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7. Strategy for Vacuum Insulation Tests of MITICA 1 MV Electrostatic Accelerator

Author

Chitarin, G., primary, Kojima, A., additional, Boldrin, M., additional, Luchetta, A., additional, Marcuzzi, D., additional, Zaccaria, P., additional, Zanotto, L., additional, Toigo, V., additional, Aprile, D., additional, Marconato, N., additional, Patton, T., additional, Pilan, N., additional, Barbato, P., additional, Berton, G., additional, Breda, M., additional, Dan, M., additional, Fincato, M., additional, Lotto, L., additional, Rigoni-Garola, A., additional, Sartori, E., additional, Tollin, M., additional, Valente, M., additional, Grando, L., additional, Pomaro, N., additional, De Lorenzi, A., additional, Hiratsuka, J., additional, Ichikawa, M., additional, Kisaki, M., additional, Murayama, M., additional, Saquilayan, G. M., additional, Tobari, H., additional, Umeda, N., additional, Watanabe, K., additional, and Kashiwagi, M., additional

Published
2022
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12. Hippocampal Sparing Radiotherapy in adults with Primary Brain Tumors: A comparative planning and dosimetric study using IMPT, IMRT and 3DCRT

Author

Aka, P, Taylor, R, Hugtenburg, R, Lambert, J, Powell, J, Bevolo, T, Gao, M, Gondi, V, Hartsell, W.H, Bolsi, A, Beer, J, Belosi, M.F, Siewert, D, Lomax, A.J, Weber, D.C, Huang, Y.J, Huang, C.C, Chao, P.J, Liu, C, Shang, H, Ding, X, Wang, Y, Mammar, H, Froelich, Sébastien, Alapetite, Claire, Bolle, Stéphanie, Calugaru, Valentin, Feuvret, Loic, Helfre, Sylvie, Champion, Laurence, Goudjil, Farid, Dendal, Remi, Engelholm, S.A, Munck Af Rosenschold, P, Kristensen, I, Smulders, B, Muhic, A, Alkner, S, Jacob, E, Engelholm, S, Aljabab, S, Lui, A, Wong, T, Liao, J, Laramore, G, Parvathaneni, U, Kharouta, M, Pidikiti, R, Jesseph, F, Smith, M, Dobbins, D, Mattson, D, Choi, S, Mansur, D, Machtay, M, Bhatt, A, Lütgendorf-Caucig, C, Dunavölgyi, R, Georg, P, Perpar, A, Fussl, C, Konstantinovic, R, Ulrike, M, Piero, F, Eugen, H, Vidal, M, Gerard, A, Barnel, C, Maneval, D, Herault, J, Claren, A, Doyen, J, Dendale, R, Toutee, A, Pasquie, I, Goudjil, F, Lumbroso Lerouic, L, Levy, C, Desjardins, L, Cassoux, N, Elisei, G, Pella, A, Calvi, G, Ricotti, R, Tagaste, B, Valvo, F, Ciocca, M, Via, R, Mastella, E, Baroni, G, Saotome, N, Yonai, S, Makishima, H, Hara, Y, Inaniwa, T, Sakama, M, Kanematsu, N, Tsuji, H, Furukawa, T, Shirai, T, Sauerwein, W, Finger, P.T, Gallie, B, Gavrylyuk, Y, Thariat, J, Salleron, J, Maschi, C, Fevrier, E, Caujolle, J.P, Hofverberg, P, Angellier, G, Peyrichon, M.L, Breneman, J, Esslinger, H, Pater, L, Vatner, R, Habrand, J.L, Stefan, D, Lesueur, P, Kao, W, Véla, A, Geffrelot, J, Tessonnier, T, Balosso, J, Mahé, M.A, Lim, P.S, Rompokos, V, Chang, Y.C, Royle, G, Gaze, M, Gains, J, Vennarini, S, Francesco, F, Rombi, B, Amichetti, M, Schwarz, M, Lorentini, S, Mee, T, Burnet, N.G, Crellin, A, Kirkby, N.F, Smith, E, Kirkby, K.J, Roggio, M, Buwenge, M, Melchionda, F, Ammendolia, I, Ronchi, L, Cammelli, S, Morganti, A.G, Youn, S.H, Kim, J.Y, Park, H.J, Shin, S.H, Lee, S.H, Hong, E.K, Czerska, K, Winczura, P, Wejs-Maternik, J, Blukis, A, Antonowicz-Szydlowska, M, Rucinski, A, Olko, P, Badzio, A, Kopec, R, Franceschini, D, Cozzi, L, De Rose, F, Meattini, I, Fogliata, A, Cozzi, S, Becherini, C, Tomatis, S, Livi, L, Scorsetti, M, Garda, A, Fattahi, S, Michel, A, Mutter, R, Yan, E, Park, S, Corbin, K, Giap, H, LAM, W.W, Geng, H, Tang, K.K, Lee, T.Y, Kong, C.W, Yang, B, Chiu, T.L, Cheung, K.Y, Yu, S.K, Ma, M, Gao, X, Zhao, Z, Zhao, B, Mullikin, T, Routman, D, Yu, J, Greco, K, Fagundes, M, Shan, J, Daniels, T, Rule, W, DeWees, T, Hu, Y, Bues, M, Sio, T, Liu, W, chenbin, L, yuehu, P, yuenan, W, Bai, Y, Gao, X.S, Zhao, Z.L, Ma, M.W, Ren, X.Y, Salem, A, Woolf, D, Aznar, M, Azadeh, A, Eccles, C, Charlwood, F, Faivre-Finn, C, Teoh, S, Fiorini, F, George, B, Vallis, K, Van den Heuvel, F, Huang, E.Y, Juang, P.J, Pan, S, Hawkins, M, Clarke, M, Lowe, M, Radhakrishna, G, Schaub, S, Bowen, S, Nyflot, M, Chapman, T, Apisarnthanarax, S, Vitek, P, Kubes, J, Vondracek, V, Vinakurau, S, Zamecnik, L, Vitolo, V, Barcellini, A, Brugnatelli, S, Cobianchi, L, Vanoli, A, Fossati, P, Facoetti, A, Dionigi, P, Orecchia, R, Iannalfi, A, Vischioni, B, Ronchi, S, D’Ippolito, E, Petrucci, R, Yamaguchi, H, Honda, M, Hamada, K, Todate, Y, Seto, I, Suzuki, M, Wada, H, Murakami, M, Yu, Z, Zheng, W, Lien-Chun, L, Zhengshan, H, Qing, Z, Jiade, L, Guoliang, J, Fiore, M.R, D'Ippolito, E, Fukumitsu, N, Hayakawa, T, Yamashita, T, Mima, M, Demizu, Y, Suzuki, T, Soejima, T, Hartsell, W, Collins, S, Casablanca, V, Mihalcik, S, Brennan, E, Van Nispen, A, Corbett, A, Mohammed, N, Lee, P, van Nispen, A, Liang, Y.S, Mein, S, Kopp, B, Choi, K, Haberer, T, Debus, J, Abdollahi, A, Mairani, A, Ogino, H, Iwata, H, Hashimoto, S, Nakajima, K, Hattori, Y, Nomura, K, Shibamoto, Y, Li, P, Wu, S, Deng, L, Zhang, G, Zhang, Q, Fu, S, Yang, Z, Zhang, Y, Sasaki, R, Okimoto, T, Akasaka, H, Miyawaki, D, Yoshida, K, Wang, T, Komatsu, S, Fukumoto, T, Shuang, W, Xin, C, zhengshan, H, Shen, F, Vorobyov, N, Andreev, G, Martynova, N, Lyubinsky, A, Kubasov, A, Chen, J, Ma, N, Lu, Y, Zhao, J, Shahnazi, K, Lu, J, Jiang, G, Mao, J, Walser, M, Bojaxhiu, B, Kawashiro, S, Tran, S, Pica, A, Bachtiary, B, Weber, D, Gaito, S, Abravan, A, Richardson, J, Colaco, R, Saunders, D, Brennan, B, Petersen, I, Ahmed, S, Laack, N, Mizoe, J.E, Iizumi, T, Minohara, S, Kusano, Y, Matsuzaki, Y, Tsuchida, K, Serizawa, I, Yoshida, D, Katoh, H, Sakurai, H, Tujii, H, Kim, T.H, Park, J.W, Bo Hyun, K, Hyunjung, K, Sung Ho, M, Sang Soo, K, Sang Myung, W, Young-Hwan, K, Woo Jin, L, Dae Yong, K, Hong, Z, Wang, Z, Koroulakis, A, Molitoris, J, Kaiser, A, Hanna, N, Jiang, Y, Regine, W, DeCesaris, C.M, Choi, J.I, Carr, S.R, Burrows, W.M, Regine, W.F, Simone, C.B, Aihara, T, Hiratsuka, J, Kamitani, N, Higashino, M, Kawata, R, Kumada, H, Ono, K, Chou, Y.C, Dippolito, E, Bonora, M, Alterio, D, Gandini, S, Jereczeck, B.A, Kelly, C, Dobeson, C, Iqbal, S, Chatterjee, S, Hague, C, Li, T, Lin, A, Lukens, J, Slevin, N, Thomson, D, van Herk, M, West, C, Teo, K, Jeans, E, Manzar, G, Patel, S, Ma, D, Lester, S, Foote, R, Friborg, J, Jensen, K, Hansen, C.R, Andersen, E, Andersen, M, Eriksen, J.G, Johansen, J, Overgaard, J, Grau, C, Dědečková, K, Vítek, P, Ondrová, B, Sláviková, S, Zapletalová, S, Zapletal, R, Vondráček, V, Rotnáglová, E, Kwanghyun, J, Woojin, L, Dongryul, O, Yong Chan, A, Paudel, N, Schmidt, S, Ruckman, M, Gans, S, Stauffer, M, Helenowski, I, Patel, U, Samant, S, Gentile, M, Damico, N, Yao, M, Shuja, M, Routman, D.M, Foote, R.L, Garces, Y.I, Neben-Wittich, M.A, Patel, S.H, McGee, L.A, Harmsen, W.S, Ma, D.J, Sommat, K, Tong, A.K.T, Hu, J, Ong, A.L.K, Wang, F, Sin, S.Y, Wee, T.S, Tan, W.K, Fong, K.W, Soong, Y.L, Wallace, N, Fredericks, S, Fitzgerald, T, Vernimmen, F, Petringa, G, Cirrone, P, Agosteo, S, Attili, A, Cammarata, F.P, Cuttone, G, Conte, V, La Tessa, C, Manti, L, Rosenfeld, A, Lojacono, P.A, Hennings, F, Fattori, G, Peroni, M, Lomax, A, Hrbacek, J, Nguyen, H.G, Bach Cuadra, M, Sznitman, R, Schalenbourg, A, Pflaeger, A, Weber, A, Seidel, S, Stark, R, Heufelder, J, Mailhot Vega, R, Bradley, J, Lockney, N, Macdonald, S, Liang, X, Mazal, A, Mendenhall, N, Sher, D, Korreman, S.S, Andreasen, S, Petersen, J.B, Offersen, B.V, Gergelis, K, Jethwa, K, Whitaker, T, Shiraishi, S, Shumway, D, Press, R, Shelton, J, Zhang, C, Dang, Q, Tian, S, Shu, T, Seldon, C, Jani, A, Zhou, J, McDonald, M, Gort, E, Beukema, J.C, Spijkerman-Bergsma, M.J, Both, S, Langendijk, J.A, Matysiak, W.P, Brouwer, C.L, Baba, K, Numajiri, H, Murofushi, K, Oshiro, Y, Mizumoto, M, Onishi, K, Nonaka, T, Ishikawa, H, Okumura, T, Dominietto, M, Adam, K, Ahlhelm, F.J, Safai, S, Abdul-Jabbar, L, Song, J, Tseng, Y. D, Rockhill, J, Fink, J, Chang, L, Halasz, L. M, Guntrum, F, Steinmeier, T, Nagaraja, S, Jazmati, D, Geismar, D, Timmermann, B, Plaude, S, Lynch, C, Petras, K, Chang, J, Grimm, S, Lukas, R, Kumthekar, P, Merrell, R, Kalapurakal, J, Gross, J, Hoppe, B, Simone, C, Nichols, R.C, Pham, D, Mohindra, P, Chon, B, Morris, C, Li, Z, Flampouri, S, Powell, J.R, Murray, L, Burnet, N, Fernandez, S, Lingard, Z, McParland, L, O’Hara, D, Whitfield, G, Short, S.C, Guan, X, Gao, J, Hu, W, Yang, J, Xing, X, Hu, C, Kong, L, Zou, Z, Thomas, H, Sasidharan, B.K, Rengan, R, Zeng, J, Busold, S, Heese, J, Cerello, P, Bottura, L, Felcini, E, Ferrero, V, Monaco, V, Pennazio, F, de Rijk, G, Chang, H, KyungDon, C, Byunghun, H, Gyuseong, C, Chilukuri, S, Jalali, R, Panda, P.K, Korn, G, Larosa, G, Russo, A, Schillaci, F, Scuderi, V, Margarone, D, Fredén, E, Almhagen, E, Mejaddam, Y, Siegbahn, A, Guardiola, C, Gómez, F, Prieto-Pena, J, Fleta, C, De