Dosimetry from organ to cellular dimensions

Dosimetry from organ to cellular dimensions

While the conventional Medical Internal Radiation Dose (MIRD) approach is useful for estimating approximate organ absorbed doses in diagnostic applications of isotopes, this strategy is suited neither to the exacting requirements of targeted radionuclide therapy nor to radiopharmaceuticals with a no...

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Veröffentlicht in:Computerized medical imaging and graphics 2001-03, Vol.25 (2), p.187-193
Hauptverfasser: Thierens, H.M, Monsieurs, M.A, Brans, B, Van Driessche, T, Christiaens, I, Dierckx, R.A
Format: Artikel
Sprache:eng
Schlagworte:
3-Iodobenzylguanidine - therapeutic use
Alpha Particles - therapeutic use
Alpha-radioimmunotherapy
Antineoplastic Agents - pharmacokinetics
Antineoplastic Agents - therapeutic use
Applied radiobiology (equipment, dosimetry...)
Auger electrons
Beta Particles - therapeutic use
Biological and medical sciences
Biological effects of radiation
Bone Marrow - radiation effects
Cells - radiation effects
Computational methods
Computer Simulation
DNA
Dosimetry
Female
Fundamental and applied biological sciences. Psychology
Humans
Image analysis
Internal dosimetry
Linear Energy Transfer
Male
Medical internal radiation dose
Monte Carlo Method
Monte Carlo methods
Neuroblastoma - diagnostic imaging
Neuroblastoma - radiotherapy
Point–kernel methods
Predictive Value of Tests
Radioimmunotherapy - standards
Radiometry - methods
Radiometry - standards
Radiopharmaceuticals - pharmacokinetics
Radiopharmaceuticals - therapeutic use
Radiotherapy - standards
Tissue Distribution
Tissues, organs and organisms biophysics
Tomography, Emission-Computed, Single-Photon
Tomography, X-Ray Computed
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Zusammenfassung:While the conventional Medical Internal Radiation Dose (MIRD) approach is useful for estimating approximate organ absorbed doses in diagnostic applications of isotopes, this strategy is suited neither to the exacting requirements of targeted radionuclide therapy nor to radiopharmaceuticals with a non-uniform activity distribution. For the individual treatment planning of patients treated with common radionuclides emitting high energy betas, the individual activity distribution has to be obtained from CT-SPECT images and the doses to the target organs and critical tissues have to be calculated by point-kernel methods. Due to the stochastic nature, alpha-radioimmunotherapy (alpha-RIT) requires microdosimetric calculations with Monte Carlo on a realistic model of the source and target tissue at the micrometer level. For a prediction of the biological effects of intracellular labelling with Auger electron emitters an accurate subcellular modelling including the DNA structure at the nanometre level with knowledge of the target for the considered biological effect is necessary.
ISSN:0895-6111
1879-0771
DOI:10.1016/S0895-6111(00)00047-1