Latest revision as of 15:04, 3 October 2024

3T hardware

Scanner: Philips Ingenia 3.0T CX
Bore diameter: 60 cm
Headcoil: ds Head 32channels 3.0T serial number 791 part number 453 5303 12384
Digital broadband architecture; digitizes the signal right in the coil.
Dual transmit parallel RF transmission technology
multiband SENSE (simultaneous multislice imaging) and compressed SENSE acceleration available
Max gradient strength: 40 mT/m
Max gradient slew rate: 200 mT/m/ms
Field-of-view (in head-feet direction): 45 cm

Setting up an MRI protocol

A basic MR scan session usually starts with the following scans:

Pre-scanning - a 3-plane localizer or 'scout' scan meant to find the subject's head. It is also be used for prescription for the subsequent scans. Doing some sort of localizer is necessary.
Anatomical MRI - usually a 3D T1-weighted scan at 1mm isotropic resolution. It is essential for image alignment and anatomical analysis. More choices of anatomical scans are listed in the Anatomical imaging section.
Shim - measures the magnetic field inhomogeneity and corrects it with polynomial gradients up to 2nd order. It should be run before fMRI or diffusion scans.

At this point you will want to add a number of functional scans, diffusion scans or other type of scans based on your experiment. In the next section we describe templates for different categories of MRI protocols. The protocol templates are organized by category.

You can get help in customizing the parameters from the Spinoza staff.

Pre-scanning

Anatomical MRI

T1 weighted

1.0mm, TR=2000ms, FOV 256x256x176mm, flip angle=8°, TR=7ms, TE= 3ms, RCS = 6 (AP), oversampling (RL) 1.28, for a total of 38 shots, and a duration of 1:55sec

Please cite "Stutters et al., Structural 3DT1 scans with compressed sensing are suitable for cross-sectional brain volume measures in multiple sclerosis. Proc Intl Soc Magn Reson Med 29(2021): 2150"

T2 weighted

TSE: 1.0 mm, TR 2500ms, FOV 256x240x250, SENSE 2x2, TSE factor 117, TEeff 331ms / TEequiv 135ms. Duration: 4:08sec
FLAIR 1 (TSE with fluid attenuation): 1.1mm (interpolated; 1mm), TR 4800, TI 1650, FOV 256x240x250, TEeff 254ms / TEequiv 111ms. Duration: 6:00sec
FLAIR 2 (Incidental finding protocol): 1.1mm (interpolated; 1mm), TR 4800, TI 1650ms, FOV 256x250x183, TEeff 256ms / TEequiv 112ms. Duration: 4:34sec

Classical BOLD fMRI

All with 10% gap, TE=27.63ms, SENSE 2, moderate PNS, maximum gradient mode, regular dynamic stabilization, 135Hz fat suppression SPIR offset, ascending slice order

3.0mm, TR=2000ms, FOV 240x240xxxxmm, WFS 12.0pix (36.0mm), Max dyns xxx (workhorse)
2.5mm, TR=3000ms, FOV 240x240xxxxmm, WFS 15.1pix (37.75mm), Max dyns xxx (high-res reduces signal drop out)

Multiband BOLD fMRI

All with 10% gap, TE=30ms, SENSE 1.5, multiband 4, moderate PNS, maximum gradient mode, regular dynamic stabilization, 175Hz fat suppression SPIR offset, ascending slice order

3.0mm, TR=0550ms, FOV 240x240x118mm, WFS 14.2pix (42.6mm), Max dyns 1820 (denoising in people with increased heart rate)
2.7mm, TR=0700ms, FOV 240x240x130mm, WFS 14.4pix (38.9mm), Max dyns 1489 (workhorse)
2.0mm, TR=1600ms, FOV=224x224x132mm, WFS 23.7pix (47.4mm), Max dyns 1050 (high-res reduces signal drop out)

Considerations:

Set shimbox to contain as little non-brain tissue and air as possible or use image based shimming through MRCode tool (requires image_based_shim patch)
Create second GE-EPI with opposite fatshift direction, set preparation to auto for this sequence (so it won't perform a second B0 shim) and group the sequences
Perhaps not include dummies and use one of the pre-saturation scans for registration as it has better grey/white matter contrast (see Multiband data registration)

Diffusion Imaging

There are many different flavours of diffusion scans. These are merely examples, do check the scanner for more.

