Monte Carlo based dosimetry and treatment planning for neutron capture therapy of brain tumors.

Monte Carlo based dosimetry and computer-aided treatment planning for neutron capture therapy have been developed to provide the necessary link between physical dosimetric measurements performed on the MITR-II epithermal-neutron beams and the need of the radiation oncologist to synthesize large amounts of dosimetric data into a clinically meaningful treatment plan for each individual patient. Monte Carlo simulation has been employed to characterize the spatial dose distributions within a skull/brain model irradiated by an epithermal-neutron beam designed for neutron capture therapy applications. The geometry and elemental composition employed for the mathematical skull/brain model and the neutron and photon fluence-to-dose conversion formalism are presented. A treatment planning program, NCTPLAN, developed specifically for neutron capture therapy, is described. Examples are presented illustrating both one and two-dimensional dose distributions obtainable within the brain with an experimental epithermal-neutron beam, together with beam quality and treatment plan efficacy criteria which have been formulated for neutron capture therapy. The incorporation of three-dimensional computed tomographic image data into the treatment planning procedure is illustrated. The experimental epithermal-neutron beam has a maximum usable circular diameter of 20 cm, and with 30 ppm of B-10 in tumor and 3 ppm of B-10 in blood, it produces (with RBE weighting) a beam-axis advantage depth of 7.4 cm, a beam-axis advantage ratio of 1.83, a global advantage ratio of 1.70, and an advantage depth RBE-dose rate to tumor of 20.6 RBE-cGy/min (cJ/kg-min). These characteristics make this beam well suited for clinical applications, enabling an RBE-dose of 2,000 RBE-cGy/min (cJ/kg-min) to be delivered to tumor at brain midline in six fractions with a treatment time of approximately 16 minutes per fraction. With parallel-opposed lateral irradiation, the planar advantage depth contour for this beam (with the B-10 distribution defined above) encompasses nearly the whole brain. Experimental calibration techniques for the conversion of normalized to absolute treatment plans are described.

[1]  G. Brownell,et al.  Boron neutron capture therapy for the treatment of cerebral gliomas. I. Theoretical evaluation of the efficacy of various neutron beams. , 1975, Medical physics.

[2]  V. Bond,et al.  Current status of 10B-neutron capture therapy: enhancement of tumor dose via beam filtration and dose rate, and the effects of these parameters on minimum boron content: a theoretical evaluation. , 1985, International journal of radiation oncology, biology, physics.

[3]  J. H. Hubbell,et al.  Photon mass attenuation and energy-absorption coefficients , 1982 .

[4]  O. Harling,et al.  Monte Carlo treatment planning and high-resolution alpha-track autoradiography for neutron capture therapy. , 1989, Strahlentherapie und Onkologie : Organ der Deutschen Rontgengesellschaft ... [et al].

[5]  W. S. Snyder,et al.  Estimates of absorbed fractions for monoenergetic photon sources uniformly distributed in various organs of a heterogeneous phantom. , 1974, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[6]  R. Ojemann,et al.  NEUROPATHOLOGIC STUDY OF FOURTEEN CASES OF MALIGNANT BRAIN TUMOR TREATED BY BORON‐10 SLOW NEUTRON CAPTURE RADIATION , 1972, Journal of neuropathology and experimental neurology.

[7]  R A Brooks,et al.  Explanation of cerebral white--gray contrast in computed tomography. , 1980, Journal of computer assisted tomography.

[8]  R. P. Spencer Therapy in nuclear medicine , 1978 .

[9]  E. Betz Cerebral blood flow: its measurement and regulation. , 1972, Physiological reviews.

[10]  H. Hatanaka Boron-Neutron Capture Therapy for Tumors , 1986 .

[11]  R M Neer,et al.  Computed Tomography Scanning for the Measurement of Bone Mineral in the Human Spine , 1978, Journal of computer assisted tomography.

[12]  T. Matsumoto,et al.  Depth-dose evaluation and optimisation of the irradiation facility for boron neutron capture therapy of brain tumours. , 1985, Physics in medicine and biology.

[13]  B. Murray,et al.  Monte Carlo dosimetry calculation for boron neutron-capture therapy in the treatment of brain tumors , 1975 .

[14]  M. L. Randolph,et al.  Kerma factors of elements and compounds for neutron energies below 30 MeV , 1982 .

[15]  Briesmeister MCNP: a general Monte Carlo code for neutron and photon transport. Version 3A. Revision 2 , 1986 .

[16]  O. Harling,et al.  Neutron capture therapy beams at the MIT Research Reactor. , 1990, Basic life sciences.

[17]  R. Fairchild Development and Dosimetry of an `Epithermal' Neutron Beam for Possible Use in Neutron Capture Therapy I. `Epithermal' Neutron Beam Development , 1965 .