Библиотека дозовых распределений элементарных источников фотонов для целей планирования лучевой терапии
Диссертация
В современных, наиболее развитых системах дозиметрического планирования ведущее место занимают методы дозовых интегральных ядер, часто называемые методами свертки/суперпозиции. Эти методы основаны на использовании предварительно полученных специальных дозовых функций, представляющих собой распределения поглощенной энергии в воде для элементарных источников фотонов. Эти распределения принято… Читать ещё >
Список литературы
- Clinical dosimetry handbook 87. ICRU publication lOd, 1963 (Washington, DC, National Bureau of Standards)
- Measurement of absorbed dose in phantom irradiated by beams of x or gamma rays in radiotherapy procedures. ICRU publication 23, 1973 (Bethesda, MA: International commission on radiation units and measurements)
- Determination of absorbed dose in a patient irradiated by a single beam of x or gamma rays. ICRU publication 24,1976 (Bethesda, MA: International commission on radiation units and measurements)
- Use of computers in external beam radiotherapy procedures with high-energy photons and electrons. ICRU publication 42,1987 (Bethesda, MA: International commission on radiation units and measurements)
- Fundamental quantities and units for ionizing radiation. ICRU publication 60,1998 (Bethesda, MA: International commission on radiation units and measurements)
- Bramhe A. Dosimetric precision requirements in radiation therapy. Acta Radiol. Oncol., 1984. 23, 379−391
- Andreo P. Uncertainties in dosimetric data and calibration. Phys. Med. Biol., 1990 33, 861−920
- Wong J W and Purdy J A On methods of inhomogeneity corrections Med Phys, 1990,17, 807−814
- A Ahnesjo and M Aspradakis, Dose calculations for external photon beams in radiotherapy. Phys. Med. Biol. 44 99−155 (1999)
- Cunnigham J R. Scatter air ratios. Phys. Med. Biol., 1972 17, 42−51
- J.K. Cunnigham, Tissue Inhomogeneity Corrections in Photon-Beam Treatment Planning in Progress in Modern Radiation Physics, (Plenum, New York, 1982) pp.103−131.
- M.R. Sontag and J.R. Cunnigham. «Corrections to absorbed dose calculations for tissue inhomogeneities». Med. Phys. 4, 431−436 (1977)
- Batho H F Lung Corrections in cobalt 60 beam therapy J. Can. Assoc. Radiol., 15, 79−83 (1964)126
- Webb S and Fox R A Verification by Monte Carlo methods of a power law tissue-air ratio algorithm for inhomogeneity corrections in photon beam dose calculations Phys. Med. Biol. 25 2250(1980)
- El-Khatib E and Battista J J Improved lung dose calculation using tissue-maximum ratios in the Batho correction Med. Phys. 11 279−86 (1984)
- Wong J Wand Henkelman RM1982 Reconsideration of the power-law (Batho) equation for inhomogeneity corrections Med. Phys. 9 521−30
- Sontag M R and Ray S K Determination of differential scatter-air ratios (dSAR) for three dimentional scatter integration Med Phys, 1995,22 775−780
- M.R. Sontag and J.R. Cunnigham. «Clinical application of a CT based teratment planning system». Comput. Tomogr. 2,117−130 (1978)
- Petti P L, Rice R K, Mijnheer B J, Chin L M and Bj" arngard B E A heterogeneity model for photon beams incorporating electron transport Med. Phys. 14 349−54 (1987)
- P L Petti, R L Siddon and B E Bj arngard «A multiplicative correction factor for tissue heterogeneities», Phys. Med. Biol. 31(10) (1986)
- Sontag M R and Cunningham J «The equivalent tissue-air ratio method for making absorbed dose calculations in a heterogeneous medium» Radiology 129 787−94 (1978)
- O’Connor J E The variation of scattered x-rays with density in an irradiated body Phys. Med. Biol. 1 352−69 (1957)
- Beaudoin L 1968 Analytical approach to the solution of the dosimetry in heterogeneous media MSc Thesis University of Toronto
- Mackie, T.R., Scrimger, J.W., Battista, J.J. (1985). A convolution method of calculating dose for 15 MV x rays. Med. Phys. 12: 188−196.
