Understanding of MRI Pluse Sequences Diagram.

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Understanding of MRI Pulse Sequences Diagram.

 

Feburay 15. 2007.

Ho NamKoong.

◈ Contents.

     1. Why need to know Pulse Sequences?

2. Basic terms to understand Pulse Sequences.

3. Spin Echo Family.

4. Fast Spin Echo Family.

5. Inversion Recovery Family.

6. Gradient Echo Family.

7. Clinical Application. 

 

 

 

1. Why need to know Pulse Sequences?

 

MR Images should show the location and specific characters of the lesion.

ex) SE T1 Tra(Ax), FSE T2 Sag, GE T2^* Cor...

 

▷ specific characters : T1-Weighted, T2-Weighted, T2^*-Weighted, Flow Character (Angiography), Contrast Media(Dynamic), Fat Saturated, Cine, Diffusion, Perfusion, MRS, fMRI...

▷ location : planes ( axial, sagittal, coronal, oblique).

 

▷ Signal Intensity (SI)

 

► S_SE ∝ [1-e^(-TR/T1)]e^(-TE/T2)

► SI ∝ Density of proton × T1 factors × T2 factors

▷ The points of scanning in clinical filed.

Patients (Scan Time)

Doctors (Resolution)

Technologists (SNR)

Best Image

What is the best image?

2. Basic terms to understand Pulse Sequences.

 

▷ Voxel (Volume of Element)          /         Pixel (Picture of Element)

 

 

 

 ▷ Matrix: the number of rows and columns of pixels.

 

Matrix = Phase encoding ×Frequency Encoding.

 

▷ FOV (Field of View): Anatomic region of interest.

 

FOV = Matrix × Pixel size.

 

▷ TR (Repetition Time): the time between two 90^o RF Pulses.

 

  ► Effect of T1 relaxation time.

► amount of magnetization vector.

  à Signal Production

 

▷ TE (Echo Time): the time between initial 90^o RF Pulse and Echo.

 

    ► the results of T2 dephasing.

 

▷ FA (Flip Angle): The angle to flip the NMV to the transverse plane.

  ► amount of transverse magnetization.

  ► amount of signal.

 

▷ IR (Invresion Time):

 

▷ NEX (Number of Acquisition, Number of Excitation), NSA(Number of Signal Averages):

 ► Produce one image.

 

▷ Gradient performance: mT/m, G/cm.

 

B

A

 

 

         

 

3. Spin Echo Family.

 

. Try to draw SE Pulse diagram! (Fig1.)

 

▷ Erwin Hahn, 1949.

 

① FID (Free Induction Decay)

 ► too process quickly to turn on and measure it.

 ► No spatial information.

 

② Encoding: for spatial information.

 ► direct impact on the overall scan time.

 

 

 

 

③ Refocusing.

 ► use 180o RF Pulse or Gradient.

 

 

④ Read-out the Signal.DAS(Data Acquisition System)

 ► data acquisition.

 ► frequency encoding of the signal.

 

 

 ▷ Gradient Phase Effects.

► Phase dispersion.(Please draw the phase dispersion according to gradient!)

Φx

Gx

 ► Balancing Pulse: refocusing phases at Slice selection and read out.(Fig, 3, 4, 5 and 6)

 

▷ multi echo (double, triple echo)

 ► limit number of slice.

 ► PD and T2 weighted images.

 ► same matrix (phase encoding)

 

▷ multi slice

 ► using dead time.

 ► slice number = TR / TE + To.

 

▷ The TR and TE values in conventional SE.

 

TR: Short (less than 750ms), Long (more than 1500ms)

TE: Short (less than 40ms), Long (more than 75ms)

 

 

 

4. Fast Spin Echo Family.

 

RARE (Rapid Acquisition with Relaxation Enhancement): Dr. J Henning, 1986.

à FSE (Fast Spin Echo), TSE (Turbo Spin Echo).

RF

180O

90O

180O

180o

 

 ▷ Inter Echo Spacing (IES, ESP, Echo Spacing): time between successive echos.

 

▷ ETL (Echo Train Length), TF (Turbo Factor): number of echos.

 

▷ Scan Time = TR × NP × NEX / ETL

 

▷ Rewind the phase encoding to undo the dephasing of the spins.

 

▷ Central segment determines the effective echo time affects the contrast.

 

▷ The feature of FSE.

 ► Reduced scan time.

 ► reduced slice number à use long TR.

 ► higher RF exposures à increased SAR limits.

 ► complicated contrast behavior.

