Experimental imaging and profiling of absorbed dose in phantoms exposed to epithermal neutron beams for neutron capture therapy G. Gambarini and C. Colombi Dipartimento di Fisica, Università di Milano, and INFN, Sezione di Milano, Milan, Italy Abstract. Absorbed-dose images and depth-dose profiles have been measured in a tissue-equivalent phantom exposed to an epithermal neutron beam designed for neutron capture therapy. The spatial distribution of absorbed dose has been measured by means of gel dosimeters, imaged with optical analysis. From differential measurements with gels having different isotopic composition, the contributions of all the components of the neutron field have been separated. This separation is important, owing to the different biological effectiveness of the various kinds of emitted radiation. The doses coming from the reactions 1H(n,γ)2H and 14N(n,p)14C and the fast-neutron dose have been imaged. Moreover, a volume simulating a tumour with accumulation of 10B and/or 157Gd has been incorporated in the phantom and the doses due to the reactions with such isotopes have been imaged and profiled too. The results have been compared with those obtained with other experimental techniques and the agreement is very satisfactory. of the completeness of the information that can be obtained utilizing gel dosimeters in NCT and also of showing absorbed dose distribution in situations not yet reported in literature. INTRODUCTION The promising features continuously achieved by neutron capture therapy (NCT) encourage the development of all the correlated multidisciplinary research. In the field of radiation dosimetry, this therapy requires complex measurements and computations, both for what concerns beam controls and for in-phantom dose determinations aimed at validating treatment planning [1]. The complexity of performing exhaustive determinations of absorbed dose comes from the multiplicity of the energy release and absorption mechanisms in neutron fields. The various secondary radiations are characterized by different transport and interaction modalities in materials. Therefore, it is mandatory to perform precise evaluation of the absorbed dose in tissue, separating the dose contributions whose biological effect is different. ABSORBED DOSES IN NEUTRON CAPTURE THERAPY The therapy is based on the energy released by the secondary radiation emitted in nuclear reactions of thermal neutrons with suitable isotopes, selectively accumulated in tumor tissues. The more convenient isotope has appeared to be 10B, because of the high cross section of the reaction with thermal neutrons 10 B(n,α)7Li (σ = 3837 b) and of the high LET (linear energy transfer) and RBE (relative biological effectiveness) of the emitted charged particles. In fact, boron neutron capture therapy (BNCT) is now the common application of this therapy in clinical trials. The higher cross section is presented by 157Gd, but the low LET and RBE of the secondary radiation generated by the reaction 157 Gd(n,γ)158Gd (σ = 255000 b) have limited the interest in developing the therapy involving such an isotope. Recently, some increases in the interest towards this isotope has occurred as a Gel dosimeters have shown to give the possibility of in-phantom imaging and profiling the absorbed dose [2-4], separating the contributions of the various secondary radiation components. Some results obtained by means of Fricke-infused gel dosimeters are here shown, with the purpose of giving new proof CP680, Application of Accelerators in Research and Industry: 17th Int'l. Conference, edited by J. L. Duggan and I. L. Morgan © 2003 American Institute of Physics 0-7354-0149-7/03/$20.00 1102 The absorbed dose results to be proportional to the difference of optical absorption (OD) before and after irradiation. The difference of OD is obtained from the logarithm of the ratio of GL values before and after. Therefore, from light transmittance images, detected before and after exposure, dose images are obtained by means of proper algorithms and of pixel-to-pixel image elaboration [6]. result of the radiobiological studies which have revealed good effects for cell killing, which are attributed to the electrons emitted in the above cited reaction owing to internal conversion or Auger electrons. Moreover, the fact that gadolinium is commonly used as image intensifier in nuclear magnetic resonance imaging (NMRI) suggests to enquire the feasibility of determining the spatial distribution of boron in patients by means of NMRI, bounding a proper amount of gadolinium, besides boron, to the