- T.R. Mackie, A.F. Bielajev, B.W.O.R Rogers, J.J. Battista. «Generation of photon energy deposition kernels using the EGS Monte Carlo code», Phys. Med. Biol., 33,1−20, (1988)
- R Mohan, C. Chui, L. Lidofsky, «Differential pencil beam dose computation model for photons», Med/ Phys., 13, 64−73, (1986)
- A.Ahnesjo. Collapsed cone convolution of radiant energy for photon dose calculation in heterogeneous media", Med. Phys., 16, 577−592, (1989)
- Ahnesj" o A, Andreo P and Brahme A 1987 Calculation and application of point spread functions for treatment planning with high energy photon beams Acta Oncol. 26 49−56
- Ahnesj" o A, Saxner M and Trepp A 1992b A pencil beam model for photon dose calculation Med. Phys. 19 263−73 127
- Boyer A L, Zhu Y, Wang L and Francois P Fast Fourier transform convolution calculations of x-ray isodose distributions in homogeneous media Med. Phys. 16 248−53 (1989)
- Boyer A L and Mok E C 1985 A photon dose distribution model employing convolution calculations Med. Phys. 12 169−77
- Boyer A L and Mok E C 1986 Calculation of photon dose distributions in an inhomogeneous medium using convolutions Med. Phys. 13 503−9
- N. Papanikolaou, T.R. Mackie, C. Meger-Wells, M. Gehring,. «Investigation of the convolution method for polyenergetic spectra», Med. Phys., 20(5), 1327−1336, (1993).
- Metcalfe P E, Hoban P W, Murray D C and Round W H Modeling polychromatic high energy photon beams by superposition Australas. Phys. Eng. Sci. Med. 12 138−48.R152 A Ahnesj o and MMAspradakis (1989)
- Metcalfe P E, Hoban P W, Murray D C and Round WH Beam hardening of 10 MVradiotherapy x-rays: analysis using a convolution/superposition method Phys. Med. Biol. 35 1533−49 (1990)
- Hoban P.W. Accounting for the variation in collision kerma-to-terma ratio in polyenergetic photon beam convolution. Med. Phys., 22,2035−2044, (1995)
- Lee P C 1997 Monte Carlo simulations of the differential beam hardening effect of a flattening filter on a therapeutic x-ray beam Med. Phys. 24 1485−9
- Sharpe M B and Battista J J Dose calculations using convolution and superposition principles: the orientation of dose spread kernels in divergent x-ray beams Med. Phys. 20 1685−94 (1993)
- Liu H H, Mackie T R and McCullough E C Correcting kernel tilting and hardening in convolution/superposition dose calculations for clinical divergent and polychromatic photon beams Med. Phys. 24 1729−41 (1997)
- Zhu Y and Van Dyk J 1995 Accuracy requirements of the primary x-ray spectrum in dose calculations using FFT convolution techniques Med. Phys. 22 421−6
- Zhu Y and Boyer A 1990 X-ray dose computations in heterogeneous media using 3-dimensional FFT convolution Phys. Med. Biol. 35 351−68
- Wong E, Van Dyk J and Zhu Y 1997 Lateral electron transport in FFT photon dose calculations Med. Phys. 24 1992−2000
- Wong E, Zhu Y and Van Dyk J 1996 Theoretical developments on fast Fourier transform convolution dose calculations in inhomogeneous media Med. Phys. 23 1511−21 128
- Murray D С, Hoban P W, Metcalfe P E and Round W H 1989 3-D superposition for radiotherapy treatment planning using fast Fourier transforms Australas. Phys. Eng. Sci. Med. 12 128−37
- Gustafsson A, Lind В К and Brahme A 1994 A generalized pencil beam algorithm for optimization of radiation therapy Med. Phys. 21 343−56
- Klimanov V.A., Donskoy E.N. et al. «Development of 3-D planning systems for radiation therapy purposes», Annual report on the ISTS project N 144, Moscow, 1995.
- Y.A. Klimanov, E.N. Donskoy, V.V. Smirnov, V.S. Troshin. «Database of the energy deposition kernels for radiation therapy purposes», Conference proceedings «Nuclear data for science and technology. Part 2», Trieste, 1704−1706, 19−24 may 1997.
- B.A. Климанов, Б. Н. Мещерин, B.B. Смирнов, B.C. Трошин, Е. Б. Козлов. «Дозовые энергетические распределения дифференциального и интегрального тонких лучей фотонов в воде для целей планирования лучевой терапии», Медицинская физика, 4, 38−41,1997.
- В.А. Климанов, Е. Б. Козлов, B.C. Трошин, В. В. Смирнов. «Библиотека интегральных дозовых ядер для расчета дозовых распределений в лучевой терапии.», Мед. радиол. И радиац. Безопасность., 5, 55−61,2000.
