Dose Calculations A qualitative overview of Empirical Models and Algorithms Hanne Kooy
Dose Dose is the energy, in Joules (or calories), imparted to mass, in kg: J / kg Unit is Gy “gray,” after Louis Harold Gray (1905 - 65) was a British physicist who worked mainly on the effects of radiation on biological systems, inventing the field of radiobiology as he went. There is NO unit for biological dose Practice CGE, recommendation Gy (RBE)
Dose Energy is imparted by the passage of ionizing, charged, particles through matter Particles collide with orbital electrons or nuclei EM processes dominate “Dose” is a measure of the damage to cells inflicted by direct hits to DNA or free radicals (water ions)
Radiation Types Controls All: Intensity e-: Distal depth Typically over the field area e-: Distal depth HCP: Distal and Proximal Depth
Dose in Patient IMRT Proton
Dose Problem Equipment with many dials to set radiation field Patient’s anatomy and presentation dictates dose distribution in situ Dose calculation is “missing” link For photon RT, problem is to 1st order GEOMETRIC Reduces problem to intensity control Permitted RT to evolve based on X-ray analysis of patient only
Field Dose Shaping
Range Compensation Compute radiological, density-corrected, path lengths, Pi, for each ray from skin surface to the points along the distal edge of target volume For each ray compute “overshoot” range as: Pi R0 { Pi DRi
Range Compensator DRi
Spread-out Bragg peak
Dose Modeling Equipment Physics Description in terms of parameters Jaw size, energy, devices Physics as a function of those parameters Either in terms of measurements – or – in terms of explicit MC modeling Physics Develop models to quantify dose in patient Phenomenological to Exact
Equipment Modeling
Dose Modeling #0 The “old” days Measure ad nauseam Cover all equipment parameters Measurements in lieu of physics model Make plots and tables Overlay on patient anatomy based on external contour and extents of target
History of Proton Radiotherapy
Dose Modeling Physics, in general, was always known Computational equipment, hardware & software, evolved to permit a transition, in clinical practice, from Measurements to empirical models (70-80) Empirical to exact to MC (80-Now) Large scale calculations (Now) Not just dose but also “optimized” dose
Dose Modeling #1 “Orthogonal” set of measurements to quantify dose deposition as a function of equipment
Measurements Dose Depth Field size
Empirical Dose Model Generalize from measurements in specific conditions to predictions in patient
The Big Problems Radiation scatters which introduces secondary components Scattered photon interacts again Scatter depends on internal patient features Patient more complex than a water tank Tissue inhomogeneities (bone, tissue, lung) Irregular geometries
Scattered Radiation Consider “primary” contributions separately from “scattered” contributions Primary dose contribution is easy Simple lines from source to point of interest Scatter dose:
Computer Implementation #1 First codes implemented the parameterized models based Comprehensive, orthogonal, measurements of dose as function of parameters in water Models of dose in water Patient = Water (Fair assumption for X-rays) Description of patient’s anatomy by a few external contours obtained at time of simulation
Process #1 Simulate patient on simulator Has the same DOF’s as LINAC Produces X-ray’s to give a Beam’s Eye View of anatomy in path of radiation Allows MD to assess, based on empirical knowledge of anatomy, appropriateness of this beam approach Planner uses X-ray’s to Reconstruct internal anatomy Define the LINAC beams (= Sim beams) Paradigm completely driven by the original availability of X-ray
Dose Modeling #2 Use of MC in RT (Rogers ~1980) Parameterization of interaction details
Dose Modeling #2 + = Tissue Fluence calculation (“Primary” type calc, specified how many particles pass through the point of interest) Lung
Dose Modeling #2 Increased availability of CT scans enabled dose calculations on a “natural” patient representation with A measure of the local (electron) density Appropriate scaling of energy spread function A geometric representation of the patient
Equipment Modeling #2 Monte Carlo allows a replacement of the physical machine with a “virtual” machine Obviates the need for measurements Improves knowledge of such measurements
Pencil-beam algorithms A PB is a convenient approximation of how the particle stream distributes through a medium Both e and p have nice MCS Gaussian formalism, which has a convenient numerical implementation Photon energy kernels are more complex to implement A PB permits local “probing” of the medium to account for heterogeneities.
Pencil-beam algorithms Transport “primary” radiation, fluence, through patient’s anatomy represented by a CT slices Trace radiation rays, “pencils,” through anatomy At each step of the trace, transform local intensity to energy, “dose,” released in the medium.
Proton pencil-beam
Proton pencil-beam