New-MRI-Lecture.pdf

Transcript

10/1/24

Cluster 5: MRI Basic Components of
(I. Physical MRI
Principles of MRI)
-Simplified Version-
1. Scanner
2. Computer
3. Recording Hardware
Prepared by:
Juan Carlo C. Bentinganan, MSRT, RRT

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Main
Components of
Static Magnetic
a Scanner: Field (B)

Static Magnetic Field Coils
Gradient Coils
RF (Radiofrequency Coils)

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3 Methods to Generate Magnetic Field

1. Fixed Magnet (permanent magnet)
2. Resistive Magnet (electromagnet)
3. Superconducting Magnet
Fixed magnets and resistive magnets are generally restricted to field strength below 0.4 tesla
High-resolution imaging systems use super conducting magnets
Super conducting magnets are large and complex.
They need the coils to be soaked in liquid helium to reduce their temperature.

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Gradient Coils Radiofrequency Coils

Gradient coils are used to produce deliberate variations in
the main magnetic field
RF coils act as transmitter and
These variations allow for localization of the tissue slicing receiver
as well as for phase encoding and frequency encoding. They are the “antennas” of
the MRI system
They transmit RF signal and
receive the return signals.

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MRI Hardware Four Basic Steps are involved in getting an MR
image
Magnet 1. Placing the patient in the magnet
RF Coil 2. Sending RF pulse by coil

Gradient Echo 3. Receiving signals from the patient by coil.
4. Transformation of signals into image by complex
Shim Coil
processing in the computers

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Basic Principles of MRI Spin Angular Momentum
(h)
MRI is based on the principle of NMR (Nuclear Magnetic
Resonance)
Spin is an intrinsic angular
NMR – certain atomic nuclei demonstrate the ability to absorb momentum of charged
and re-emit RF energy when placed in a magnetic field. nucleus.
Hydrogen atoms are most commonly used as they are There are 2 types of spins
called as “spin up” and “spin
present everywhere in the body
down”

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Why Hydrogen?

N ucleus needs to have 2 properties:
- Spin
- charge
Nuclei are made of protons and neutrons
- Both have spin ½
- Protons have charge
Pairs of spins tend to cancel, so only atoms with an odd number of protons or
neutrons have spin

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Magnetic Dipole Moment Gyromagnetic Ratio
(nu)
It is a unique value for each type of nucleus given by
Gamma (y) gyromagnetic ratio = Magnetic Dipole Moment (nu)
It is defined as the property of a
spin angular momentum
nucleus that causes it to behave
like a tiny bar magnet i.e it tries
to align itself parallel in a
magnetic field

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Precession

It is defined as the change in the rotational axis of a rotating body when an
external magnetic field ( torque) is applied.

“wobble” spin of a hydrogen atom

LARMOR FREQUENCY - Defines that each type of nucleus will precess at a
unique frequency in the magnetic field (torque) is applied.
(w) Omega = (y) gyromagnetic ratio * (B) magnetic field

1. Precession frequency is never constant

2. It is proportional to Bo. (i.e. the external magnetic field)

3. It becomes higher as the strength of the external magnetic field increases.

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Test Questions: 1.What type of nonionizing
electromagnetic radiation does MR
use?
A. x-ray
B. Gamma
C. Radiofrequency
D. Alpha

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1.What type of nonionizing 2. When protons spin in place within the
electromagnetic radiation does MR atom they create
use? A. A small magnetic field
A. x-ray B. A small hydrogen moment
C. An electrical charge
B. Gamma D. Pressure on the electron
C. Radiofrequency
D. Alpha

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2. When protons spin in place within the 3. Precessional frequency is
atom they create determined by the ___equation
A. A small magnetic field A. Faraday
B. A small hydrogen moment
C. An electrical charge
B. Larmor
D. Pressure on the electron C. Precessional
D. Magnetic frequency

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3. Precessional frequency is Concept of Magnetization
determined by the ___equation
A. Faraday
B. Larmor
C. Precessional
D. Magnetic frequency