 ► possibly reduced resolution (Ginging or Gibb’s artifacts)

   à using high matrix or filtering.

 ► fat brightening.
      subtle contrast changes in the knee.

      high level of motion artifacts from the highly motional suborbital fat.

      rapid train of refocusing pulse à breaking J-coupling (T2á)

      Long IES à GRASE(TGSE): conserve the J-coupling & more Spin-Echo like.

 

▷ Singl-Shot FSE and HASTE.

 ► one initial 90^O RF pulse.

 ► very long echo train (all phase-encoding steps).

 ► scan time = N_slice × (scan time for slice + TD).

 ► predominately fluid structures (biliary system: MRCP)

 

 

 

5. Inversion Recovery Family.

 

▷ IR (Inversion time): the time.

 

RF

180O

90O

180O

 

 ► Heavily T1 weighted images.

 ► TR = 3 × TI (to optimize SNR).

 ► Null point = 0.69 × T1

 ► very long measurement time. 

 ► STIR (Short TI Inversion Recovery): Breast.

 ► FLAIR (Fluid Attenuated Inversion Recovery)

-    nulling the water signal (CSF).

-    MS (Multiple Sclerosis).

-    Periventricular lesion.

 

▷ IR-FSE.

 ► Useful for examining the degree of myelination in the immature brain.

 

▷ interleaved IR-FSE.

 ► Interleaved TI for long TI (FLAIR).

 

 

▷ Real Reconstruction (true) IR.

► Good contrast in neonatal brain.

 

Magnitude reconstruction

Real-valued reconstruction

Signal

TI/T1

 

 

6. Gradient Echo Family.

 

Conventional SE (long TR, TE)  à  reduced flip angle, gradient reveral.

 

110O

0O

SNR

TR:500ms

TR:100ms

TR:10ms

The Ernst Angle.

 

  ▷ Try to draw Fig 7 and 8.

 

 ▷ Using a small flip angle  à  TR can be reduced dramatically without saturation.

 

▷ TE (less than 10ms)  à  used early two decay of signal determined by T2^* not T2. ( T2^* contrast: spin-spin interaction, magnetic field inhomogeneities, magnetic susceptibility.)

 

▷ TR > T2: FID signal depend largely upon T1.

   TR < T2: remnant transverse magnetization remains until next RF pulse is applied.  à  in addition to the FID.

 

▷ Reduce RF power deposition (SAR), but more work for the gradients and noisier for the patient.

 

▷ Increased number of slice.

 

▷ relatively low SN but high CN.

▷ show unpredictable contrast but increased sensitivity to hemorrhage.

 

▷ TR á = T1 dependence ↓, SNR á

     TE á = T2^* dependence á, SNR ↓

     FA á = T1 dependence á, SNR ↓

TE: Short (less than 15ms), Long (more than 30ms)

FA: Small (less than 40^o), Large (more than 50^o).

 

▷ The branches of in GE.

Transverse magnetization: Spoiling, rewinding, stead-state, modified.

 

① FID (T1 Weighted): Spoiling, incoherence: spoiled transverse signal on Gs

à successfully relaxed in longitudinal direction à only longitudinal signal contributes to next RF pulse à provide more T1 dependence.(Fig. 9)

 

 ► Hahn echo and Stimulated echo (multiple echo).

 ► insufficient spoiling  à flash bands (balanced SSFP that reduce it).

 

FLASH (Fast Low Angle Shot; Siemens), SPGR (SPoiled Gradient Recalled echo; GE), T1-FFE (T1 Fast Field Echo; Philips), FAST (RF Spoiled Fourier Acquisition Steady-state Technique; Picker).

 

② FID and Echo (T1/T2 mixed): Rewinding, coherence: rewinding transverse signal on Gp à more signal than spoiled but more complicated weighting.(Fig. 10).

 

 ► Ideal contrast depends upon the flip angle and the ratio T1/T2.

 ► True FISP (Balanced FFE): rewinding gradients in all three directions à excellent SNR and Contrast between blood and myocardium (cardiac imaging).

 

 

GRASS (Gradient Recalled Acquisition in the steady-state; GE), GRE (Gradient Recalled Echo; GE), FISP (Fast Imaging with Steady-state Precession; Siemens), FFE (Fast Field Echo; Philips), FAST (Fourier Acquisition Steady-state Technique; Picker).

 

③ Echo only (T2): Steady-state free precession: echo from prior TR (reverse TE > TR).

