RADIOBIOLOGY

1. RADIOBIOLOGY

2. Principles of Radiobiology based on • Random nature of radiation interactions • how radiation interacts at cellular level • factors that can alter these interactions

3. REMEMBER • All radiation damage occurs at cellular or subcellular level • visible effects are seen after millions of cells are impacted

4. Characteristics of ionizing radiation • Charge • Mass • Energy Vary among different types of radiation

5. Ionizing radiation causes injury through these concepts • LET • RBE • OER

6. LET • High and low LET (chart 6-1, pg 108 Sherer) • LET IS AVERAGED DUE TO POLYENERGETIC NATURE OF IONIZING RADIATION

7. RBEBackground information • QF-How much biologic damage one type of radiation does vs. type of radiation • What is the QF of x-rays? • What about Alpha? • QF=rounded estimate of RBE

8. RBE (Pg. 495-Bushong) • Compares: dose of standard radiation necessary to produce a given effect dose of test radiation necessary to produce same effect • Standard radiation is 250 KeV • RBE’s of diagnostic is 1 • Max. is approx. 3 • As LET increases; so does RBE • Alpha and Beta have high RBE

9. OER The ratio of radiation damage done with oxygen vs. without oxygen

10. OXYGEN EFFECT • Tissue more sensitive to rad when oxygenated or in aerobic state • VS • anoxic or hypoxic • Oxygen produces free radicals • Why would this be important in radiation therapy?

11. Alpha-insensitive to oxygen (Low OER) • Gamma and x-rays more sensitive (High OER) • Therefore Low LET is associated with ____OER (LOW OR HIGH)

12. IONIZING RADATION AND BIOLOGIC DAMAGE • Direct or indirect • occurs more with high LET radiation • Relative Biologic Effectiveness

13. Direct • Can be fatal to cell • high LET

14. A FREE RADICAL • Hydroperoxl • Hydroxyl • H2O2 • 2/3 of all biologic damage is from H2O2 which is… • hydrogen peroxide

15. INDIRECT • RADIOLYSIS OF WATER • Breakdown of H2O • produces an ion pair of HOH and e- • These can attach to uncharged water molecules (unstable)= free radical

16. CHROMOSOMAL EFFECT • Biologic damage occurs during breakage of chromosomal backbone or to DNA • Point mutations • Frameshift mutation

17. RADIATION MUTATION CHARACTERISTICS • Germ cells-carry on to future generations • Somatic cells-effect only occurs once • undesirable • probably cumulative • threshold • effects are not specific to radiation

18. TARGET THEORY ADDRESSES LETHAL DAMAGE THERE ARE AREAS ON THE DNA CHAIN THAT, IF DAMAGED, ARE LETHALTO THE CELL

19. UNDERSTANDING THE “TARGET” • CELLS ARE MADE UP MOLECULES • OVERABUNDANCE OF MOLECULES • CRITICAL MOLECULE • “WHEN RADIATION INTERACTS WITH OR NEAR A CRITICAL MOLECULE, THIS SENSITIVE AREA IS CALLED ‘TARGET’.” • NUCLEUS VS CYTOPLASM

20. Principles of Radiobiology based on • Random nature of radiation interactions • how radiation interacts at cellular level • factors that can alter these interactions

21. NOW ON TO THE THEORIES • DNA SEQUENCE VITAL-DAMAGE TO ANY TARGET(SEQUENCE) WILL KILL THE CELL • NO SINGLE SEQUENCE IS IMPORTANT-2 TO 3 TARGETS (SEQUENCES) NEED TO BE HIT

22. TARGET ONLY NEEDS ONE HIT TO CAUSE FETAL DAMAGE • TARGET NEEDS TO BE HIT TWICE OR MORE TO CAUSE DAMAGE

23. Radiation damage • Cannot be distinguished from other sources (chemical, heat or trauma)