users. To take the guesswork out of 3D acquisition, SmartCT provides step-by-step guidance and visual aids during acquisition to help easily acquire 3D images. 3D imaging can enhance diagnostic accuracy [1-3], support improved treatment outcomes[4-6] and increase procedural efficiency in the interventional lab [7].

SmartCT empowers you to easily adopt 3D imaging in the lab

Despite the advantages of 3D imaging, it can still be considered difficult to perform by many users. To take the guesswork out of 3D acquisition, SmartCT provides step-by-step guidance and visual aids during acquisition to help easily acquire 3D images. 3D imaging can enhance diagnostic accuracy [1-3], support improved treatment outcomes[4-6] and increase procedural efficiency in the interventional lab [7].
Click here for more information
SmartCT empowers you to easily adopt 3D imaging in the lab
SmartCT empowers you to easily adopt 3D imaging in the lab

SmartCT empowers you to easily adopt 3D imaging in the lab

Despite the advantages of 3D imaging, it can still be considered difficult to perform by many users. To take the guesswork out of 3D acquisition, SmartCT provides step-by-step guidance and visual aids during acquisition to help easily acquire 3D images. 3D imaging can enhance diagnostic accuracy [1-3], support improved treatment outcomes[4-6] and increase procedural efficiency in the interventional lab [7].
Control advanced 3D visualization and measurement tools at tableside​
Control advanced 3D visualization and measurement tools at tableside​

Control advanced 3D visualization and measurement tools at tableside​

Using simple tablet gestures, you can carry out advanced measurements and visualizations on the touchscreen at tableside to study the disease in great detail. SmartCT 3D images can help reveal information not apparent on DSA images. This additional information may change diagnosis, treatment planning or treatment delivery, supporting better patient outcomes[4-9]. ​

Control advanced 3D visualization and measurement tools at tableside​

Control advanced 3D visualization and measurement tools at tableside​
Using simple tablet gestures, you can carry out advanced measurements and visualizations on the touchscreen at tableside to study the disease in great detail. SmartCT 3D images can help reveal information not apparent on DSA images. This additional information may change diagnosis, treatment planning or treatment delivery, supporting better patient outcomes[4-9]. ​

Control advanced 3D visualization and measurement tools at tableside​

Using simple tablet gestures, you can carry out advanced measurements and visualizations on the touchscreen at tableside to study the disease in great detail. SmartCT 3D images can help reveal information not apparent on DSA images. This additional information may change diagnosis, treatment planning or treatment delivery, supporting better patient outcomes[4-9]. ​
Click here for more information
Control advanced 3D visualization and measurement tools at tableside​
Control advanced 3D visualization and measurement tools at tableside​

Control advanced 3D visualization and measurement tools at tableside​

Using simple tablet gestures, you can carry out advanced measurements and visualizations on the touchscreen at tableside to study the disease in great detail. SmartCT 3D images can help reveal information not apparent on DSA images. This additional information may change diagnosis, treatment planning or treatment delivery, supporting better patient outcomes[4-9]. ​
CBCT with helical acquisition​​
CBCT with helical acquisition​

CBCT with helical acquisition​

Soft Tissue CBCT protocol with helical movement improves the image quality and appearance, compared to conventional CBCT acquisition techniques, to spot soft tissue changes in the Angio suite. The asymmetrical motion of the arm during the acquisition increases the field of view(FOV) of the scan imaging parts of the brain multiple times. This increase of information, in combination with improved image reconstruction software, leads to improvements in image quality. The speed of the scan has also been increases from 20secs to 10secs to minimize the impact of patient motion for non-sedated stroke patients.

CBCT with helical acquisition​

CBCT with helical acquisition​
Soft Tissue CBCT protocol with helical movement improves the image quality and appearance, compared to conventional CBCT acquisition techniques, to spot soft tissue changes in the Angio suite. The asymmetrical motion of the arm during the acquisition increases the field of view(FOV) of the scan imaging parts of the brain multiple times. This increase of information, in combination with improved image reconstruction software, leads to improvements in image quality. The speed of the scan has also been increases from 20secs to 10secs to minimize the impact of patient motion for non-sedated stroke patients.

