Angela's Radiation therapy

Question 1

What is an alpha particle?

Answer 1

Two protons and two neutrons (+ charge) emitted from the nucleus during a form of radioactive decay, called alpha-decay. An alpha-particle is identical to the nucleus of a normal helium atom.

“An alpha man is full of helium”

Question 2

What is a beta particle?

Answer 2

Single electron (- charge) - high energy, high speed electrons (β-) that are ejected from the nucleus, [Can also form a positron (β+).

Question 3

What is the penetrance of a beta particle?

Answer 3

None - it is stopped by sheets of aluminum or a few mm of tissue.

Question 4

What is a gamma particle?

Answer 4

Gamma particle is a photon (a unit of electromagnetic energy), that is emitted by the nucleus of some radionuclides following radioactive decay. Gamma photons are the most energetic photons in the electromagnetic spectrum.

High enerG - G - gamma

Question 5

What is an X ray?

Answer 5

A penetrating form of high-energy electromagnetic radiation. An X-ray is a packet of electromagnetic energy (photon). X-rays are produced by electrons external to the nucleus.

Question 6

Where do x-rays originate?

Answer 6

OUTSIDE the nucleus - from the electron cloud of an atom. This is generally caused by energy changes in an electron, which moves from a higher energy level to a lower one, causing the excess energy to be released.

Question 7

How are X-rays produced?

Answer 7

X-rays are commonly produced in X-ray tubes by accelerating electrons through a potential difference (a voltage drop) and directing them onto a target material (i.e. tungsten).

Question 8

What are properties of alpha particles?

Answer 8

Alpha particles are highly ionising because of their double positive charge, large mass, and because they are relatively slow. They can cause multiple ionisations within a very small distance. This gives them the potential to do much more biological damage for the same amount of deposited energy. They are unable to penetrate very far through matter and are brought to rest by a few centimetres of air or less than a tenth of a millimetre of biological tissue.

Question 9

What is a proton?

Answer 9

Large, positively charged elementary particle. Created by by ionization of a hydrogen atom - stripping an electron from a hydrogen atom via acceleration at 300MeV energies.

Sport Pros stay HYDRidated. Protons are from hydrogens

Question 10

What is a neutron?

Answer 10

Large, neutral elementary particle.

Question 11

How are neutrons produced?

Answer 11

Neutrons are produced when alpha particles are accelerated at and hit any of several light isotopes including isotopes of beryllium, carbon, or oxygen. Also can be produced by fission.

Question 12

What is a pi meson (pion)?

Answer 12

Any of three subatomic particles: π0, π+, and π−
Each pion consists of a quark and an antiquark. They are unstable, decaying after a short lifetime. Neutral pions generally decay into gamma rays.

Question 13

What is the clinical application of the photoelectric effect?

Answer 13

Diagnostic radiology

Question 14

Is the photoelectric effect dependent on atomic number?

Answer 14

Yes, Z^3
(Z is the atomic number)

Question 15

What radiologic phenomenon starts to occur at 1.02 meV?

Answer 15

Pair production - continues up to 30meV
Pair production is the production of a particle-antiparticle pair from the decay of a neutral particle or from a pulse of electromagnetic energy traveling through matter. The most commonly observed pair-production process is the materialization of an electron and a positron from a high-energy photon.

At energies greater than 1.02 MeV, pair production is the dominant mechanism of radiation interaction with matter. As photon energy increases, the dominant interaction mechanism shifts from photoelectric effect to Compton scattering to pair production.

Question 16

Is pair production dependent on atomic number?

Answer 16

Yes

PP is related to the atomic number (Z) of attenuator, incident photon energy (E) and physical density (p) by Z E (- 1.022) p.

Question 17

What is the Compton Effect?

Answer 17

The Compton effect (also called Compton scattering) is the result of a high-energy photon (X-ray or gamma ray) colliding with a target, which releases loosely bound electrons from the outer shell of the atom or molecule. The scattered radiation experiences a wavelength shift

“The Compton family is Phony” To remember PHOtones.

