Fast spin echo
|Type of sequence||Philips||Siemens||GE||Hitachi||Toshiba|
|Multi-echo SE||Multi SE||
|Fast SE||Turbo SE||Turbo SE||Fast SE||Fast SE||Fast SE|
Fast spin echo
In fast spin echo sequences, the interval of time after the first echo, is used to receive the echo train, to fill the other k-space lines in the same slice . Because of the reduced number of repetitions (TR) required, the k-space is filled faster and slice acquisition time is reduced.
This is done by applying new 180° pulses to obtain a spin echo train. After each echo, the phase-encoding is cancelled and a different phase-encoding is applied to the following echo.
The number of echoes received in the same repetition (during TR time) is called the Turbo Factor or Echo Train Length (ETL).
Multi-echo SE sequences
These sequences allow several images of the same slice position without increasing overall acquisition time. The advantage is that the images are obtained with a different contrast, which is useful in characterizing certain lesions (for example, highlighting contrast at long TE for hepatic angioma, which appears as a relative hypersignal).
After the first echo is obtained, there is a free interval until the next TR. By applying a new 180° pulse, a new echo is received, with the same phase encoding, to build the second image . The echo time of the 2 images differs and the second image will be more T2 weighted than the first.
Typically, these sequences are used to obtain simultaneously PD- and T2-weighted images.
Contrast, resolution, scan time
The contrast in fast spin echo is modified in relation to a standard spin echo sequence. As the echoes are received at different echo times, the echoes corresponding to the central k-space lines are the ones that will determine image contrast. The moment at which theses echoes are acquired is called effective TE.
In T1 weighted sequences, the need to choose a short TR limits echo train length. This type of sequence is very commonly used in T2 weighting, namely in pelvic imagery.
Fat signal in fast spin echo
Within lipid molecules a spin-spin coupling (J coupling) occurs between the atomic nuclei. This coupling shortens relaxation time T2. Fast repetition of 180° pulses in fast spin echo sequences will perturb J coupling, causing fat T2 to lengthen.
Thus, fat has a higher T2 signal in fast spin echo than in standard spin echo, the latter respecting J coupling.
A DIET (Delayed Interval Echo Train) sequence is a fast SE sequence where the delays between 180° pulses are designed to respect J coupling: as a result, the fat maintains an appearance closer to that observed in a standard SE sequence.
Interest and limits
The interest of fast SE sequences resides in their speed (around ten seconds) added to their low sensitivity to magnetic susceptibility artifacts and magnetic field heterogeneities.
Modifications in contrast and fat signal must be taken into account in interpreting the images. The risk of artifacts and the large quantity of radiofrequency energy deposited by 180° pulses restricts the parameters (TR, effective TE, echo train length) of this type of sequence.
Fast spin echo can be combined with the technique developed for multi-echo sequences to obtain images faster with different contrasts in the same zone of interest.
- Spin echo
- Fast spin echo
- Ultrafast spin echo
- Inversion Recovery / STIR / FLAIR
- Gradient echo
- Spoiled gradient echo
- Ultrafast spoiled gradient echo
- Steady-state gradient echo
- T2-enhanced steady-state gradient echo
- Balanced gradient echo
- Echo planar imaging (EPI)
- Hybrid echo (spin echo + gradient echo)