Aquillion 64

Manufactured by Canon

Sourced in Japan, United States

The Aquillion 64 is a computed tomography (CT) imaging system developed by Canon. It is designed to capture high-quality, detailed images of the body's internal structures. The system features a 64-row detector configuration, which allows for efficient data acquisition and reconstruction of three-dimensional images. The Aquillion 64 is intended for use in medical and research settings, providing healthcare professionals with a valuable tool for diagnosis and analysis.

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Lab products found in correlation

Aquillion one, by Canon (1 mentions) Avanto fit, by Siemens (1 mentions)

4 protocols using aquillion 64

Detailed CT Scan Parameters for Radiomics

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CT scans were performed using a 64-detector-row CT scanner (Aquillion 64, Canon Medical Systems, Otawara, Japan) or a 320-detector-row scanner (Aquillion ONE, Canon Medical Systems). Images were reconstructed with a soft-tissue kernel (FC11, 13) and a slice thickness of 1 mm for radiomics analysis and with lung kernel (FC51) and a slice thickness of 0.5 mm for evaluation of the C/T ratio, using a filtered back-projection algorithm. Table E1 enumerates the detailed scan parameters.

Takehana K., Sakamoto R., Fujimoto K., Matsuo Y., Nakajima N., Yoshizawa A., Menju T., Nakamura M., Yamada R., Mizowaki T, & Nakamoto Y. (2022). Peritumoral radiomics features on preoperative thin-slice CT images can predict the spread through air spaces of lung adenocarcinoma. Scientific Reports, 12, 10323.

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Multimodal Neuroimaging Protocol for Research

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All CT examinations were performed on a 64-row CT scanner (Aquillion 64, Canon Medical, Tustin, CA). Representative CT imaging protocol was the following: volumetric acquisition from above the ear below the level of the skull base; 120 kV, 150 mA. All CT dataset were reconstructed in axial and coronal planes in bone window/level settings with a standard field-of-view (FoV; 22 cm) with a slice thickness of 1 mm and a slice gap of 0.5 mm.
All MR examinations were performed at 1.5T (Avanto Fit, Siemens Medical System, Erlangen, Germany) using a 20 channel head coil for signal detection. Following the localizer, an axial T1-weighted (T1w) Spin Echo (SE) sequence was acquired. Imaging parameters were time of repetition (TR)/time of echo (TE) 450/8.5 ms, FoV 180 mm, matrix size 192 Â 256 with an in-plane resolution 0.7 Â 0.7 mm and a slice thickness of 3 mm. Next, a coronal T2-weighted (T2w) Turbo Spin Echo (TSE) sequence was acquired (imaging parameters: TR/TE 3500/79 ms, FoV 170 mm, matrix 192 Â 256, in-plane resolution 0.3 Â 0.3 mm, slice thickness

Weiss N.M., Stecher S., Bächinger D., Schuldt T., Langner S., Zonnur S., Mlynski R, & Schraven S.P. (2020). Open Mastoid Cavity Obliteration With a High-Porosity Hydroxyapatite Ceramic Leads to High Rate of Revision Surgery and Insufficient Cavity Obliteration. Otology & neurotology : official publication of the American Otological Society, American Neurotology Society [and] European Academy of Otology and Neurotology, 41(1).

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Feline Cystic Progression Imaging

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CT scans were performed using a third generation 64 slice instrument (Aquillion 64, Canon Medical Systems, Tustin, CA, USA) under the same anesthetic event as the MRI scan. Follow-up imaging was performed for two cats at 12 months and 15 months, which were thought to have fast and slow cyst progression (i.e., high and low FCV at the youngest age), respectively.

Yu Y., Shumway K.L., Matheson J.S., Edwards M.E., Kline T.L, & Lyons L.A. (2019). Kidney and cystic volume imaging for disease presentation and progression in the cat autosomal dominant polycystic kidney disease large animal model. BMC Nephrology, 20, 259.

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Fasting Effects on Feline Kidney Volume

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CT imaging of cats was conducted using a third generation 64 slice instrument (Aquillion 64, Canon Medical Systems, Tustin, CA). Each cat was placed in dorsal recumbency and pre- and post-contrast images were obtained from the diaphragm to the anus (slice thickness 1–2 mm, kvp 80–100, mAs 230–500). Intravenous non-ionic, iodinated contrast media (Omnipaque 350 Iohexol injection, GE Healthcare, Marlboro, MA.) was administered at a dose of 0.5 mg/kg and post-contrast images were obtained after a three-minute delay. For the fasting study, cats were fasted for ~12 – 13 hrs prior to sedation for the pre-trial CT imaging. After the pre-trial CT, the fast was continued up to ~60 hrs. The cats were then re-sedated and the post-trial CT imaging and blood sampling was conducted. Total kidney volumes were determined by semi-automated volumetric segmentation using 3D Slicer software (http://www.slicer.org (Fedorov et al., 2012 (link))) using the Segmentation Wizard module (author: Andrew Beers, Athinoula A. Martinos Center for Biomedical Imaging at Massachusetts General Hospital; available at: https://www.slicer.org/wiki/Documentation/Nightly/Extensions/SegmentationWizard, accessed 9 Apr. 2019).

Torres J.A., Kruger S., Broderick C., Amarlkhagva T., Agrawal S., Dodam J.R., Mrug M., Lyons L.A, & Weimbs T. (2019). Ketosis ameliorates renal cyst growth in polycystic kidney disease. Cell metabolism, 30(6), 1007-1023.e5.

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