23 | | || 1. 15Feb21 || 1. [raw-attachment:Wk01-Lctr01.pdf Introduction, nuclear medicine o/v, nuclear decay theory] || 1. [raw-attachment:Wk01-Lctr01-Sctn01.pdf Introduction] || || |
24 | | || || || 2. [raw-attachment:Wk01-Lctr01-Sctn02.pdf Nuclear medicine] || || |
25 | | || || || 3. [raw-attachment:Wk01-Lctr01-Sctn03.pdf Nuclear decay, revision] || || |
26 | | || || 2. [raw-attachment:Wk01-Lctr02.pdf Radionuclides, production methods, gamma-camera intro] || 1. [raw-attachment:Wk01-Lctr02-Sctn01.pdf Radionuclides for nuclear medicine] || || |
27 | | || || || 2. [raw-attachment:Wk01-Lctr02-Sctn02.pdf Methods for production of radionuclides] || || |
28 | | || || 3. [raw-attachment:Wk01-Lctr03.pdf The gamma camera] || 1. [raw-attachment:Wk01-Lctr03-Sctn01.pdf Introduction] || || |
29 | | || || || 2. [raw-attachment:Wk01-Lctr03-Sctn02.pdf Gamma camera] || || |
30 | | || || || 3. [raw-attachment:Wk01-Lctr03-Sctn03.pdf Collimator] || || |
31 | | || || || 4. [raw-attachment:Wk01-Lctr03-Sctn04.pdf Scintillator] || || |
32 | | || || || 5. [raw-attachment:Wk01-Lctr03-Sctn05.pdf Examples] || || |
33 | | || 2. 22Feb21 || 4. [raw-attachment:Wk02-Lctr04.pdf Single photon emission computed tomography] || 1. [raw-attachment:Wk02-Lctr04-Sctn01.pdf Introduction] || || |
34 | | || || || 2. [raw-attachment:Wk02-Lctr04-Sctn02.pdf Reconstruction] || || |
35 | | || || || 3. [raw-attachment:Wk02-Lctr04-Sctn03.pdf Attenuation correction] || || |
36 | | || || || 4. [raw-attachment:Wk02-Lctr04-Sctn04.pdf Scattering correction] || || |
37 | | || || || 5. [raw-attachment:Wk02-Lctr04-Sctn05.pdf Examples] || || |
38 | | || || 5. [raw-attachment:Wk02-Lctr05.pdf Positron emission tomography I] || 1. [raw-attachment:Wk02-Lctr05-Sctn01.pdf Principles of positron emission tomography] || || |
39 | | || || || 2. [raw-attachment:Wk02-Lctr05-Sctn02.pdf System resolution] || || |
40 | | || || || 3. [raw-attachment:Wk02-Lctr05-Sctn03.pdf Sensitivity] || || |
41 | | || 3. 01Mar21 || 6. [raw-attachment:Wk03-Lctr06.pdf Positron emission tomography II] || 1. [raw-attachment:Wk03-Lctr06-Sctn01.pdf Types of coincidence event] || || |
42 | | || || || 2. [raw-attachment:Wk03-Lctr06-Sctn02.pdf System resolution] || || |
43 | | || || || 3. [raw-attachment:Wk03-Lctr06-Sctn03.pdf Data acquisition] || || |
44 | | || || || 4. [raw-attachment:Wk03-Lctr06-Sctn04.pdf Comparison of sensitivity and corrections] || || |
45 | | || || || 5. [raw-attachment:Wk03-Lctr06-Sctn05.pdf Examples] || || |
46 | | || || 7. [raw-attachment:2020-11-01-Wk04-Blk01-Slides.pdf Introduction to MRI and quantum-mechanical foundations] || 1. [raw-attachment:2020-11-01-Wk04-Blk01-Sctn01-Slides.pdf Introduction to MRI] || || |
47 | | || || || 2. [raw-attachment:2020-11-01-Wk04-Blk01-Sctn02-Slides.pdf Quantum mechanical foundations] || || |
48 | | || 4. 08Mar21 || 8. [raw-attachment:2020-11-14-Wk04-Blck02-Slides.pdf Classical derivation of Larmor equation, Rotating M] || 1. [raw-attachment:2020-11-14-Wk04-Blck02-Sctn01-Slides.pdf Classical derivation of Larmor equation] || || |
49 | | || || || 2. [raw-attachment:2020-11-14-Wk04-Blck02-Sctn02-Slides.pdf Rotating the magnetisation] || || |
50 | | || || || 3. [raw-attachment:2020-11-14-Wk04-Blck02-Sctn03-Slides.pdf Free induction decay] || || |
51 | | || || 9. [raw-attachment:2020-11-18-Wk05-Blck01-Slides.pdf Determination of T1 and T2] || 1. [raw-attachment:2020-11-18-Wk05-Blck01-Sctn01-Slides.pdf Determination of the spin-lattice relaxation time, T1] || || |
52 | | || || || 2. [raw-attachment:2020-11-18-Wk05-Blck01-Sctn02-Slides.pdf Determination of the spin-spin relaxation time, T2] || || |
