Medical Physics

Question 1

What are ultrasounds?

Answer 1

Ultrasound consists of sound waves (longitudinal waves) of such high frequency that they cannot be detected by the human ear. Strictly speaking, the ultrasound range starts at about 20 kHz, but medical applications use much higher frequencies, typically between 1 MHz and 20 MHz

Question 2

How can ultrasounds be produced?

Answer 2

By applying an alternating voltage to a piezoelectric crystal. The crystal will expand and contract at the frequency of the voltage due to the pizolectric effect. This will produce a pressure wave (ultrasound). The piezolelctric crystal must be cut to a certain size in order to work in resonant condition

Question 3

What is a common material for a piezoelectric crystal?

Answer 3

Quartz

Question 4

How is an ultrasound pulse generated by a transducer?

Answer 4

A high frequency p.d. is applied at the natural frequency of the piezoelectric crystal causing the crystal to vibrate.

Question 5

How is an ultrasound pulse detected by a transducer?

Answer 5

Sound incident on the crystal causes it to vibrate generating an EMF across its faces.

Question 6

What is the piezoelectric effect

Answer 6

A voltage applied to a piezoelectric material induces some strain/deformation. The opposite is also true. Stress applied to a material induces a voltage

Question 7

What is an ultrasound A-scan?

Answer 7

A single transducer is placed on the skin emits a single, short pulse. Echoes return from boundaries between different body tissues. The output is displayed as a graph on an oscilloscope, showing how the echo amplitude changes with time

Question 8

What is an ultrasound B-scan?

Answer 8

A B-scan or brightness scan creates an image by scanning the ultrasound beam over the patient. A rapid sequence of A-scans is carried out as the beam sweeps across. The strength of the echo signal is used to control the brightness of a picture element, rather than the height of a trace on an oscilloscope

Question 9

How does an ultrasound A-scan calculate the distance to boundaries between tissues?

Answer 9

2 x Distance = v x t, where v is the speed of the ultrasound and t is the time interval between the pulse reflected by the first boundary and the pulse reflected by the second boundary.

Question 10

What determines the acoustic impedence of a substance?

Answer 10

The density and the speed of sound in the substance.

Question 11

What are the units of acoustic impedance?

Answer 11

kgm⁻²s⁻¹

Question 12

What is the intensity reflection coefficient for ultrasound?

Answer 12

The ratio (reflected intensity of ultrasound ÷ incident intensity of ultrasound)

Question 13

What factor determines the refelction intensity coefficient for ultrasound at a boundary?

Answer 13

The difference between the acoustic impedances of the two substances.

Question 14

Why does a coupling gel need to be used when performing an ultrasound?

Answer 14

Air pockets between the transducer and skin cause reflection of nearly all of the ultrasound at the skin-air boundary.

Question 15

What is an ultrasound coupling gel?

Answer 15

A substance applied to the skin and transducer with an impedance similar to skin.

Question 16

What is doppler ultrasound used for?

Answer 16

Measuring the speed of blood flow.

Question 17

What is measured in doppler ultrasound to determine the velocity of the blood?

Answer 17

The observed change in frequency of the reflected ultrasound pulse

Question 18

Why does the transducer have to placed away from the normal during a doppler ultrasound?

Answer 18

To ensure there is a component of the blood flow’s velocity in the direction of the ultrasound pulse.

Question 19

What is ∆f in the equation? ∆f = (2fvcosθ)÷c

Answer 19

Change in the observed frequency of the reflected ultrasound.

Question 20

What is v in the equation? ∆f = (2fvcosθ)/c

Answer 20

Blood flow speed.

Question 21

What is θ in the equation? ∆f = (2fvcosθ)/c

Answer 21

The angle between the tranducer axis and the blood flow.

Question 22

What is c in the equation? ∆f = (2fvcosθ)/c

Answer 22

The speed of ultrasound in blood

Question 23

What are the four mechanisms of X-ray attenuation?

Answer 23

Simple scattering (or Elastic scattering or Thomson scattering)
Photoelectric Effect
Compton Scattering (or inelastic scattering)
Pair Production

Question 24

What occurs during simple scattering of X-rays?

Answer 24

The X-ray interacts with an electron in an atom and changes direction but not energy.

Question 25

Which method of attenuation is most significant with X-rays with energy in the range 1-20keV?

Answer 25

Simple scattering (Or Elastic scattering)

Question 26

What occurs during the photoelectric effect attenuation of X-rays?

Answer 26

The X-ray is absorbed by an electron in an atom which gains the energy of the photon and leaves the atom.

Question 27

Which method of attenuation is significant with X-rays with energies up to 100keV?

Answer 27

Photoelectric effect

Question 28

What occurs during Compton scattering attenuation of X-rays?

Answer 28

The X-ray interacts with an electron in the atom causing the electron to be ejected and the photon to be scattered with reduced energy.

Question 29

Which method of attenuation is significant with X-rays with energy in the range 0.5-5MeV?

Answer 29

Compton scattering

Question 30

What occurs during pair production with X-rays?

