Medical Imaging II PDF

Summary

This presentation covers Medical Imaging II, focusing on Nuclear Medicine Imaging. It explains the principles behind nuclear medicine, various imaging modalities, and the use of radiotracers. The presentation also delves into nomenclature, decay modes, and instrumentation.

Full Transcript

Medical Imaging II
Vicky Varghese
Nuclear Medicine Imaging
Projection radiography and computed
tomography, two imaging modalities
that rely on the transmission of photons
through the body to form images
Nuclear medicine, an imaging modality
that relies on the emission of photons
from within the body
The ionizing radiation emitted when the
radioactive atom undergoes radioactive
decay is used to determine the location
of the molecule within the body
 A radiotracer is injected into a peripheral arm vein of the patient, or
the patient inhales or ingests the radiotracer
Specialized instrumentation produces images of the internal
distribution of radioactivity, which is assumed to mirror the
distribution of the compound of interest
These images are compared with known distributions in different
disease states
In order to most accurately depict the biodistribution of radiotracers,
instrumentation that emphasizes high image quality and quantitative
accuracy has been developed
 Nuclear medicine is used whenever a
physician needs information on
physiologic or biochemical function
The two most common nuclear
medicine procedures are bone
scanning and myocardial perfusion
imaging
A projection radiograph can show a
fracture; a bone scan can show
active metabolism during the healing
process
Introduction
Nuclear medicine relies on radiopharmaceuticals introduced into the body to
trace the spatial and temporal distribution of the underlying physiological and
biochemical processes that govern the radiopharmaceutical’s distribution
Radiopharmaceuticals consist of both a chemical compound (the
‘‘pharmaceutical’’ portion of the word) and a radioactive atom (the ‘‘radio’’
portion of the word)
The radioactive atom undergoes radioactive decay, radiation is emitted that
leaves the body.
External imaging devices, such as scintillation cameras, record these radiation
emissions coming from the patient and produce either a planar, two-dimensional
image or cross-sectional, tomographic images.
Depending on the specific radiotracer, different physiological or biochemical
functions are imaged
Differences from the projection radiography
In nuclear medicine, however, each different radiotracer produces a
depiction of a completely different physiological or biochemical
function
Radiation that forms the basis of the image is not transmitted through
the body, but arises from the radioactive atoms within the body
hence referred to as emission imaging
Nomenclature
An atom consists of a nucleus of protons and neutrons, which
together are called nucleon
The atomic number Z is equal to the number of protons in the nucleus
and defines the element
The mass number A is equal to the number of nucleons in the nucleus
The term nuclide refers to any unique combination of protons and
neutrons that forms a nucleus. If a particular nuclide is radioactive
(i.e., it can undergo radioactive decay), it is termed a radionuclide
 Atoms with the same atomic number but different mass number (i.e.,
different numbers of neutrons) are called isotopes. For example,
carbon-11
Atoms with the same mass number but different atomic numbers are
called isobars. For example, carbon-11 decays to boron-11; the two
are isobars
Atoms with the same number of neutrons are called isotones
Atoms with the same atomic and mass number (i.e., the same
nuclide) but with different energy levels are called isomers
 The sum of the masses of the constituents of an atom (i.e., the
protons, neutrons, and electrons) is greater than the atom’s actual
mass. The difference between the sum of the masses of the atom’s
constituents and the actual mass is called the mass defect
The energy required to remove an electron completely from an atom
is the electron binding energy, which is greater for electrons in the
orbits closer to the nucleus because of the greater attractive force of
the nucleus for inner electrons
Radioactive decay is the process by which an atom rearranges its
constituent protons and neutrons to end up with lower inherent
energy
 Radioactivity describes how many radioactive atoms are undergoing
radioactive decay every second
The half-life t1/2 is the time it takes for the radioactivity (or the
number of radioactive atoms) to decrease by a factor of 2.
Line of Stability
If the different unique combinations of
protons and neutrons as a nucleus
that are found in nature are cataloged,
they can be separated into two
groups:
nonradioactive nuclides,
radioactive nuclides
the total number of nucleons, and the
ratio of neutrons to protons,
determine whether a nuclide is stable
or radioactive.
Modes of Decay
There are four main modes of decay:
1. alpha decay, which results in emission of an alpha particle;
2. beta decay, which results in emission of a beta particle