53 | | || 6. 15Mar21 || 10. [raw-attachment:2020-11-19-Wk05-Blck02-Slides.pdf Magnetic Resonance Imaging: spatial localisation] || 1. [raw-attachment:2020-11-19-Wk05-Blck02-Sctn01-Slides.pdf Slice selective excitation] || || |
54 | | || || || 2. [raw-attachment:2020-11-19-Wk05-Blck02-Sctn02-Slides.pdf Encoding spatial information in k-space] || || |
55 | | || || || 3. [raw-attachment:2020-11-19-Wk05-Blck02-Sctn03-Slides.pdf Encoding spatial information into net magnetisation] || || |
56 | | || || 11. [raw-attachment:2020-11-19-Wk06-Blck01-Slides.pdf Magnetic Resonance Imaging: contrast] || 1. [raw-attachment:2020-11-19-Wk06-Blck01-Sctn01-Slides.pdf Spin-echo sequence for proton-density weighted image] || || |
57 | | || || || 2. [raw-attachment:2020-11-19-Wk06-Blck01-Sctn02-Slides.pdf Spin-echo sequence for T1-weighted image] || || |
58 | | || || || 3. [raw-attachment:2020-11-19-Wk06-Blck01-Sctn03-Slides.pdf Spin-echo sequence for T2-weighted image] || || |
59 | | || || || 4. [raw-attachment:2020-11-19-Wk06-Blck01-Sctn04-Slides.pdf Comparison of T1, T2, and proton-weighted images] || || |
60 | | || || || 5. [raw-attachment:2020-11-19-Wk06-Blck01-Sctn05-Slides.pdf Inversion recovery] || || |
61 | | || 7. 22Mar21 || 12. [raw-attachment:2020-11-19-Wk06-Blck02-Slides.pdf Magnetic Resonance Imaging: artefacts] || 1. [raw-attachment:2020-11-19-Wk06-Blck02-Sctn01-Slides.pdf Aliasing (wraparound) and the Nyquist theorem] || || |
62 | | || || || 2. [raw-attachment:2020-11-19-Wk06-Blck02-Sctn02-Slides.pdf Truncation artefact; Gibbs phenomenon] || || |
63 | | || || || 3. [raw-attachment:2020-11-19-Wk06-Blck02-Sctn03-Slides.pdf Random motion artefacts] || || |
64 | | || || 13. [raw-attachment:2020-11-19-Wk07-Blck01-Slides.pdf More MRI artefacts] || 1. [raw-attachment:2020-11-19-Wk07-Blck01-Sctn01-Slides.pdf MRI artefacts: periodic motion] || || |
65 | | || || || 2. [raw-attachment:2020-11-19-Wk07-Blck01-Sctn02-Slides.pdf MRI artefacts: chemical shift] || || |
| 23 | || 1. 15Feb21 || 1. [raw-attachment:Wk01-Lctr01.pdf Introduction, nuclear medicine o/v, nuclear decay theory] || 1. [raw-attachment:Wk01-Lctr01-Sctn01.pdf Introduction] || || |
| 24 | || || || 2. [raw-attachment:Wk01-Lctr01-Sctn02.pdf Nuclear medicine] || || |
| 25 | || || || 3. [raw-attachment:Wk01-Lctr01-Sctn03.pdf Nuclear decay, revision] || || |
| 26 | || || 2. [raw-attachment:Wk01-Lctr02.pdf Radionuclides, production methods, gamma-camera intro] || 1. [raw-attachment:Wk01-Lctr02-Sctn01.pdf Radionuclides for nuclear medicine] || || |
| 27 | || || || 2. [raw-attachment:Wk01-Lctr02-Sctn02.pdf Methods for production of radionuclides] || || |
| 28 | || || 3. [raw-attachment:Wk01-Lctr03.pdf The gamma camera] || 1. [raw-attachment:Wk01-Lctr03-Sctn01.pdf Introduction] || || |
| 29 | || || || 2. [raw-attachment:Wk01-Lctr03-Sctn02.pdf Gamma camera] || || |
| 30 | || || || 3. [raw-attachment:Wk01-Lctr03-Sctn03.pdf Collimator] || || |
| 31 | || || || 4. [raw-attachment:Wk01-Lctr03-Sctn04.pdf Scintillator] || || |
| 32 | || || || 5. [raw-attachment:Wk01-Lctr03-Sctn05.pdf Examples] || || |
| 33 | || 2. 22Feb21 || 4. [raw-attachment:Wk02-Lctr04.pdf Single photon emission computed tomography] || 1. [raw-attachment:Wk02-Lctr04-Sctn01.pdf Introduction] || || |
| 34 | || || || 2. [raw-attachment:Wk02-Lctr04-Sctn02.pdf Reconstruction] || || |
| 35 | || || || 3. [raw-attachment:Wk02-Lctr04-Sctn03.pdf Attenuation correction] || || |
| 36 | || || || 4. [raw-attachment:Wk02-Lctr04-Sctn04.pdf Scattering correction] || || |
| 37 | || || || 5. [raw-attachment:Wk02-Lctr04-Sctn05.pdf Examples] || || |