same carrier. Gel dosimetry has revealed peculiar characteristics that are very advantageous for NCT. The modalities with which the energy is released and absorbed are very near to those in tissue. For neutron fields, in particular, it is possible to obtain a tissue-equivalent matrix in which neutron interactions are similar to those in tissue. The transport characteristics and the mechanisms of energy release and absorption of the secondary radiation generated by neutron reactions are similar to those in tissue. Moreover, it is possible to make convenient variations to the isotopic composition of the gel in order to separate the various contributions to the absorbed dose. The basic gel composition is: Agarose [C12H14O5(OH)4] 1% of the final weight Ferrous Sulphate solution [1 mM Fe(NH4)2(SO4)2⋅6H2O] Sulphuric Acid [25 mM H2SO4] Xylenol-Orange [0.165 mM C31H27N2Na5O13S]. Other dose components have to be determined, normally released in tissue also in absence of boron or gadolinium accumulation: the dose due to the reactions of thermal neutrons with hydrogen and nitrogen: 1 H(n,γ)2H (σ = 0.33 b) 14 N(n,p)14C (σ = 1.81 b) and the fast-neutron dose, which is mainly released by recoil protons owing to the elastic scattering of neutrons with H nuclei. IN-PHANTOM IMAGING OF ABSORBED DOSE The imaging method is based on radiochromic geldosimeters obtained by incorporating Ferrous-sulphate and Xylenol-orange in Agarose-gel matrix. The effect of ionizing radiation results in changes of the optical absorption of visible light [5]. Transmittance images of conveniently shaped layers of this dosimetric gel are detected utilizing a CCD camera. An example of gel layer irradiated in phantom is shown in Fig. 1. The gel layer is placed on the illuminator for transmittance image detection. The strip of gray level (GL) standards is utilized for amending illumination instability. In a gel layer having the standard composition and placed in a phantom exposed to epithermal neutron beams, the absorbed dose is due to the whole γ-dose component (background and reactions of thermal neutrons with hydrogen and eventually with gadolinium) and to the fast-neutron. If to the previous gel composition an isotope is added, responsible for reactions with thermal neutrons with production of charged particles, such as 10B or 14N, the measured dose also contains this dose contribution. From the comparative analysis of dose images detected with this gel and with the standard one, the dose from charged particles can be separated. For separating γ-dose and fast-neutron dose, a method as been proposed based on comparative analysis of dose images detected with a standard gel layer and a layer of gel made with heavy water [3]. It is possible to compose phantoms of the desired shape and structure or to insert layers of dosimeter-gel in anthropomorphic phantoms. After exposure, the imaging of the gel-dosimeters allows obtaining the imaging of the absorbed dose. Suitable gel compositions and operation modalities have been studied, aimed at imaging and profiling the various dose contributions in tissue-equivalent phantoms both FIGURE 1. GL image of a gel layer after exposure in the epithermal column of the TAPIRO reactor, detected with the CCD camera. 1103 conventional techniques. The γ-dose component has been mapped by means of thermoluminescence dosimeters (TLDs) and the neutron fluence has been measured with activation technique and TLDs also. with and without boron and also in phantoms containing a volume with accumulation of 157Gd. The phantom utilized in this experiment, shown in Fig. 2(a), is a cylinder (14 cm of height and 16 cm of diameter) made in polyethylene because its content of hydrogen is near that in tissue. Dose images in the central plane have been detected. Dosimeters and simulated tumors have been suitably placed, in order to avoid empty spaces in the phantom that could cause alterations of neutron transport. RESULTS Exposures have been performed in the epithermal column of the fast research reactor TAPIRO of ENEA (Casaccia, Italy). Phantoms faced the collimator (having squared shape, 10 cm × 10 cm)with the phantom axis on the neutron beam axis. Gamma and fast-neutron doses have been imaged in the central plane of a polyethylene phantom and in a phantom in which a cylindrical polyethylene volume (3 cm of height and 7 cm of diameter) has been replaced with agarose-gel containing gadolinium, in order to simulate a big tumor. Natural gadolinium has been incorporated, in the proper amount so to have 100 ppm of 157Gd. The scheme of this phantom is shown