Magneton vision system

Manufactured by Siemens

Sourced in Germany

The Magneton VISION system is a laboratory equipment designed for magnetic resonance imaging (MRI) data acquisition. It provides the core functionality required for MRI scanning, including the generation of a strong magnetic field and the detection of radio frequency signals from the sample under examination. The system is engineered to deliver high-quality MRI data for various research and clinical applications.

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Lab products found in correlation

Magnetom avanto system, by Siemens (1 mentions)

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Magneton Vision Vision system

2 protocols using magneton vision system

Longitudinal Brain Structural MRI Scans

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The brain structural MRI scans at the time of diagnosis (baseline image) and 1-year follow-up were obtained with a 1.5 Tesla Magneton VISION system (Siemens Inc., Iselin, NJ). A volumetric magnetization prepared rapid gradient echo (MP-RAGE) MRI was used to obtain a T1-weighted image of the entire brain, using acquisition parameters described elsewhere (Gorno-Tempini et al., 2004b (link)).

Brambati S.M., Amici S., Racine C.A., Neuhaus J., Miller Z., Ogar J., Dronkers N., Miller B.L., Rosen H, & Gorno-Tempini M.L. (2015). Longitudinal gray matter contraction in three variants of primary progressive aphasia: A tenser-based morphometry study. NeuroImage : Clinical, 8, 345-355.

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Multimodal Neuroimaging Data Processing

Cited 2 times

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97/101 subjects underwent structural T1-weighted MRI. Scans were obtained on different MRI units, including three 1.5T units (Magnetom Avanto System, Siemens Medical Systems, Erlangen Germany; Magneton VISION system, Siemens Inc., Iselin, NJ; or GE sygna), two 3T units (Siemens Tim Trio/Prisma scanners), and one 4T unit (BrukerMedSpec) at the UCSF neuroimaging center or the UC Davis Imaging Research Center. Acquisition parameters for all scanners have been previously described.^{24 (link),28 (link)} MRI was used for PET image preprocessing only. PET frames were realigned, averaged and co-registered onto their corresponding T1 MRI. T1 MRI images were parcellated using FreeSurfer 5.3 (wsurfer.nmr.mgh.harvard.edu). We calculated PIB standard uptake value ratio (SUVR) using the cerebellar gray matter (defined on the MRI) as the reference region. When 90-minute acquisition was available, we also generated PIB Distribution Volume Ratio (DVR) images using Logan graphical analysis with cerebellar gray matter as the reference region. FDG SUVR images were created using the pons (defined on the MRI) as a reference region.^{29 –31 (link)}

Lesman-Segev O.H., Joie R.L., Iaccarino L., Lobach I., Rosen H.J., Seo S.W., Janabi M., Baker S.L., Edwards L., Pham J., Olichney J., Boxer A., Huang E., Gorno-Tempini M., DeCarli C., Hepker M., Hwang J.H., Miller B.L., Spina S., Grinberg L.T., Seeley W.W., Jagust W.J, & Rabinovici G.D. (2020). Diagnostic Accuracy of Amyloid versus FDG PET in Autopsy-Confirmed Dementia. Annals of neurology, 89(2), 389-401.

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