| 38 | || || 5. [raw-attachment:Wk02-Lctr05.pdf Positron emission tomography I] || 1. [raw-attachment:Wk02-Lctr05-Sctn01.pdf Principles of positron emission tomography] || || |
| 39 | || || || 2. [raw-attachment:Wk02-Lctr05-Sctn02.pdf System resolution] || || |
| 40 | || || || 3. [raw-attachment:Wk02-Lctr05-Sctn03.pdf Sensitivity] || || |
| 41 | || 3. 01Mar21 || 6. [raw-attachment:Wk03-Lctr06.pdf Positron emission tomography II] || 1. [raw-attachment:Wk03-Lctr06-Sctn01.pdf Types of coincidence event] || || |
| 42 | || || || 2. [raw-attachment:Wk03-Lctr06-Sctn02.pdf System resolution] || || |
| 43 | || || || 3. [raw-attachment:Wk03-Lctr06-Sctn03.pdf Data acquisition] || || |
| 44 | || || || 4. [raw-attachment:Wk03-Lctr06-Sctn04.pdf Comparison of sensitivity and corrections] || || |
| 45 | || || || 5. [raw-attachment:Wk03-Lctr06-Sctn05.pdf Examples] || || |
| 46 | || || 7. [raw-attachment:Wk04-Lctr07-Slides.pdf Introduction to MRI and quantum-mechanical foundations] || 1. [raw-attachment:Wk04-Lctr07-Sctn01-Slides.pdf Introduction to MRI] || || |
| 47 | || || || 2. [raw-attachment:Wk04-Lctr07-Sctn02-Slides.pdf Quantum mechanical foundations] || || |
| 48 | || 4. 08Mar21 || 8. [raw-attachment:Wk04-Lctr08-Slides.pdf Classical development of principles of MRI] || 1. [raw-attachment:Wk04-Lctr08-Sctn01-Slides.pdf Classical derivation of Larmor equation] || || |
| 49 | || || || 2. [raw-attachment:Wk04-Lctr08-Sctn02-Slides.pdf Rotating the magnetisation] || || |
| 50 | || || || 3. [raw-attachment:Wk04-Lctr08-Sctn03-Slides.pdf Free induction decay] || || |
| 51 | || || 9. [raw-attachment:Wk05-Lctr09-Slides.pdf Determination of T1 and T2] || 1. [raw-attachment:Wk05-Lctr09-Sctn01-Slides.pdf Determination of the spin-lattice relaxation time, T1] || || |
| 52 | || || || 2. [raw-attachment:Wk05-Lctr09-Sctn02-Slides.pdf Determination of the spin-spin relaxation time, T2] || || |
| 53 | || 6. 15Mar21 || 10. [raw-attachment:Wk05-Lctr10-Slides.pdf Magnetic Resonance Imaging: spatial localisation] || 1. [raw-attachment:Wk05-Lctr10-Sctn01-Slides.pdf Slice selective excitation] || || |
| 54 | || || || 2. [raw-attachment:Wk05-Lctr10-Sctn02-Slides.pdf Encoding spatial information in k-space] || || |
| 55 | || || || 3. [raw-attachment:Wk05-Lctr10-Sctn03-Slides.pdf Encoding spatial information into net magnetisation] || || |
| 56 | || || 11. [raw-attachment:Wk06-Lctr11-Slides.pdf Magnetic Resonance Imaging: contrast] || 1. [raw-attachment:Wk06-Lctr11-Sctn01-Slides.pdf Spin-echo sequence for proton-density weighted image] || || |
| 57 | || || || 2. [raw-attachment:Wk06-Lctr11-Sctn02-Slides.pdf Spin-echo sequence for T1-weighted image] || || |
| 58 | || || || 3. [raw-attachment:Wk06-Lctr11-Sctn03-Slides.pdf Spin-echo sequence for T2-weighted image] || || |
| 59 | || || || 4. [raw-attachment:Wk06-Lctr11-Sctn04-Slides.pdf Comparison of T1, T2, and proton-weighted images] || || |
| 60 | || || || 5. [raw-attachment:Wk06-Lctr11-Sctn05-Slides.pdf Inversion recovery] || || |
| 61 | || 7. 22Mar21 || 12. [raw-attachment:Wk06-Lctr12-Slides.pdf Magnetic Resonance Imaging: artefacts] || 1. [raw-attachment:Wk06-Lctr12-Sctn01-Slides.pdf Aliasing (wraparound) and the Nyquist theorem] || || |
| 62 | || || || 2. [raw-attachment:Wk06-Lctr12-Sctn02-Slides.pdf Truncation artefact; Gibbs phenomenon] || || |
| 63 | || || || 3. [raw-attachment:Wk06-Lctr12-Sctn03-Slides.pdf Random motion artefacts] || || |
| 64 | || || 13. [raw-attachment:Wk07-Lctr13-Slides.pdf More MRI artefacts] || 1. [raw-attachment:Wk07-Lctr13-Sctn01-Slides.pdf MRI artefacts: periodic motion] || || |
| 65 | || || || 2. [raw-attachment:Wk07-Lctr13-Sctn02-Slides.pdf MRI artefacts: chemical shift] || || |