in Fig. 2(b). The obtained results, reported in Fig. 3, show that the presence of gadolinium in the above amount gives noticeable increase of γ-dose in all the phantom. It is important to underline that 100 ppm of 157Gd is a low amount, principally with respect to that proposed for therapy purposes. (a) Simulated tumour 0.15 Dose Rate (Gy/min) γ dose in phantom n with simulated tumour FriXy-Gel TLD γ dose in phantom without simulated tumour FriXy-Gel TLD 0.1 0.05 Fast neutron dose 0 0 (b) Gel-dosimeter layers Tumour 4 8 Depth in phantom (cm) 12 FIGURE 3. Gamma dose components in the phantom with and without a simulated tumor containing 100 ppm of 157Gd and dose component due to fast neutrons. FIGURE 2. View of the cylindrical phantom during preparation for exposure. The phantom contain a simulated tumor (3 cm of height and 7 cm of diameter) with 100 ppm of 157Gd. In case of 157Gd accumulation, the dose component coming from internal conversion and Auger electrons has also been measured. The energy released by electrons is a very small fraction of the total but its determination is important because at present many radiobiology studies concerning the efficacy of such a dose are in development. Therefore, also the electron In order to check the consistency of the obtained results, dose and fluence measurements have been performed in the central plane of the phantom utilizing 1104 The results shown here give further confirmation of the validity of gel dosimetry in NCT. In fact, the profiles of dose components in phantoms exposed to epithermal neutrons are usually calculated by means computer simulations, because no other experimental techniques allows obtaining images and profiles of the absorbed doses. dose component has been measured with gel dosimeters. In order to also inspect the consistency of such results, the obtained electron dose profiles have been compared with values evaluated on the basis of kerma factors. In conclusion, the measured doses are: 1) γ-dose, coming in small fraction from reactor background and mainly from thermal neutron reactions with H and with157Gd, when gadolinium is present in the phantom; 2) proton-dose, due to thermal neutron reactions with nitrogen; 3) fast-neutron dose; 4) if gadolinium is present in the phantom, internal conversion and Auger electron dose, caused by the reactions of thermal neutron with 157Gd. Moreover, the results reported above give preliminary information that can contribute to the valuation of the convenience of employing gadolinium in NCT. ACKNOWLEDGEMENTS In Fig. 4(a) an example of the dose rate profiles along the axis of the phantom is shown and in Fig. 4(b) the same components are shown, multiplied by their RBE values. The work was partially supported by INFN (Italy) and partially by MURST (Prot. 970916835_002 and Prot. 2001062789_002). Authors are grateful to all the staff of ENEA’s TAPIRO reactor, G. Rosi, O. Fiorani, A. Perrone, G. Possenti and P. Di Venanzio, for their efficient collaboration during phantom exposures. Authors are grateful to Dr. G.Ranghetti and Dr. P.Giammello of ROYALITE PLASTICS s.r.l., Div. Caleppio, for having supplied polystyrene plates for transparent windows of gel-dosimeter samples. 0.2 Electrons Dose Rate (Gy/min) 0.16 Gamma (a) Recoil proton 0.12 Thermal neutron(Nitrogen) Total 0.08 0.04 REFERENCES 0 0 Gd 4 8 1. Watkins P., Moss R. L., Stecher-Rasmussen F. and Voorbraak W., “Dosimetry for BNCT in theory and pratice” in Advances in Neutron Capture Therapy, edited by B. Larsson et al., Amsterdam: Elsevier, 1997, Vol. I, pp. 141-146. 12 Depth in phantom (cm) 0.3 Dose Rate RBE (Gy/min) Thermal neutron(Nitrogen) 0.24 Recoil proton (b) 2. Gambarini G., Agosteo S., Marchesi P., Nava E., Palazzi P., Pecci A., Rosi G. and Tinti R., Appl. Radiat. Isot. 53, 765-772 (2000). Electrons 0.18 Gamma 0.12 3. Gambarini G., Agosteo S., Danesi U., Garbellini F., Lietti B., Mauri M. and Rosi G. IEEE Transactions on Nuclear Science 48, 780-784 (2001). Total 0.06 4. Gambarini G., Birattari C., Colombi C., Pirola L.and Rosi G., Radiat. Prot. Dosim. 101, 419-422 (2002). 0 0 Gd 4 8 12 Depth in phantom (cm) 5. Appleby A. and Leghrouz A., Med. Phys. 18, 309-312 (1991). FIGURE 4. Dose rate profiles (a) and dose rate RBE profiles (b) in the central axis of a cylindrical phantom containing a simulated tumor with 100 ppm of 157Gd, exposed in epithermal column of a TAPIRO reactor. 6. Gambarini G., Gomarasca G., Pecci A., Pirola L., Marchesini R. and Tomatis S., Nucl. Instr. and Meth. A422, 643-648 (1999). 1105
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