Marzi, L, Prezado, Y, Kabolizadeh, P, Reitemeier, P, Navin, M, Hamstra, D, Anderson, J, Stevens, C, Bartolucci, L, Adrien, C, Lejars, M, Vaillant, M, Fourquet, A, Robillard, M, Costa, E, Kirova, Y, Kolano, A.M, Degiovanni, A, Farr, J.B, Kundel, S, Pinto, M, Kurichiyanil, N, Würl, M, Englbrecht, F, Hillbrand, M, Schreiber, J, Parodi, K, Kurup, A, Magliari, A, Perez, J, Masui, S, Asano, T, Owen, H, Burt, G, Apsimon, R, Pitman, S, Popovici, M.A, Vasilache, R, Safavi-Naeini, M, Chacon, A, Howell, N, Middleton, R.J, Fraser, B, Guatelli, S, Rendina, L, Matsufuji, N, Gregoire, M.C, Sikora, K, Pettingell, J, Crocker, M, Saplaouras, A, Snijders, A, Mao, J.H, Nakamura, K, Bin, J, Gonsalves, A, Mao, H.S, Steinke, S, Roach, M, Leemans, W, Blakely, E, Takayama, K, Tan, T.S, Wee, J.T.S, Tuan, J.K.L, Wang, M.L.C, Quah, J.S.H, Tay, N.C.W, Lee, J.C.L, Lim, J.K.H, Oei, A.A, Tan, J.M, Park, S.Y, Chow, W.W.L, Omar, Y.B, Chew, P.G, Taylor, P, Lee, J, Tsurudome, T, Hirabayashi, M, Tsutsui, H, Yoshida, J, Takahashi, N, Kamiguchi, N, Hashimoto, A, Tachikawa, T, Mikami, Y, Kumata, Y, Wang, M, Chua, E.T, Wee, J, Wong, F.Y, Tuan, J, Master, Z, Wong, S, Welsh, J, Hentz, C, Pankuch, M, DeJongh, F, Xia, Y, Aitkenhead, A.H, Appleby, R, Merchant, M.J, MacKay, R.I, Young, H, Hughes, V, Alsulimane, M, Barajas, C.A, Taylor, J, Casse, G, Omar, A, Burdin, S, Boon, C, Lester, J, Thomas, A.J, Khan, A, Huthart, L, Leaver, K, Snell, J, Warlow, A, Burigo, L.N, Oborn, B, Belosi, F, Fredh, A, van de Water, S, Schneider, T, Patriarca, A, Bergs, J, Hierso, E, Hirayama, R, Martínez-Rovira, I, Seksek, O, Shirato, H, Nakamura, T, Ogino, T, Akimoto, T, Tamamura, H, Nishimoto, N, Proton-Net, G, Shimizu, S, Fabiano, S, Bangert, M, Guckenberger, M, Unkelbach, J, Mcauley, G, Teran, A, Slater, J, Wroe, A, Boon, I, Clorley, J, Owen, K, Oliver, T, Cicchetti, A, Ballarini, F, Rancati, T, Carrara, M, Zaffaroni, N, Bezawy, R. El, Carante, M, Valdagni, R, Faccini, R, Forte, G.I, Dhinsey, S, Greenshaw, T, Parsons, J, Welsch, C, Stock, M, Grevillot, L, Kragl, G, Carlino, A, Martino, G, Hug, E, Arya, H, Chirayath, V.A, Jin, M, Weiss, A.H, Glass, G.A, Chi, Y, Kaplan, L.P, Perez, R.A, Vestergaard, A, Gittings, E, Stamper, J, Beltran, C, Mark, P, Furutani, K, McAuley, G, Gordon, J, Boisseau, P, Dart, A, Nett, W, Kollipara, S, Grossmann, M, Actis, O, Diete, W, Rudolf, D, Klein, H.U, Kramert, R, Meer, D, Venkataraman, C, Waterstradt, T, Hérault, J, Bergerot, J.M, Hsi, W.C, Zhou, R, Zhang, X, Yang, F, Yinxiangzi, S, Sun, J, Li, X, Zhiling, C, Yuehu, P, Mengya, G, Haiyun, K, Qi, L, Zhentang, Z, Lin, Y.H, Tan, H.Q, Tan, L.K.R, Ang, K.W, Xiufang, L, Milkowski, K, Pang, D, Jones, M, Mizota, M, Tsunashima, Y, Himukai, T, Ogata, R, Uno, T, Ouyang, L, Jia, B, Li, D, Paul, K, Pullia, M, Savazzi, S, Lante, V, Foglio, S, Donetti, M, Falbo, L, Casalegno, L, Rousseau, M, Shinomiya, K, Yazawa, T, Iseki, Y, Kanai, Y, Hirata, Y, Powers, J, Solovev, A, Chernukha, A, Saburov, V, Shegai, P, Ivanov, S, Kaprin, A, Stolarczyk, L, Mojżeszek, N, Van Hoey, O, Farah, J, Domingo, C, Mares, V, Ploc, O, Trinkl, S, Harrison, R, Toltz, A, Nevitt, Z, Bloch, C, Taddei, P, Saini, J, Regmi, R, Yuntao, S, Jinxing, Z, Yap, J.S.L, Hentz, M, Silverman, J, Jolly, S, Boogert, S, Nevay, L, Kacperek, A, Schnuerer, R, Resta-Lopez, J, Zeng, X, Zheng, J, Li, M, Han, M, Song, Y, Holm, A, Korreman, S, Petersen, J.B.B, Bäumer, C, Fuenstes, C, Janson, M, Matic, A, Wulff, J, Psoroulas, S, Lomax, T, Arjomandy, B, Athar, B, Tesfamicael, B, Bejarano Buele, A, Deemer, J, Kozlyuk, V, VanSickle, K, Bolt, R, van Goethem, M.J, Langendijk, J, van t Veld, A, Chen, K.L, Wlodarczyk, B, Wu, H, Chen, Z, Shen, L, Fachouri, N, Placidi, L, Böhlen, T, Ieko, Y, Iwai, T, Nemoto, K, Suzuki, K, Kanai, T, Miyasaka, Y, Harada, M, Yamashita, H, Kubota, I, Kayama, T, Jensen, M.F, Bræmer-Jensen, P, Randers, P, Søndergaard, C.S, Nørrevang, O, Taasti, V.T, Kong, H, Yin, C, Gu, M, Liu, M, Shu, H, Chongxian, Y, Haiyang, Z, Juan, Z, Ming, L, Manzhou, Z., Liying, Z, Kecheng, C, Xiaolei, D, Castro, J, Freire, J, Cremades, M, Moral, L, Rico, P, Ares, C, Miralbell, R, Shi, J, Xia, J, Wang, B, Li, Q, Liu, X, Sung, C.C, Chen, W.P, Liao, T.Y, Takashina, M, Hamatani, N, Tsubouchi, T, Yagi, M, Mizoe, J, Titt, U, Mirkovic, D, Yepes, P, Wang, Q, Grosshans, D, Wieser, H.P, Mohan, R, Vadrucci, M, Xiao, G, Cai, X, Li, G, Yuan, Y, Lu, R, Sun, G, Zhang, M, Deming, L, lianhua, O, Takada, K, Tanaka, S, Matsumoto, Y, Naito, F, Kurihara, T, Nakai, K, Matsumura, A, Sakae, T, Shamurailatpam, D, P, K, Mp, N, A, M, Kg, G, T, R, C, S, J, R, Rozes, A, Dutheil, P, Batalla, A, Vela, A, Rana, S, Bennouna, J, Gutierrez, A, He, P, Shen, G, Dai, Z, Ma, Y, Chen, W, Pandey, J, Chirvase, C, Osborne, M, Ilsley, E, Di Biase, I, Kato, T, Hirose, K, Arai, K, Motoyanagi, T, Harada, T, Takeuchi, A, Kato, R, Tanaka, H, Mitsumoto, T, Takai, Y, Bolsa-Ferruz, M, Palmans, H, Chen, Y.S, Wu, S.W, Huang, H.C, Wang, H.T, Yeh, C.Y, Chen, H.H, Cook, H, Lourenço, A, Dal Bello, R, Magalhaes Martins, P, Hermann, G, Kihm, T, Seimetz, M, Brons, S, Seco, J, De Saint-Hubert, M, Swakon, J, De Freitas Nascimento, L, Tessaro, V.B, Poignant, F, Gervais, B, Beuve, M, Galassi, M.E, Harms, J, Chang, C.W, Zhang, R, Lin, Y, Langen, K, Liu, T, Lin, L, Howard, M, Denbeigh, J, Remmes, N, Debrot, E, Herman, M, Huang, Y.Y, Tsai, S.H, Fang, F.M, Mizuno, H, Sagara, T, Yamazaki, Y, Kato, M, Oyama, S, Pembroke, C, Joslin-Tan, T, Maggs, R, O’Neil, K, Barrett-Lee, P, Staffurth, J, Resch, A, Heyes, P, Georg, D, Fuchs, H, Hideyuki, M, katsuhisa, N, Wataru, Y, Samnøy, A.T, Ytre-Hauge, K.S, Povoli, M, Kok, A, Summanwar, A, Linh, T, Malinen, E, Röhrich, D, Asp, J, Santos, A, Afshar, V.S, Zhang, W.Q, Bezak, E, a, M, k, G, p, K, mp, N, t, R, c, S, j, R, Smith, B, Hammer, C, Hyer, D, DeWerd, L, Culberson, W, Brooke, M, Straticiuc, M, Craciun, L, Matei, C.E, Radu, M, Xiao, M, Paschalis, S, Joshi, P, Price, T, Mehta, M, 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Pike, L, Horick, N, Yeap, B, Franck, K, Wang, I, Loeffler, J, McKenna, M, Shih, H, Kountouri, M, Kole, A.J, Murray, F.R, Kliebsch, U, Combescure, C, iannalfi, A, Riva, G, Dougherty, J, Kruse, J, Iott, M, Brown, P, Olivier, K, Brodin, P, Kabarriti, R, Schechter, C, Kalnicki, S, Garg, M, Tomé, W, Lu, J.J, Chen, P.J, Dhanireddy, B, Severo, C, Lee, C.H, Lin, C.R, Rosier, L, Mathis, T, DeLaney, T, Lin, S, O’Meara, E, Powell, T, Hong, T, Hall, D, Liu, A, Ntentas, G, Dedeckova, K, Darby, S, Cutter, D, Zapletalova, S, Chen, Y.L, Miao, R, Lee, H, Hsiao-Ming, L, Choy, E, Cote, G, Eulitz, J, Lutz, B, Enghardt, W, Lühr, A, Mcmahon, S, Prise, K, Sung Hyun, L, Tansho, R, Mizushima, K, Warmenhoven, J.W, Hufnagl, A, Friedrich, T, Deycmar, S, Gruber, S, Dörr, W, Pruschy, M, Waissi, W, Burckel, H, Nicol, A, Noel, G, Yousef, I, Koizumi, M, Santa Cruz, G.A, González, S.J, Longhino, J, Provenzano, L, Oña, P, Rao, M, Cantarelli, M.D.L.Á, Leiras, A, Olivera, M.S, Alessandrini, P, Brollo, F, Boggio, E, Costa, H, Ventimiglia, R, Binia, S, Nievas, S.I, Langle, Y, Eijan, A.M, Colombo, L.L, Kawai, K, Nakamura, H, Natsuko, K, Masaki, H, Nakada, M, Furuse, M, Miyatake, S.I, Koivunoro, H, Kankaanranta, L, González, S, Joensuu, H, Sokol, O, Hild, S, Wiedemann, J, Köthe, A, Perry, D, Batie, M, Mascia, A, Sertorio, M, Luhr, A, Suckert, T, Müller, J, Beyreuther, E, Gotz, M, Haase, R, Schürer, M, Tillner, F, von Neubeck, C, Davis, A, Sishc, B, Saha, J, Ding, L, Story, M, Wagner, S, Kim, S.Y, Geary, S, Woodruff, T, Xu, T, Meng, Q, Gilchrist, S, Perentesis, J.P, Zheng, Y, Wells, S.I, Kong, Y, Liu, Y, Geng, Y, Knoll, M, Schwager, C, Schlegel, J, Schnölzer, M, Ding, L.H, Aroumougame, A, Chen, B, Saha, D, Pompos, A, Carter, R, Nickson, C, Thomson, J, Hill, M, Rodrigues, D, Snider, J, Sharma, A, Zakhary, M, Kara, L, Vujaskovic, Z, Dykstra, M, Best, T, Keane, F, Khandekar, M, Fintelmann, F, Willers, H, Singh, P, Eley, J, Malyapa, R, Mahmood, J, Hårdemark, B, Sandison, G.A, Wootton, L.S, Miyoaka, R.S, Laramore, G.E, Yang, P, van der Weide, H, Maduro, J, Heesters, M, Gawryszuk, A, Davila-Fajardo, R, Langendijk, H, Eckhard, M, Maxwell, A, VanNamen, K, Cashin, M, Jacovic, A, Dunn, M, kim, T, Jung, J, Kim, J, Swerdloff, S, Saunders, A, Thomas, J, Kidani, T, Okada, A, Tomida, K, Pennington, H, Xiaoqiang, L, Weigang, H, An, Q, Di, Y, Craig, S, Inga, G, Peyman, K, Xuanfeng, D, Cunningham, C, de Kock, M, Slabbert, J, Panaino, C.M, Phoenix, B, Regan, P.H, Shearman, R, Collins, S.M, Taylor, M.J, Grayson, M, Kato, K, Choi, H, Jang, J.W, Shin, W.G, Min, C.H, McMahon, S, Padilla Cabal, F, Fragoso, J.A, Resch, A.F, Katsis, A, Girdhani, S, Marshall, A, Jackson, I, Bentzen, S, Parry, R, Gantz, S, Schellhammer, S, Hoffmann, A, Delorme, R, Dos Santos, M, Salmon, R, Öden, J, Bullivant, K, Rucksdashal, R, Ferret, E, Covington, F, Rice, S, Decesaris, C, Siddiqui, O, Kowalski, E, Samanta, S, and Rothwell, B