Question 18

What is the clinical application of the Compton Effect?

Answer 18

Radiotherapy

Question 19

What is the particle in the Compton Effect that interacts with DNA directly and H2O to form hydroxy free radicals?

Answer 19

Displaced electron

Question 20

At what energy does the Compton Effect predominate in tissue?

Answer 20

~25 keV to 25 MeV
Most radiation treatments are performed at energy levels of about 6-20 MeV

keV is 1000 times smaller than a MeV

Question 21

In the Compton effect, what does the incident photon interact with?

Answer 21

Loosely bound outer orbital electrons

Question 22

In the Compton effect, what is % of damage to DNA is caused directly from the interaction of the photon with DNA

Answer 22

direct DNA interaction - responsible for 25% of damage due to radiation. The other 75% is caused by indirect action (the photon creating incidental free radicals when go on to cause DNA damage

Question 23

In the Compton effect, what is indirect action? (ie how much DNA damage is not caused by the direct interaction of the electron with DNA)

Answer 23

Formation of free hydroxy radicals - responsible for 75% of damage due to radiation
Most DNA damage is induced indirectly by free radicals

Question 24

In Compton Effect, is absorption dependent on tissue density or atomic number?

Answer 24

Not dependent on atomic number; is dependent on tissue density because Tissue density is correlated with electron density for biological tissues

Compton scatter is dependent on the number of available electrons; the electron density of the material; and on the physical density but not on the atomic number of the material.

The probability of a Compton interaction is directly proportional to the electron density of the absorber. The density of electrons in bone (5.55 × 1023/cm3) is greater than in soft tissue (3.34 × 1023/cm3); therefore the probability of Compton scattering is correspondingly greater in bone than in tissue.

Question 25

At what energy range does the photoelectric effect predominates in tissue?

Answer 25

10-25 keV

keV is 1000 times smaller than a MeV

Question 26

What are the most common sources of radiation for brachytherapy in GYN cancers?

Answer 26

Cesium-137 (half-life 30 years)
Iridium-192 (half-life 74 days)

Question 27

What is Linear Energy Transfer (LET)?

Answer 27

The average amount of energy that is lost per unit path-length as a charged particle travels through a given material

Question 28

What has high LET?

Answer 28

Densely ionizing radiation like neutrons, alpha particles, pi-mesons

Question 29

What has low LET?

Answer 29

Sparsely ionizing radiation like gamma rays and X-rays, beta particles/high-energy electrons, photons, Protons

Question 30

What are the benefits of high LET energy?

Answer 30

More effective in hypoxic tissue (necrotic tumor)

Question 31

What has the highest LET?

Answer 31

Neutrons (more than protons, pi mesons, X-rays, photons)

Alpha > neutron if this is an answer

Question 32

What has the lowest LET?

Answer 32

X-rays (250 keV)

Question 33

What is the most potent radiation modulator?

Answer 33

Oxygen tension

Question 34

What does the shoulder of cell survival curve represent?

Answer 34

The width of shoulder of the survival curve indicates the degree of sublethal damage, which is more readily repaired in the S phase.

Question 35

What does increased oxygen do to the shoulder of the cell survival curve?

Answer 35

Shifts it to the left

Question 36

Half lives of:
Iridium
Radium
Cesium

Answer 36

Iridium - 74 days
Radium - 1600 years
Cesium - 30 years

Question 37

Decay products of:
Iodine-125
Phosphate-32

Answer 37

Iodine-125 –> gamma ray
Phosphate-32 –> beta particle

Question 38

What is the 100% isodose depth of Cobalt-60 (Co-60)?

Answer 38

5mm

Question 39

What dose of radiation sterilizes microscopic disease?

Answer 39

45-50 Gy

Question 40

What is a benefit of hyperfractionation?

Answer 40

Higher total dose is delivered, with no increase in late side effects

Question 41

What is a drawback to hyper fractionation?