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Magnetization (M) Transverse Plane: It is
perpendicular to Bo (x, y)
Transverse Magnetization:

is defined as the net single - When a magnetic field
perpendicular to B is applied (i.e.
B1) the magnetization is flipped
vector obtained by adding all out of alignment with B and this
angle is called ”flip angle”
the individual MDMs - Needs to take place for protons
to precess and this is achieved by
giving the radiofrequency signal
(RF signal)
- If the applied B1 is long enough
to flip M by 90 degree we call it
“90 degree pulse”

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Introduction to Relaxation Free Induction Decay (FID) Precession of
the particles is
influenced by
the radiation
frequency pulse
given

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Transverse When the RF pulse is switch
off, the protons precessing lose
T2
Relaxation their phase (dephasing) and Time taken by the
their precessing decreases. transverse
magnetization to return
to its original vector is
called as "T2 relaxation
time'

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T2 Weighted T2 Weighted Images
MRI
The images are made T2-wighted by keeping the TE longer. At
short TE, tissues with long as well as short T2 have strong signal.
At longer TE, only those tissues with long T2 will have sufficiently
strong signal and the signal difference between tissues with short
and long T2 will be pronounced.

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SPIN-SPIN Relaxation Time Longitudinal Relaxation

When the radiofrequency (RF) pulse is switched off, the high energy protons tend to transfer
As the protons lose their precession and begin to relax, energy to surrounding lattice and align themselves along z- axis
they transfer their energy to low energy protons in the
process of defacement.
Hence T2 is also called as spin-spin relaxation time.

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T1 T1 Relaxation
Time
Time taken by the longitudinal magnetization to return to it's
original value after the RF signal has been switched off is
called 'T1’
it is the time taken for 63% of nuclei to return to lower energy
state following a 90 degree pulse
Also called “Spin Lattice Relaxation”
Can be measured in NMR technique

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T1 Weighted T1 Weighted Images
MRI
keeping the TR short. If TR is long the tissues with long T1 will
also regain maximum LM giving stronger signal with next RF
pulse.
This will result in no significant difference between signal intensity
of tissues with different T1. With short TR only the tissues with
short T1 will show high signal intensity.

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Test Questions: 1. The MR signal generated by a single RF-pulse is called a
_______.
a. Free induction decay (FID)
b. Spin echo (SE)
c. Gradient echo (GRE)
d. Stimulated echo (STE)

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1. The MR signal generated by a single RF-pulse is called a 2. A spin-echo sequence using a short TR and long
_______. TE produces
a. Free induction decay (FID) a. A T1-weighted image
b. Spin echo (SE) b. A T2-weigthed image
c. Gradient echo (GRE) c. A PD-weighed image
d. Stimulated echo (STE)
d. A noisy low contrast image

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2. A spin-echo sequence using a short TR and long
TE produces

a. A T1-weighted image
b. A T2-weigthed image
c. A PD-weighed image
d. A noisy low contrast image

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Various MRI Introduction
Sequences

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Magnetic Resonance
Imaging
MRI Pulse
Sequence
an imaging modality that uses a programmed
non-ionizing radiation to create
useful diagnostic images.
set of changing
magnetic
gradients.

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Number of
Parameters
MRI Principle

TE
TR
Flip Angle
Diffusion Weighting
(Multiple sequences are grouped together into an MRI
protocol.)

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Two (2) Basic Principles of NMR

Atoms with an odd number of protons or neutrons have
MRI is based on the Nuclear Magnetic Resonance spin
(NMR) A moving electric charge, be it positive or negative,
produces a magnetic field
Body has many such atoms that can act as good MR
nuclei (1H,13C, 19F, 23Na)

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MRI Scanner Main
Components:
TR & TE

Magnet – in which the patient lies
Radio wave Antenna - to send
signals to the body and then
receive signals back.
Scanner - These returning signals
are converted into images by a
computer attached to the scanner.

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TR (Repetition Time) TE (Echo Time)

the time between two excitations time interval in which signals are measured after RF
excitation

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In General Why MRI?

No Ionizing Radiation
Short TR (45 ms) scan is T2 W Superior soft tissue contrast

Long TR (>2000 ms) and Short TE (