Subjects
Biology: Biological Differences between Carbon, Proton and Photons Poster Discussion SessionsPTC58-0642, Physics: Absolute and Relative DosimetryPTC58-0180, Biology: Biology and Clinical InterfacePTC58-0685, Physics: Commissioning New FacilitiesPTC58-0385, Physics: 4D Treatment and DeliveryPTC58-0546, Clinics: EyePTC58-0714, Biology: Biological Differences between Carbon, Proton and Photons Poster Discussion SessionsPTC58-0528, Physics: Quality Assurance and VerificationPTC58-0507, Oral AbstractsPhysics: Dose Calculation and OptimisationPTC58-0661, Biology: Translational and Biomarkers Poster Discussion SessionsPTC58-0221, Oral AbstractsPhysics: Dose Calculation and OptimisationPTC58-0531, Oral AbstractsPhysics: Dose Calculation and OptimisationPTC58-0653, Biology: Drug and Immunotherapy CombinationsPTC58-0163, Clinics: Sarcoma - LymphomaPTC58-0055, Biology: Drug and Immunotherapy CombinationsPTC58-0166, Clinics: CNS / Skull BasePTC58-0198, Physics: Treatment PlanningPTC58-0421, Clinics: PediatricsPTC58-0560, General: New HorizonsPTC58-0709, Physics: Treatment PlanningPTC58-0664, Clinics: Eye / Breast / Pelvis Poster Discussion SessionsPTC58-0286, Physics: Treatment PlanningPTC58-0666, Biology: Translational and Biomarkers Poster Discussion SessionsPTC58-0346, Physics: Treatment PlanningPTC58-0547, Physics: Treatment PlanningPTC58-0308, Physics: Treatment PlanningPTC58-0549, Physics: Beam Delivery and Nozzle Design Poster Discussion SessionsPTC58-0111, Physics: Absolute and Relative DosimetryPTC58-0050, Biology: Enhanced Biology in Treatment Planning Poster Discussion SessionsPTC58-0587, Biology: Biology and Clinical InterfacePTC58-0454, Physics: Absolute and Relative DosimetryPTC58-0052, Physics: Commissioning New FacilitiesPTC58-0395, Physics: 4D Treatment and DeliveryPTC58-0534, Physics: Dose Calculation and OptimisationPTC58-0072, Physics: 4D Treatment and DeliveryPTC58-0533, Physics: 4D Treatment and DeliveryPTC58-0538, Physics: Commissioning New Facilities Poster Discussion SessionsPTC58-0113, Physics: Quality Assurance and VerificationPTC58-0633, Physics: Treatment PlanningPTC58-0431, Physics: Beam Delivery and Nozzle DesignPTC58-0230, Biology: Mathematical Modelling SimulationPTC58-0179, Clinics: Head and Neck / EyePTC58-0365, Physics: Treatment PlanningPTC58-0319, Biology: Translational and Biomarkers Poster Discussion SessionsPTC58-0697, Biology: Biology and Clinical InterfacePTC58-0663, Physics: Commissioning New FacilitiesPTC58-0240, Physics: Adaptive TherapyPTC58-0177, Physics: Commissioning New FacilitiesPTC58-0363, Physics: Commissioning New FacilitiesPTC58-0487, Physics: 4D Treatment and DeliveryPTC58-0209, Physics: 4D Treatment and DeliveryPTC58-0206, Clinics: CNS / Skull BasePTC58-0294, Physics: Commissioning New FacilitiesPTC58-0127, Biology: Mathematical Modelling SimulationPTC58-0068, Physics: Treatment Planning Poster Discussion SessionsPTC58-0062, Physics: 4D Treatment and DeliveryPTC58-0692, Physics: Quality Assurance and VerificationPTC58-0723, Physics: Commissioning New Facilities Poster Discussion SessionsPTC58-0494, Physics: Treatment PlanningPTC58-0643, Physics: Treatment PlanningPTC58-0521, Physics: Treatment PlanningPTC58-0402, Physics: Treatment PlanningPTC58-0405, Clinics: Head and Neck / EyePTC58-0273, Clinics: GIPTC58-0397, Physics: Treatment PlanningPTC58-0648, Biology: Enhanced Biology in Treatment Planning Poster Discussion SessionsPTC58-0489, Physics: Quality Assurance and VerificationPTC58-0617, Physics: Quality Assurance and VerificationPTC58-0616, Physics: Dose Calculation and Optimisation Poster Discussion SessionsPTC58-0668, Clinics: CNS / Skull BasePTC58-0188, Oral AbstractsPhysics: Dose Calculation and OptimisationPTC58-0625, Physics: Treatment PlanningPTC58-0654, Physics: Treatment PlanningPTC58-0655, Biology: Drug and Immunotherapy Combinations Poster Discussion SessionsPTC58-0133, Clinics: PediatricsPTC58-0313, Physics: Treatment PlanningPTC58-0659, Poster AbstractsClinics: CNSPTC58-0290, Physics: Commissioning New FacilitiesPTC58-0064, Physics: Adaptive TherapyPTC58-0396, Physics: Dose Calculation and OptimisationPTC58-0281, Physics: Quality Assurance and VerificationPTC58-0427, Physics: Quality Assurance and VerificationPTC58-0669, General: New Horizons SessionPTC58-0191, Physics: Dose Calculation and Optimisation Poster Discussion SessionsPTC58-0217, Physics: Quality Assurance and VerificationPTC58-0303, Physics: Quality Assurance and VerificationPTC58-0665, Clinics: Sarcoma - LymphomaPTC58-0495, Physics: Dose Calculation and OptimisationPTC58-0398, Physics: Quality Assurance and VerificationPTC58-0667, Physics: Quality Assurance and VerificationPTC58-0425, Physics: Quality Assurance and VerificationPTC58-0541, Physics: Treatment PlanningPTC58-0584, Physics: Quality Assurance and VerificationPTC58-0540, Biology: Drug and Immunotherapy Combinations Poster Discussion SessionsPTC58-0163, Physics: Treatment PlanningPTC58-0224, Physics: Treatment PlanningPTC58-0229, Clinics: PediatricsPTC58-0249, Physics: Beam Delivery and Nozzle Design Poster Discussion SessionsPTC58-0555, Clinics: PediatricPTC58-0463, Physics: Commissioning New Facilities Poster Discussion SessionsPTC58-0556, Physics: Absolute and Relative DosimetryPTC58-0498, Physics: Commissioning New FacilitiesPTC58-0078, Physics: Dose Calculation and OptimisationPTC58-0270, Physics: Dose Calculation and OptimisationPTC58-0032, Physics: Dose Calculation and OptimisationPTC58-0274, Physics: 4D Treatment and DeliveryPTC58-0614, Physics: Dose Calculation and OptimisationPTC58-0026, Clinics: Head and Neck / EyePTC58-0280, Clinics: Eye / Breast / Pelvis Poster Discussion SessionsPTC58-0091, Physics: Treatment PlanningPTC58-0593, Biology: Drug and Immunotherapy CombinationsPTC58-0012, Physics: Dose Calculation and OptimisationPTC58-0025, Physics: Dose Calculation and OptimisationPTC58-0146, Clinics: Sarcoma - LymphomaPTC58-0261, Physics: Treatment PlanningPTC58-0110, Clinics: Lung / Sarcoma / LymphomaPTC58-0733, Physics: Quality Assurance and VerificationPTC58-0554, Physics: Treatment PlanningPTC58-0597, Physics: Dose Calculation and Optimisation Poster Discussion SessionsPTC58-0330, Physics: Treatment PlanningPTC58-0115, Physics: Treatment PlanningPTC58-0598, Physics: Absolute and Relative DosimetryPTC58-0040, Physics: Absolute and Relative DosimetryPTC58-0282, Biology: Enhanced Biology in Treatment Planning Poster Discussion SessionsPTC58-0399, Physics: Absolute and Relative DosimetryPTC58-0283, Physics: Commissioning New Facilities Poster Discussion SessionsPTC58-0569, Clinics: GUPTC58-0647, Biology: Biological Differences between Carbon, Proton and Photons Poster Discussion SessionsPTC58-0506, Physics: Commissioning New FacilitiesPTC58-0047, Physics: Dose Calculation and OptimisationPTC58-0067, Clinics: GUPTC58-0409, Physics: Dose Calculation and OptimisationPTC58-0065, Biology: BNCT Poster Discussion SessionsPTC58-0586, Physics: Absolute and Relative Dosimetry PTC58-0393, Physics: Image GuidancePTC58-0712, Physics: Quality Assurance and VerificationPTC58-0645, Physics: Treatment PlanningPTC58-0683, Biology: BNCT Poster Discussion SessionsPTC58-0107, Physics: Treatment Planning Poster Discussion SessionsPTC58-0266, Physics: Monitoring and Modelling MotionPTC58-0530, Biology: BNCT Poster Discussion SessionsPTC58-0341, Physics: Commissioning New FacilitiesPTC58-0172, Physics: Commissioning New Facilities Poster Discussion SessionsPTC58-0456, Physics: Dose Calculation and OptimisationPTC58-0170, Physics: Commissioning New Facilities Poster Discussion SessionsPTC58-0458, Physics: Absolute and Relative DosimetryPTC58-0034, Physics: Quality Assurance and VerificationPTC58-0417, Physics: Quality Assurance and VerificationPTC58-0413, Physics: Treatment Planning Poster Discussion SessionsPTC58-0492, Physics: Dose Calculation and OptimisationPTC58-0168, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0724, Physics: Treatment PlanningPTC58-0694, Physics: Adaptive TherapyPTC58-0005, Physics: Treatment PlanningPTC58-0696, Physics: Treatment PlanningPTC58-0453, Physics: Adaptive TherapyPTC58-0366, Clinics: BreastPTC58-0197, Physics: Beam Delivery and Nozzle DesignPTC58-0652, Physics: Treatment Planning Poster Discussion SessionsPTC58-0017, Physics: Treatment PlanningPTC58-0338, Clinics: Head and Neck / EyePTC58-0539, General: New Horizons SessionPTC58-0390, Physics: Image Guidance Poster Discussion SessionsPTC58-0651, General: New HorizonsPTC58-0660, Physics: Dose Calculation and OptimisationPTC58-0360, Physics: Image GuidancePTC58-0297, Physics: 4D Treatment and DeliveryPTC58-0147, Scientific: RTTPTC58-0388, Physics: Dose Calculation and OptimisationPTC58-0484, General: New HorizonsPTC58-0301, Physics: Dose Calculation and OptimisationPTC58-0485, General: New HorizonsPTC58-0304, Physics: 4D Treatment and Delivery Poster Discussion SessionsPTC58-0532, Clinics: GIPTC58-0575, General: New HorizonsPTC58-0306, Physics: Quality Assurance and VerificationPTC58-0589, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0344, Physics: Quality Assurance and VerificationPTC58-0225, Physics: Treatment PlanningPTC58-0381, Physics: Quality Assurance and VerificationPTC58-0467, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0585, Physics: Commissioning New FacilitiesPTC58-0416, Physics: Quality Assurance and VerificationPTC58-0228, Physics: Quality Assurance and VerificationPTC58-0348, Physics: Dose Calculation and OptimisationPTC58-0234, Physics: Quality Assurance and VerificationPTC58-0101, Physics: Treatment PlanningPTC58-0386, Physics: Dose Calculation and OptimisationPTC58-0118, Physics: Treatment PlanningPTC58-0265, Physics: Dose Calculation and OptimisationPTC58-0119, Clinics: GIPTC58-0218, Physics: Treatment PlanningPTC58-0267, Physics: Treatment PlanningPTC58-0387, Clinics: BreastPTC58-0142, Physics: Treatment PlanningPTC58-0269, Physics: Beam Delivery and Nozzle DesignPTC58-0620, Clinics: PediatricsPTC58-0048, Physics: Quality Assurance and VerificationPTC58-0220, Physics: Quality Assurance and VerificationPTC58-0461, Physics: Treatment PlanningPTC58-0029, Physics: Absolute and Relative DosimetryPTC58-0571, Physics: Image GuidancePTC58-0046, Clinics: GUPTC58-0557, Physics: Absolute and Relative DosimetryPTC58-0211, Oral AbstractsPhysics: Dose Calculation and OptimisationPTC58-0131, Oral AbstractsPhysics: Dose Calculation and OptimisationPTC58-0373, General: New HorizonsPTC58-0411, Physics: Dose Calculation and OptimisationPTC58-0595, Clinics: CNS / Skull BasePTC58-0361, General: New HorizonsPTC58-0414, General: New HorizonsPTC58-0537, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0628, Physics: Treatment PlanningPTC58-0271, Physics: Commissioning New FacilitiesPTC58-0307, Physics: Quality Assurance and VerificationPTC58-0359, Physics: Quality Assurance and VerificationPTC58-0354, General: New HorizonsPTC58-0419, Physics: Treatment PlanningPTC58-0035, Biology: BNCTPTC58-0474, Clinics: GIPTC58-0460, Biology: BNCTPTC58-0596, Clinics: GIPTC58-0222, Physics: Image GuidancePTC58-0193, Clinics: PediatricPTC58-0312, Clinics: GUPTC58-0441, Clinics: LungPTC58-0701, Clinics: EyePTC58-0536, Clinics: GUPTC58-0205, Physics: Dose Calculation and OptimisationPTC58-0140, Clinics: GUPTC58-0208, Physics: Dose Calculation and OptimisationPTC58-0020, Physics: Image GuidancePTC58-0195, Poster AbstractsClinics: CNSPTC58-0717, Physics: Quality Assurance and VerificationPTC58-0325, Physics: Dose Calculation and OptimisationPTC58-0015, Physics: Commissioning New FacilitiesPTC58-0634, General: New HorizonsPTC58-0646, Physics: Quality Assurance and VerificationPTC58-0566, Physics: Dose Calculation and OptimisationPTC58-0134, Physics: Dose Calculation and OptimisationPTC58-0376, Biology: Mathematical Modelling SimulationPTC58-0462, Biology: BNCTPTC58-0567, General: New HorizonsPTC58-0527, Physics: Treatment PlanningPTC58-0482, Clinics: GI, GU, BreastPTC58-0693, Physics: Commissioning New FacilitiesPTC58-0518, Physics: Quality Assurance and VerificationPTC58-0686, Physics: Quality Assurance and VerificationPTC58-0202, Physics: Quality Assurance and VerificationPTC58-0322, Physics: Quality Assurance and VerificationPTC58-0564, Physics: Quality Assurance and VerificationPTC58-0680, Physics: Treatment PlanningPTC58-0247, Physics: Quality Assurance and VerificationPTC58-0682, Physics: Quality Assurance and VerificationPTC58-0440, Biology: Translational and BiomarkersPTC58-0514, Physics: Beam Delivery and Nozzle Design Poster Discussion SessionsPTC58-0178, Clinics: EyePTC58-0520, Physics: Absolute and Relative DosimetryPTC58-0231, Clinics: Head and Neck / EyePTC58-0424, Physics: Absolute and Relative DosimetryPTC58-0471, Physics: Absolute and Relative DosimetryPTC58-0356, Physics: Dose Calculation and OptimisationPTC58-0491, Physics: Dose Calculation and OptimisationPTC58-0250, Physics: Commissioning New FacilitiesPTC58-0650, Biology: Biology and Clinical InterfacePTC58-0719, Physics: Absolute and Relative DosimetryPTC58-0232, Physics: Absolute and Relative DosimetryPTC58-0353, General: New HorizonsPTC58-0511, Physics: Quality Assurance and VerificationPTC58-0219, Physics: Absolute and Relative DosimetryPTC58-0238, General: New HorizonsPTC58-0512, Physics: 4D Treatment and Delivery Poster Discussion SessionsPTC58-0401, Clinics: PediatricPTC58-0688, Physics: Quality Assurance and VerificationPTC58-0457, Physics: Quality Assurance and VerificationPTC58-0214, Physics: Quality Assurance and VerificationPTC58-0459, General: New HorizonsPTC58-0516, Physics: Treatment PlanningPTC58-0372, Physics: Treatment PlanningPTC58-0011, Physics: Treatment PlanningPTC58-0254, Physics: Quality Assurance and VerificationPTC58-0332, Clinics: CNS / Skull BasePTC58-0468, Biology: Mathematical Modelling SimulationPTC58-0357, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0649, Physics: Dose Calculation and OptimisationPTC58-0006, Physics: Quality Assurance and VerificationPTC58-0212, Physics: Image Guidance Poster Discussion SessionsPTC58-0565, Physics: Treatment PlanningPTC58-0018, Physics: Treatment PlanningPTC58-0019, Clinics: BreastPTC58-0576, Clinics: Head and Neck / EyePTC58-0335, Clinics: Head and Neck / EyePTC58-0577, General: New HorizonsPTC58-0621, Physics: Absolute and Relative DosimetryPTC58-0426, Physics: Commissioning New Facilities Poster Discussion SessionsPTC58-0268, Physics: Absolute and Relative DosimetryPTC58-0423, Physics: Treatment PlanningPTC58-0184, Physics: Quality Assurance and VerificationPTC58-0149, Clinics: GIPTC58-0378, Clinics: GIPTC58-0257, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0662, General: New HorizonsPTC58-0627, Physics: Treatment PlanningPTC58-0186, Physics: Treatment PlanningPTC58-0185, Physics: Quality Assurance and VerificationPTC58-0144, Biology: BNCT Poster Discussion SessionsPTC58-0602, Physics: Treatment PlanningPTC58-0189, Physics: Dose Calculation and OptimisationPTC58-0315, Clinics: Head and neckPTC58-0300, General: New Horizons SessionPTC58-0347, Physics: Image GuidancePTC58-0082, Clinics: BreastPTC58-0443, Physics: 4D Treatment and Delivery Poster Discussion SessionsPTC58-0629, Physics: Adaptive Therapy Poster Discussion SessionsPTC58-0007, Physics: Commissioning New FacilitiesPTC58-0472, Clinics: GI, GU, BreastPTC58-0515, Physics: Dose Calculation and Optimisation Poster Discussion SessionsPTC58-0606, Oral AbstractsPhysics: Dose Calculation and OptimisationPTC58-0450, Physics: Absolute and Relative DosimetryPTC58-0657, Physics: Dose Calculation and OptimisationPTC58-0551, Physics: Treatment PlanningPTC58-0192, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0675, Physics: Treatment PlanningPTC58-0194, Physics: Dose Calculation and OptimisationPTC58-0544, Physics: Treatment PlanningPTC58-0199, Physics: Quality Assurance and VerificationPTC58-0037, Oral AbstractsPhysics: Dose Calculation and OptimisationPTC58-0207, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0434, Physics: Quality Assurance and VerificationPTC58-0036, Physics: Quality Assurance and VerificationPTC58-0278, Physics: Quality