Your search keyword '"Rombi, B."' showing total 50 results

1. Patients’ needs in proton therapy: A survey among ten European facilities

Author

Mazzola, G.C., Bergamaschi, L., Pedone, C., Vincini, M.G., Pepa, M., Zaffaroni, M., Volpe, S., Rombi, B., Doyen, J., Fossati, P., Haustermans, K., Høyer, M., Langendijk, J.A., Matute, R., Orlandi, E., Rylander, H., Troost, E.G.C., Orecchia, R., Alterio, D., and Jereczek-Fossa, B.A.

Published

2023

2. Consolidative active scanning proton therapy for mediastinal lymphoma: selection criteria, treatment implementation and clinical feasibility

Author

Dionisi, F., Scartoni, D., Rombi, B., Vennarini, S., Righetto, R., Farace, P., Lorentini, S., Schwarz, M., Di Murro, L., Demofonti, C., D’Angelillo, R. M., Petrongari, M. G., Sanguineti, G., and Amichetti, M.

Published

2022

3. CO-07.4 - REALISTIC ROBUSTNESS EVALUATION TOOL TO IMPROVE THE RELIABILITY OF MFO PROTON THERAPY PLAN EVALUATIONS IN SKULL BASE PATIENTS

Author

Fracchiolla, F., Lorentini, S., Widesott, L., Amelio, D., Cianchetti, M., Rombi, B., and Trianni, A.

Published

2023

4. 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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Choy, H, Miyashiro, I, Bush, D, Chuong, M, Kozarek, J, Rubens, M, Larson, G, Vargas, C, Hung, S.P, Hsieh, C.E, Huang, B.S, Tsang, N.M, Smith, N, Viehman, J, Harmsen, W, Elswick, S, Boughey, J, Harless, C, Jimenez, R, Hickey, S, DePauw, N, Ho, A, Taghian, A, MacDonald, S, Meek, A, Hedrick, S, Baliga, S, Gallotto, S, Lewy, J, Patteson, B, Speroni, S, Omsberg, A, Tarbell, N, Musolino, P, Yock, T, Indelicato, D, Rotondo, R, Mailhot, R, Uezono, H, Bradfield, S, Agarwal, V, Gillies, C, Gosling, A, Casares-Magaz, O, Eskildsen, S.F, Lassen, Y, Hasle, H, Tofting-Olesen, K, Alapetite, C, Puget, S, Nauraye, C, Beccaria, K, Bolle, S, Doz, F, Sainte-Rose, C, Bouffet, E, Zerah, M, Wu, J, Qiu, X, Hua, W, Mao, Y, Frakulli, R, Kramer, P.H, Glas, M, Blase, C, Tippelt, S, Konrath, L, Gruber, N, Schallerbauer-Peter, A, Mock, U, Niyazi, M, Niemierko, A, Schapira, E, Kim, V, Oh, K.S, Hwang, W.L, Busse, P.M, Loeffler, J.S, Shih, H.A, Appel, H, Tseng, Y.D, Tsai, H, Sinesi, C, Rossi, C, Badiyan, S, Kotecha, R, 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

5. Current radiotherapy practice for children with metastases from solid tumors : SIOPE survey analysis

Author

Huijskens, S., Kroon, P., Abakay, C. Demiroz, Timmermann, B., Giralt, J., Gaze, M., Harrabi, S., Scarzello, G., Alexopoulou, A., Padovani, L., Escande, A., Gandola, L., Supiot, S., Chojnacka, M., Bokun, J., Napieralska, A., Rombi, B., Maduro, J. H., Bolle, S., Mussano, A., Mandeville, H., Claude, L., Seravalli, E., Janssens, G. O., and Guided Treatment in Optimal Selected Cancer Patients (GUTS)

Subjects

Medizin

Published

2020

6. MO-0558 Patients’ needs in Proton Therapy: a survey among 10 European Facilities

Author

Mazzola, G.C., Bergamaschi, L., Pedone, C., Vincini, M.G., Pepa, M., Zaffaroni, M., Volpe, S., Doyen, J., Fossati, P., Haustermans, K., Høyer, M., Langendijk, J.A., Matute, R., Orlandi, E., Rylander, H., Rombi, B., Troost, E., Orecchia, R., Alterio, D., and Jereczek-Fossa, B.A.