 

► Actually not a gradient echo (Hahn echo origin)

► motion artifacts  á and SNR ↓

 

PSIF (reversed FISP; Siemens), SSFP (Steady-state Free Precession; GE), CE-FAST (Contrast-Enhanced Fourier Acquired Steady-state Technique; Picker), T2-FFE (T2 Fast Field Echo; Philips)

 

④ Double Echo: Double Echo Steady-state: two echo acquired (FISP echo and PSIF echo): combined high resolution and strong T2-weighted.

 

 ► 3D orthopedic study.

 ► IAC

 

DESS (Double Echo Steady-state, Siemens), CISS (Constructive Interference in Steady-State, GE), FADE (Fast Acquired Dual Echo)

 

⑤ Ultra-Fast GE Imaging: extremely short TR and very low flip angle using inversion pulse.

 

 ► TR ↓, FA ↓ à T1 very poor. (so, using IR pulse).

 ► phase encoding order à Contrast.

 ► changing matrix size in phase encoding à changed the contrast.

 

▷ MP-RAGE: very high resolution T1-weighted images à showing very good anatomical detail (brain).

 

TFL (Turbo-FLASH, Siemens), MP-RAGE (Magnetization Prepared Rapid Acquired Gradient Echo, Siemens), FSPGR (Fast SPGR, GE).

 

▷ GE Echo Planar Imaging.

 ► fastest pulse sequence.

 ► real-time cardiac imaging.

 ► functional MRI of brain.

 

7. Clinical Application.

Pulse Sequences		Applications
SE	SE	T1, PD, T2 for anatomical areas.
		MT-frequency off set 8~16ms MT pulse.
		Fermi Pulse (high  FA, lower amplitudes)
FSE	FSE	T1, PD, T2-WI images
		breathhold abdominal images
		joint scan
		use blurring cancellation, ESPò
	T1-FLAIR(IR-FSE)	achieve better tissue CNR and SNR
		in same or shorter scan time than SE T1.
	T2-FLAIR(IR-FSE)	the null point of CSF, TI:2000~2300ms
	Double or Tripple IR-FSE	cardiac anatomy, myocardial wall masses
		valve leaflets, black blood, carotid imaging
	FR-FSE	refocused -90o RF.
		PD, T2-WI of spine
		abdomianal breath hold, head, joint.
		MRCP, T2-spine, IAC
	SSFSE(IR-SSFSE)	short ESP, 0.5NEX (half-fourier)
		to reduce motion artifacts and scan time
		to scan uncooperative patients
		for BH abdominal and cardiac imaging with long TE (300~1300ms) to GB & biliary tree
	IR-FSE	suppress the signal from fat in ABD & extrimity
		do not use with contrast studies because enhancing pathology could be suppresed
GE	SPGR	T1-WI,
		short TR (40~60ms), moderate flip angle (30o~50o)
	GRE	generally create T2* contrast
		C-spine, Knee
	Sequential Fast GRE/SPGR	T1, T2* BH ABD & pelvis imaging
		ultra-fast localizers
		BH cardiac/aortic arch imaging.
	Multi-phase Fast SPGR	temporally resolved contrast studies
		joint motion studies of knee, TMJ, Wrist
	3D Fast GRE/SPGR	high resolution T1, T2* joint & musculoskeletal image when fast scan times are desired
		reformat into multiple planes
		BH ABD & breast w/wo SPECIAL
		multi-phase contrast enhanced volume imaging
	FIESTA	fully balanced steady-state coherent image
		high SNR & T2/T1 contrast at very short TR
		cardiac function, valve assessment, wall motion, qantitative analysis, great vessels, valvular morphology
		(with fat-sat) biliary tree, urinary tract, great vessels & branches in abdomen / when contrast adminstration is contraindicated.
	3D FIESTA	whole body iamging, bile ducts, cochelia, joint, spine for disc herniation, spinal cord block, IACs
	3D FIESTA-C	cycling of the RF phase
		to reduce banding artifacts and improve image homogeneity. (when TR >4~5ms, dark band appears on the 3D FIESTA)
		inter-vertebral discs, hydrocephalus obstructions, biliary tree dilatation, cholangio-pancreato graphy, IAC applications
	MERGE	Multi-Echo Recalled Gradient Echo: 2D fast GRE with multiple echos
		use larger receive bandwidth (31.24KHz) which reduces the chemical and susceptibility artifacts.
		T2* WI C-spine imaging: improve visualization of cord compression and parenchymal disease.
	LAVA	3D SPGR with Partial Kz filling techniques
		segmented SPECIAL technique
		liver imaging.