CBCT with helical acquisition​

Soft Tissue CBCT protocol with helical movement improves the image quality and appearance, compared to conventional CBCT acquisition techniques, to spot soft tissue changes in the Angio suite. The asymmetrical motion of the arm during the acquisition increases the field of view(FOV) of the scan imaging parts of the brain multiple times. This increase of information, in combination with improved image reconstruction software, leads to improvements in image quality. The speed of the scan has also been increases from 20secs to 10secs to minimize the impact of patient motion for non-sedated stroke patients.
Click here for more information
CBCT with helical acquisition​​
CBCT with helical acquisition​

CBCT with helical acquisition​

Soft Tissue CBCT protocol with helical movement improves the image quality and appearance, compared to conventional CBCT acquisition techniques, to spot soft tissue changes in the Angio suite. The asymmetrical motion of the arm during the acquisition increases the field of view(FOV) of the scan imaging parts of the brain multiple times. This increase of information, in combination with improved image reconstruction software, leads to improvements in image quality. The speed of the scan has also been increases from 20secs to 10secs to minimize the impact of patient motion for non-sedated stroke patients.
Automatic motion compensation for neuro helical​​
Automatic motion compensation for neuro helical​​

Automatic motion compensation for neuro helical​​

The Automatic motion compensation algorithm is a Helical Soft Tissue option, which the physician can use to salvage a CBCT soft tissue scan during which the patient had moved. During stroke procedures, the patient is not always sedated, and this often results in significant head motion, affecting the value of the 3D scan and often requiring a second scan. The automatic motion compensation algorithm takes the original scan and re-runs the reconstruction software to generate an improved volume.

Automatic motion compensation for neuro helical​​

Automatic motion compensation for neuro helical​​
The Automatic motion compensation algorithm is a Helical Soft Tissue option, which the physician can use to salvage a CBCT soft tissue scan during which the patient had moved. During stroke procedures, the patient is not always sedated, and this often results in significant head motion, affecting the value of the 3D scan and often requiring a second scan. The automatic motion compensation algorithm takes the original scan and re-runs the reconstruction software to generate an improved volume.

Automatic motion compensation for neuro helical​​

The Automatic motion compensation algorithm is a Helical Soft Tissue option, which the physician can use to salvage a CBCT soft tissue scan during which the patient had moved. During stroke procedures, the patient is not always sedated, and this often results in significant head motion, affecting the value of the 3D scan and often requiring a second scan. The automatic motion compensation algorithm takes the original scan and re-runs the reconstruction software to generate an improved volume.
Click here for more information
Automatic motion compensation for neuro helical​​
Automatic motion compensation for neuro helical​​

Automatic motion compensation for neuro helical​​

The Automatic motion compensation algorithm is a Helical Soft Tissue option, which the physician can use to salvage a CBCT soft tissue scan during which the patient had moved. During stroke procedures, the patient is not always sedated, and this often results in significant head motion, affecting the value of the 3D scan and often requiring a second scan. The automatic motion compensation algorithm takes the original scan and re-runs the reconstruction software to generate an improved volume.
Metal artifact reduction algorithm for CBCT ​​
Metal artifact reduction algorithm for CBCT ​​

Metal artifact reduction algorithm for CBCT ​​

SmartCT Soft Tissue Helical includes a metal artifact reduction algorithm. Imaging a patient with coils from previous treatments and/or dental replacements can result in significant artifacts in the form of dark and bright streaks on the image. These artifacts can limit confident diagnosis when assessing soft tissue changes in the brain. The metal artifact reduction algorithm processes the volume with the goal of removing the artifacts and improving image quality.​