Assurance and VerificationPTC58-0394, Physics: Quality Assurance and VerificationPTC58-0151, Physics: Quality Assurance and VerificationPTC58-0154, Physics: Dose Calculation and OptimisationPTC58-0428, Clinics: BreastPTC58-0116, Biology: Enhanced Biology in Treatment Planning Poster Discussion SessionsPTC58-0435, Physics: Commissioning New FacilitiesPTC58-0681, Physics: Absolute and Relative DosimetryPTC58-0323, Physics: Dose Calculation and OptimisationPTC58-0583, Physics: Absolute and Relative DosimetryPTC58-0448, Clinics: CNS / Skull BasePTC58-0251, General: New HorizonsPTC58-0721, Physics: Absolute and Relative DosimetryPTC58-0203, Physics: Dose Calculation and OptimisationPTC58-0455, Physics: 4D Treatment and DeliveryPTC58-0130, Physics: Commissioning New FacilitiesPTC58-0679, Physics: Absolute and Relative DosimetryPTC58-0329, General: New HorizonsPTC58-0604, Physics: Absolute and Relative DosimetryPTC58-0449, Clinics: CNS / Skull BasePTC58-0132, General: New HorizonsPTC58-0607, Physics: Quality Assurance and VerificationPTC58-0122, Physics: Quality Assurance and VerificationPTC58-0243, Physics: Treatment PlanningPTC58-0165, Oral AbstractsPhysics: Dose Calculation and OptimisationPTC58-0437, Physics: 4D Treatment and DeliveryPTC58-0377, Physics: Quality Assurance and VerificationPTC58-0125, Physics: Quality Assurance and VerificationPTC58-0245, Physics: Dose Calculation and OptimisationPTC58-0337, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0334, Physics: Quality Assurance and VerificationPTC58-0121, General: New Horizons SessionPTC58-0563, General: New Horizons SessionPTC58-0321, Clinics: Head and Neck / EyePTC58-0477, Physics: Quality Assurance and VerificationPTC58-0480, Clinics: GUPTC58-0010, Clinics: EyePTC58-0684, Clinics: GUPTC58-0496, Clinics: Head and neckPTC58-0676, Clinics: GUPTC58-0137, Physics: Beam Delivery and Nozzle Design Poster Discussion SessionsPTC58-0256, Physics: 4D Treatment and DeliveryPTC58-0117, Physics: Absolute and Relative DosimetryPTC58-0552, Physics: Absolute and Relative DosimetryPTC58-0310, Physics: Absolute and Relative DosimetryPTC58-0672, Physics: Absolute and Relative DosimetryPTC58-0436, Physics: Dose Calculation and OptimisationPTC58-0452, Physics: Dose Calculation and OptimisationPTC58-0331, Physics: Commissioning New FacilitiesPTC58-0213, Biology: Mathematical Modelling SimulationPTC58-0272, Clinics: EyePTC58-0326, Physics: Commissioning New FacilitiesPTC58-0568, Physics: Dose Calculation and OptimisationPTC58-0444, Physics: Quality Assurance and VerificationPTC58-0379, Physics: Treatment Planning Poster Discussion SessionsPTC58-0095, Physics: Treatment PlanningPTC58-0053, Physics: Absolute and Relative DosimetryPTC58-0438, Physics: Absolute and Relative DosimetryPTC58-0317, Physics: Quality Assurance and VerificationPTC58-0497, Physics: Quality Assurance and VerificationPTC58-0375, Physics: Treatment PlanningPTC58-0056, Physics: 4D Treatment and DeliveryPTC58-0124, Clinics: GIPTC58-0009, Physics: Quality Assurance and VerificationPTC58-0014, Physics: Quality Assurance and VerificationPTC58-0374, Clinics: LungPTC58-0727, General: New Horizons SessionPTC58-0578, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0470, Clinics: LungPTC58-0204, Clinics: Head and neckPTC58-0227, Clinics: LungPTC58-0446, Physics: Quality Assurance and VerificationPTC58-0190, Clinics: Eye / Breast / Pelvis Poster Discussion SessionsPTC58-0609, Clinics: LungPTC58-0689, General: New HorizonsPTC58-0021, General: New HorizonsPTC58-0262, Biology: BNCT Poster Discussion SessionsPTC58-0081, Clinics: GIPTC58-0726, General: New HorizonsPTC58-0145, Physics: Image GuidancePTC58-0573, General: New HorizonsPTC58-0027, General: New HorizonsPTC58-0028, Biology: Mathematical Modelling and SimulationPTC58-0148, Physics: Dose Calculation and OptimisationPTC58-0635, Physics: Image GuidancePTC58-0215, Physics: Image GuidancePTC58-0336, Poster AbstractsClinics: CNSPTC58-0535, Physics: Quality Assurance and VerificationPTC58-0187, Biology: BNCT Poster Discussion SessionsPTC58-0084, General: New Investigator SessionPTC58-0339, General: New Horizons SessionPTC58-0420, Physics: Treatment Planning Poster Discussion SessionsPTC58-0523, Biology: BNCT Poster Discussion SessionsPTC58-0088, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0112, Physics: Quality Assurance and VerificationPTC58-0182, Clinics: Eye / Breast / Pelvis Poster Discussion SessionsPTC58-0615, Physics: Quality Assurance and VerificationPTC58-0080, Biology: BNCTPTC58-0085, Physics: Adaptive Therapy Poster Discussion SessionsPTC58-0722, General: New HorizonsPTC58-0253, General: New HorizonsPTC58-0255, Clinics: PediatricPTC58-0703, General: New HorizonsPTC58-0499, Physics: Image Guidance Poster Discussion SessionsPTC58-0380, General: New HorizonsPTC58-0259, Clinics: GI, GU, BreastPTC58-0288, Clinics: GI, GU, BreastPTC58-0045, Physics: Absolute and Relative DosimetryPTC58-0619, Clinics: PediatricPTC58-0707, Physics: Quality Assurance and VerificationPTC58-0196, Physics: Quality Assurance and VerificationPTC58-0074, Physics: Quality Assurance and VerificationPTC58-0077, Biology: BNCT Poster Discussion SessionsPTC58-0073, Biology: BNCTPTC58-0075, Biology: Biological Differences between Carbon, Proton and Photons Poster Discussion SessionsPTC58-0093, Clinics: GUPTC58-0161, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0371, Physics: Monitoring and Modelling MotionPTC58-0181, General: New HorizonsPTC58-0120, General: New HorizonsPTC58-0362, General: New HorizonsPTC58-0364, Physics: Image GuidancePTC58-0473, Scientific: RTTPTC58-0641, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0296, General: New HorizonsPTC58-0004, General: New HorizonsPTC58-0128, Clinics: BreastPTC58-0316, Physics: 4D Treatment and Delivery Poster Discussion SessionsPTC58-0236, General: New HorizonsPTC58-0008, General: New Investigator SessionPTC58-0673, Physics: Quality Assurance and VerificationPTC58-0167, Physics: Quality Assurance and VerificationPTC58-0289, Physics: Quality Assurance and VerificationPTC58-0284, General: New Horizons SessionPTC58-0522, Physics: Quality Assurance and VerificationPTC58-0164, Physics: Quality Assurance and VerificationPTC58-0285, Clinics: Eye / Breast / Pelvis Poster Discussion SessionsPTC58-0623, Clinics: Eye / Breast / Pelvis Poster Discussion SessionsPTC58-0502, Clinics: GUPTC58-0293, Biology: Translational and BiomarkersPTC58-0599, Biology: BNCTPTC58-0063, Clinics: LungPTC58-0656, General: New HorizonsPTC58-0592, Biology: BNCT Poster Discussion SessionsPTC58-0092, Poster AbstractsClinics: CNSPTC58-0302, Physics: Image GuidancePTC58-0464, General: New HorizonsPTC58-0352, Physics: Image GuidancePTC58-0465, General: New HorizonsPTC58-0476, Physics: Image GuidancePTC58-0100, General: New HorizonsPTC58-0235, Biology: Mathematical Modelling and SimulationPTC58-0349, Physics: Treatment PlanningPTC58-0094, Physics: 4D Treatment and Delivery Poster Discussion SessionsPTC58-0367, Physics: Dose Calculation and OptimisationPTC58-0400, Biology: Translational and BiomarkersPTC58-0244, Physics: Dose Calculation and OptimisationPTC58-0640, Biology: Mathematical Modelling and SimulationPTC58-0355, General: New Investigator SessionPTC58-0320, Physics: Quality Assurance and VerificationPTC58-0057, Physics: Quality Assurance and VerificationPTC58-0174, Physics: Quality Assurance and VerificationPTC58-0295, Physics: Dose Calculation and OptimisationPTC58-0529, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0123, Physics: Quality Assurance and VerificationPTC58-0171, Biology: Biological Differences between Carbon, Proton and Photons Poster Discussion SessionsPTC58-0049, Clinics: BreastPTC58-0731, General: New HorizonsPTC58-0223, General: New HorizonsPTC58-0102, General: New HorizonsPTC58-0466, Scientific: RTTPTC58-0503, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0389, General: New HorizonsPTC58-0108, General: New HorizonsPTC58-0109, Physics: Commissioning New FacilitiesPTC58-0736, Biology: Mathematical Modelling and SimulationPTC58-0343, Biology: Mathematical Modelling and SimulationPTC58-0342, Clinics: GI, GU, BreastPTC58-0237, Physics: Dose Calculation and OptimisationPTC58-0711, Biology: Mathematical Modelling and SimulationPTC58-0581, Clinics: GI, GU, BreastPTC58-0114, Clinics: Base of SkullPTC58-0730, Clinics: Head and neckPTC58-0383, Clinics: CNS / Skull BasePTC58-0559, Clinics: Base of SkullPTC58-0613, General: New HorizonsPTC58-0691, Biology: Biological Differences between Carbon, Proton and Photons Poster Discussion SessionsPTC58-0054, General: New HorizonsPTC58-0210, Clinics: BreastPTC58-0729, General: New HorizonsPTC58-0574, Clinics: GI, GU, BreastPTC58-0239, Scientific: RTTPTC58-0637, General: New HorizonsPTC58-0579, Clinics: Lung / Sarcoma / LymphomaPTC58-0176, General: New HorizonsPTC58-0699, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0156, Biology: Mathematical Modelling and SimulationPTC58-0333, Biology: Translational and BiomarkersPTC58-0345, Physics: Image GuidancePTC58-0369, Physics: Commissioning New FacilitiesPTC58-0509, Biology: Mathematical Modelling SimulationPTC58-0658, Biology: Biological Differences between Carbon, Proton and Photons Poster Discussion SessionsPTC58-0051, General: New Investigator SessionPTC58-0548, Clinics: GI, GU, BreastPTC58-0241, Clinics: Eye / Breast / Pelvis Poster Discussion SessionsPTC58-0412, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0024, Clinics: LungPTC58-0226, Biology: Biological Differences between Carbon, Proton and Photons Poster Discussion SessionsPTC58-0069, General: New HorizonsPTC58-0562, General: New HorizonsPTC58-0561, General: New HorizonsPTC58-0201, Biology: Mathematical Modelling and SimulationPTC58-0439, General: New HorizonsPTC58-0445, General: New HorizonsPTC58-0324, Physics: Image GuidancePTC58-0031, Biology: Mathematical Modelling and SimulationPTC58-0558, Physics: Image GuidancePTC58-0392, Biology: Mathematical Modelling and SimulationPTC58-0678, Physics: Beam Delivery and Nozzle DesignPTC58-0090, General: New Investigator SessionPTC58-0630, Biology: Biological Differences between Carbon / Proton and Photons Carbons / Proton and PhotonPTC58-0524, Physics: Commissioning New FacilitiesPTC58-0713, Clinics: GI, GU, BreastPTC58-0139, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0248, Clinics: CNS / Pediatrics / Lung Poster Discussion SessionsPTC58-0368, Biology: Enhanced Biology in Treatment PlanningPTC58-0519, General: New Horizons SessionPTC58-0720, Physics: Quality Assurance and VerificationPTC58-0083, General: New HorizonsPTC58-0311, General: New HorizonsPTC58-0674, General: New HorizonsPTC58-0553, Physics: Image GuidancePTC58-0023, Scientific: RTTPTC58-0612, General: New HorizonsPTC58-0677, Biology: Mathematical Modelling and SimulationPTC58-0545, Physics: Dose Calculation and OptimisationPTC58-0601, Physics: Dose Calculation and OptimisationPTC58-0725, Physics: Quality Assurance and VerificationPTC58-0098, Physics: Dose Calculation and OptimisationPTC58-0605, Biology: Biological Differences between Carbon / Proton and Photons Carbons / Proton and PhotonPTC58-0517, Biology: Translational and Biomarkers Poster Discussion SessionsPTC58-0618, Physics: Monitoring and Modelling MotionPTC58-0481, Clinics: GI / Sarcoma Poster Discussion SessionsPTC58-0071, Physics: Adaptive TherapyPTC58-0351, Physics: 4D Treatment and DeliveryPTC58-0702, Physics: Image GuidancePTC58-0734, Physics: Image GuidancePTC58-0611, Physics: Treatment Planning Poster Discussion SessionsPTC58-0486, Physics: Absolute and Relative Dosimetry Poster Discussion SessionsPTC58-0442, Biology: Drug and Immunotherapy CombinationsPTC58-0327, Clinics: Head and Neck / EyePTC58-0096, Clinics: LungPTC58-0159, Physics: Treatment PlanningPTC58-0708, General: New HorizonsPTC58-0097, Physics: Treatment Planning Poster Discussion SessionsPTC58-0350, Biology: Biological Differences between Carbon / Proton and Photons Carbons / Proton and PhotonPTC58-0016, Physics: Adaptive TherapyPTC58-0104, Physics: Absolute and Relative Dosimetry Poster Discussion SessionsPTC58-0433, Physics: Image GuidancePTC58-0608, Biology: Translational and Biomarkers Poster Discussion SessionsPTC58-0610, Clinics: Head and neckPTC58-0058, Physics: Treatment PlanningPTC58-0715, Clinics: Head and neckPTC58-0298, Clinics: EyePTC58-0099, General: New HorizonsPTC58-0086, General: New HorizonsPTC58-0089, Clinics: Lung / Sarcoma / LymphomaPTC58-0200, Poster AbstractsClinics: CNSPTC58-0157, Clinics: LungPTC58-0141, Clinics: LungPTC58-0260, Clinics: LungPTC58-0264, Physics: Image GuidancePTC58-0513, Physics: Image GuidancePTC58-0631, Clinics: Eye / Breast / Pelvis Poster Discussion SessionsPTC58-0469, Biology: BNCT Poster Discussion SessionsPTC58-0384, Physics: Image GuidancePTC58-0639, Clinics: PediatricsPTC58-0700, Clinics: LungPTC58-0136, Clinics: BreastPTC58-0706, General: New HorizonsPTC58-0079, Biology: Drug and Immunotherapy Combinations Poster Discussion SessionsPTC58-0406, Clinics: Base of SkullPTC58-0382, Physics: Image GuidancePTC58-0624, Physics: Beam Delivery and Nozzle DesignPTC58-0173, Biology: Drug and Immunotherapy CombinationsPTC58-0358, Poster AbstractsClinics: CNSPTC58-0690, General: New HorizonsPTC58-0061, Clinics: Lung / Sarcoma / LymphomaPTC58-0580, Physics: Monitoring and Modelling MotionPTC58-0162, Physics: Adaptive TherapyPTC58-0550, Physics: Adaptive TherapyPTC58-0430, Clinics: Lung / Sarcoma / LymphomaPTC58-0103, General: New Investigator SessionPTC58-0252, Physics: Quality Assurance and VerificationPTC58-0704, Physics: Image GuidancePTC58-0418, Clinics: Base of SkullPTC58-0572, Clinics: Lung / Sarcoma / LymphomaPTC58-0106, Physics: Beam Delivery and Nozzle DesignPTC58-0022, Physics: Monitoring and Modelling MotionPTC58-0279, Physics: Treatment Planning Poster Discussion SessionsPTC58-0447, Physics: Treatment PlanningPTC58-0622, Clinics: PediatricsPTC58-0644, Biology: Biology and Clinical InterfacePTC58-0490, Clinics: CNS / Skull BasePTC58-0716, General: New HorizonsPTC58-0292, Biology: Biological Differences between Carbon / Proton and Photons Carbons / Proton and PhotonPTC58-0570, General: New HorizonsPTC58-0059, Physics: Quality Assurance and VerificationPTC58-0710, Biology: Biological Differences between Carbon / Proton and Photons Carbons / Proton and PhotonPTC58-0216, Physics: Image GuidancePTC58-0404, Physics: Image GuidancePTC58-0525, Physics: Image GuidancePTC58-0526, Poster AbstractsClinics: CNSPTC58-0328, Clinics: LungPTC58-0070, Clinics: Eye / Breast / Pelvis Poster Discussion SessionsPTC58-0135, Biology: BNCT Poster Discussion SessionsPTC58-0391, Physics: Treatment PlanningPTC58-0510, Physics: Treatment PlanningPTC58-0636, Physics: Treatment PlanningPTC58-0638, Physics: Image GuidancePTC58-0408, Physics: Absolute and Relative Dosimetry Poster Discussion SessionsPTC58-0632, Physics: Treatment Planning Poster Discussion SessionsPTC58-0318, Biology: Enhanced Biology in Treatment PlanningPTC58-0246, Clinics: PediatricsPTC58-0504, General: New HorizonsPTC58-0160, Physics: Image Guidance Poster Discussion SessionsPTC58-0076, Physics: Monitoring and Modelling MotionPTC58-0143, Biology: Mathematical Modelling and SimulationPTC58-0718, Physics: Image GuidancePTC58-0671, Clinics: LungPTC58-0183, Physics: Image GuidancePTC58-0670, Report, Physics: Treatment Planning Poster Discussion SessionsPTC58-0422, Biology: Biological Differences between Carbon / Proton and Photons Carbons / Proton and PhotonPTC58-0129, Physics: Adaptive Therapy Poster Discussion SessionsPTC58-0705, Biology: Enhanced Biology in Treatment PlanningPTC58-0258, General: New HorizonsPTC58-0030, General: New HorizonsPTC58-0150, Biology: Biology and Clinical InterfacePTC58-0479, General: New HorizonsPTC58-0153, Clinics: PediatricPTC58-0087, General: New HorizonsPTC58-0152, General: New HorizonsPTC58-0155, General: New HorizonsPTC58-0033, General: New HorizonsPTC58-0158, Physics: Image GuidancePTC58-0429, Biology: Translational and BiomarkersPTC58-0287, Physics: Adaptive TherapyPTC58-0403, Physics: Image GuidancePTC58-0309
Published
2020

