Spin–lattice relaxation

During nuclear magnetic resonance observations, spin–lattice relaxation is the mechanism by which the longitudinal component of the total nuclear magnetic moment vector (parallel to the constant magnetic field) exponentially relaxes from a higher energy, non-equilibrium state to thermodynamic equilibrium with its surroundings (the "lattice"). It is characterized by the spin–lattice relaxation time, a time constant known as T₁.

There is a different parameter, T₂, the

spin-spin relaxation time, which concerns the exponential relaxation of the transverse component of the nuclear magnetization vector (perpendicular to the external magnetic field). Measuring the variation of T₁ and T₂ in different materials is the basis for some magnetic resonance imaging techniques.^[1]

Nuclear physics

T₁ characterizes the rate at which the longitudinal M_z component of the magnetization vector recovers exponentially towards its thermodynamic equilibrium, according to equation

M_{z}(t)=M_{z,\mathrm {eq} }-\left[M_{z,\mathrm {eq} }-M_{z}(0)\right]e^{-t/T_{1}}

Or, for the specific case that

M_{z}(0)=-M_{z,\mathrm {eq} }

M_{z}(t)=M_{z,\mathrm {eq} }\left(1-2e^{-t/T_{1}}\right)

It is thus the time it takes for the longitudinal magnetization to recover approximately 63% [1-(1/e)] of its initial value after being flipped into the magnetic transverse plane by a 90° radiofrequency pulse.

Nuclei are contained within a molecular structure, and are in constant vibrational and rotational motion, creating a complex magnetic field. The magnetic field caused by thermal motion of nuclei within the lattice is called the lattice field. The lattice field of a nucleus in a lower energy state can interact with nuclei in a higher energy state, causing the energy of the higher energy state to distribute itself between the two nuclei. Therefore, the energy gained by nuclei from the RF pulse is dissipated as increased vibration and rotation within the lattice, which can slightly increase the temperature of the sample. The name spin-lattice relaxation refers to the process in which the spins give the energy they obtained from the RF pulse back to the surrounding lattice, thereby restoring their equilibrium state. The same process occurs after the spin energy has been altered by a change of the surrounding static magnetic field (e.g. pre-polarization by or insertion into high magnetic field) or if the nonequilibrium state has been achieved by other means (e.g., hyperpolarization by optical pumping).^{[citation needed]}

The relaxation time, T₁ (the average lifetime of nuclei in the higher energy state) is dependent on the gyromagnetic ratio of the nucleus and the mobility of the lattice. As mobility increases, the vibrational and rotational frequencies increase, making it more likely for a component of the lattice field to be able to stimulate the transition from high to low energy states. However, at extremely high mobilities, the probability decreases as the vibrational and rotational frequencies no longer correspond to the energy gap between states.

Different tissues have different T₁ values. For example, fluids have long T₁s (1500-2000 ms), and water-based tissues are in the 400-1200 ms range, while fat based tissues are in the shorter 100-150 ms range. The presence of strongly magnetic ions or particles (e.g.,

paramagnetic) also strongly alter T₁ values and are widely used as MRI contrast agents

.

T₁ weighted images

Larmor frequency) and then the excess energy is released in the form of a minuscule amount of heat to the surroundings as the spins return to their thermal equilibrium. The magnetization of the proton ensemble goes back to its equilibrium value with an exponential curve characterized by a time constant T₁ (see Relaxation (NMR)).^{[citation needed}

]

T₁ weighted images can be obtained by setting short

echo time (TE) such as < 40 ms in conventional spin echo

sequences, while in Gradient Echo Sequences they can be obtained by using flip angles of larger than 50^o while setting TE values to less than 15 ms.

T₁ is significantly different between grey matter and white matter and is used when undertaking brain scans. A strong T₁ contrast is present between fluid and more solid anatomical structures, making T₁ contrast suitable for morphological assessment of the normal or pathological anatomy, e.g., for musculoskeletal applications.

In the rotating frame

Spin–lattice relaxation in the rotating frame is the mechanism by which M_xy, the transverse component of the magnetization vector, exponentially decays towards its equilibrium value of zero, under the influence of a

spin-lattice relaxation time.^[2]

T_1ρ MRI is an alternative to conventional T₁ and T₂ MRI by its use of a long-duration, low-power radio frequency referred to as spin-lock (SL) pulse applied to the magnetization in the transverse plane. The magnetization is effectively spin-locked around an effective B₁ field created by the vector sum of the applied B₁ and any off-resonant component. The spin-locked magnetization will relax with a time constant T_1ρ, which is the time it takes for the magnetic resonance signal to reach 37% (1/e) of its initial value, $M_{xy}(0)$ . Hence the relation: $M_{xy}(t_{\rm {SL}})=M_{xy}(0)e^{-t_{\rm {SL}}/T_{1\rho }}\,$ , where t_SL is the duration of the RF field.

Measurement

T_1ρ can be quantified (relaxometry) by curve fitting the signal expression above as a function of the duration of the spin-lock pulse while the amplitude of spin-lock pulse (γB₁~0.1-few kHz) is fixed. Quantitative T_1ρ MRI relaxation maps reflect the biochemical composition of tissues.^[3]

Imaging

T_1ρ MRI has been used to image tissues such as cartilage,^[4]^[5] intervertebral discs,^[6] brain,^[7]^[8] and heart,^[9] as well as certain types of cancers.^[10]^[11]

References

ISBN 978-3-7460-9518-9
.

ISBN 978-0470511176
.

PMID 17075961
.

PMID 17307365
.

PMID 20432308
.

PMID 21358489
.

PMID 18479942
.

PMID 22270722
.

PMID 20677236.{{cite journal}}: CS1 maint: numeric names: authors list (link
)

PMID 19366661
.

PMID 22302557
.

Furhter Reading

McRobbie D., et al. MRI, From picture to proton. 2003

Hashemi Ray, et al. MRI, The Basics 2ED. 2004.

Retrieved from "https://en.wikipedia.org/w/index.php?title=Spin–lattice_relaxation&oldid=1220360940"

[Rinck-1] ISBN 978-3-7460-9518-9
.

[Levitt-2] ISBN 978-0470511176
.

[3] PMID 17075961
.

[4] PMID 17307365
.

[5] PMID 20432308
.

[6] PMID 21358489
.

[7] PMID 18479942
.

[8] PMID 22270722
.

[9] PMID 20677236.{{cite journal}}: CS1 maint: numeric names: authors list (link
)

[10] PMID 19366661
.

[11] PMID 22302557
.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

Nuclear physics

T1 weighted images

In the rotating frame

Measurement

Imaging

See also

References

Furhter Reading

T₁ weighted images