Radiopharmacy

Question 1

what is nuclear medicine?

Answer 1

scans that give poor anatomical detail but do show functionality of the organs

Question 2

what are radiopharmaceuticals made out of?

Answer 2

a ‘useful molecule’ that allows us to target the desired organ + a radioactive isotope that allows us to be detected on the imaging

Question 3

what are the two views of imaging from a gamma camera?

Answer 3

planar imaging or view organs from multiple angles

Question 4

how is radiation detected?

Answer 4

1. radiopharmaceuticals are injected into the pt
2. collimator is placed on the patient
3. the gamma photons emitted straight-up from the pt is detected by the detector

Question 5

why do we use a collimator on the pt?

Answer 5

gamma photons are emitted multi-directionally from the pt
this is stopped with the collimator, allowing the physician to differentiate between the different organs and see your desired organ

Question 6

what is a collimator?

Answer 6

a sheet of lead with holes in areas to allow the visualisation of the your desired organ by gamma photons only exiting through these gaps.

Question 7

what is the measurements used for radiation?

Answer 7

sievert (Sv)

Question 8

what factors affect Sv?

Answer 8

• Storing
• Shielding (lead thickness0

Question 9

why is ALARP important?

Answer 9

as it means that the radiation given to a pt is AS LOW AS REASONABLY POSSIBLE

Question 10

what are effects of long exposure of radiation?

Answer 10

• effects the bone marrow
• skin reddening / burning
• pelvis radiotherapy = diarrhoea
• neck radiotherapy = vocal chord damage

Question 11

what is the inverse square rule?

Answer 11

he strength of the X-ray beam is inversely proportional to the square of distance from the source (X). Standing back by double the distance from a source of radiation (d to 2d) will quarter the dose to the radiologist or radiographer.

Question 12

how can limit radiation exposure?

Answer 12

• time
• distance
• shielding

Question 13

what are idealistic pharmacokinetics of radiopharmaceuticals?

Answer 13

• short physical half life
• short biological half life
• nature of radioactive decay

Question 14

what’s the difference between physical and biological Half life?

Answer 14

physical half life - the period of time required to reduce the radioactivity level of a source to exactly one half its original value due solely to radioactive decay.

biological half life - The time required for a biological system, such as that of a human, to eliminate, by natural processes, half of the amount of a substance (such as a radioactive material) that has entered it.

Question 15

what are becquerels?

Answer 15

rate of disintegration

Question 16

what are the different type of radioactive decay?

Answer 16

alpha, beta, gamma

Question 17

what are the properties of alpha particles?

Answer 17

He nucleus, charge +2
large and collides with tissue = very damaging in small areas
easily shielded
no diagnostic agents but potential for therapeutic use

Question 18

what are the properties of beta particles?

Answer 18

can be positive or negative
smaller than alpha particles - interact less with tissues
valuable for therapy but not diagnosis

Question 19

what are the properties of beta+ particles?

Answer 19

known as positrons - antimatter
interact with beta -‘ve particles immediately after emission from the nucleus

Question 20

what happens when B +’ve and B -‘ve particles collide?

Answer 20

produce 2 gamma rays
which is important in diagnostic procedures

Question 21

what are the properties of gamma rays?

Answer 21

less interaction with tissue
energy emitted gamma ray is constant for a given radionuclide
valuable in diagnostic

Question 22

what are the ideal diagnostic properties?

Answer 22

1. gamma ray emission only
2. for imaging studies, 100-250 Kev
3. physical half life of approx. 1.5x(test duration)
4. simple cheap
5. rapid production
6. least exposure to everyone even handling
7. versatile chemistry
8. chemical quantity
9. pure sample
10. predictable biodistribution

Question 23

why is it important to have a predicable biodistribution of radiopharmaceuticals?

Answer 23

to allow us to test the pt’s organ functions rather than unpredictable radiopharmaceuticals so we can evaluate the functionality

Question 24

describe 99m Tc

Answer 24

43 protons in the nucleus, 43 electrons
20 different isotopes - all radioactive

Question 25

how is 99 Tc produced?

Answer 25

Question 26

what’s the significance of 99Mo and 99TcM having difference energy states?

Answer 26

that they can be separated due to having different chemical properties

Question 27

what is the source of 99Mo?

Answer 27

fission from a nuclear reactor,
no reactors within the UK, therefore, we rely on import

Question 28

how does a technetium generator work?

Answer 28

contains a shielded glass column packed with alumina,
99Mo is strongly absorbed onto the column,
column is sealed
99Mo decays into 99m-Tc
99m-Tc is separated by passing saline thru the column

Question 29

how long does it take for a technetium generator to re-establish an equilibrium?

Answer 29

24 hours

Question 30

how do we know if we have impurities after using a technetium generator?