14. Updated results of a phase II study evaluating accelerator-based boron neutron capture therapy (AB-BNCT) with borofalan(10B) (SPM-011) in recurrent squamous cell carcinoma (R-SCC-HN) and recurrent and locally advanced non-SCC (R/LA-nSCC-HN) of the head and neck

Author

Hirose, K., primary, Konno, A., additional, Yoshimoto, S., additional, Ono, K., additional, Otsuki, N., additional, Hatazawa, J., additional, Hiratsuka, J., additional, and Takai, Y., additional

Published
2019
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18. L-H transition and pedestal studies on MAST

Author

Meyer, H, De Bock, M F M, Conway, N J, Freethy, S, Gibson, K J, Hiratsuka, J., Kirk, A., Michael, Clive, Morgan, T., Scannell, R, Naylor, G, Saarelma, S., Saveliev, A, Shevchenko, V, Suttrop, W., Temple, D., Vann, R G L, MAST Team, The, Meyer, H, De Bock, M F M, Conway, N J, Freethy, S, Gibson, K J, Hiratsuka, J., Kirk, A., Michael, Clive, Morgan, T., Scannell, R, Naylor, G, Saarelma, S., Saveliev, A, Shevchenko, V, Suttrop, W., Temple, D., Vann, R G L, and MAST Team, The

Abstract

On MAST studies of the profile evolution of the electron temperature (Te), electron density (ne), radial electric field (Er) as well as novel measurements of the ion temperature (Ti) and toroidal current density (jø) in the pedestal region allow further

Published
2011

19. Boron neutron capture therapy outcomes for advanced or recurrent head and neck cancer

Author

Suzuki, M., primary, Kato, I., additional, Aihara, T., additional, Hiratsuka, J., additional, Yoshimura, K., additional, Niimi, M., additional, Kimura, Y., additional, Ariyoshi, Y., additional, Haginomori, S.-i., additional, Sakurai, Y., additional, Kinashi, Y., additional, Masunaga, S.-i., additional, Fukushima, M., additional, Ono, K., additional, and Maruhashi, A., additional

Published
2013
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23. Boron Neutron Capture Therapy of Malignant Melanoma Using 10 B-Paraboronophenylalanine with Special Reference to Evaluation of Radiation Dose and Damage to the Normal Skin

Author

Fukuda, H., primary, Hiratsuka, J., additional, Honda, C., additional, Kobayashi, T., additional, Yoshino, K., additional, Karashima, H., additional, Takahashi, J., additional, Abe, Y., additional, Kanda, K., additional, Ichihashi, M., additional, and Mishima, Y., additional

Published
1994
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24. Effect of patient characteristics on vessel enhancement on arterio-venous fistula CT angiography in a retrospective cohort study.

Author

Masuda T, Nakaura T, Funama Y, Sato T, Masuda S, Yoshiura T, Gotanda R, Arao K, Imaizumi H, Arao S, Ono A, Hiratsuka J, and Awai K

Subjects
Humans, Retrospective Studies, Tomography, X-Ray Computed methods, Angiography methods, Body Weight, Contrast Media, Radiation Dosage, Computed Tomography Angiography methods, Fistula
Abstract

To evaluate the effects of various patient characteristics on vessel enhancement on arterio-venous fistula (AVF) computed tomography (CT) angiography (AVF-CT angiography). A total of 127 patients with suspected or confirmed shunt stenosis and internal AVF complications were considered for inclusion in a retrospective cohort study. The tube voltage was 120 kVp, and the tube current was changed from 300 to 770 mA to maintain the image quality (noise index: 14) using automatic tube current modulation. To evaluate the effects of age, sex, body size, and scan delay on the CT number of the brachial artery or vein, we used correlation coefficients and multivariate regression analyses. There was a significant positive correlation between the CT number of the brachial artery or vein and age (R = 0.21 or 0.23, P < .01). The correlations were inverse with the height (r = -0.45 or -0.42), total body weight (r = -0.52 or -0.50), body mass index (r = -0.21 or -0.23), body surface area (body surface area [BSA]; r = -0.56 or -0.54), and lean body weight (r = -0.55 or -0.53) in linear regression analysis (P < .01 for all). There was a significant correlation between the CT number of the brachial artery or vein and scan delay (R = 0.19 or 01.9, P < .01). Only the BSA had significant effects on the CT number in multivariate regression analysis (P < .01). The BSA was significantly correlated with the CT number of the brachial artery or vein on AVF-CT angiography., Competing Interests: The authors have no conflicts of interest to disclose., (Copyright © 2023 the Author(s). Published by Wolters Kluwer Health, Inc.)

Published
2023
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25. Long-term outcome of cutaneous melanoma patients treated with boron neutron capture therapy (BNCT).

Author

Hiratsuka J, Kamitani N, Tanaka R, Tokiya R, Yoden E, Sakurai Y, and Suzuki M

Subjects
Aged, Aged, 80 and over, Boron, Female, Follow-Up Studies, Humans, Male, Middle Aged, Neoplasm Recurrence, Local, Radiation Dosage, Radiometry, Radiotherapy Dosage, Treatment Outcome, Melanoma, Cutaneous Malignant, Boron Neutron Capture Therapy methods, Melanoma mortality, Melanoma radiotherapy, Skin Neoplasms mortality, Skin Neoplasms radiotherapy
Abstract

Our aim was to assess the long-term clinical outcome of boron neutron capture therapy (BNCT) using 10B-para-boronophenylalanine (BPA) as the boron delivery agent for cutaneous melanoma. Eight patients (eight lesions) were treated between October 2003 and April 2014. Their ages ranged from 48 to 86 years at the time of treatment. All of the targets were primary lesions and they were located on the sole or face. No patient had evidence of regional lymph node involvement, distant metastases or an active secondary cancer. The clinical stage was cT1-2N0M0 and performance scores were <2. BNCT was carried out at the Kyoto University Research Reactor (KUR). The patients were irradiated with an epithermal neutron beam between the curative tumor dose and the tolerable skin dose. Eight patients were evaluated and six showed a complete response (CR), while two patients had a partial response (PR). Of the two patients with a PR, one has remained a PR with brown spots persisting for 7.5 years following BNCT. The tumor in the other patient recurred after 6 years at the site of persisting brown macula. The overall control rate (CR + PR without recurrence) for the cohort was 88% (7/8). There have never been any adverse events >Grade 2 for the long follow-up period. Our results suggest that BNCT may be a promising treatment modality in the management of early stage cutaneous melanoma when wide local excision is not feasible., (© The Author(s) 2020. Published by Oxford University Press on behalf of The Japanese Radiation Research Society and Japanese Society for Radiation Oncology.)

