Medical Imaging

Question 1

How are X-rays produced?

Answer 1

By rapidly accelerating or decelerating charged particles - their kinetic energy is transferred into high-energy photons

Question 2

How can you differentiate between X-rays and Gamma rays?

Answer 2

X-rays and gamma rays have frequencies that overlap, so you can’t distinguish them by their wavelengths. Instead, you have to use their method of production - gamma rays come from radioactive decay or particle collisions with a mass defect, whereas X-rays are produced by accelerating charged particles.

Question 3

Why are X-rays used in medical imaging often referred to as ‘soft X-rays’?

Answer 3

Because they have energies that are lower than gamma rays.

Question 4

Describe the general structure of an X-rays tube.

Answer 4

Heated filament (cathode) and tungsten anode with a potential difference between them of up to 200kV and sealed in a vacuum tube.

Question 5

How does an X-rays tube work?

Answer 5

Electrons are emitted from the heated filament via thermionic emission and drawn towards the anode. They collide with the anode and some of their Ek is released as X-rays in all directions (the rest is transferred to heat energy within the anode).

Question 6

Why does the X-rays tube need a vacuum?

Answer 6

To prevent electrons from colliding with molecules of air before they gain enough energy to release X-rays.

Question 7

How is the anode prevented from overheating?

Answer 7

By either rotating it so that a new section of it is in contact with the X-rays all the time or by using water as a coolant, circulating it through the anode.

Question 8

How are the X-rays focused into one beam?

Answer 8

The vacuum tube is encased in a material that is thinner in one area, so only X-rays that pass through that section are released from the tube. They then pass through a collimator - a series of straight, parallel tubes that absorb any rays that are not travelling parallel to the axis of the tubes.

Question 9

Why is it better for X-rays to be in a beam rather then emitted in all directions?

Answer 9

Because it allows them to be directed at specific areas (like a broken bone) and minimises the patient’s exposure to them.

Question 10

What is x-rays attenuation

Answer 10

When a material absorbs X-rays, decreasing the intensity exponentially

Question 11

How can you calculate the intensity of X-rays leaving a material?

Answer 11

I = Io e^-μx
Io = initial intensity (Wm^-2)
μ = attenuation (absorption) coefficient (m^-1)
x = thickness of the material (m)

Question 12

Explain the process of taking an X-ray of a patient

Answer 12

X-rays are directed at an area of a patient’s body and pass through the bone and soft tissue. Since bone has a higher attenuation coefficient, it absorbs more X-rays than soft tissue does. If the photographic film is placed behind the patient, the areas where the bone is will not blacken as much as the areas of soft tissue, creating an image of the inside of the patient’s body. However, nowadays, digital detectors are used in place of photographic film.

Question 13

The greater the attenuation (absorption) coefficient…

Answer 13

…The more the material will absorb incident X-rays

Question 14

Explain the process of simple scattering

Answer 14

• X-rays of energy between 1 and 20keV are directed at a material
• The X-rays will reflect off layers of atoms or molecules in the material because they have insufficient energy to undergo more complex processes (like the photoelectric effect)

Question 15

Explain the process of the photoelectric effect

Answer 15

• X-rays of energy less than 100keV are directed at a material
• The X-rays can be absorbed by electrons in the material if they have the same energy as the ionisation energy of the atoms
• When an X-ray is absorbed, a photoelectron is released and another electron may de-excite, releasing another photon in the process

Question 16

Explain the process of the Compton Effect

Answer 16

• X-rays of energy between 0.5 and 5 Mev are directed at a material
• the X-rays will lose a small amount of their energy to electrons in the absorbing material due to an inelastic collision between the photon and electron.
• The scattering X-rays photon will have less energy than before (greater wavelength)
• The Compton electron will be scattered in a different direction as momentum must be conserved
• The wavelength can only change up to 2 times greatest then the incident wavelength

Question 17

Explain the process of pair production?

Answer 17

An X-ray of energy greater than 1.02 Mev passes through the electric field of an atom

• An elctron-positron pair is produced
• The positron will annihilate with another electron and produce two photons

This process is not very important in medical X-rays as the photon energies are usually not high enough to cause pair production

Question 18

Define contrast media and give two examples?

