Introduction to Nuclear Medicine for Trainees in Imaging and Imaging Sciences

Adrien Michael Peters has been a consultant nuclear medicine physician since 1984. He previously held chairs in Diagnostic Radiology at Royal Postgraduate Medical School (and then Imperial College), in Nuclear Medicine at University of Cambridge (Foundation Chair) and in Applied Physiology at Brighton Sussex Medical School. He is currently a nuclear medicine consultant at King s College Hospital and holds an honorary chair in Nuclear Medicine at King s College, London. He was awarded the higher doctorate of DSc by the University of Liverpool in 2009, was Nimmo Visiting Professor at the Royal Adelaide Hospital in 2001, and is a Fellow of the Academy of Medical Sciences.

Dr Manuela Vadrucci graduated and completed her specialist training in Nuclear Medicine in Milan, Italy in 2016. Then, she worked as a research fellow at the European Institute of Oncology IEO in Milan, focusing on molecular imaging in breast and neuroendocrine tumours, before relocating to the UK in 2017. After a few years working as a Locum and then substantive consultant in King s College Hospital, London, in 2020 she joined St Bartholomew s Hospital in the same city. Her current position as a Nuclear Medicine Consultant in one of the largest teaching hospitals in England enables her to broaden her knowledge on molecular imaging techniques in common and less common oncological and inflammatory diseases, as well as to contribute regularly to the teaching of pre- and post-graduate medical trainees and radiology resident doctors. She has also shared her experience through several publications, often in collaboration with the co-author of this book.

Part I. Tracer Kinetics.- 1. Mathematical Equations.- 2. Physiological Equations.- 3. Clearance, Blood Flow And Extraction Fraction [Or Efficiency (%)].- 4. Distribution Volume And Mean Transit Time.- 5. Blood Capillary Function.- Part II. Basic Medical Statistics.- 6. Parametric Statistics.- 7. Non-Parametric Statistics.- 8. Interpretation of Statistical Significance.- Part III. Basic Sciences of Nuclear Medicine.- 9. Basic Sciences of NM.- Part IV. Tc-99m Compounds.- 10. FREE Tc-99m (Pertechnetate; Tc-99mO4; 161 Da; Half-Life 6 H).- 11. Tc-99m-Diethyltriaminepentaacetic Acid (DTPA; MW 650 Da).- 12. Tc-99m-Mercaptoacetyltriglycine (MAG3) (MW 417 Da).- 13. Tc-99m-Dimercaptosuccinic Acid (DMSA) (MW 182 Da).- 14. Tc-99m-Iminodiacetic Acid (HIDA) (MW 177 Da).- 15. Tc-99m-Labelled Diphosphonates (MW ~300 Da).- 16. Tc-99m-Sestamibi (MW 778 Da) And Tc-99m-Tetrafosmin (MW 895 Da).- 17. Tc-99m-Hexamethylpropylamine Oxime (HMPAO) (MW 385 Da).- 18. Tc-99m-Labelled Aerosols.- 19. Tc-99m-Labelled Liquid and Semisolid Meals.- 20. Tc-99m-Labelled Red Blood Cells.- 21. Tc-99m-Labelled Proteins.- 22. Tc-99m-Labelled Nanocolloids.- Part V. Miscellaneous Radiopharmaceuticals.- 23. Noble Gases.- 24. Iodine-123 (Half-Life 13.2 H; Decays by Electron Capture To Te-123) and Iodine-131 (8.1 D, Beta Minus Emission, Xe-131).- 25. Selenium-75 (Half-Life 120 D; Decays by Electron Capture to As-75; 136, 265 and 401 Kev).- 26. Indium-111 (Half-Life 2.8 D; Decays by Electron Capture to Cd-111; 172 Kev and 245 Kev).- 27. Radionuclides of Historical Interest.- Part VI. Positron Emission Tomography (PET).- 28. Compounds Of Fluorine-18.- 29. Compounds Of Gallium 68 (Half-Life 68 Minutes).- 30. Rubidium-82 (Half-Life 78 Sec).