In an external magnetic field, more hydrogen nuclei align with their magnetic

moments parallel to the external field than antiparallel

Protons subject to a strong static external magnetic field start to precess in phase

The frequency of precession (Larmor frequency) of protons in a static magnetic field

of 1.5 T equals 42.6 MHz

At 1.5 T, the precessional frequency of hydrogen nuclei in fat is 220 Hz lower than

that of hydrogen nuclei in water

Apart from hydrogen, other nuclei that can be polarized in an external magnetic

field include carbon 12C and oxygen 16O

A free induction decay (FID) signal can only occur after a 90 degree pulse

After a 90 degree pulse, the longitudinal magnetization recovers at the same rate as the

transverse magnetization decays

The rate of the longitudinal magnetization recovery does not depend on the external

magnetic field strength

Dephasing of the transverse magnetization is mainly due to spin–spin relaxation

The FID is not usually considered in clinical MRI

Signal is generated from 12C nuclei

Paramagnetic contrast agent is used to enhance tissue contrast

The SI unit for main magnetic field strength is Gauss

Scanning time is reduced by using shorter time to repeat (TR)

Vascular pulsation artefacts occur in the phase encoding direction

Larmor frequency is proportional to the proton density

the flip angle depends on the applied radiofrequency strength

the free induction decay signals are detected with gradient coils

nuclei with odd number of nucleons are used

the longitudinal magnetization lies perpendicular to the X-Y plane

The first radiofrequency pulse in a spin–echo pulse sequence is a 180 degree pulse

Rephasing of the transverse magnetization is caused by the 180 degree pulse

Effects of local field inhomogeneities on the MRI signal are eliminated

For practical purposes, the delay between excitation and the refocusing pulse is kept constant, but signal readout can be performed at any chosen echo time (TE)

Rephasing can only be performed once, and the whole sequence must be repeated to obtain another echo

increasing TR will decrease the signal intensity on T2-weighted

decreasing pixel size will decrease signal-to-noise ratio

image resolution is improved by increasing the matrix size

shimming improves field homogeneity

image quality is unaffected by TE (echo time)

TR is the time between two 90 degree radiofrequency pulses

Signal read-out during the 180 radiofrequency pulse

Field inhomogeneity is due to introduction of patient onto the magnetic field.

Spin-Spin relaxation is T1 relaxation.

T2 is the time for the MR signal to fall to 63% of its maximum value.