Published

2023

7. PO-0842: Proton Therapy in children, adolescents and young adults: Patterns of care survey in Europe

Author

Journy, N., Kleinerman, R., Alapetite, C., Bernier-Chastagner, V., Dendale, R., Bolle, S., Doyen, J., Gurtner, K., Habrand, J.L., Helfre, S., Hoyer, M., Krause, M., Maduro, J., Nyström, P.W., Rombi, B., Timmermann, B., De Vathaire, F., Weber, D.C., Indelicato, D., and Berrington de Gonzalez, A.

Published

2018

8. Adron therapy in the treatment of chordoma of the spinal axis: a systematic review

Author

Amelio, D, Cianchetti, M, Rombi, B, and Amichetti, M

Subjects

musculoskeletal diseases, ddc: 610, 610 Medical sciences, Medicine

Abstract

Background: Chordoma is a rare neoplasm mainly involving the spinal axis. Radical excision of operable lesions may be curative and to date represents the mainstay of treatment. Unfortunately, the extent of resection directly correlates with possible resulting functional deficits. Moreover, radical surgery[for full text, please go to the a.m. URL], PTCOG 48; Meeting of the Particle Therapy Co-Operative Group

Published

2009

9. Proton Radiotherapy for Pediatric Ewing’s Sarcomas: Initial Clinical Outcome of 29 Patients

Author

Rombi, B, MacDonald, SM, Marcus, KJ, DeLaney, T, Huang, MS, Tarbell, NJ, and Yock, TI

Subjects

ddc: 610, 610 Medical sciences, Medicine

Abstract

Background: Proton radiotherapy can be prescribed similarly to photon radiotherapy to achieve comparable disease control rates. The chief advantage of protons for a given prescription dose is to spare acute and late toxicities by decreasing the amount of normal tissue receiving radiation. We have [for full text, please go to the a.m. URL], PTCOG 48; Meeting of the Particle Therapy Co-Operative Group

Published

2009

10. Spine Chordoma, Chondrosarcomas, and Other Sarcomas: The Initial Experience of 1 Institution

Author

Cianchetti, M., Giacomelli, I., Scartoni, D., Dionisi, F., Amelio, D., Rombi, B., Vennarini, S., and Amichetti, M.

Published

2017

11. PO-1020: Re-irradiation of Head and Neck Sarcomas: initial results of Protontherapy Center of Trento, Italy

Author

Giacomelli, I., Scartoni, D., Cianchetti, M., Dionisi, F., Rombi, B., and Amichetti, M.

Published

2017

12. OC-0345: Comparing cranio spinal irradiation planning for photon and proton techniques at 15 European centers

Author

Seravalli, E., Bosman, M., Smyth, G., Alapetite, C., Christiaens, M., Gandola, L., Hoeben, B., Horan, G., Koutsouveli, E., Kusters, M., Lassen, Y., Losa, S., Magelssen, H., Marchant, T., Mandeville, H., Oldenburger, F., Padovani, L., Paraskevopoulou, C., Rombi, B., Visser, J., Whitfield, G., Schwarz, M., Vestergaard, A., and Janssens, G.O.

Published

2017

13. PO-1432 Proton-therapy in pediatric patients with central nervous system tumors: a systematic review.

Author

Rombi, B., Roggio, M., Ronchi, L., Bertini, F., Cavallini, L., Deraco, E., Medici, F., Amichetti, M., Morganti, A.G., and Cammelli, S.

Subjects

*CHILD patients, CENTRAL nervous system tumors

Published

2021

14. Proton Radiotherapy for Pediatric Ewing's Sarcoma: Initial Clinical Outcomes.

Author

Rombi B, Delaney TF, Macdonald SM, Huang MS, Ebb DH, Liebsch NJ, Raskin KA, Yeap BY, Marcus KJ, Tarbell NJ, and Yock TI

Published

2012

15. PO-1244: Neuroradiological abnormalities and toxicity following proton therapy (PT) of CNS pediatric tumors.

Author

Rombi, B., Ruggi, A., Toni, F., Ronchi, L., Buwenge, M., Ammendolia, I., Cammelli, S., Prete, A., Maffei, M., Giacomelli, I., Amichetti, M., Morganti, G., and Melchionda, F.