Answer 18

High attenuation coefficient materials that have meavy atoms with a larger proton number (and therefore a large number of electrons). They are easily identified in X-rays images as they absorb a lot of X-rays.

Examples of contrast media include Barium (Z=56) or Iodine (Z=53) - compared to soft tissue (Z≈ 7)

Question 19

Define the relationship between attenuation coefficient and proton number

Answer 19

μ ∝ Z^3

Question 20

What does the CAT stand for in CAT scan?

Answer 20

Computerised Axial Tomography

Question 21

What is a CAT scan and how do they work?

Answer 21

A CAT scan is a 3D X-ray image of a patient’s body made up of lots of 2D images. An X-ray tube generates a fan-shaped beam that is directed onto a patient that is laying down. There is a ring of detectors. The tube and the detectors around the patient and up and down their body to create a 3D image of their whole body

Question 22

Compare CAT scans to conventional X-rays images

Answer 22

CAT scans give a better resolution image, and having a 3D image makes it easier to assess the injury. However, CAT scans take significantly longer than conventional X-rays so the patient is exposed for longer

Question 23

Define medical tracer

Answer 23

A compound made of a radioactive isotope and specific elements that collects in a particular location in the body. Medical tracers can be used to locate things such as cancerous tumors in the body.

Question 24

How are tracers used in a non-invasive diagnosis and which type of radiation is best-suited for it?

Answer 24

The tracer is administered to the patient and its radioactive emissions are detected from the outside. Gemma emitters are the best for this since they are the least ionising and most penetrative.

Question 25

What are the characteristics of radioisotopes used in medicine and why are they important?

Answer 25

They usually have high activities and short half-lives. This is image can be obtained quickly, the patient is not exposed to harmful radiation for longer than necessary, and only a small amount of the radioactive substance is requires

Question 26

Why are many of the radioactive sources needed for medical tracers produced on sites?

Answer 26

Because they have such short half-lives meaning they need to be used almost immediately.

Question 27

What is Technetium-99?

Answer 27

A gamma-only emitter. It is in a metastable state (shown by the m in its name), meaning it remains in an excited state for a prolonged period of time. In this state, it has a half-life of 6 hours. After this, it will decay into Technetium-99, whish is a stable isotope with a half-life of 210,000 years

Question 28

What is a gamma camera used for?

Answer 28

Detecting gamma photons emitted by medical tracers inside the body

Question 29

Describe the general structure of a gamma camera.

Answer 29

Collimator which only allows photons travelling a certain
direction through
Scintillation crystal which emits many visible light photons for
every incident high-energy photon
Photocathode which produces an electron for every incident
visible photon
Photomultiplier tube which amplifies the signal
Computer which detects the signal and displays the image on a
screen.

Question 30

Explain briefly the process that occurs in a gamma

Answer 30

camera when gamma photons are incident on it.
Photons are collimated and then incident on a scintillation crystal,
which absorbs the gamma photons and releases thousands of
visible light photons. These are then directed to a photocathode
where an electron is produced for every incident visible photon.
The electrons are passed into a photomultiplier tube which
releases more electrons. The position of impact on the scintillator is
used to locate the emission site of the original gamma photon The
signal is detected by the computer and the image is displayed.

Question 31

Describe the structure of a PET scanner.

Answer 31

A ring of gamma cameras placed aroun

patient in order to create a 3D image.

Question 32

Explain the process of a PET scan

Answer 32

A positron emitter is administered to the patient. The positrons
travel only a few millimetres before annihilating with an electron
and releasing two gamma photons which are detected at two
diametrically opposed detectors in the camera ring. The arrival
times are recorded and speed is known so the location of
annihilation can be calculated. Since annihilation is very close to
the initial positron emission,
the location of the tracer can be
estimated. This is repeated until a 3D image can be produced.

Question 33

Give an example of a radioisotope

commonly used in PET scans.

Answer 33

Fluorine-18 (made by bombarding Oxygen-18 with protons)

Has a half-life of approximately 110 minutes,

Question 34

What is fluorodeoxyglucose and how is it

used?

Answer 34

Glucose substituted with Fluorine-18. It is used in PET scans to locate areas in the body with high respiration rates such as cancerous tumours or active areas of the brain.

Question 35

Evaluate the pros and cons of PET

scans.

