3t whole body magnetic resonance scanner

Manufactured by Philips

The 3T whole body magnetic resonance scanner is a medical imaging device that uses a strong magnetic field and radio waves to create detailed images of the body's internal structures. It is designed to provide high-resolution scans of the entire body.

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Lab products found in correlation

16 channel sense head coil, by Philips (2 mentions)

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3T scanner (120 citations) 3T magnetic resonance scanner (5 citations)

2 protocols using 3t whole body magnetic resonance scanner

MRI-guided Neuroimaging Analysis Pipeline

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MRI scans were obtained prior to and following surgery. All scans were obtained using a 3T whole body magnetic resonance scanner (Philips Medical Systems) fitted with a 16-channel SENSE head coil. Images were collected using a magnetization-prepared 180° radiofrequency pulse and a rapid gradient-echo sequence with 1 mm sagittal slices and in-plane resolution of 1 mm isotropic. Pial surface reconstructions were computed with FreeSurfer (v6.0)^{25 (link)} and imported into AFNI (https://afni.nimh.nih.gov).

Snyder K.M., Forseth K.J., Donos C., Rollo P.S., Fischer-Baum S., Breier J, & Tandon N. (2023). Critical role of the ventral temporal lobe in naming. Epilepsia, 64(5), 1200-1213.

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Anatomical MRI Acquisition and Lesion Segmentation

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Anatomical MRI scans were obtained for Case 2 using a 3 T whole-body magnetic resonance scanner (Philips Medical Systems) fitted with a 16-channel SENSE head coil. Images were collected using a magnetization-prepared 180 radio-frequency pulse and rapid gradient-echo sequence with 1 mm sagittal slices and an in-plane resolution of 0.938 x 0.938 mm. The same specifications were used for Case 1, with the exception of a 1.5 T field strength and a transmit/receive head coil. Images and renderings were generated with MRIcroGL (https://www.nitrc.org/projects/mricrogl/). Lesion segmentations were drawn on axial slices by a trained neuropsychologist (author G.W.) using MRIcroGL and checked for accuracy by a neurologist (author N.T.). Cortical atrophy and ventricle dilation were not identified as part of the lesion segmentation. The central sulcus on each patient’s scan was traced by hand to provide an anatomical reference (with some approximation required inside the lesions).

Walker G.M., Rollo P.S., Tandon N, & Hickok G. (2021). Effect of Bilateral Opercular Syndrome on Speech Perception. Neurobiology of Language, 2(3), 335-353.

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