Radiation Generator

Question 1

What voltages were primarily used in external beam radiotherapy up to about 1950?

Answer 1

Up to 300 kVp

This refers to kilovoltage peak, a measure of the maximum voltage applied across the x-ray tube.

Question 2

What is Grenz ray therapy?

Answer 2

Treatment with beams of very soft (low-energy) x-rays produced at potentials below 20 kV

Grenz rays have very low depth of penetration and are no longer used in radiation therapy.

Question 3

What are the typical operating potentials for contact therapy machines?

Answer 3

40 to 50 kV

These machines are used for irradiating accessible lesions at very short source to surface distances.

Question 4

What is the half-value layer (HVL)?

Answer 4

The thickness of a specified material that reduces the exposure rate by one-half

HVL is used to express the degree of hardening or beam quality.

Question 5

What is the depth of maximum dose for superficial therapy beams?

Answer 5

Approximately 5 mm

Beyond this depth, the dose drop-off is too severe to deliver adequate depth dose.

Question 6

What is orthovoltage therapy used for?

Answer 6

Treatment with x-rays produced at potentials ranging from 150 to 500 kV

Most orthovoltage equipment operates at 200 to 300 kV.

Question 7

What is a major limitation of orthovoltage therapy?

Answer 7

High skin dose when adequate doses are delivered to deep-seated tumors

This became a concern leading to the use of megavoltage beams.

Question 8

What is supervoltage therapy?

Answer 8

X-ray therapy in the range of 500 to 1,000 kV

This therapy was developed in the 1950s and 1960s as a quest for higher-energy x-ray beams.

Question 9

What is the function of a resonant transformer in x-ray machines?

Answer 9

To generate x-rays from 300 to 2,000 kV efficiently

The transformer operates at its resonant frequency to achieve high amplitude voltage.

Question 10

What are megavoltage beams classified as?

Answer 10

X-ray beams of energy 1 MV or greater

This classification includes γ-ray beams produced by radionuclides.

Question 11

What does the Van de Graaff generator do in radiotherapy?

Answer 11

Accelerates electrons to produce high-energy x-rays, typically at 2 MV

The generator operates by collecting negative charges on a spherical dome.

Question 12

What is the main operational principle of a linear accelerator (linac)?

Answer 12

Uses high-frequency electromagnetic waves to accelerate charged particles

Electrons can be used directly for superficial tumors or to produce x-rays for deeper tumors.

Question 13

What are the two types of wave structures used in linear accelerators?

Answer 13

Traveling wave and standing wave structures

Each type has a different design for accelerating particles.

Question 14

How does the standing wave structure in a linear accelerator function?

Answer 14

Provides maximum reflection of waves at both ends to create stationary waves

This design allows for more efficient particle acceleration.

Question 15

What is the typical initial energy of electrons injected into the accelerator structure of a linac?

Answer 15

About 50 keV

Electrons gain energy from the microwave electromagnetic field during acceleration.

Question 16

What is a significant design feature of high-energy linear accelerators?

Answer 16

The accelerator structure can be placed horizontally or at an angle

This design allows for bending the electron beam before it strikes the target.

Question 17

What is the main function of the magnetron?

Answer 17

To produce microwaves as a high-power oscillator generating microwave pulses.

Question 18

What is the frequency of the microwaves generated by a magnetron?

Answer 18

About 3,000 MHz.

Question 19

Describe the construction of a magnetron.

Answer 19

It has a cylindrical construction with a central cathode and an outer anode containing resonant cavities machined from copper.

Question 20

How are electrons generated in a magnetron?

Answer 20

Through thermionic emission from a heated cathode.

Question 21

What is the typical peak power output of a magnetron used in low-energy linacs?

Answer 21

2 MW.

Question 22

True or False: The klystron generates microwaves.

Answer 22

False.

Question 23

What is the role of the buncher cavity in a klystron?

Answer 23

To modulate the velocity of electrons using low-power microwaves.

Question 24

What phenomenon occurs when electrons are incident on a high-Z material target in a linac?

Answer 24

Bremsstrahlung x-rays are produced.

Question 25

What is the average photon energy of the x-ray beam in a linac?

Answer 25

Approximately one-third of the maximum energy.

Question 26

What is the purpose of the electron scattering foil in a linac?

Answer 26

To spread the electron beam and achieve uniform electron fluence.

Question 27

Fill in the blank: The treatment head consists of a thick shell of high-density shielding material such as _______.

Answer 27

[lead, tungsten, or lead-tungsten alloy]

Question 28

What does the flattening filter do in a linac?

Answer 28

It makes the beam intensity uniform across the field.

Question 29

What materials are commonly used for the flattening filter?

Answer 29

Lead, tungsten, uranium, steel, aluminum.

Question 30

What is the function of the ion chambers in the treatment head?

Answer 30

To monitor the dose rate, integrated dose, and field symmetry.

Question 31

What is the significance of the isocenter in a linac?