Answer 30

assess every time we pollute a new generator using a calibrator.

block all 99Tc using a lead shield (4mm thick) and test for any radiation, any radiation observed is due to 99Mo

Question 31

what are the practical points when using a technetium generator?

Answer 31

• swab collection vial’s rubber bung
• elute in a grade A environment
• make sure the collection vial has reached atmospheric pressure before removal
  -require shielding to the operator

Question 32

when is sodium (99Tc) pertechnetate used?

Answer 32

most commonly for thyroid imaging

Question 33

why is sodium (99Tc) pertechnetate taken up by the thyroid?

Answer 33

due to its similar shape and size as iodine

iodine (used to make thyroid hormones), however, sodium (99Tc) pertechnetate will not formate these

Question 34

what are the properties of TcO4?

Answer 34

chemically stable due to having a valency of +7
Tc surrounded by ‘big’ oxygen molecules stopping ligand formation

Question 35

how can we get the oxygen molecules in TcO4 to leave the molecule?

Answer 35

using tin ions which are more attracted to the oxygen, allowing dissociation to Tc, leaving Tc highly reactive

Question 36

what happens when we leave Tc highly reactive?

Answer 36

ligands can form if done quickly IF NOT then water may react to form Tc colloid

Question 37

what is stannous chloride used for?

Answer 37

a reducing agent

Question 38

what should you be careful of when using Tc vials? and why?

Answer 38

so you do not inject air into the vial as the air will oxidise the stannous ion

Question 39

why is the choice of ligand used in Tc-ligand important?

Answer 39

as it makes 20 different Tc complexes which allow use in clinical use
which determines the biodistribution

Question 40

what does 99m-Tc bone radiopharmaceuticals do?

Answer 40

detect osteoblastic activity (bone growth & break down) which occurs to most tumours. therefore, allows tumour detection

Question 41

how do 99m-Tc bone radiopharmaceuticals detect tumours?

Answer 41

by binding to hydroxyapatite Ca10(PO4)6(OH)2 which is found within growing bone

the greater the bone turnover the greater the uptake

Question 42

how can we control the quality of radiopharmaceuticals?

Answer 42

mainly thru chromotagraphy…
1. column chromatography - HPLC
2. planar chromatography

this is calculated by radiochemical purity determination RCP (%)

Question 43

what is the RCP needed for Tc-ligands?

Answer 43

> 95% to pass

Question 44

what’s the difference between column and planar chromatography in use clinically ?

Answer 44

Question 45

what are the planar chromatography?

Answer 45

• paper
• instant thin layer chromatography (ITLC)

Question 46

what are the features of using paper as a stationary phase?

Answer 46

good resolution slower to develop
poor mechanical strength - collapses and tears easily

Question 47

what are the features of using ITLC as a stationary phase?

Answer 47

glass fibre web inpregnated with modified
silica
stationary phases, silica gel and silicic acid much faster to develop
resolution poor

Question 48

what are the mobile phases used ?

Answer 48

Butanone or acetone may be used to separate 99mTcO4 from mixture

Saline used to separated 99mTcO4 and 99mTc- ligand from 99mTc-colloid

Exceptions include 99mTc MAG3 which is more difficult to separate

Question 49

how does the chromatography process work?

Answer 49

Question 50

is the sample volume important for radiopharmaceuticals?

Answer 50

yes as smaller samples allow a better resolution but a specific volume is not needed

Question 51

should the spots of the sample applied to chromatography dry?

Answer 51

drying will allow the sample to react with the air, which is not ideal

Question 52

how do we process chromatogram?

Answer 52

Scan using chromatogram scanner - scintillation detector connected to ratemeter. Signal passed to a chart recorder

Chromatogram counting - cut and count
Can be simply cut in half and counted in a dose calibrator or Cut into smaller sections (e.g. 10) and count each section

Question 53

what are the problems we may see once undergoing quality control?

Answer 53

1. Reaction with the support, especially by drying spots
2. Splashing when spotting
3. Interaction with dyes used to visualise solvent front
4. Grease from fingers
5. Strips touching wet walls of the
   developing chamber
6. Contamination with other radiopharmaceuticals when spotting
7. Incorrect mobile phase
8. Correct, but contaminated mobile phase
9. Insufficient mobile phase to allow full development to the requires solvent front
10. Contaminated forceps or scissors
11. Uneven sample spotting
12. Poor mixing of mobile phase components
13. Sample washed off by using too much mobile phase in the chamber
14. Selective evaporation of the mobile phase component on storage

Question 54

how will free TcO4- and reduced Tc affect the pt?

Answer 54

will be taken up by unintended organs - unnecessarily radiating
causing sub-diagnostic imaging which will require a doubling in the dose of radiation exposure to the pt