single-shell, b1800: 2.0mm, TR=4100ms, FOV 224x224x124mm, MB2/SENSE 1.5/halfscan 0.62, 12 dirs, b1800. Duration: 1:02s.
single-shell, b1000: 2.0mm, TR=2700ms, FOV 224x224x126mm, MB3/SENSE 1.3/halfscan 0.63, 128 dirs, b1000. Duration: 5:56s.
multi-shell (ISMRM-recommended): TR=4730ms, FOV 212x242x132mm, MB2/SENSE 1.5/halfscan 0.71, 96 dirs, b1000+b2000, Duration: 7:58s.

classic multi-shell: 2.3mm, TR=4150ms, FOV 224x224x135mm, MB2/SENSE 1.5/halfscan 0.69, 52 directions, b600 / b1000. Duration: 3:48s. Can be combined with 48 directions b1700 (3:32sec) + 64 directions b2200 (4:38 sec) and extra b0 scans

Magnetic Resonance Spectroscopy

If you have questions about our standard MRS sequences (e.g. GABA, glutamate), please contact Anouk Schrantee.

@@ Line 1: / Line 1: @@
 __FORCETOC__
+=3T hardware=
+* Scanner: Philips Ingenia 3.0T CX
+* Bore diameter: 60 cm
+* Headcoil: ds Head 32channels 3.0T serial number 791 part number 453 5303 12384
+* Digital broadband architecture; digitizes the signal right in the coil.
+* Dual transmit parallel RF transmission technology
+* multiband SENSE (simultaneous multislice imaging) and compressed SENSE acceleration available
+* Max gradient strength: 40 mT/m
+* Max gradient slew rate: 200 mT/m/ms
+* Field-of-view (in head-feet direction): 45 cm
 =Setting up an MRI protocol=
@@ Line 14: / Line 24: @@
 =Anatomical MRI=
+==T1 weighted==
+.0mm, TR=2000ms, FOV 256x256x176mm, flip angle=8°, TR=7ms, TE= 3ms, RCS = 6 (AP),  oversampling (RL) 1.28, for a total of 38 shots, and a duration of 1:55sec <br>
+Please cite "Stutters et al., Structural 3DT1 scans with compressed sensing are suitable for cross-sectional brain volume measures in multiple sclerosis. Proc Intl Soc Magn Reson Med 29(2021): 2150"
+==T2 weighted==
+TSE: 1.0 mm, TR 2500ms, FOV 256x240x250, SENSE 2x2, TSE factor 117, TEeff 331ms / TEequiv 135ms. Duration: 4:08sec <br>
+FLAIR 1 (TSE with fluid attenuation): 1.1mm (interpolated; 1mm), TR 4800, TI 1650, FOV 256x240x250, TEeff 254ms / TEequiv 111ms. Duration: 6:00sec <br>
+FLAIR 2 (Incidental finding protocol): 1.1mm (interpolated; 1mm), TR 4800, TI 1650ms, FOV 256x250x183, TEeff 256ms / TEequiv 112ms. Duration: 4:34sec <br>
 =Classical BOLD fMRI=
- All with 10% gap, TE-27.63ms, SENSE 2, moderate PNS, maximum gradient mode, regular dynamic stabilization, 135Hz fat suppression SPIR offset
+All with 10% gap, TE=27.63ms, SENSE 2, moderate PNS, maximum gradient mode, regular dynamic stabilization, 135Hz fat suppression SPIR offset, ascending slice order
 .0mm, TR=2000ms, FOV 240x240xxxxmm, WFS 12.0pix (36.0mm), Max dyns xxx (workhorse)
 .5mm, TR=3000ms, FOV 240x240xxxxmm, WFS 15.1pix (37.75mm), Max dyns xxx (high-res reduces signal drop out)
@@ Line 23: / Line 43: @@
 =Multiband BOLD fMRI=
- All with 10% gap, TE-30ms, SENSE 1.5, multiband 4, moderate PNS, maximum gradient mode, regular dynamic stabilization, 175Hz fat suppression SPIR offset
+All with 10% gap, TE=30ms, SENSE 1.5, multiband 4, moderate PNS, maximum gradient mode, regular dynamic stabilization, 175Hz fat suppression SPIR offset, ascending slice order
-.0mm, TR=0550ms, FOV 240x240x118mm, WFS 14.2pix (42.6mm), Max dyns 1820 (can be considered for denoising in people with increased heart rate)
+.0mm, TR=0550ms, FOV 240x240x118mm, WFS 14.2pix (42.6mm), Max dyns 1820 (denoising in people with increased heart rate)
 .7mm, TR=0700ms, FOV 240x240x130mm, WFS 14.4pix (38.9mm), Max dyns 1489 (workhorse)
-.0mm, TR=1600ms, FOV=224x224x125mm, WFS 23.7pix (47.4mm), Max dyns 1170 (high-res reduces signal drop out)
+.0mm, TR=1600ms, FOV=224x224x132mm, WFS 23.7pix (47.4mm), Max dyns 1050 (high-res reduces signal drop out)
-Considerations:
- Set shimbox to contain as little non-brain tissue and air as possible or use image based shimming through MRCode tool (requires image_based_shim patch)