Published
2020
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26. Boron neutron capture therapy for vulvar melanoma and genital extramammary Paget's disease with curative responses.

Author

Hiratsuka J, Kamitani N, Tanaka R, Yoden E, Tokiya R, Suzuki M, Barth RF, and Ono K

Subjects
Aged, Female, Humans, Male, Radiotherapy Dosage, Time Factors, Treatment Outcome, Melanoma, Cutaneous Malignant, Boron Neutron Capture Therapy methods, Melanoma radiotherapy, Paget Disease, Extramammary radiotherapy, Penile Neoplasms radiotherapy, Skin Neoplasms radiotherapy, Vulvar Neoplasms radiotherapy
Abstract

Background: Although the most commonly recommended treatment for melanoma and extramammary Paget's disease (EMPD) of the genital region is wide surgical excision of the lesion, the procedure is highly invasive and can lead to functional and sexual problems. Alternative treatments have been used for local control when wide local excision was not feasible. Here, we describe four patients with genital malignancies who were treated with boron neutron capture therapy (BNCT)., Methods: The four patients included one patient with vulvar melanoma (VM) and three with genital EMPD. They underwent BNCT at the Kyoto University Research Reactor between 2005 and 2014 using para-boronophenylalanine as the boron delivery agent. They were irradiated with an epithermal neutron beam between the curative tumor dose and the tolerable skin/mucosal doses., Results: All patients showed similar tumor and normal tissue responses following BNCT and achieved complete responses within 6 months. The most severe normal tissue response was moderate skin erosion during the first 2 months, which diminished gradually thereafter. Dysuria or contact pain persisted for 2 months and resolved completely by 4 months., Conclusions: Treating VM and EMPD with BNCT resulted in complete local tumor control. Based on our clinical experience, we conclude that BNCT is a promising treatment for primary VM and EMPD of the genital region. Trial registration numbers UMIN000005124.

Published
2018
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27. Retrospective analysis of definitive radiotherapy for neck node metastasis from unknown primary tumor: Japanese Radiation Oncology Study Group study.

Author

Yamazaki T, Kodaira T, Ota Y, Akimoto T, Wada H, Hiratsuka J, Nishimura Y, Ishihara S, Nonoshita T, Hayakawa K, Sekii S, and Uchida N

Subjects
Adult, Aged, Aged, 80 and over, Disease-Free Survival, Female, Humans, Japan, Male, Middle Aged, Neoplasms, Unknown Primary pathology, Retrospective Studies, Lymphatic Metastasis radiotherapy, Neck pathology, Neoplasms, Unknown Primary radiotherapy
Abstract

Objective: To investigate the optimal treatment method and risk factor of neck node metastasis from unknown primary tumors (NUP) treated by radiotherapy., Methods: Retrospective case study based on a multi-institutional survey was conducted by the Japanese Radiation Oncology Study Group. Patients pathologically diagnosed as having NUP from 1998 to 2007 were identified. Univariate and multivariate analyses of overall survival (OS), progression free survival (PFS), neck progression free survival (NPFS) and mucosal progression free survival (MPFS) were evaluated., Results: In total, 130 patients with median age of 65 years were included. Nodal stages N1, N2a, N2b and N2c were observed for 10, 26, 43, 12 and 39 patients, respectively. All the patients received radiotherapy (RT) with neck dissection in 60 and with chemotherapy in 67 cases. The median doses to the metastatic nodes, prophylactic neck and prophylactic mucosal sites were 60.0, 50.4 and 50.4 Gy, respectively. The median follow-up period for surviving patients was 42 months. Among 12 patients, occult primary tumors in the neck region developed after radiotherapy. The 5-year OS, PFS, NPFS and MPFS were 58.1%, 42.4%, 47.3% and 54.9%, respectively. Univariate analysis showed that lower N stage (N1-2b), non-bulky node (<6 cm) and negative extracapsular extension (ECE) status were the factors associated with favorable OS, PFS, NPFS and MPFS. Radical surgery proved to be a favorable factor of OS, NPFS and MPFS. On multivariate analysis, lower N stage and negative ECE status were correlated with improved survival., Conclusions: Lower nodal stage and negative ECE status showed a favorable impact on survival and disease control in patients with NUP treated by radiotherapy., (© The Author 2017. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com)

Published
2017
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28. Genetic polymorphisms of enzyme proteins and transporters related to methotrexate response and pharmacokinetics in a Japanese population.

Author

Hashiguchi M, Shimizu M, Hakamata J, Tsuru T, Tanaka T, Suzaki M, Miyawaki K, Chiyoda T, Takeuchi O, Hiratsuka J, Irie S, Maruyama J, and Mochizuki M

Abstract

Background: Methotrexate (MTX) is currently the anchor drug widely used worldwide in the treatment of rheumatoid arthritis (RA). However, the therapeutic response to MTX has been shown to vary widely among individuals, genders and ethnic groups. The reason for this has been not clarified but it is considered to be partially due to several mechanisms in the cellular pathway of MTX including single-nucleotide polymorphisms (SNPs). The purpose of this study was to investigate the allelic frequencies in different ethnic and/or population groups in the 10 polymorphisms of enzyme proteins and transporters related to the MTX response and pharmacokinetics including MTHFR, TYMS, RFC1, FPGS, GGH, ABCB1, ABCC2 and ABCG2 in unrelated healthy Japanese adults and patients with RA., Methods: Ten polymorphisms, methylenetetrahydrofolate reductase (MTHFR) 1298, thymidylate synthase (TYMS) 3'-UTR, reduced folate carrier 1 (RFC1) 80 and-43, folypolyglutamyl synthase (FPGS) 1994, γ-glutamyl hydrolase (GGH) 452 and-401, the ABC transporters (ABCB1 3435, ABCC2 IVS23 + 56, ABCG2 914) of enzyme proteins and transporters related to MTX response and pharmacokinetics in 299 unrelated healthy Japanese adults and 159 Japanese patients with RA were investigated to clarify their contributions to individual variations in response and safety to MTX and establish personalized MTX therapy. SNPs were evaluated using real-time polymerase chain reaction (PCR)., Results: Comparison of allelic frequencies in our study with other ethnic/population groups of healthy adults and RA patients showed significant differences in 10 polymorphisms among healthy adults and 7 among RA patients. Allelic frequencies of MTHFR 1298 C, FPGS 1994A and ABCB1 3435 T were lower in Japanese than in Caucasian populations and those of ABCC2 IVS23 + 56 C and ABCG2 914A were higher in Japanese than in Caucasian/European populations in both healthy adults and RA patients. Allelic frequencies of MTHFR 1298 C, GGH-401 T, ABCB1 3435 T, and ABCG2 914A were higher in healthy Japanese adults than in an African population, and those of RFC1 80A, RFC1-43C and ABCC2 IVS23 + 56 C in healthy Japanese adults were lower than in Africans. However, no significant differences were seen in the distribution of allelic frequencies between healthy Japanese adults and RA patients., Conclusion: The variations in allelic frequencies in different ethnic and/or population groups in healthy adults and RA patients may contribute to individual variations in MTX response and toxicity.

Published
2016
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29. A phase I/II clinical trial for the hybrid of intracavitary and interstitial brachytherapy for locally advanced cervical cancer.

Author

Murakami N, Kato S, Nakano T, Uno T, Yamanaka T, Sakurai H, Yoshimura R, Hiratsuka J, Kuroda Y, Yoshio K, and Itami J

Subjects
Adult, Aged, Antineoplastic Agents therapeutic use, Cisplatin therapeutic use, Dose Fractionation, Radiation, Feasibility Studies, Female, Humans, Middle Aged, Prospective Studies, Radiotherapy, Radiotherapy Dosage, Survival Analysis, Treatment Outcome, Uterine Cervical Neoplasms pathology, Young Adult, Antineoplastic Agents administration & dosage, Brachytherapy methods, Cisplatin administration & dosage, Uterine Cervical Neoplasms therapy
Abstract

Background: This paper describes about a study protocol of phase I/II multicenter prospective clinical trial evaluating the feasibility and efficacy of the hybrid of intracavitary and interstitial brachytherapy (HBT) for locally advanced uterine cervical cancer patients., Methods and Design: Patients with histologically confirmed FIGO stage IB2, IIA2, IIB, and IIIB uterine cervical carcinoma width of which is larger than 5 cm assessed by MRI will be entered to this clinical trial. Protocol therapy is 30-30.6 Gy in 15-17 fractions of whole pelvic radiotherapy concurrent with weekly CDDP (40 mg/m(2)), followed by 24 Gy in 4 fractions of HBT and central shield EBRT up to 50-50.4 Gy in 25-28 fractions. Tumor width is assessed again within one week before the first HBT and if the tumor width is larger than 4 cm, patients proceed to the secondary registration. In phase I section, feasibility of this will be investigated. If less than 10 % out of 20 patients experienced greater than grade 3 acute non-hematologic adverse effects, the study proceeds to phase II part. In phase II part a total of 55 patients will be accrued and the efficacy of the HBT will be investigated comparing with historical control data. If the lower margin of 90 % confidence interval of the 2-year pelvic progression-free survival of the HBT trial is higher than 64 %, the HBT is considered to be more effective than conventional ICBT., Discussion: The aim of this study is to demonstrate the feasibility and efficacy of the HBT for locally advanced cervical cancer. This trial will clarify the indication, feasibility, and efficacy of this new technique., Trial Registration: UMIN000019081 ; Registration date: 2015/9/30.

Published
2016
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30. Early clinical experience utilizing scintillator with optical fiber (SOF) detector in clinical boron neutron capture therapy: its issues and solutions.

Author

Ishikawa M, Yamamoto T, Matsumura A, Hiratsuka J, Miyatake S, Kato I, Sakurai Y, Kumada H, Shrestha SJ, and Ono K

Subjects
Calibration, Humans, Neoplasms radiotherapy, Optical Fibers, Boron Neutron Capture Therapy methods, Computer Systems, Fiber Optic Technology methods, Radiometry instrumentation, Radiometry methods
Abstract

Background: Real-time measurement of thermal neutrons in the tumor region is essential for proper evaluation of the absorbed dose in boron neutron capture therapy (BNCT) treatment. The gold wire activation method has been routinely used to measure the neutron flux distribution in BNCT irradiation, but a real-time measurement using gold wire is not possible. To overcome this issue, the scintillator with optical fiber (SOF) detector has been developed. The purpose of this study is to demonstrate the feasibility of the SOF detector as a real-time thermal neutron monitor in clinical BNCT treatment and also to report issues in the use of SOF detectors in clinical practice and their solutions., Material and Methods: Clinical measurements using the SOF detector were carried out in 16 BNCT clinical trial patients from December 2002 until end of 2006 at the Japanese Atomic Energy Agency (JAEA) and Kyoto University Research Reactor Institute (KURRI)., Results: The SOF detector worked effectively as a real-time thermal neutron monitor. The neutron fluence obtained by the gold wire activation method was found to differ from that obtained by the SOF detector. The neutron fluence obtained by the SOF detector was in better agreement with the expected fluence than with gold wire activation. The estimation error for the SOF detector was small in comparison to the gold wire measurement. In addition, real-time monitoring suggested that the neutron flux distribution and intensity at the region of interest (ROI) may vary due to the reactor condition, patient motion and dislocation of the SOF detector., Conclusion: Clinical measurements using the SOF detector to measure thermal neutron flux during BNCT confirmed that SOF detectors are effective as a real-time thermal neutron monitor. To minimize the estimation error due to the displacement of the SOF probe during treatment, a loop-type SOF probe was developed.

Published
2016
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31. Development of a wavelength-separated type scintillator with optical fiber (SOF) dosimeter to compensate for the Cerenkov radiation effect.

Author

Ishikawa M, Nagase N, Matsuura T, Hiratsuka J, Suzuki R, Miyamoto N, Sutherland KL, Fujita K, and Shirato H

Subjects
Background Radiation, Electromagnetic Fields, Equipment Design, Equipment Failure Analysis, Miniaturization, Reproducibility of Results, Sensitivity and Specificity, Artifacts, Fiber Optic Technology instrumentation, Lenses, Radiometry instrumentation, Scintillation Counting instrumentation
Abstract

The scintillator with optical fiber (SOF) dosimeter consists of a miniature scintillator mounted on the tip of an optical fiber. The scintillator of the current SOF dosimeter is a 1-mm diameter hemisphere. For a scintillation dosimeter coupled with an optical fiber, measurement accuracy is influenced by signals due to Cerenkov radiation in the optical fiber. We have implemented a spectral filtering technique for compensating for the Cerenkov radiation effect specifically for our plastic scintillator-based dosimeter, using a wavelength-separated counting method. A dichroic mirror was used for separating input light signals. Individual signal counting was performed for high- and low-wavelength light signals. To confirm the accuracy, measurements with various amounts of Cerenkov radiation were performed by changing the incident direction while keeping the Ir-192 source-to-dosimeter distance constant, resulting in a fluctuation of <5%. Optical fiber bending was also addressed; no bending effect was observed for our wavelength-separated SOF dosimeter., (© The Author 2015. Published by Oxford University Press on behalf of The Japan Radiation Research Society and Japanese Society for Radiation Oncology.)

Published
2015
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32. Docetaxel/ TS-1 with radiation for unresectable squamous cell carcinoma of the esophagus--a phase II trial.