- Bortfeld Т, Schlegel W and Rhein В 1993 Decomposition of pencil beam kernels for fast dose calculations in three-dimensional treatment planning Med. Phys. 20 311−18
- Y. Zhu and J. Van Dyk, «Accuracy requirements of the primary x-ray spectrum in dose calculations using FFT convolution techniques» Med. Phys., 22, 421−426, (1995)
- M.B. Sharpe and J.J. Batista, «Dose calculations using convolution and superposition principles: The orientation of dose spread kernels in divergent x-ray beams», Med. Phys., 20, 1685−1694,(1993)
- J. D. Bourland, E.L. Chaney. «A finite-size pencil beam model for photon dose calculations in three dimensions «, Med. Phys., 19, 1401−1412, (1992)
- O. Z. Ostapiak, Y. Zhu, J Van Dyk. «Refinements to the finite-size pencil beam model of three-dimensional photon dose calculation «, Med. Phys., 24(5), 743−750, (1997)
- Bleir A., Carol M., Curran В., e.a. Dose calculation for Intensity Modulated Radiotherapy using Finite-Size Pencil Beams derived from standard measured data. Nomos corporation, Sewickly, PA 15 143.
- Bortfeld T, Schlegel W and Rhein В 1993 Decomposition of pencil beam kernels for fast dose calculations in three-dimensional treatment planning Med. Phys. 20 311−18 129
- W. Ulmer, D.Harder. «А triple gaussian pencil beam model for photon beam treatment planning», Z. Med. Phys., 5, 25−30, (1995)
- W. R. Nelson, H. Hirayama, and D. W. O. Rogers. The EGS4 Code System. Report SLAC{265, Stanford Linear Accelerator Center, Stanford, Calif, 1985.
- Hartmann Siantar C., Bergstrom P., Chandler W e.a. Validation and clinical implementation of the PEREGRINE Monte-Carlo dose calculation system for photon beam therapy. Ibid., p. 1102
- Е.Н. Донской. PL-оценки с конечной дисперсией потока в точке. // Вопросы атомной науки и техники. Сер. Математическое моделирование физических процессов. 1997. Вып. 3. С. 65−74.
- Ahnesj’o A and Andreo Р 1989 Determination of effective bremsstrahlung spectra and electron contamination for photon dose calculations Phlys. Med. Biol. 34 1451−64
- Ahnesj» о A and Trepp A 1991 Acquisition of the effective lateral energy fluence distribution for photon beam dose calculations by convolution models Phys. Med. Biol. 36 973−85
- R Mohan, C. Chui, L. Lidofsky «Energy and angular distributions of photons from medical linear accelerators», Med/ Phys., 12, 592−597, (1985)
- Rogers D W 0, Faddegon В A, Ding G X, Ma С M, We J and Mackie T R 1995 BEAM: a Monte Carlo code to simulate radiotherapy treatment units Med. Phys. 22 503−24
- G. M. Mora, A. Maio, and D. W. O. Rogers. «Monte Carlo simulation of a typical 60Co therapy source». Med. Phys., 26(11), pp. 2494−2502, (1999)
- Desobry G E and Boyer A L 1994 An analytic calculation of the energy fluence spectrum of a linear accelerator Med. Phys. 21 1943−52
- A Ahnesjo. «Analytic modeling of photon scatter from flattening filters in photon therapy beams», Med. Phys., 21,1227−1235, (1994)130
- Beauvais H, Bridier A and Dutreix A 1993 Characteristics of contamination electrons in high energy photon beams Radiother. Oncol 29 308−16
- E. Storm, H. Israel. «Photon cross sections from 0.001 to 100 MeV for element 1 through 100», LASL, New Mexico, 1967
- Hubbel J.H. Photon Cross Sections, Attenuation Coefficients, and Energy Absorption Coefficients from 10 keV to lOOGeV, 1982 Int J. Appl. Radiat. Isot. 133, 1268−1290
- S. A. Goudsmit and J. L. Saunderson. Multiple scattering of electrons. Phys. Rev., 57: 2429, 1940.
- Nordell Band Brahme А1984 Angular distribution and yield from bremsstrahlung targets Phys. Med. Biol. 29 797−810
- B.A. Климанов, Е. Б. Козлов. «Влияние сглаживающего фильтра медицинского ускорителя на энергетическое и дозовое распределения тормозного излучения при дозиметрическом планировании.», Мед. радиол, и радиац. Безопасность., 4, 58−62, 1999.
- NUMERICAL RECIPES IN С: THE ART OF SCIENTIFIC COMPUTING. Cambridge University Press. 1992.