Fig 1 Diagrammatic Representation of Microscopic Patterns of Tracks in Tissue Irradiated with 10 mGy of Dose for Three Different Radiations (Low-LET γ Rays, High-LET α Particles, and Mixed-LET Fast Neutrons). For Each Radiation the Mean Numbers of Tracks are Given for Large Volumes, Corresponding to Whole Tissues, then for Cells, Chromatin, and Down to the Very Small Volumes of Segments of DNA. Also Given are the Dose Uniformity at these Four Levels of Resolution; These are Expressed as the Range of Doses Received by Individual Target Volumes. For Example, for the 2-nm Long Segments of DNA Only 1 Such Target Volume in 10⁸ Receives Any Energy Deposition at All; When This does Occur the Microscopic Dose to that Segment can have any Value up to about 10⁶ GY, Depending on the Chance Interactions of the Radiation Track as it Passes Through. The Last Column Illustrates how These Different Patterns of Local Energy Deposition (in all Cases for the Same Macroscopic Average Energy Deposition or Dose, 10 mGy) Affect the Probability of Permanent Biological Damage to the Cell. The Quoted Values are Typical for Cell Inactivation; Much Lower Probabilities are Found for Cell Transformation, or Mutation at a Single Locus, but the Sequence of Relative Effectiveness of the Radiations Persists. (From Goodhead, 1987b).

Fig 2 Diagrammatic Illustration of the Production of Tracks of Charged Particles in Material Irradiation with Neutral Particles (Photons, Neutrons) or Heavier Ions Such as α Particles or Accelerated Heavy Ions. (Reproduced with Permission from Paretzke, 1987.)