RF Pulse Design. Multi-dimensional Excitation II. M229 Advanced Topics in MRI Kyung Sung, Ph.D Class Business

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RF Pulse Design Multi-dimensional Excitation II M229 Advanced Topics in MRI Kyung Sung, Ph.D. 2018.04.12 Class Business - Homework 1 will be due on 4/26 - Office hours Instructors: Fri 10-12 noon TAs: Thursday 3-5pm Emails beforehand would be helpful - Papers and Slides

Today s Topics - Recap of excitation k-space - 2D excitation pulses 2D EPI pulse design Spatial-spectral pulse design - Matlab exercise Summary for Excitation k-space

Small-Tip Approximation B1(t) T Gz(t) k(t,t0) t1 t2 t3 t4 t5 t6 t7 Small-Tip-Angle Solution as a k-space Integral k-space weighting k-space sampling

2D Pulse Design 1. Choose a k-space trajectory 2. Choose a weighting function 3. Design the RF pulse 2D Spatial Pulse Design - EPI Non-isotropic resolution Sidelobes in one dimension Spectral-spatial pulses - Spiral Unity aspect ratio Minimum length Circular sidelobe

2D EPI Pulse Design Designing EPI k-space Trajectory - Ideally, an EPI trajectory scans a 2D raster in k- space Resolution? / FOV?

Designing EPI k-space Trajectory - Resolution: - FOV = 1/ ky - Ghost FOV = FOV/2 Eddy currents & delays produce this Designing EPI k-space Trajectory - Refocusing gradients Returns to origin at the end of pulse

Designing EPI Gradients - Designing readout lobes and blips Flat-top only design RF only played during flat part (simpler) To the board...

Designing EPI Gradients - Easy to get k-space coverage in ky - Hard to get k-space coverage in kx - We can get more k-space coverage by making blips narrower playing RF during part of ramps Blipped EPI - Rectilinear scan of k-space - Most efficient EPI trajectory - Common choice for spatial pulses - Sensitive to eddy currents and gradient delays

Blipped EPI G x,g y Gradient Waveforms k y k x 2k y,max k-space Trajectory 2k x,max Continuous EPI - Non-uniform k-space coverage - Need to oversample to avoid side lobes Less efficient than blipped - Sensitive to eddy currents and gradient delays Only choice for spectral-spatial pulses

Continuous EPI G x,g y Gradient Waveforms k y k x 2k y,max k-space Trajectory 2k x,max Flyback EPI - Can be blipped or continuous - Less efficient since retraces not used (depends on gradient system) - Almost completely immune to eddy currents and gradient delays

Flyback EPI G x,g y Gradient Waveforms k y Retrace k x 2k y,max k-space Trajectory 2k x,max Designing 2D EPI Spatial Pulses - Two major options General approach, same as 2D spiral pulses Seperable, product design (easier) - General approach Choose EPI k-space trajectory Design gradient waveforms Design W(k), k-space weighting Design B1(t)

Separable, Product Design - Assume, AS(ky): weighting in the slow, blipped direction AF(kx): weighting in the fast oscillating direction - Each impulse corresponds to a pulse in the fast direction, AF(kx) Separable, Product Design

Spectral Spatial Pulse Spatial-Spectral Pulses - 2D pulses selective in space and frequency - Excite a slice at a limited band of frequencies - Clinical applications High speed imaging (spiral/epi) Robust lipid suppression Spectroscopic imaging (MRSI)

Basic Idea - Gy gradient simply establishes a linear relationship between position and frequency Spatial selectivity in y Frequency selectivity Basic Idea

Basic Idea f kf Note that kf is time! Spectral Pulses

Add Spatial Selectivity to a Spectral Pulse - Hard pulses Hard pulses B1(t) B1(t) t Slice selective subpulses t Gz(t) Each sub pulse starts and ends at kz = 0 To the board...

Flyback Design 1.1 ms sublobes 8 sublobes 250 Hz spectral passband 15 ms length Water Lipid Opposed Null Design 2.2 ms sublobes 8 sublobes 250 Hz spectral passband 13.2 ms length Water Lipid

True Null Design 1.1 ms sublobes 16 sublobes 250 Hz spectral passband 15ms length Water Lipid Source of Bipolar Sidelobes Interference between excitations from positive and negative gradient lobes position [mm]............ position [mm]............ position [mm] resonant frequency [Hz] resonant frequency [Hz] resonant frequency [Hz]

Matlab Exercise Windowed Sinc RF Pulse

RF Pulse Scaling RF Pulse Scaling

Bloch Simulation Slice Thickness - Pulse duration = 1 ms - TBW = 4 - Gz = 1 G/cm ɣ/2π = 4.257 khz/g

Summary - Adiabatic Pulse Design - 2D Pulse Design Examples: - EPI pulse design - Spatial-Spectral Pulses - Matlab Exercise - Homework 2-2D EPI design - SPSP design - Next time: Pulse sequences Thanks! Kyung Sung, PhD ksung@mednet.ucla.edu http://kyungs.bol.ucla.edu

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