Answer 30

An X-ray interacts with the nucleus of an atom converting the energy of the photon to and electron and a positron.

Question 31

Which method of attenuation start to occur with X-rays with energies of 1.02MeV?

Answer 31

Pair production

Question 32

What is I in the equation I = I₀e^(-µx)?

Answer 32

Transmitted intensity

Question 33

What is I₀ in the equation I = I₀e^(-µx)?

Answer 33

Intensity before absorption( Incident energy)

Question 34

What is µ in the equation I = I₀e^(-µx)?

Answer 34

Attenuation/absorption coefficient

Question 35

What is x in the equation I = I₀e^(-µx)?

Answer 35

Thickness of the absorbing substance

Question 36

What contrast medium is typically to examine blood flow?

Answer 36

Iodine

Question 37

What contrast medium is typically used to imagine the digestive system?

Answer 37

Barium sulfate

Question 38

What is the typical p.d. of an X-ray tube for medical imaging?

Answer 38

20-150kV

Question 39

What causes the emission of electrons from the cathode in an X-ray tube?

Answer 39

It is heated to produce thermionic emission.

Question 40

What connected above the anode in an X-ray tube?

Answer 40

The target metal

Question 41

What is an essential property for the target metal in an X-ray tube?

Answer 41

High melting point

Question 42

What causes the production of X-rays in an X-ray tube?

Answer 42

The deceleration of electrons when they hit the target metal/anode (Bremsstrahlung effect) and some descrete k-lines

Question 43

In an X-ray tube what happens to most of the kinetic energy lost by the electrons when they hit the anode?

Answer 43

It is transferred to thermal energy of the anode.

Question 44

What measures can be taken to prevent an anode melting in an X-ray tube?

Answer 44

It is cooled by water/oil and rotated

Question 45

What determines the maximum frequency of X-rays produced in an X-ray tube?

Answer 45

The maximum kinetic energy of a single electron.

Question 46

When is the equation λ = hc/eV used?

Answer 46

To find the minimum wavelengths of X-ray produced (by an X-ray tube)

Question 47

What happens to the x-ray spectra if the accelerating voltage in the x-ray tube is increased

Answer 47

The continuous spectra inreases in amplitude and shifts to the left. The K-lines do not change.

Question 48

Describe the beam used by CAT scanners

Answer 48

A thin (1-10mm) fan shaped beam

Question 49

What happens to the position of the X-ray tube during a CAT scan?

Answer 49

It rotates around the patient

Question 50

What are the key advantages of CAT scans over conventional X-rays?

Answer 50

They produce a 3D image and can distinguish between tissues with similar attenuation coefficients.

Question 51

What are the disadvantages of CAT scans compared to conventional X-rays?

Answer 51

The radiation dose is greater and they are more expensive and take more time.

Question 52

How does a CAT scan produce a 3D image?

Answer 52

A series of slices are imaged and processed via a computer to produce a 3D image.

Question 53

Which radionuclide is used for imaging with a gamma camera?

Answer 53

Technitium-99m

Question 54

Which radionuclide is used in PET scanning?

Answer 54

Fluorine-18

Question 55

Why are gamma emitting sources useful for imaging inside the body?

Answer 55

They are the least ionising and can penetrate through a patient to be detected externally.

Question 56

Why are short half-lives necessary for the radioisotopes used for medical imaging?

Answer 56

To ensure a large activity from a small amount and to minimise radiation dose after the procedure.

Question 57

What is a medical tracer?

Answer 57

A chemical compound containing a radioisotope that is put into the patients body.

Question 58

What is the function of a collimator in a gamma camera?

Answer 58

To absorb any photons not travelling along the axis of the tubes so the source location of gamma radiation can be idenitifed.

Question 59

How is a collimator in a gamma camera constructed?

Answer 59

It is a honeycomb of long, thin lead tubes.

Question 60

What is the function of a scintillator in a gamma camera?

Answer 60

It produces many photons of visible light when a gamma photon interacts with it.

Question 61

What is the function of the photomultiplier tubes in a gamma camera?

Answer 61

They convert visible light photons to an electrical pulse. They have a photocathode first that convert visible light into electrons, The through collision with a series of dynos kep at a graudally increasing potential the electrons are exponentially multiplied

Question 62

What is the function of the computer in a gamma camera?

Answer 62

It processes the signals from the photomultipliers to locate where the gamma ray originated to produce an image showing the concentrations of medical tracer.

Question 63

What process produces gamma photons in a PET scan?

Answer 63

lectron and positron annihilation.

Question 64

How is the the source of the gamma photons located in a PET scan?

Answer 64

By the time delay between the arrival of diametrically opposite gamma photons.

Question 65

Why is medical imaging using gamma emitting tracers useful?

Answer 65

It can measure the function of organs in the body rather than just the structure.

Question 66

What are the disadvantages of a PET scan?

Answer 66

They are expensive and require facilities (particle accelarotor) to prepare tracers local to the scanner.

Question 67

How is Fluorine -18 produced?

Answer 67

In a small particle accelarator. Hi energy protons collide with Oxygen-18 to produce Fluorine-18