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1. 2  Ray Imaging u Inject a pharmaceutical labelled with a radioactive nuclide  Detect where  -rays are coming from u Local concentration in patient.

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Presentation on theme: "1. 2  Ray Imaging u Inject a pharmaceutical labelled with a radioactive nuclide  Detect where  -rays are coming from u Local concentration in patient."— Presentation transcript:

1 1

2 2  Ray Imaging u Inject a pharmaceutical labelled with a radioactive nuclide  Detect where  -rays are coming from u Local concentration in patient indicates problems or otherwise

3 3 SCANNING

4 4 The figure shows an image from a rectilinear scan showing cancer in the upper left lung using a 67 Ga citrate.

5 5 Radiopharmaceutical u Choice of isotope for labelling: êHalf life a few hours  Produces  photon of a few hundred keV êEasily attached to pharmaceuticals êCan be delivered to hospital in a form to last several days

6 6 Technetium 99 u Most commonly used isotope  Decays from excited to ground state by  ray êParent isotope is Molybdenum 99 êHalf life about 6 hours 42994299Mo Tc m   42 99 TcTc+(140keV) m 42 99  Half life 2.7 days Half life 6.01 hours

7 7 The Cow Input needle Output needle lead shield Chromatographic Adsorbent Radionuclide Generator

8 8 Att coef 0.16 1/cm

9 9 Gamma Camera u Consists of: êLight Guide êCollimator êScintillator êArray of photomultipliers êComputer u Position of scintillations can be found u Distribution of radioactivity imaged

10 10 Gamma Camera Output pulse shapes Photomultiplier tubes Light guide NaI(Tl) Crystal Collimator Lead Shield  photon

11 11

12 12

13 13

14 14 Analysis u Pulse are passed through a pulse height analyser êAllow only right energy pulses êLow energy pulses may come from other scattering processes u Position of each event calculated from relative energy at each photomultiplier

15 15

16 16 NaI (Tl)

17 17 Collimator u Collimator restricts direction from which photons reach the camera. u Made of lead with holes. u Bigger, shorter holes means more photons, but more blurring u Visa versa. Radioactive Source Collimator Detector

18 18

19 19 Collimator u Collimator restricts direction from which photons reach the camera. u Close to the collimator the umbra region determines the resolution. u At distance the penumbra region dominates.

20 20

21 21

22 22 Collimator u Collimator restricts direction from which photons reach the camera. u Made of lead with holes. u High gamma energies can penetrate the lead septa leading to detoriation in resolution. Radioactive Source Collimator Detector

23 23

24 24

25 25 Diagnostics and therapy, 99m Tc and 153 Sm

26 26

27 27

28 28 Lung metastases (SPECT/CT)

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