Subjects

*PROTON therapy, *HUMAN abnormalities, *TUMORS

Abstract

Poster: Clinical track: Paediatric tumours PO-1244: Neuroradiological abnormalities and toxicity following proton therapy (PT) of CNS pediatric tumors B. ROMBI, A. Ruggi, F. Toni, L. Ronchi, M. Buwenge, I. Ammendolia, S. Cammelli, A. Prete, M. Maffei, I. Giacomelli, M. Amichetti, G. Morganti, F. Melchionda. [Extracted from the article]

Published

2020

16. PO-1241: Clinical results and toxicities in pediatric CNS tumors treated with proton pencil-beam scanning.

Author

Rombi, B., Ruggi, A., Ronchi, L., Buwenge, M., Ammendolia, I., Cammelli, S., Melchionda, F., Prete, A., Fracchiolla, F., Zucchelli, M., Morganti, G., and Amichetti, M.

Subjects

*PROTONS, *TUMORS

Abstract

Poster: Clinical track: Paediatric tumours PO-1241: Clinical results and toxicities in pediatric CNS tumors treated with proton pencil-beam scanning B. Rombi, A. Ruggi, L. Ronchi, M. Buwenge, I. Ammendolia, S. Cammelli, F. Melchionda, A. Prete, F. Fracchiolla, M. Zucchelli, G. Morganti, M. Amichetti. [Extracted from the article]

Published

2020

17. 3 mm Spot Size IMPT vs. IMRT for 3 Complex Pediatric Cases

Author

Olch, A.J., Lorentini, S., Schwarz, M., Rombi, B., and Wong, K.K.T.

Published

2010

18. EP-1691: A planning approach for lens sparing proton craniospinal irradiation in pediatric patients.

Author

Bizzocchi, N., Rombi, B., Farace, P., Algranati, C., Righetto, R., Schwarz, M., and Amichetti, M.

Subjects

*CHILDHOOD cancer, *CRANIAL nerves, *RADIOTHERAPY treatment planning, *CANCER radiotherapy, *HEALTH outcome assessment, *CANCER treatment, *TUMORS, SPINE cancer

Published

2016

19. P13.02 PROTON THERAPY FOR BRAIN AND SKULL BASE TUMORS AT THE NEW OPENING TRENTO FACILITY.

Author

Amelio, D., Cianchetti, M., Rombi, B., Vennarini, S., Dionisi, F., Vinante, L., and Amichetti, M.

Published

2014

20. Combined 18F-FDG-PET/CT imaging in radiotherapy target delineation for head-and-neck cancer.

Author

Guido A, Fuccio L, Rombi B, Castellucci P, Cecconi A, Bunkheila F, Fuccio C, Spezi E, Angelini AL, Barbieri E, Guido, Alessandra, Fuccio, Lorenzo, Rombi, Barbara, Castellucci, Paolo, Cecconi, Agnese, Bunkheila, Feisal, Fuccio, Chiara, Spezi, Emiliano, Angelini, Anna Lisa, and Barbieri, Enza

Abstract

Purpose: To evaluate the effect of the use of (18)F-fluorodeoxyglucose (FDG)-positron emission tomography (PET)/computed tomography (CT) in radiotherapy target delineation for head-and-neck cancer compared with CT alone. Methods and Materials: A total of 38 consecutive patients with head-and-neck cancer were included in this study. The primary tumor sites were as follow: 20 oropharyngeal tumors, 4 laryngeal tumors, 2 hypopharyngeal tumors, 2 paranasal sinuses tumors, 9 nasopharyngeal tumors, and 1 parotid gland tumor. The FDG-PET and CT scans were performed with a dedicated PET/CT scanner in one session and then fused. Subsequently, patients underwent treatment planning CT with intravenous contrast enhancement. The radiation oncologist defined all gross tumor volumes (GTVs) using both the PET/CT and CT scans. Results: In 35 (92%) of 38 cases, the CT-based GTVs were larger than the PET/CT-based GTVs. The average total GTV from the CT and PET/CT scans was 34.54 cm(3) (range, 3.56-109) and 29.38 cm(3) (range, 2.87-95.02), respectively (p < 0.05). Separate analyses of the difference between the CT- and PET/CT-based GTVs of the primary tumor compared with the GTVs of nodal disease were not statistically significant. The comparison between the PET/CT-based and CT-based boost planning target volumes did not show a statistically significant difference. All patients were alive at the end of the follow-up period (range, 3-38 months). Conclusion: GTVs, but not planning target volumes, were significantly changed by the implementation of combined PET/CT. Large multicenter studies are needed to ascertain whether combined PET/CT in target delineation can influence the main clinical outcomes. [ABSTRACT FROM AUTHOR]

Published

2009

21. PO-1041 Skull base chordomas and chondrosarcomas: Trento Protontherapy Centre early experience.

Author

Cianchetti, M., Amelio, D., Rombi, B., Vennarini, S., Scartoni, D., Giacomelli, I., Turkaj, A., Dionisi, F., and Amichetti, M.