Answer 41

Increased acute toxicity, more demanding schedule for patient

Question 42

What is a common dose per fraction in hyper fractionated treatment?

Answer 42

1.15 Gy/fraction twice daily

Question 43

What are the sources commonly used in LDR?

Answer 43

Cesium-137 and Iridium-192

Question 44

What is the dose rate of LDR?

Answer 44

40-60 cGy/hour, usually done over 1-2 insertions.

Always less than 200cGy (or 2 gy) / hr

Question 45

What is the benefit of LDR?

Answer 45

Late-responding tissue sparing

Question 46

What are the sources commonly used for HDR?

Answer 46

Cobalt-60 and Iridium-192

Question 47

What is the dose rate for HDR?

Answer 47

> 12 Gy/hr or 20 cGy (or 0.2 Gy) / min

Question 48

What fraction of a total LDR dose is commonly administered during HDR?

Answer 48

HDR:LDR is 0.5-0.6:1

Chi textbook: the equivalent radiation dose (ERD) is a mathematical model that can be used to determine an appropriate dose for HDR based upon LDR techniques. These calculations show that one must give approximately 60 to 70% of the LDR dose with HDR (this conversion strictly for Brachytherapy)
—> HDR : LDR = 0.6-0.7 : 1.0

Question 49

What preparation may improve late side effects with HDR?

Answer 49

Rectal retraction and packing

Question 50

What is the dose to point A in a patient with stage II cervical cancer?

Answer 50

8500 cGy up to 9000cGy with bulky/barrel cervix

Question 51

What is the brachy dose for endometrial cancer?

Answer 51

60 Gy to mucosa
30 Gy to 0.5cm deep to mucosa

Question 52

What is associated with more complications in treatment of IB2 cervix cancer?
A) Radical hysterectomy followed by adjuvant RT
B) Neoadjuvant chemo then rad hyst
C) Radical chemoradiatoin
D) Radiation followed by extrafascial hyst

Answer 52

Radical hysterectomy followed by adjuvant RT

Question 53

Which has the lowest tolerance for radiation?
A) Bladder
B) Rectum
C) Peripheral nerves
D) Small intestine
E) Ureter

Answer 53

Small intestine

Question 54

What does TD5, TD50, TD100 mean?

Answer 54

TD5 = tolerance dose with 5% risk of injury
TD50 = tolerance dose with 50% risk of injury
TD100 = tolerance dose with 100% risk of injury
*[Sometimes written as TD50/5 meaning 50% risk at 5 years
*Specific to individual organs. Different values for single dose vs fractionated dose.

TD: maximum radiation dose or intensity of fractionated radiotherapy that is associated with an acceptable low complication probability

Question 55

What is the radiation doses required to sterilize an ovary?

Answer 55

TD5-50 single dose: 2-6 Gy
TD5-50 fractionated dose: 6-10 Gy

Most adult women have ovarian failure after 20 Gy

Question 56

What are the clinical properties of high-LET radiation?

Answer 56

Smaller shoulder to cell survival curve

Question 57

What percentage of the dose at 2cm from the source is present at 1cm from the source?

Answer 57

400% (inverse square law)

Question 58

What is the most common time frame for bowel radiation injuries to manifest?

Answer 58

6-18 months

Question 59

What dose of radiation is needed to sterilize subclinical nodes?

Answer 59

4500 cGy

Question 60

What is the most important factor in HDR dose?
A) Size of source
B) Age of source
C) Shape of source
D) Location of source

Answer 60

Age

Question 61

What radiation source is most likely to be used for implanted seeds?

Answer 61

Iridium

Question 62

Normal tissue tolerance for radiation (TD5 and TD50) for the following organs:

Bone marrow:
Kidney:
Liver:
Small intestine:
Spinal cord:
Large intestine:
Bladder:
Rectum:
Vagina:
Skin:
Stomach:

Answer 62

Bone marrow: Aplasia 250/450, Pancytopenia 3000/4000
Kidney: 1500/2000
Liver: 3000/4000
Small intestine: 4000/xx
Spinal cord: 4500/5500
Large intestine: 4500/xx
Bladder: 6000/8000
Rectum: 6000/8000
Vagina: 8000-8500/xx
Skin: 5000/xx
Stomach: 5000/xx

Question 63

What is a benefit of HDR over LDR brachytherapy?