Answer 31

It is the point where the collimator axis intersects the axis of rotation of the gantry.

Question 32

What principle does the operation of a betatron rely on?

Answer 32

An electron in a changing magnetic field experiences acceleration in a circular orbit.

Question 33

What are the advantages of the microtron compared to a linear accelerator?

Answer 33

Simplicity, easy energy selection, small beam energy spread, and smaller size.

Question 34

What is the typical energy range for betatrons?

Answer 34

Less than 6 to more than 40 MeV.

Question 35

What is the primary use of the klystron in a linac?

Answer 35

As a microwave amplifier driven by a low-power microwave oscillator.

Question 36

What type of beam does the treatment head produce?

Answer 36

X-ray or electron beams.

Question 37

True or False: The monitor chambers in the treatment head are usually sealed.

Answer 37

True.

Question 38

What is the purpose of the light localizing system in the treatment head?

Answer 38

To ensure the light field is congruent with the radiation field.

Question 39

What happens to the electron beam as it exits the window of the accelerator tube?

Answer 39

It is a narrow pencil about 3 mm in diameter.

Question 40

What is the role of the secondary low-Z foil in a linac?

Answer 40

To flatten the electron beam and minimize additional bremsstrahlung radiation.

Question 41

What is the principal advantage of a microtron over a linear accelerator?

Answer 41

Simplicity, easy energy selection, small beam energy spread, and smaller machine size. ## Footnote These advantages lead to simplified beam transport systems and the ability to supply a beam to multiple treatment rooms.

Question 42

Who proposed the method of accelerating electrons used in the microtron and when?

Answer 42

Veksler in 1944. ## Footnote This method laid the groundwork for the development of microtrons in radiotherapy.

Question 43

What was the first microtron for radiotherapy described, and when?

Answer 43

A 10-MeV unit in 1972 by Reistad and Brahme. ## Footnote This marked a significant development in the field of radiotherapy.

Question 44

What is the energy range of x-ray beams produced by the 22-MeV microtron developed by AB Scanditronix?

Answer 44

6 or 10 and 21 MV. ## Footnote It also produced electron beams of various energies: 2, 5, 7, 9, 11, 13, 16, 18, 20, and 22 MeV.

Question 45

What is a racetrack microtron?

Answer 45

A microtron that uses a standing wave linac structure to accelerate electrons. ## Footnote This design alleviates constraints associated with circular microtrons.

Question 46

What is the main use of a cyclotron in radiation therapy?

Answer 46

As a source of high-energy protons for proton beam therapy. ## Footnote It has also been adopted for generating neutron beams.

Question 47

What nuclear reaction occurs when deuterons strike a low atomic number target in a cyclotron?

Answer 47

Neutrons are produced by stripping. ## Footnote This reaction is typically performed with targets like beryllium.

Question 48

What is the basic structure of a cyclotron?

Answer 48

A short metallic cylinder divided into two sections called Ds. ## Footnote These sections are placed between the poles of a DC magnet.

Question 49

How are particles accelerated in a cyclotron?

Answer 49

An alternating potential is applied between the Ds, allowing particles to travel in circular orbits and gain energy with each pass. ## Footnote Positively charged particles such as protons or deuterons are injected into the chamber.

Question 50

What is the energy limit of particles in a cyclotron due to relativistic effects?

Answer 50

Particles gain mass at high velocities, affecting their synchronization with the alternating potential. ## Footnote This limitation is addressed in synchrotrons by adjusting the frequency of the potential.

Question 52

What are some examples of radionuclides used in teletherapy?

Answer 52

Radium-226, Cesium-137, Cobalt-60 ## Footnote These radionuclides emit γ-rays during radioactive disintegration.

Question 53

Which radionuclide is considered most suitable for external beam radiotherapy?

Answer 53

Cobalt-60 ## Footnote It is preferred due to higher specific activity, greater radiation output, and higher average photon energy.

Question 54

List the reasons why cobalt-60 is chosen over radium and cesium.

Answer 54

* Higher specific activity (curies per gram) * Greater radiation output per curie * Higher average photon energy * Lower cost and less self-absorption than radium

Question 55

What is the half-life of Radium-226?

Answer 55

1,622 years

Question 56

What is the average γ-ray energy of Cobalt-60?

Answer 56

1.17 and 1.33 MeV

Question 57

How is the Cobalt-60 source produced?

Answer 57

By irradiating ordinary stable 59Co with neutrons in a reactor.

Question 58

What is the decay product of Cobalt-60?

Answer 58

Cobalt-60 decays to Nickel-60.

Question 59

What type of radiation is emitted during the decay of Cobalt-60?

Answer 59

* β particles (Emax = 0.32 MeV) * Two photons (1.17 and 1.33 MeV)

Question 60

What is the purpose of the double-welded seal in the Cobalt-60 source?

Answer 60

To prevent leakage of the radioactive material.

Question 61

Define geometric penumbra.