Subjects

*SKULL base

Published

2021

22. OC-0454: Current radiotherapy practice for children with metastases from solid tumors: SIOPE survey analysis.

Author

Huijskens, S., Kroon, P., Demiroz Abakay, C., Timmermann, B., Giralt, J., Gaze, M., Harrabi, S., Scarzello, G., Alexopoulou, A., Padovani, L., Escande, A., Gandola, L., Supiot, S., Chojnacka, M., Bokun, J., Napieralska, A., Rombi, B., Maduro, J.H., Bolle, S., and Mussano, A.

Subjects

*METASTASIS, *RADIOTHERAPY, *GAZE, *TUMORS

Abstract

Proffered Papers: Proffered papers 23: Palliation OC-0454: Current radiotherapy practice for children with metastases from solid tumors: SIOPE survey analysis S. Huijskens, P. Kroon, C. Demiroz Abakay, B. Timmermann, J. Giralt, M. Gaze, S. Harrabi, G. Scarzello, A. Alexopoulou, L. Padovani, A. Escande, L. Gandola, S. Supiot, M. Chojnacka, J. Bokun, A. Napieralska, B. Rombi, J.H. Maduro, S. Bolle, A. Mussano, H. Mandeville, L. Claude, E. Seravalli, G.O. Janssens. [Extracted from the article]

Published

2020

23. Toxicity and Clinical Results after Proton Therapy for Pediatric Medulloblastoma: A Multi-Centric Retrospective Study

Author

Alessandro Ruggi, Fraia Melchionda, Iacopo Sardi, Rossana Pavone, Linda Meneghello, Lidija Kitanovski, Lorna Zadravec Zaletel, Paolo Farace, Mino Zucchelli, Mirko Scagnet, Francesco Toni, Roberto Righetto, Marco Cianchetti, Arcangelo Prete, Daniela Greto, Silvia Cammelli, Alessio Giuseppe Morganti, Barbara Rombi, Ruggi A., Melchionda F., Sardi I., Pavone R., Meneghello L., Kitanovski L., Zaletel L.Z., Farace P., Zucchelli M., Scagnet M., Toni F., Righetto R., Cianchetti M., Prete A., Greto D., Cammelli S., Morganti A.G., and Rombi B.

Subjects

radiation, Cancer Research, Oncology, pediatric brain tumors, proton therapy, medulloblastoma, toxicity, pediatric brain tumor

Abstract

Medulloblastoma is the most common malignant brain tumor in children. Even if current treatment dramatically improves the prognosis, survivors often develop long-term treatment-related sequelae. The current radiotherapy standard for medulloblastoma is craniospinal irradiation with a boost to the primary tumor site and to any metastatic sites. Proton therapy (PT) has similar efficacy compared to traditional photon-based radiotherapy but might achieve lower toxicity rates. We report on our multi-centric experience with 43 children with medulloblastoma (median age at diagnosis 8.7 years, IQR 6.6, M/F 23/20; 26 high-risk, 14 standard-risk, 3 ex-infant), who received active scanning PT between 2015 and 2021, with a focus on PT-related acute-subacute toxicity, as well as some preliminary data on late toxicity. Most acute toxicities were mild and manageable with supportive therapy. Hematological toxicity was limited, even among HR patients who underwent hematopoietic stem-cell transplantation before PT. Preliminary data on late sequelae were also encouraging, although a longer follow-up is needed.

Published

2022

24. PO-1445 Pediatric palliative radiotherapy: a systematic review.

Author

Ronchi, L., Donati, C.M., Mondardini, M.C., Prete, A., Alfieri, M.L., Rombi, B., Bertini, F., Buwenge, M., Morganti, A.G., and Cammelli, S.

Subjects

*RADIOTHERAPY

Published

2021

25. PO-1429 Long term results of neoadjuvant radiotherapy in soft tissue sarcomas of the extremities.

Author

CortesI, A., Galietta, E., Alfieri, M.L., Buwenge, M., Donati, C.M., Bisello, S., Boriani, M., Ghigi, G., Romeo, A., Bianchi, G., Gambarotti, M., Righi, A., Macchia, G., Deodato, F., Cilla, S., Rombi, B., Morganti, A.G., and Cammelli, S.

