LET, RBE and Damage to DNA Linear Energy Transfer (LET) When is stopping power not equal to LET? Stopping power (-dE/dx) gives the energy lost by a charged particle in a medium. LET gives the energy absorbed in the target. Secondary δ-electrons can transport a fraction of the energy out of the target volume. o Particularly true with heavy charged particles if the target is small compared with the ranges of the secondary electrons (delta rays). o On the biological scale, the target dimensions are on the order of microns (cells), nanometers (chromatin), or angstroms (DNA). Restricted stopping power ? ? ? ? ? ? ? ? ?= dx dE LET ? Energy transfers > ? = 100eV are considered as imparted to δ-electrons. ? The symbol LET ∞ denotes the unrestricted stopping power. ? LET is commonly found in the biological literature with no subscript. It is assumed that the unrestricted stopping power is implied. [This is really an issue only with HZE particles and tracks.] Examples: Radiation Typical LET values 1.2 MeV 60 Co gamma 0.3 keV/μm 250 kVp x rays 2 keV/μm 10 MeV protons 4.7 keV/μm 150 MeV protons 0.5 keV/μm 14 MeV neutrons 12 keV/μm Heavy charged particles 100-2000 keV/μm 2.5 MeV alpha particles 166 keV/μm 2 GeV Fe ions 1,000 keV/μm 1 “Microdosimetric Structure of Heavy Ion Tracks in Tissue”, Chatterjee, A. and Schaefer, H.J. Radiation and Environmental Biophysics, 13, 215-227, 1976. It is possible to have two particles of different Z, and different E (velocity), but the same LET. The microscopic distribution of energy around the track will be different. ? Glancing collisions: the track core null E transferred is small null the number of these interactions is large ? Close collisions: the track penumbra null E transferred is large, up to a maximum null The number of these interactions is small. The core radius is given by the formula: β0116.0= c r (μm) where β = v/c, i.e., the velocity of the particle relative to the speed of light. The penumbra radius, r p , is given by the formula: 257.1925.1768.0 +?= EEr p (μm) where E is the kinetic energy of the particle in MeV/nucleon. Data for three nuclei with different Z numbers and energies yet same LET ? (from Table 3 in Chatterjee and Schaefer, 1976). “Radiation effects for HZE particles cannot be measured with conventional dosimetric units.” “…the core must be seen radiobiologically as a submicroscopic region of complete saturation and destruction.” !!! 2 Relative Biological Effectiveness (RBE) Image removed. Given: 1 Gy = 1 J/kg; 1 eV = 1.6 x 10 -19 J Assume: 1 ionization = 33 eV; 1 nucleus = 10 -10 gram or about 5 μm 3 Therefore: 1 Gy ≈ 20,000 ionizations / 10 -10 g In crossing the 5 μm nucleus: 1 MeV electrons lose 200 eV in 6 ionizations/μm, 700 tracks ≈ 20,000 ionizations ≈ 1 Gy 30 keV electrons lose 1 keV in 30 ionizations/μm, 140 tracks ≈ 20,000 ionizations ≈ 1 Gy 4 MeV protons lose 10keV in 300 ionizations/μm 14 tracks ≈ 20,000 ionizations ≈ 1 Gy The dose to the nucleus is the same. The biological effect is very different. 3 In comparing different types of radiation, it is customary to use x rays (classically 250 kVp x rays, currently shifting to 60 Co gamma or > 1 MeV xrays) as the reference standard. ? Relative biological effectiveness (RBE) is defined as: test ref D D RBE= , where ? D ref is the dose of x rays, and ? D test is the dose of the test radiation needed to produce the same biological effect. This requires a biologic system where the effects of radiation may be scored quantitatively. Many different endpoints are possible (in vitro, in vivo, normal tissue, tumors). Image removed. Fig. 1-7 in Turner J. E. Atoms, Radiation, and Radiation Protection, 1st ed. New York: Pergamon, 1986. 4 Relation between RBE and adsorbed dose The different shapes of low-LET and high-LET survival curves lead to a variation in RBE as a function of endpoint (survival). The RBE depends on the level of biologic damage chosen as the endpoint. RBE varies as a function of dose. ? Large doses: RBE proportional to the ratio of the final slopes ? Intermediate doses: shoulder region, RBE ↑ as dose ↓ due to the shoulder of the reference curve. ? Low doses: RBE tends towards a ratio of the initial tangents Factors that influence RBE ? Radiation quality (LET) ? Radiation dose ? Number of dose fractions ? Dose rate ? Biological system or end point Image removed. Fig. 7.3a in Hall, Eric J. Radiobiology for the Radiologist, 5 th ed. Philadephia PA: Lippincott Williams & Wilkins, 2000. 5 Relation between RBE and LET ? RBE is strongly influenced by the LET of the particular radiation. ? As the LET increases, the slope becomes steeper, and the extrapolation number, n, tends towards unity. Image removed. The “optimum” LET? ? The maximum value of 100 keV/μm is similar for a wide variety of mammalian cells and for different endpoints (mutation, cell killing). ? It has been suggested that this reflects the “target” size and is related to DNA structure, which is similar for all mammalian cells. Image removed. Fig. 7.6 in [Hall]. 