- Create second GE-EPI with opposite fatshift direction, set preparation to auto for this sequence (so it won't perform a second B0 shim) and group the sequences
- Perhaps not include dummies and use one of the pre-saturation scans for registration as it has better grey/white matter contrast (see [https://fsl.fmrib.ox.ac.uk/fslcourse/lectures/practicals/registration/index.html#multiband Multiband data registration])
-=GABA edited spectroscopy=
-We use a patch from Richard Edden (John's Hopkins University), which contains a MEGA-PRESS sequence for 3T. For more information on the development of this patch, see: [https://www.gabarmrs.com www.gabamrs.com].
-'''Please visit this website first for an explanation of the method used, before you start your experiment.'''
-If you have any remaining questions after reading this Wiki page, please contact [mailto:[email protected] Anouk Schrantee].
-===The patch===
-The patch needs to be loaded with Select Patch and is currently called ''R5_4 MEGA''.
-Please make sure you read the instructions on the do's and don't's of using patches [[Install patch | here]].
-<to be inserted: photo how to select the correct patch>
+Considerations: <br>
+*Set shimbox to contain as little non-brain tissue and air as possible or use image based shimming through MRCode tool (requires image_based_shim patch)
+*Create second GE-EPI with opposite fatshift direction, set preparation to auto for this sequence (so it won't perform a second B0 shim) and group the sequences
+*Perhaps not include dummies and use one of the pre-saturation scans for registration as it has better grey/white matter contrast (see [https://fsl.fmrib.ox.ac.uk/fslcourse/lectures/practicals/registration/index.html#multiband Multiband data registration])
-===How to acquire GABA data===
+=Diffusion Imaging=
-There are currently two implementations to scan GABA working on the 3T.
-- GABA_68_PAR: without macromolecule suppression
+There are many different flavours of diffusion scans. These are merely examples, do check the scanner for more. <br>
-- GABA_80_PAR: with macromolecule suppression
+ single-shell, b1800: 2.0mm, TR=4100ms, FOV 224x224x124mm, MB2/SENSE 1.5/halfscan 0.62, 12 dirs, b1800. Duration: 1:02s.
+ single-shell, b1000: 2.0mm, TR=2700ms, FOV 224x224x126mm, MB3/SENSE 1.3/halfscan 0.63, 128 dirs, b1000. Duration: 5:56s.
+ multi-shell (ISMRM-recommended): TR=4730ms, FOV 212x242x132mm, MB2/SENSE 1.5/halfscan 0.71, 96 dirs, b1000+b2000, Duration: 7:58s. <br>
-The HERMES implementation is not yet working.
+classic multi-shell: 2.3mm, TR=4150ms, FOV 224x224x135mm, MB2/SENSE 1.5/halfscan 0.69, 52 directions, b600 / b1000. Duration: 3:48s. Can be combined with 48 directions b1700 (3:32sec) + 64 directions b2200 (4:38 sec) and extra b0 scans <br>
-===The analysis software===
+=Magnetic Resonance Spectroscopy=
-The developers of the patch also provide an analysis toolbox to analyze your spectroscopy data. For more information on this, and examples, please see: [https://www.gabarmrs.com www.gabamrs.com].
-It exists of a series of Matlab scripts, but it can easily be called from the command line in Matlab - no need to change the scripts for the standard implementation. The manual of how to analyze your data is also in the folder mentioned below.
-'''Important:''' You can download Gannet on their website, but we have optimized the analysis toolbox for the data that we acquire at the Spinoza, so please use the version you can find here:
+If you have questions about our standard MRS sequences (e.g. GABA, glutamate), please contact [mailto:a.g.schrantee@amsterdamumc.nl Anouk Schrantee].
-[[Media:Gannet2.0-master.zip|Gannet 2.0]]

Standard sequences @ 3T: Difference between revisions

From SpinozaWiki