Answer 35

{PMT
Evaluate the pros and cons of PET scans.
Pros: non-invasive, accurately demonstrate organ function, can be used to observe the effects of various medications

Cons: expensive, require tracers to be made on-site.

Question 36

Define ultrasound.

Answer 36

Longitudinal sound waves with a frequency greater than the range of human hearing
( > 20kHz )

Question 37

What are the pros of using ultrasound?

Answer 37

It is non-ionising, non-invasive, quick and affordable.

Question 38

What is ultrasound used for?

Answer 38

Finding the boundary between two media.

Question 39

Explain the Piezoelectric effect.

Answer 39

A piezoelectric material either:
1. Generates a pd when it is contracted or expanded
2. Will contract or expand when a pd is
applied.

Question 40

How do piezoelectric crystals work?

Answer 40

Applying a pd to a piezoelectric crystal will cause it to produce ultrasound waves, and a piezoelectric crystal absorbing ultrasound waves will produce an alternating pd. They tend to be made from quartz, polymeric or ceramic materials.

Question 41

How does an ultrasound transducer

work?

Answer 41

It has an alternating pd that causes a
piezoelectric crystal to contract and expand at resonant frequency of the crystal to maximise intensity. Once the ultrasound has been created, the pd is turned off and the reflected signal is detected by the transducer.

Question 42

What is an ultrasound A-scan?

Answer 42

It uses a single transducer to emit a signal and then detect the reflected signal. It is used to determine the distance from the device to the point of reflection (usually a boundary between media) by using the time and the speed of sound in the medium

Question 43

What is an ultrasound B-scan?

Answer 43

A series of A-scans that are stitched together to create a 2D image. The transducer is moved across the patient’s skin and uses the time and speed to calculate distance to a boundary at each point.

Question 44

Why are ultrasounds pulsed?

Answer 44

To allow time for the reflected signal to be received by the transducer.

Question 45

Why do smaller wavelengths give mor

detailed images?

Answer 45

They allow the sound waves to diffract around smaller points of detail on the object that is being scanned.

Question 46

What is acoustic impedance?

Answer 46

The product of a sound wave’s density and the speed of sound in the medium.
Z= ρc
Unit: kg m^-2 s^-1

Question 47

Explain what happens when an

ultrasound hits a boundary between two media.

Answer 47

A fraction of the wave’s energy/intensity is reflected and the rest is transmitted. The amount is dependent on the acoustic
impedance of each medium.

Question 48

What is the reflection coefficient?

Answer 48

The ratio of the reflected intensity to the original intensity: Ir/Io

Question 49

How can you calculate the reflection

coefficient using the impedances of two media?

Answer 49

Ir/Io= (Z2 - Z1 )^2 | (Z2 + Z1)^2
Where Z1 is the impedance of the first medium and Z2 is the impedance of the incident medium.
This formula only applies when the ultrasound is incident on the boundary at 90° (angle of incidence = 0°)

Question 50

When Z1 and Z2 are very close, what

happens?

Answer 50

Most of the energy/intensity is transmitted.

Question 51

When Z1 and Z2 are very different, what happens?

Answer 51

Most of the energy/intensity is reflected.

Question 52

How can reflection be minimised when
using a transducer against a patient’s
skin?

Answer 52

Since the impedances of air and skin are very different, most of the intensity would be reflected. However, using an impedance matching gel between the transducer and the skin (that has a Z similar to skin) minimises reflection.

Question 53

Define the Doppler Effect.

Answer 53

When there is a change in frequency of a wave when it is reflected or emitted by a moving source.
When the source is moving away the frequency and wavelength (pitch lowers) decreases and vis versa

Question 54

What is Doppler imaging?

Answer 54

A non-invasive technique to measure blood flow.

Question 55

Explain the process of Doppler imaging.

Answer 55

1. Ultrasound waves are sent into a blood vessel
2. The iron in the blood cells reflects the waves back to the transducer and the frequency is shifted depending on the direction and how fast the cells are moving

Question 56

Give the formula for the change in
frequency of the ultrasound waves
during Doppler imaging.

Answer 56

Δf/f = (2fvcosθ) / c
f = original frequency, 
V = speed of blood flow,
θ = the angle between the probe and the direction of blood flow
C= the speed of ultrasound in blood.