Answer 61

The region at the edge of a radiation beam where the dose rate changes rapidly as a function of distance from the beam axis.

Question 62

What is a typical diameter range for a teletherapy Cobalt-60 source?

Answer 62

1.0 to 2.0 cm

Question 63

What is the purpose of the source housing in a Cobalt-60 unit?

Answer 63

To provide shielding and a mechanism for moving the source to the treatment position.

Question 64

List the four methods for moving the source from the off position to the on position.

Answer 64

* Rotating wheel mechanism * Heavy metal drawer mechanism * Mercury flow mechanism * Fixed source with shutter mechanism

Question 65

What is the role of the collimator system in a Cobalt-60 unit?

Answer 65

To vary the size and shape of the beam for individual treatment requirements.

Question 66

What is transmission penumbra?

Answer 66

The region irradiated by photons that are transmitted through the edge of the collimator block.

Question 67

What effect does increasing the source diameter have on penumbra width?

Answer 67

It increases the penumbra width.

Question 68

What is the impact of extending the source to diaphragm distance (SDD) on penumbra?

Answer 68

It decreases the penumbra width.

Question 69

What is the term for the lateral distance between two specified isodose curves at a specified depth?

Answer 69

Physical penumbra width.

Question 70

True or False: The geometric penumbra is dependent on field size.

Answer 70

False

Question 71

Fill in the blank: The combined effect of the transmission and geometric penumbras creates a region of dose variation at the field _______.

Answer 71

edges

Question 72

What are the main radiations used in radiotherapy?

Answer 72

X-rays and electrons ## Footnote Heavy particle beams offer advantages in dose localization and therapeutic gain.

Question 73

What are the types of heavy particles used in radiation therapy?

Answer 73

* Neutrons * Protons * Deuterons * α particles * Negative pions * Heavy ions ## Footnote Their use in radiation therapy is experimental due to high costs.

Question 74

What is the primary advantage of heavy particle beams in radiotherapy?

Answer 74

Greater effect on tumor than on normal tissue ## Footnote This is referred to as therapeutic gain.

Question 75

How are high-energy neutron beams produced for radiotherapy?

Answer 75

By deuterium–tritium generators, cyclotrons, or linear accelerators ## Footnote The bombarding particles can be deuterons or protons.

Question 76

What is the reaction that produces neutrons in a D–T generator?

Answer 76

Low-energy deuteron beam incident on a tritium target ## Footnote The disintegration energy of 17.6 MeV is shared between the helium nucleus and the neutron.

Question 77

What is a major problem with D–T generators in neutron therapy?

Answer 77

Lack of sufficient dose rate at the treatment distance ## Footnote The highest dose rate achieved is about 15 cGy/min at 1 m.

Question 78

What is the typical energy range for deuterons used in cyclotrons?

Answer 78

~15 to 50 MeV ## Footnote Deuterons bombard a low-atomic-number target like beryllium to produce neutrons.

Question 79

What is the Bragg peak?

Answer 79

The region of high dose at the end of the particle range ## Footnote It is characterized by a rapid falloff to zero dose after the peak.

Question 80

What is the range-energy relationship for protons in water?

Answer 80

α = 0.0022 cm, p = 1.77 ## Footnote This applies for protons of energy <200 MeV.

Question 81

What does the term 'specific kinetic energy' refer to?

Answer 81

Kinetic energy per nucleon (MeV/u) ## Footnote Particles with the same MeV/u have approximately the same velocity.

Question 82

What is the mass of a pi meson compared to an electron?

Answer 82

273 times that of an electron ## Footnote Pions can have positive, negative, or neutral charges.

Question 83

Which type of pions have been used for radiation therapy?

Answer 83

Negative pions ## Footnote They are produced in nuclear reactions using protons.

Question 84

What are the challenges associated with pion beams in radiation therapy?

Answer 84

* Low dose rates * Beam contamination * High cost ## Footnote Despite their attractive radiobiologic properties, these challenges limit their use.

Question 85

What has largely replaced kilovoltage and cobalt-60 units in radiotherapy?

Answer 85

Linear accelerators ## Footnote Some older machines are still in use for specific applications.

Question 86

What frequency energizes a linear accelerator?

Answer 86

~3,000 MHz ## Footnote This frequency is used in the microwave technology of linear accelerators.

Question 87

What is the function of the flattening filter in a linear accelerator?

Answer 87

To make the x-ray beam intensity uniform across the field ## Footnote It is used in the x-ray mode of the treatment head.

Question 88

What is a penumbra in radiotherapy?

Answer 88

A dose transition region near the borders of the field ## Footnote There are three kinds: geometric, transmission, and physical penumbra.

Question 89

What is the difference between geometric penumbra and physical penumbra?

Answer 89

* Geometric penumbra: due to source dimensions * Physical penumbra: spread of dose distribution near field borders ## Footnote Geometric penumbra increases with SSD and depth.