3. positron decay, which results in emission of a positron;
4. isomeric transition, which results in emission of a gamma ray.
These ionizing radiations fall into two classes: particulate radiation
and electromagnetic radiation.
Radiotracers
There are about 1,500 known radionuclides, of which 200 or so can
be purchased.
Out of these, however, only a dozen or so are suitable for nuclear
medicine for several reasons
We desire ‘‘clean’’ gamma ray emitters—that is, ones that do not also emit alpha and
beta particles (because these particles would only contribute to patient radiation dose
without usefully contributing to image formation)
In nuclear medicine we would prefer that there would be no attenuation of the
radiation. This is because in nuclear medicine we are trying to determine the location of
the emitters
Another important property of a radiotracer is its half-life. We need to be able to form
images in a matter of minutes, not seconds or hours.
it must be useful and safe to ‘‘trace’’ within the body, either by itself or attached to a
compound
 Iodine, for example is a naturally occurring
substance in the body, accumulating in the
thyroid gland. Iodine-123 or I-131 in a sodium
salt can be administered orally and measured in
the thyroid to assess thyroid function.
Technetium-99m can be used to label
diethylene triamine pentaacetic acid (DTPA),
which is filtered by the kidneys, and serial
images of the kidneys can be used to assess ,
renal function.
Gaseous O2 in which one oxygen atom has been
replaced by oxygen-15 is used to measure
blood flow and to assess oxygen metabolism
with positron emission tomography.
Fluorodeoxyglucose (FDG) is used by the body
like glucose, except that the (labeled) fluorine-
18 atoms remain where the molecule is first
used. Imaging the uptake of FDG in the brain,
for example, is thought to reveal aspects of the
mental processes involved in motor, perceptual,
and cognitive tasks
Planar Scintigraphy
As in diagnostic x-ray imaging, nuclear medicine imaging evolved from
projection imaging to tomographic imaging
Projection studies in nuclear medicine, called planar scintigraphy, have
always used the Anger scintillation camera, a type of electronic detection
instrumentation.
The corresponding tomographic imaging method, called single photon
emission computed tomography (SPECT), uses one or more rotating Anger
cameras to obtain projection data from multiple angles
Another imaging method, called positron emission tomography (PET), is
based on radiotracers labeled with radioactive atoms whose decay
produces a positron that is subsequently annihilated, producing two
gamma photons
Together, SPECT and PET are referred to as emission computed tomography
Instrumentation
The three basic imaging modalities in
nuclear medicine—planar imaging,
SPECT, and PET
Planar imaging and SPECT use
radiotracers that are gamma emitters,
while PET uses radiotracers that emit
positrons
SPECT and PET require tomographic
reconstruction techniques (like CT),
while planar imaging forms images by
projection
 Collimators
The collimator is a 1- to 2-inch thick slab of lead of
the same dimensions as that of the scintillation
crystal, with a geometric array of holes in it
The collimator provides an interface between the
patient and the scintillation crystal by allowing only
those photons traveling in an appropriate direction
to interact with the crystal
There are several types of collimators used with
Anger cameras: parallelhole, converging, diverging,
and pinhole.
The most commonly used collimator is the parallel-
hole collimator, which consists of an array of parallel
holes perpendicular to the crystal face
Scintillation Crystal
This type of detector is based on the property of certain crystals to
emit light photons (scintillate) after deposition of energy in the crystal
by ionizing radiation.
The most commonly used scintillation crystal in nuclear
instrumentation is sodium iodide with ‘‘thallium doping,’’ which is
written as NaI[Tl]
The scintillation crystals in a gamma camera are typically 10–25
inches in diameter and 1/4–1 inch thick.
The thicker crystals are used for high-energy gamma rays, while the
thinner crystals are used for low-energy gamma rays
Photomultiplier Tubes
Each gamma photon that interacts in
the scintillation crystal (by a
photoelectric or Compton scattering
process) produces a burst of light in
the crystal, comprising thousands of
light (scintillation) photons.
This light is reflected and channeled
out of the back of the crystal, through
a glass plate and is incident upon an
array of photomultiplier tubes.
Positioning Logic
When a gamma photon interacts with the
crystal, thousands of scintillation photons are
produced, and every PMT produces an output
pulse.
The goal of the Anger camera’s positioning
logic circuitry is to determine both where the
event occurred on the face of the crystal and
the combined output of all the tubes, which
represents the light output of the crystal
These output signals are denoted as X and Y
for the estimated two-dimensional position of
the event