Metal artifact reduction algorithm for CBCT ​​

Metal artifact reduction algorithm for CBCT ​​
SmartCT Soft Tissue Helical includes a metal artifact reduction algorithm. Imaging a patient with coils from previous treatments and/or dental replacements can result in significant artifacts in the form of dark and bright streaks on the image. These artifacts can limit confident diagnosis when assessing soft tissue changes in the brain. The metal artifact reduction algorithm processes the volume with the goal of removing the artifacts and improving image quality.​

Metal artifact reduction algorithm for CBCT ​​

SmartCT Soft Tissue Helical includes a metal artifact reduction algorithm. Imaging a patient with coils from previous treatments and/or dental replacements can result in significant artifacts in the form of dark and bright streaks on the image. These artifacts can limit confident diagnosis when assessing soft tissue changes in the brain. The metal artifact reduction algorithm processes the volume with the goal of removing the artifacts and improving image quality.​
Click here for more information
Metal artifact reduction algorithm for CBCT ​​
Metal artifact reduction algorithm for CBCT ​​

Metal artifact reduction algorithm for CBCT ​​

SmartCT Soft Tissue Helical includes a metal artifact reduction algorithm. Imaging a patient with coils from previous treatments and/or dental replacements can result in significant artifacts in the form of dark and bright streaks on the image. These artifacts can limit confident diagnosis when assessing soft tissue changes in the brain. The metal artifact reduction algorithm processes the volume with the goal of removing the artifacts and improving image quality.​
  • * The user level of expertise required is described in the Instructions for Use as the Intended Operator Profile
  • SmartCT R3.0 is subject to regulatory clearance and may not be available in all markets. Contact your sales representative for more details.
  • 1. Akkakrisee SA, Hongsakul KR. Percu-taneous transthoracic needle biopsy for pulmonary nodules: a retrospec-tive study of a comparison between C-arm cone-beam computed to-mography and conventional com-puted tomography guidance. Pol J Radiol.. 2020; 85(-): e309–e315
  • 2. Jang H, Jung WS, Myoung SU, Kim JJ, Jang CK, Cho KC, Source Image Based New 3D Rotational Angiography for Differential Diagnosis between the In-fundibulum and an Internal Carotid Artery Aneurysm : Pilot Study. J Korean Neurosurg Soc, 2021. 64(5):726-731
  • 3. Schernthaner et al., Delayed-Phase Cone-Beam CT Improves Detectability of Intrahepatic Cholangiocarcinoma During Conventional Transarterial Chemoembolization Cardiovasc Intervent Radiol , 38 (4), 929-36, 2015
  • 4. Xiong, F., et al., Xper-CT combined with laser-assisted navigation radiofrequency thermocoagulation in the treatment of trigeminal neuralgia. Front Neu-rol, 2022. 13: p. 930902
  • 5. Schott, P., et al., Radiation Dose in Prostatic Artery Embolization Using Cone-Beam CT and 3D Roadmap Software. J Vasc Interv Radiol, 2019. 30(9): p. 1452-1458
  • 6. Rosi, A., et al., Three-dimensional rotational angiography improves mechanical thrombectomy recanalization rate for acute ischaemic stroke due to mid-dle cerebral artery M2 segment occlusions. Interv Neuroradiol, 2022: p. 15910199221145745
  • 7. Ribo et al, Direct Transfer to Angiosuite to Reduce Door-To-Puncture Time in Thrombectomy for Acute Stroke, J Neurointerv Surg , 2018, 10 (3), 221-224
  • 8. Fagan et al., MultiModality 3-dimensional image integration for Congenital Cardiac Catheterization. Methodist Debakey Cardiovasc J. 2014, 10 (2), 68-76
  • 9. Hirotaka Hasegawa et al, Integration of rotational angiography enables better dose planning in Gamma Knife radiosurgery for brain arteriovenous malformations, J Neurosurg (Suppl) 129:17–25, 2018

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