Answer 63

Shorter overall duration of acute GU toxicity for HDR vs LDR (but similar rates of late toxicity)

Question 64

What is the outcome of radiation to embryo within the first two weeks of pregnancy?

Answer 64

Embryonic death

Question 65

What is the outcome of radiation to fetus within 2-16 weeks GA of pregnancy?

Answer 65

Microcephaly, growth retardation

Question 66

What is the outcome of radiation to fetus within 16-20 weeks GA of pregnancy?

Answer 66

Less severe microcephaly, growth retardation

Question 67

What is the outcome of radiation to fetus after 30+ weeks GA of pregnancy?

Answer 67

Minimal effects

Question 68

What is the outcome of radiation to fetus after 30+ weeks GA of pregnancy?

Answer 68

Minimal effects

Question 69

What percent of DNA damage caused by radiation is due to indirect and direct interactions?

Answer 69

75% indirect via free radicals
25% direct via photon damage to DNA

Question 70

What mechanism of radiation induced DNA damage ultimately leads to cell death?

Answer 70

Double-stranded DNA breaks lead to errors in telophase due to incorrect annealment and segregation, which leads to mitotic cell death

Question 71

What is the biologically effective dose (BED)?

Answer 71

An attempt to quantify the biological effect (log cell kill) of radiation dose delivery. This is tissue-specific - cell-survival curves are modeled on a homogeneous tissue type.

Question 72

What are the 4 Rs of radiobiology and what is the significance?

Answer 72

1. Repair of DNA damage
2. Redistribution of cells in the cell cycle
3. Repopulation
4. Reoxygenation of hypoxic tumor areas

4 R’s are the biological principles governing how/why fractionating radiation improves the therapeutic ratio.

success or failure of radiation treatment is determined by the 4 R’s of radiobiology

Question 73

4 R’s of radiobiology: redistribution

Answer 73

Redistribution - cells are distributed in different phases of the cell cycle. Certain phases are radio resistant due to the specific mechanism of DNA repair at that stage. Cells tend to synchronize after multiple fractions of radiation (redistribute to different phases of the cell cycle), so eventually they will be at a radiosensitive time point.

S phase: most radio resistant
M phase: most radio sensitive

Question 74

4 R’s of radiobiology: repair

Answer 74

Repair - different cells repair DNA at different rates. Normal cells with intact DNA are better able to repair radiation damage than cancer cells (“therapeutic ratio”).

Question 75

4 R’s of radiobiology: repopulation

Answer 75

Repopulation of tumor cells occurs between fractions. Avoid treatment breaks!

Question 76

4 R’s of radiobiology: reoxygenation

Answer 76

Reoxygenation - as tumor cells die, there is less competition for nutrients. Surviving cells become more oxygenated and thus there is more substrate for free radical formation.

Question 77

What dose of RT is given for positive margins (i.e. microscopic high volume disease)?

Answer 77

55-65 Gy

Question 78

What dose of RT is given for gross residual disease?

Answer 78

70+ Gy (biologically effective dose will account for differences in dose per fraction)

Question 79

What is the typical radiation dose given per fraction?

Answer 79

EBRT - 1.8-2 Gy per day
Brachytherapy 1.15 Gy/fraction

Question 80

What is the inverse square law?

Answer 80

Radiation dose to tissue is inversely proportional to the square of the distance from the source of radiation.

Question 81

What is meant by prescription depth?

Answer 81

Depth of the target dose (i.e. if target is 3cm deep to surface, you can prescribe XX Gy to 3cm; tissues shallower or deeper to that point will get a certain percentage of that dose)