Author

Matsumoto H, Kubota H, Higashida M, Yoden E, Hiratsuka J, Haruma K, Nakamura M, and Hirai T

Subjects
Adult, Aged, Docetaxel, Female, Humans, Male, Middle Aged, Oxonic Acid administration & dosage, Pyridines administration & dosage, Taxoids administration & dosage, Tegafur administration & dosage, Antineoplastic Combined Chemotherapy Protocols therapeutic use, Carcinoma, Squamous Cell drug therapy, Carcinoma, Squamous Cell radiotherapy, Esophageal Neoplasms drug therapy, Esophageal Neoplasms radiotherapy
Abstract

Background: We tried a new regimen of docetaxel / TS-1 (tegafur-gimestat-otastat potassium) combined with radiation for squamous cell carcinoma of the esophagus in a phase II trial., Patients and Methods: The patients, whose tumor invaded other organs without other organ metastasis, were given TS-1 (60 mg/m2/day) from days 1 to 14, and docetaxel (20-30 mg/m2) on days 1 and 8. They received radiation in 2.0 Gy from days 1 to 21. Patients were given a seven-day rest after the first course, and then were treated with the same regimen from days 28 to 49., Results: Seventeen cases were enrolled in the study. The response rate was 76.4% (13/17). The overall 5-year survival rate was 29.6% (5/17) and median survival time was 15.2 months. Adverse events more than grade 3 occurred in 10 cases., Conclusion: This combination therapy may be one of the most effective treatments because of its lower rate of non-hematological adverse events and higher response rate. Three cases also underwent salvage surgery when the tumor recurred, and in one case, chemoradiation to a metastatic nodule on the thoracic wall was added., (Copyright© 2014 International Institute of Anticancer Research (Dr. John G. Delinassios), All rights reserved.)

Published
2014

33. Boron neutron capture therapy outcomes for advanced or recurrent head and neck cancer.

Author

Suzuki M, Kato I, Aihara T, Hiratsuka J, Yoshimura K, Niimi M, Kimura Y, Ariyoshi Y, Haginomori S, Sakurai Y, Kinashi Y, Masunaga S, Fukushima M, Ono K, and Maruhashi A

Subjects
Adult, Aged, Aged, 80 and over, Female, Humans, Japan epidemiology, Male, Middle Aged, Prevalence, Radiotherapy Dosage, Retrospective Studies, Risk Factors, Survival Rate, Treatment Outcome, Boron Neutron Capture Therapy mortality, Head and Neck Neoplasms mortality, Head and Neck Neoplasms radiotherapy, Neoplasm Recurrence, Local mortality, Neoplasm Recurrence, Local radiotherapy
Abstract

We retrospectively review outcomes of applying boron neutron capture therapy (BNCT) to unresectable advanced or recurrent head and neck cancers. Patients who were treated with BNCT for either local recurrent or newly diagnosed unresectable head or neck cancers between December 2001 and September 2007 were included. Clinicopathological characteristics and clinical outcomes were retrieved from hospital records. Either a combination of borocaptate sodium and boronophenylalanine (BPA) or BPA alone were used as boron compounds. In all the treatment cases, the dose constraint was set to deliver a dose <10-12 Gy-eq to the skin or oral mucosa. There was a patient cohort of 62, with a median follow-up of 18.7 months (range, 0.7-40.8). A total of 87 BNCT procedures were performed. The overall response rate was 58% within 6 months after BNCT. The median survival time was 10.1 months from the time of BNCT. The 1- and 2-year overall survival (OS) rates were 43.1% and 24.2%, respectively. The major acute Grade 3 or 4 toxicities were hyperamylasemia (38.6%), fatigue (6.5%), mucositis/stomatitis (9.7%) and pain (9.7%), all of which were manageable. Three patients died of treatment-related toxicity. Three patients experienced carotid artery hemorrhage, two of whom had coexistent infection of the carotid artery. This study confirmed the feasibility of our dose-estimation method and that controlled trials are warranted.

Published
2014
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34. Effect of asbestos exposure on differentiation of cytotoxic T lymphocytes in mixed lymphocyte reaction of human peripheral blood mononuclear cells.

Author

Kumagai-Takei N, Nishimura Y, Maeda M, Hayashi H, Matsuzaki H, Lee S, Hiratsuka J, and Otsuki T

Subjects
Apoptosis, Asbestos, Serpentine adverse effects, Biomarkers metabolism, Cell Proliferation, Granzymes metabolism, Humans, Interferon-gamma metabolism, Leukocytes, Mononuclear immunology, Lymphocyte Count, T-Lymphocytes, Cytotoxic immunology, Tumor Necrosis Factor-alpha metabolism, Asbestos, Crocidolite adverse effects, Cell Differentiation, Leukocytes, Mononuclear drug effects, Lymphocyte Culture Test, Mixed, T-Lymphocytes, Cytotoxic drug effects
Abstract

Asbestos fibers are associated with tumorigenicity, and are thought to cause mesothelioma. However, their effect on immune response remains unclear. We examined the effect of asbestos exposure on differentiation of cytotoxic T lymphocytes (CTLs) in mixed lymphocyte reactions (MLR) of human peripheral blood mononuclear cells (PBMCs) upon exposure to chrysotile B (CB) or crocidolite (CR) asbestos at 5 μg/ml for 7 days. Exposure to CB during MLR suppressed increases in the percentage and number of CD8⁺ T cells in response to allogenic cells. The cytotoxicity for allogenic targets decreased in PBMCs exposed to CB, but not CR, when compared with PBMCs without any exposure during MLR. Exposure to CB during MLR resulted in suppression of increases in granzyme B⁺ cells and IFN-γ⁺ cells. CB exposure also resulted in suppression of increases in CD45RO⁺ effector/memory cells and CD25⁺-activated cells in CD8⁺ lymphocytes, and a decrease in CD45RA⁺ cells. CB exposure suppressed the proliferation of CD8⁺ lymphocytes without an increase in annexin V⁺ apoptotic cells in CD8⁺ lymphocytes. Moreover, the production of IL-10, IFN-γ, and TNF-α, but not IL-2, decreased in the presence of CB. These results suggest that exposure to asbestos potentially suppresses the differentiation of cytotoxic T lymphocyte, accompanied by decreases in IFN-γ and TNF-α.

Published
2013
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35. A combined therapy with docetaxel and nedaplatin for relapsed and metastatic esophageal carcinoma.

Author

Matsumoto H, Hirabayashi Y, Kubota H, Murakami H, Higashida M, Haruma K, Hiratsuka J, Nakamura M, and Hirai T

Subjects
Aged, Antineoplastic Combined Chemotherapy Protocols adverse effects, Docetaxel, Esophageal Neoplasms mortality, Esophageal Neoplasms pathology, Female, Humans, Male, Middle Aged, Neoplasm Metastasis, Neoplasm Recurrence, Local drug therapy, Organoplatinum Compounds administration & dosage, Taxoids administration & dosage, Antineoplastic Combined Chemotherapy Protocols therapeutic use, Esophageal Neoplasms drug therapy
Abstract

We performed combined chemotherapy using docetaxel and nedaplatin with and without radiation therapy as a second-line treatment for relapsed or metastatic esophageal carcinoma. Eighteen patients were enrolled from April 2003 to June 2010; 10 cases were metastatic and 8 cases were recurrent. Nedaplatin (30 mg/m(2)) and Docetaxel (30 mg/m(2)/day) were administered on days 1, 8 and 15. Nine cases undertook the combined-chemotherapy only, with a response rate of 22.2% (2/9). The other nine cases received combined chemo-radiotherapy, with a response rate of 55.5% (5/9). The median survival time of all patients was 273 days, the median survival time for patients treated with combined chemotherapy was 331 days, while for patients treated with combined chemoradiotherapy was 244 days. The two-year survival rate overall was 11.1% (1/9). The adverse event of leukocytopenia greater than grade 3 was observed in three cases of combined chemoradiotherapy cases only. Docetaxel and Nedaplatin combination chemotherapy is well tolerated and useful as second-line chemotherapy for patients with relapsed or metastatic esophageal cancer.

Published
2012

36. Asbestos-induced cellular and molecular alteration of immunocompetent cells and their relationship with chronic inflammation and carcinogenesis.

Author

Matsuzaki H, Maeda M, Lee S, Nishimura Y, Kumagai-Takei N, Hayashi H, Yamamoto S, Hatayama T, Kojima Y, Tabata R, Kishimoto T, Hiratsuka J, and Otsuki T

Subjects
Animals, Asbestosis etiology, Asbestosis immunology, Autoimmunity, Cell Transformation, Neoplastic chemically induced, Chronic Disease, Humans, Inflammation immunology, Mesothelioma etiology, Mesothelioma immunology, Asbestos poisoning, Asbestos toxicity, Cell Transformation, Neoplastic chemistry, Inflammation etiology
Abstract

Asbestos causes lung fibrosis known as asbestosis as well as cancers such as malignant mesothelioma and lung cancer. Asbestos is a mineral silicate containing iron, magnesium, and calcium with a core of SiO(2). The immunological effect of silica, SiO(2), involves the dysregulation of autoimmunity because of the complications of autoimmune diseases found in silicosis. Asbestos can therefore cause alteration of immunocompetent cells to result in a decline of tumor immunity. Additionally, due to its physical characteristics, asbestos fibers remain in the lung, regional lymph nodes, and the pleural cavity, particularly at the opening sites of lymphatic vessels. Asbestos can induce chronic inflammation in these areas due to the production of reactive oxygen/nitrogen species. As a consequence, immunocompetent cells can have their cellular and molecular features altered by chronic and recurrent encounters with asbestos fibers, and there may be modification by the surrounding inflammation, all of which eventually lead to decreased tumor immunity. In this paper, the brief results of our investigation regarding reduction of tumor immunity of immunocompetent cells exposed to asbestos in vitro are discussed, as are our findings concerned with an investigation of chronic inflammation and analyses of peripheral blood samples derived from patients with pleural plaque and mesothelioma that have been exposed to asbestos.

Published
2012
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37. Decreased CXCR3 expression in CD4+ T cells exposed to asbestos or derived from asbestos-exposed patients.

Author

Maeda M, Nishimura Y, Hayashi H, Kumagai N, Chen Y, Murakami S, Miura Y, Hiratsuka J, Kishimoto T, and Otsuki T

Subjects
Adult, Apoptosis drug effects, Asbestosis genetics, Asbestosis immunology, Asbestosis pathology, CD4-Positive T-Lymphocytes immunology, CD4-Positive T-Lymphocytes pathology, Case-Control Studies, Cell Line, Tumor, Chemokine CXCL10 blood, Dose-Response Relationship, Drug, Down-Regulation, Female, Humans, Interferon-gamma genetics, Interferon-gamma metabolism, Lung Neoplasms genetics, Lung Neoplasms immunology, Lung Neoplasms pathology, Male, Mesothelioma genetics, Mesothelioma immunology, Mesothelioma pathology, Middle Aged, RNA, Messenger metabolism, Time Factors, Asbestos, Serpentine toxicity, Asbestosis etiology, CD4-Positive T-Lymphocytes drug effects, Construction Materials toxicity, Lung Neoplasms chemically induced, Mesothelioma chemically induced, Receptors, CXCR3 metabolism, Tumor Escape drug effects
Abstract

Asbestos causes malignant tumors such as lung cancer and malignant mesothelioma (MM). To determine whether asbestos exposure causes reduction of antitumor immunity, we established an in vitro T-cell line model of low-dose and continuous exposure to asbestos using an human adult T-cell leukemia virus-1 immortalized human polyclonal T-cell line, MT-2, and revealed that MT-2 cells exposed continuously to asbestos showed resistance to asbestos-induced apoptosis. In addition, the cells presented reduction of surface CXCR3 chemokine receptor expression and IFN-γ production. In this study, to confirm that these findings are suitable for clinical translation, surface CXCR3 and IFN-γ expression were analyzed using freshly isolated human CD4(+) T cells derived from healthy donors and patients with pleural plaque (PP) or MM. The results revealed that CXCR3 and IFN-γ expression in the ex vivo model were reduced in some cases. Additionally, CXCR3 expression in CD4(+) T cells from PPs and MMs was significantly reduced compared with that from healthy donors, and CD4(+) T cells from patients with MMs exhibited a marked reduction in IFN-γ mRNA levels after stimulation in vitro. Moreover, CD4(+)CXCR3(+) T cells in lymphocytes from MMs showed a tendency for an inverse correlation with its ligand CXCL10/IP10 in plasma. These findings show reduction of antitumor immune function in asbestos-exposed patients and indicate that CXCR3, IFN-γ, and CXCL10/IP10 may be candidates to detect and monitor disease status.

Published
2011
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38. Reduction of CXC chemokine receptor 3 in an in vitro model of continuous exposure to asbestos in a human T-cell line, MT-2.

Author

Maeda M, Nishimura Y, Hayashi H, Kumagai N, Chen Y, Murakami S, Miura Y, Hiratsuka J, Kishimoto T, and Otsuki T

Subjects
Apoptosis, CD4-Positive T-Lymphocytes cytology, Cell Line, Cluster Analysis, Down-Regulation, Enzyme-Linked Immunosorbent Assay methods, Humans, Immune System, In Vitro Techniques, Interferon-gamma metabolism, Lung Neoplasms metabolism, Mesothelioma metabolism, Oligonucleotide Array Sequence Analysis, Asbestos toxicity, Receptors, CXCR3 biosynthesis, T-Lymphocytes drug effects
Abstract

Because patients with silicosis who are chronically exposed to silica particles develop not only pulmonary fibrosis, but also complications involving autoimmune diseases such as rheumatoid arthritis and systemic sclerosis, exposure to asbestos may affect the human immune system. This immunologic effect may impair antitumor immune function because cancer complications such as lung cancer and malignant mesothelioma are found in patients exposed to asbestos. To elucidate the antitumor immune status caused by CD4(+) T cells exposed to asbestos, an in vitro T-cell model of long-term and low-level exposure to chrysotile asbestos was established from a human adult T-cell leukemia virus-1-immortalized human polyclonal T cell line, MT-2, and the resulting six sublines showed resistance to asbestos-induced apoptosis after more than 8 months of continuous exposure. The results of DNA microarray analysis showed that the expression of 139 genes was altered by long-term and low-level exposure to asbestos, and the profile was almost similar among the six sublines when compared with the original MT-2 cells that had never been exposed to asbestos. Pathway and network analysis indicated a down-regulation of IFN-γ signaling and expression of CXC chemokine receptor 3 (CXCR3) in the sublines, whereas ELISA and flow cytometry analysis demonstrated a reduction in Th1-related IFN-γ production and cell-surface CXCR3 expression. These findings suggest that chronic exposure to asbestos may reduce antitumor immune status in CD4(+) T cells, and that an in vitro T-cell model may be useful in identifying molecules related to the impairment of antitumor immune function.

Published
2011
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39. A survey of patients with inflammatory skin recurrence corresponding to the area of previous irradiation after postoperative radiotherapy for breast cancer.