6 The “overkill” effect ? Based on target theory. ? Two inactivated sites required for cell kill. ? Densely ionizing radiation is inefficient in producing the maximum amount of cell kill. ? Low-LET radiation produces a sparsely ionizing track. ? It is a rare event for two tracks to deposit energy in the same cell. ? LET values above 100 keV/ /μm ”waste” dose The molecular theory ….. Images removed. Image removed. Fig. 7.7 in [Hall]. 7 This effect could also be related to repair. ? Low LET damage is easier for the cell to repair. ? Some fraction of the high-LET damage is more difficult or impossible to repair. ? The overall result would be similar. ? At some point dose is wasted. Image removed. 8 The Oxygen Enhancement Ratio (OER) Image removed. Fig. 7.8 in [Hall]. Significant implications for tumor therapy… OER vs LET Images removed. Fig. 7.8, 7.9 in [Hall]. 9 What is the evidence that DNA is the target? Selectively irradiate the nucleus or the cytoplasm. Results show the nucleus to be much more sensitive than the cytoplasm. ? Polonium needle: alpha particle range ~ 40μm. Image removed. Fig. 3.4 in [Hall]. ? Microbeams capable of delivering particles (protons or alpha particles) with μm resolution. Image removed. Microbeam Experiments Images removed. 10 Radioisotope Incorporation ? Incorporation of halogenated base analogues into DNA sensitizes cells. Image removed. Incorporation makes the DNA more susceptible to damage, including radiation damage. ? Radioisotopes incorporated into DNA kill cells much more efficiently than radioisotopes in RNA or in proteins. 125 I in the DNA is 200-300 times more effective than 125 I in the cytoplasm or on the cell membrane. ? Tritium is particularly useful: emits beta particles of 18 keV, range in tissue is less than 1-2 μm. o Tritiated thymidine….labels DNA o Tritiated uracil ….labels RNA o Tritiated amino acids to label proteins o Tritiated water (uniform distribution) is 1000 times less effective than tritiated thymidine (DNA localization). o [ 3 H]Thd incorporation caused chromosome breaks, correlating with the point of attachment visualized by autoradiography. ? Cells deficient in DNA repair enzymes are generally more radiosensitive. ? Drugs that inhibit DNA repair are sensitizers. 11 Types of DNA Damage Radiation can produce a variety of lesions in DNA ? Single strand break ? Double strand break ? Alteration to bases ? Destruction of sugars ? Crosslinks and formation of dimers But what about the background levels of DNA damage that occur every day from “natural” sources, primarily oxygen and reactive oxygen species? We have evolved sophisticated DNA damage detection and repair mechanisms to deal with this damage. Does radiation produce unique damage? Image removed. 12 DNA Strand Breaks Single strand breaks: ? Can take place at the phosphodiester bond, or at the bond between the base and the sugar. ? A large proportion of the single strand breaks are caused by hydroxyl radicals (OH?). Radical scavenging experiments have demonstrated this. Image removed. Single strand breaks are easily repaired. Double strand breaks are repaired more slowly and with more errors. Measured Numbers of Damaged Sites per Cell per Gray Type Yield Reference Single-strand breaks 1000 17 8-Hydroxyadenine 700 18 T* (thymine damage) 250 19 Double-strand breaks 40 17 DNA–protein cross-links 150 20 ? An X-ray dose of ~1 Gy produces about 1000 single strand breaks and about 40 double strand breaks in a typical mammalian cell. ? This dose causes about 50% cell death. ? DSBs are not necessarily lethal. 13 Double strand breaks ? Involves breakage of both strands at points less than 3 nucleotides apart. ? Double strand breaks have shown a direct proportionality to radiation dose, ? …but NOT to LET. Image removed. 14 See Holley, W.R., I. S. Mian, S. J. Park, B. Rydberg, and A. Chatterjee. “A Model for Interphase Chromosomes and Evaluation of Radiation-Induced Aberrations” Radiation Research 158 (2002) 568-580 Images removed. 15 So What Kills Cells? Chromosome aberrations correlate with dose. Image removed. High LET radiation is more effective than low-LET for production of aberrations. Image removed. Chromosome aberrations correlate with cell death. Image removed. Fig. 3.5 in [Hall]. ? Observation of individual cells following irradiation: if a micronucleus was present in the daughter cell, no colony was formed. ? N.B., Aberrations present at mitosis, may be far removed from initial damage. ? Repair, cell cycle, changes in chromatin structure all can affect the results. ? Chromosome aberrations also show the LET dependency with a maximum at about 100 keV/μm. At high LET, the damage could be too severe for survival. 16 Image removed. Chromosome aberrations require a dsb. The fact that ssbs and dsbs do not show the same LET dependence as other endpoints is unexplained. Recent work indicates that clustered damage is involved. 17