Subjects

*SARCOMA, *RADIOTHERAPY

Published

2021

26. PO-1221 Proton beam radiotherapy in pancreatic cancer: a systematic review.

Author

Cavallini, L., Arcelli, A., Guido, A., Buwenge, M., Rombi, B., Bertini, F., Strigari, L., Strolin, S., Bellarosa, C., Donati, C.M., Bisello, S., Scirocco, E., Ferioli, M., Macchia, G., Pezzulla, D., Amichetti, M., Morganti, A.G., and Cammelli, S.

Subjects

*PROTON beams, *PANCREATIC cancer, *CANCER radiotherapy

Published

2021

27. OC-0757 Proton pencil beam scanning and the brainstem in pediatric posterior fossa tumors: a European survey.

Author

Toussaint, L., Matysiak, W., Muren, L.P., Alapetite, C., Ares, C., Bolle, S., Calvo, F., Demoor-Goldschmidt, C., Doyen, J., Engellau, J., Harrabi, S., Kristensen, I., Missohou, F., Ondrova, B., Rombi, B., Schwarz, M., Van Beek, K., Vennarini, S., Vestergaard, A., and Vidal, M.

Subjects

*PROTON beams, *INFRATENTORIAL brain tumors, *BRAIN stem, *POSTERIOR cranial fossa

Published

2022

28. Patterns of proton therapy use in pediatric cancer management in 2016: An international survey

Author

T.Z. Vern-Gross, Shigeyuki Murayama, Joo-Young Kim, Tetsuo Akimoto, Lilia N. Loredo, Beate Timmermann, Claire Alapetite, Masayuki Araya, Ralph P. Ermoian, B.H. Chon, Satoshi Shibata, Stephanie M. Perkins, J.B. Wilkinson, Jérôme Doyen, Takashi Ogino, Daniel J. Indelicato, Christine E. Hill-Kayser, David B. Mansur, Do Hoon Lim, Ruth A. Kleinerman, Nadia N. Laack, John Han Chih Chang, Amy Berrington de Gonzalez, Ronald Richter, Diana R. Withrow, V.S. Mangona, Andrew Chang, Masao Murakami, Barbora Ondrová, Torunn I. Yock, Arnold C. Paulino, Michael E. Confer, Neige Journy, Rémi Dendale, Kristin Gurtner, Rahul R. Parikh, Hiromitsu Iwata, Barbara Rombi, Yusuke Demizu, Petra Witt Nyström, Choonsik Lee, Damien C. Weber, Shinichi Shimizu, Young Kwok, Naren Ramakrishna, Chiachien J. Wang, Centre de recherche en épidémiologie et santé des populations (CESP), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Hôpital Paul Brousse-Institut National de la Santé et de la Recherche Médicale (INSERM)-Université Paris-Saclay, Journy N., Indelicato D.J., Withrow D.R., Akimoto T., Alapetite C., Araya M., Chang A., Chang J.H.-C., Chon B., Confer M.E., Demizu Y., Dendale R., Doyen J., Ermoian R., Gurtner K., Hill-Kayser C., Iwata H., Kim J.-Y., Kwok Y., Laack N.N., Lee C., Lim D.H., Loredo L., Mangona V.S., Mansur D.B., Murakami M., Murayama S., Ogino T., Ondrova B., Parikh R.R., Paulino A.C., Perkins S., Ramakrishna N.R., Richter R., Rombi B., Shibata S., Shimizu S., Timmermann B., Vern-Gross T., Wang C.J., Weber D.C., Wilkinson J.B., Witt Nystrom P., Yock T.I., Kleinerman R.A., and Berrington de Gonzalez A.