Author

Tsujino K, Kashihara K, Kotani S, Hayakawa K, Imanaka K, Takada Y, Uno T, Hirata H, Kaneyasu Y, Sekiguchi K, Ogo E, Hiratsuka J, Yoden E, and Soejima T

Subjects
Adult, Aged, Aged, 80 and over, Breast Neoplasms surgery, Carcinoma, Ductal, Breast etiology, Carcinoma, Ductal, Breast radiotherapy, Carcinoma, Ductal, Breast secondary, Carcinoma, Ductal, Breast surgery, Data Collection, Female, Humans, Inflammatory Breast Neoplasms etiology, Inflammatory Breast Neoplasms pathology, Japan, Lymphatic Metastasis, Mastectomy, Middle Aged, Neoplasm Recurrence, Local pathology, Skin Neoplasms etiology, Skin Neoplasms pathology, Skin Neoplasms secondary, Breast Neoplasms radiotherapy, Neoplasm Recurrence, Local etiology
Abstract

One of the unusual patterns of local recurrence in breast cancer patient is an inflammatory skin recurrence (ISR) sharply demarcating the area of previous radiation fields. To clarify the characteristics of this recurrence, we conducted a nationwide survey. We sent a survey to radiation oncologists at 200 institutions in Japan and received answers from 92. Of these, 24 institutions had some experience with patients who developed ISR affecting the previously irradiated area. The case details of 16 patients from 11 institutions were available and analyzed in this study. Eight patients experienced ISR after breast conservative therapy (groupA) and 8 patients experienced ISR after post-mastectomy radiotherapy (groupB). The postoperative pathological examination of groups A and B showed positive axillary lymph-nodes in 7/8 and 8/8 patients, positive lymphatic invasion in 4/7 and 7/8 patients, and ER status negative in 7/8 and 6/7 patients respectively. Median survival period was 266 days in groupA and 1105 days in groupB (p = 0.0001). Patients who developed the ISR tended to have several characteristics, including positive lymph-node metastases, intensive lymphatic invasion, and ER status negative. Physicians should contemplate the diagnosis of ISR next to radiation recall or radiation dermatitis, especially when the aforementioned risk factors are present.

Published
2011
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40. Asbestos induces reduction of tumor immunity.

Author

Kumagai-Takei N, Maeda M, Chen Y, Matsuzaki H, Lee S, Nishimura Y, Hiratsuka J, and Otsuki T

Subjects
Animals, Antigens, Neoplasm immunology, Asbestos toxicity, Carcinogens toxicity, DNA Damage immunology, Disease Models, Animal, Early Detection of Cancer, Gene Expression Regulation immunology, Humans, Immunity, Immunosuppression Therapy, Lung Neoplasms chemically induced, Lung Neoplasms genetics, Mesothelioma chemically induced, Mesothelioma diagnosis, Mesothelioma genetics, Oxidative Stress genetics, Oxidative Stress immunology, Asbestos immunology, Lung Neoplasms diagnosis, Lung Neoplasms immunology, Mesothelioma immunology
Abstract

Asbestos-related cancers such as malignant mesothelioma and lung cancer are an important issue in the world. There are many conflicts concerning economical considerations and medical evidence for these cancers and much confusion regarding details of the pathological mechanisms of asbestos-induced cancers. For example, there is uncertainty concerning the degree of danger of the iron-absent chrysotile compared with iron-containing crocidolite and amosite. However, regarding bad prognosis of mesothelioma, medical approaches to ensure the recognition of the biological effects of asbestos and the pathological mechanisms of asbestos-induced carcinogenesis, as well as clinical trials to detect the early stage of mesothelioma, should result in better preventions and the cure of these malignancies. We have been investigating the immunological effects of asbestos in relation to the reduction of tumor immunity. In this paper, cellular and molecular approaches to clarify the immunological effects of asbestos are described, and all the findings indicate that the reduction of tumor immunity is caused by asbestos exposure and involvement in asbestos-induced cancers. These investigations may not only allow the clear recognition of the biological effects of asbestos, but also present a novel procedure for early detection of previous asbestos exposure and the presence of mesothelioma as well as the chemoprevention of asbestos-related cancers.

Published
2011
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41. Improvement of the tumor-suppressive effect of boron neutron capture therapy for amelanotic melanoma by intratumoral injection of the tyrosinase gene.

Author

Morita N, Hiratsuka J, Kondoh H, Uno M, Asano T, Niki Y, Sakurai Y, Ono K, Harada T, and Imajo Y

Subjects
Animals, Boron Compounds pharmacokinetics, Boron Compounds pharmacology, Cell Growth Processes genetics, Cell Growth Processes radiation effects, Combined Modality Therapy, Cricetinae, Female, Injections, Intralesional, Melanoma, Amelanotic genetics, Melanoma, Amelanotic metabolism, Mesocricetus, Monophenol Monooxygenase biosynthesis, Monophenol Monooxygenase metabolism, Phenylalanine analogs & derivatives, Phenylalanine pharmacokinetics, Phenylalanine pharmacology, Radiation Tolerance genetics, Radiation-Sensitizing Agents pharmacokinetics, Radiation-Sensitizing Agents pharmacology, Skin Neoplasms genetics, Skin Neoplasms metabolism, Tissue Distribution, Transfection, Boron Neutron Capture Therapy methods, Genetic Therapy methods, Melanoma, Amelanotic enzymology, Melanoma, Amelanotic radiotherapy, Monophenol Monooxygenase genetics, Skin Neoplasms enzymology, Skin Neoplasms radiotherapy
Abstract

Boron neutron capture therapy (BNCT) is successful when there is a sufficient (10)B concentration in tumor cells. In melanoma, (10)B-para-boronophenylalanine (BPA) accumulation is proportional to melanin-producing activity. This study was done to confirm enhancement of the tumor-suppressive effect of BNCT on amelanotic melanoma by intratumoral injection of the tyrosinase gene. D178 or FF amelanotic melanomas were implanted s.c. in Syrian hamsters. One group of D178- or FF-bearing hamsters (TD178 or TFF group) received intratumoral injections of pcDNA-Tyrs constructed as a tyrosinase expression plasmid. The other hamsters (pD178 and pFF groups) were injected with pUC119, and control hamsters (D178 and FF groups) only with transfection reagents. All the groups underwent immunofluorescence analysis of tyrosinase expression and BPA biodistribution studies. BNCT experiments were done at the Kyoto University Research Reactor. Tyrosinase expression increased in the tumors of the TD178 and TFF groups but remained the same in the pD178 and pFF groups. Tumor boron concentrations in the TD178 and TFF groups increased significantly (TD178: 49.7 +/- 12.6 versus D178: 27.2 +/- 4.9 microg/g, P < 0.0001; TFF: 30.7 +/- 6.6 versus FF: 13.0 +/- 4.7 microg/g, P < 0.0001). The BNCT tumor-suppressive effect was marked in the TD178 and TFF groups. In vivo transfection with the tyrosinase gene increased BPA accumulation in the tumors, the BNCT tumor-suppressive effect on amelanotic melanoma being significantly enhanced. These findings suggest a potential new clinical strategy for the treatment of amelanotic melanoma with BNCT.

Published
2006
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42. EMBRYONIC FLOWER2, a novel polycomb group protein homolog, mediates shoot development and flowering in Arabidopsis.

Author

Yoshida N, Yanai Y, Chen L, Kato Y, Hiratsuka J, Miwa T, Sung ZR, and Takahashi S

Subjects
Arabidopsis growth & development, Base Sequence, DNA Primers, Gene Expression Regulation, Developmental, Gene Expression Regulation, Plant, Molecular Sequence Data, Polycomb-Group Proteins, Reverse Transcriptase Polymerase Chain Reaction, Arabidopsis genetics, Arabidopsis Proteins, Plant Proteins genetics, Plant Shoots growth & development, Plant Stems genetics, Repressor Proteins genetics
Abstract

In higher plants, developmental phase changes are regulated by a complex gene network. Loss-of-function mutations in the EMBRYONIC FLOWER genes (EMF1 and EMF2) cause Arabidopsis to flower directly, bypassing vegetative shoot growth. This phenotype suggests that the EMF genes play a major role in repression of the reproductive program. Positional cloning of EMF2 revealed that it encodes a zinc finger protein similar to FERTILIZATION-INDEPENDENT SEED2 and VERNALIZATION2 of Arabidopsis. These genes are characterized as structural homologs of Suppressor of zeste 12 [Su(z)12], a novel Polycomb group gene currently identified in Drosophila. In situ hybridization studies have demonstrated that EMF2 RNA is found in developing embryos, in both the vegetative and the reproductive shoot meristems, and in lateral organ primordia. Transgenic suppression of EMF2 produced a spectrum of early-flowering phenotypes, including emf2 mutant-like phenotype. This result confirms the role of EMF2 in phase transitions by repressing reproductive development.

Published
2001
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43. Biodistribution of boron concentration on melanoma-bearing hamsters after administration of p-, m-, o-boronophenylalanine.

Author

Hiratsuka J, Yoshino K, Kondoh H, Imajo Y, and Mishima Y

Subjects
Animals, Cricetinae, Male, Melanins biosynthesis, Melanoma, Experimental therapy, Mesocricetus, Mice, Phenylalanine pharmacokinetics, Tissue Distribution, Boron pharmacokinetics, Boron Compounds pharmacokinetics, Boron Neutron Capture Therapy, Melanoma, Experimental metabolism, Phenylalanine analogs & derivatives, Radiation-Sensitizing Agents pharmacokinetics
Abstract

Although p-boronophenylalanine (p-BPA), a boronate analogue of tyrosine, has proven to be one of the most successful compounds for boron neutron capture therapy (BNCT) of malignant melanoma, the selective uptake mechanism of this compound into melanoma cells is not well understood. Therefore, the relationship between the structure of BPA and its specific affinity to melanoma cells appears worthy of investigation. In the present study, m- and o-boronophenylalanine (m- and o-BPA) were administered to melanoma-bearing hamsters and their uptake was measured. The time courses (0.5, 2.0, 4.0 and 48.0 h) of boron concentrations in melanoma, normal skin, and blood were determined in male Syrian (golden) hamsters bearing Greene's melanomas following a single intraperitoneal injection of either p-, m- or o-BPA (100 mg/kg of BPA fructose in 1.0 ml of saline). The boron concentrations in these tissues were measured by inductively coupled plasma-atomic emission spectrometry (ICP-AES). In melanoma, the order of boron uptake was p- > m- > o-BPA at all time points, and the boron concentrations obtained with p-BPA and m-BPA resembled each other in that they had a peak at 2 h after administration and decreased with time. The melanoma/skin boron concentration ratio of p-BPA had a peak at 4 h after administration and the ratio ranged between 7/1 and 8/1. On the other hand, m-BPA and o-BPA had a peak at 2 h and their ratios ranged between 4/1 and 5/1. The difference in the accumulations of p-BPA and m-BPA could be due to a difference in the property of p-BPA as a tyrosine analogue for melanin synthesis. The accumulation of m-BPA into melanoma might indicate the baseline level of metabolism-related amino acid transport. Our experimental findings indicate that this melanin synthesis, or the structural analogy between the boron compound and tyrosine as a precursor of melanin, is an important factor in the increased accumulation of p-BPA in melanoma cells.

Published
2000
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44. Boron neutron capture therapy of malignant melanoma using 10B-paraboronophenylalanine with special reference to evaluation of radiation dose and damage to the normal skin.

Author

Fukuda H, Hiratsuka J, Honda C, Kobayashi T, Yoshino K, Karashima H, Takahashi J, Abe Y, Kanda K, and Ichihashi M

Subjects
Aged, Boron Compounds pharmacokinetics, Boron Compounds therapeutic use, Boron Neutron Capture Therapy, Female, Humans, Male, Middle Aged, Phenylalanine analogs & derivatives, Phenylalanine pharmacokinetics, Phenylalanine therapeutic use, Radiation-Sensitizing Agents, Radiotherapy Dosage, Skin metabolism, Melanoma radiotherapy, Skin Neoplasms radiotherapy
Abstract

A treatment regimen for boron neutron capture therapy of malignant melanomas is described using 10B-paraboronophenylalanine as the tumor-targeting compound. As a therapeutic dose, we adopted the maximum tolerable dose for the skin regardless of tumor 10B concentration. In practice, the maximum neutron fluence should be decided prior to starting irradiation. For this purpose, the kinetics of the concentration of 10B in the blood and skin and the skin-to-blood ratios were analyzed in the six patients who received 170 mg/kg of the compound intravenously, and skin concentrations during irradiation were predicted using a standard skin factor curve. This yields a skin concentration at time T based on the blood concentration at time 0. We calculated the maximum tolerable fluence yielding but not exceeding 18 RBE-Gy by assuming that the RBE of 14N(n,p)14C and 10B(n, alpha)7Li reaction for skin damage is 2.5. Actual skin reactions in three of five patients treated with the therapy were, as predicted, within tolerable limits, and we were able to obtain complete tumor regression in four cases. The results indicate that application of our logical approach will be useful for subsequent cases and further development of this therapy.

Published
1994

45. The relative biological effectiveness of 10B-neutron capture therapy for early skin reaction in the hamster.

Author

Hiratsuka J, Fukuda H, Kobayashi T, Karashima H, Yoshino K, Imajo Y, and Mishima Y

Subjects
Animals, Cricetinae, Dose-Response Relationship, Radiation, Male, Mesocricetus, Phenylalanine therapeutic use, Relative Biological Effectiveness, Boron Compounds therapeutic use, Neutrons, Phenylalanine analogs & derivatives, Radiation-Sensitizing Agents therapeutic use, Skin radiation effects
Abstract

The relative biological effectiveness (RBE) of 10B-neutron capture therapy (BNCT) on skin was analyzed using hamsters. The Kyoto University Research Reactor, which has a very low contamination of gamma rays and fast neutrons, was used as a thermal neutron source. Boron-10-para-boronophenylalanine hydrochloride ([10B]BPA.HCl) was administered to the hamsters. The evolution and time course of early skin reactions were assessed. These reactions were compared with those produced by electron beams. The maximum safe skin doses (no more than moist desquamation) of BNCT and electron beams were established to be 11 and 21 Gy, respectively. The RBE at this single dose with BNCT was found to be 1.94, assuming that the RBE of the gamma rays was 1.0 and each component of BNCT (mixed radiations) was simply additive.

Published
1991

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