Subjects

Adult, Male, Pediatrics, medicine.medical_specialty, Adolescent, [SDV]Life Sciences [q-bio], Patterns of care, Medizin, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Neoplasms, Surveys and Questionnaires, medicine, Proton Therapy, Humans, Radiology, Nuclear Medicine and imaging, In patient, CNS TUMORS, Survey, Child, Proton therapy, International research, Pediatric, business.industry, International survey, Cancer, Infant, Radiotherapy Dosage, Hematology, medicine.disease, Pediatric cancer, 3. Good health, Oncology, 030220 oncology & carcinogenesis, Child, Preschool, Observational study, Female, business

Abstract

Purpose: To facilitate the initiation of observational studies on late effects of proton therapy in pediatric patients, we report on current patterns of proton therapy use worldwide in patients aged less than 22 years. Materials & methods: Fifty-four proton centers treating pediatric patients in 2016 in 11 countries were invited to respond to a survey about the number of patients treated during that year by age group, intent of treatment, delivery technique and tumor types. Results: Among the 40 participating centers (participation rate: 74%), a total of 1,860 patients were treated in 2016 (North America: 1205, Europe: 432, Asia: 223). The numbers of patients per center ranged from 1 to 206 (median: 29). Twenty-four percent of the patients were

Published

2019

29. Dosimetric comparison of five different techniques for craniospinal irradiation across 15 European centers:analysis on behalf of the SIOP-E-BTG (radiotherapy working group)*

Author

Beate Timmermann, Laetitia Padovani, G. Smyth, Morten E. Evensen, Rolf-Dieter Kortmann, Carolina Sofia Fuentes, Mirjam E. Bosman, Henriette Magelssen, Lorenza Gandola, Jorrit Visser, Efi Koutsouveli, Claire Alapetite, Yasmin Lassen-Ramshad, Chryssa Paraskevopoulou, R. Righetto, Bianca A.W. Hoeben, Eloise Garnier, Enrica Seravalli, Geert O. Janssens, Frank Saran, M. Kusters, F. Goudjil, Thomas E Marchant, Thankamma Ajithkumar, Gail Horan, Anne Vestergaard, Foppe Oldenburger, Sandra Losa, Barbara Rombi, Gillian A Whitfield, Silvia Meroni, Seravalli E., Bosman M., Lassen-Ramshad Y., Vestergaard A., Oldenburger F., Visser J., Koutsouveli E., Paraskevopoulou C., Horan G., Ajithkumar T., Timmermann B., Fuentes C.-S., Whitfield G., Marchant T., Padovani L., Garnier E., Gandola L., Meroni S., Hoeben B.A.W., Kusters M., Alapetite C., Losa S., Goudjil F., Magelssen H., Evensen M.E., Saran F., Smyth G., Rombi B., Righetto R., Kortmann R.-D., Janssens G.O., Radiotherapy, and CCA - Imaging and biomarkers

Subjects

Male, Organs at Risk, Adolescent, medicine.medical_treatment, Advisory Committees, Medizin, Craniospinal Irradiation, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, All institutes and research themes of the Radboud University Medical Center, Radiation oncology, Medicine, Humans, Radiology, Nuclear Medicine and imaging, Practice Patterns, Physicians', Pencil-beam scanning, Radiometry, Advisory Committee, Manchester Cancer Research Centre, Practice patterns, business.industry, Radiotherapy Planning, Computer-Assisted, ResearchInstitutes_Networks_Beacons/mcrc, Radiotherapy Dosage, Hematology, General Medicine, Radiation therapy, Europe, Oncology, Multicenter study, 030220 oncology & carcinogenesis, Radiation Oncology, business, Nuclear medicine, Human, Rare cancers Radboud Institute for Health Sciences [Radboudumc 9]

Abstract

Purpose: Conventional techniques (3D-CRT) for craniospinal irradiation (CSI) are still widely used. Modern techniques (IMRT, VMAT, TomoTherapy®, proton pencil beam scanning [PBS]) are applied in a limited number of centers. For a 14-year-old patient, we aimed to compare dose distributions of five CSI techniques applied across Europe and generated according to the participating institute protocols, therefore representing daily practice. Material and methods: A multicenter (n = 15) dosimetric analysis of five different techniques for CSI (3D-CRT, IMRT, VMAT, TomoTherapy®, PBS; 3 centers per technique) was performed using the same patient data, set of delineations and dose prescription (36.0/1.8 Gy). Different treatment plans were optimized based on the same planning target volume margin. All participating institutes returned their best treatment plan applicable in clinic. Results: The modern radiotherapy techniques investigated resulted in superior conformity/homogeneity-indices (CI/HI), particularly in the spinal part of the target (CI: 3D-CRT:0.3 vs. modern:0.6; HI: 3D-CRT:0.2 vs. modern:0.1), and demonstrated a decreased dose to the thyroid, heart, esophagus and pancreas. Dose reductions of >10.0 Gy were observed with PBS compared to modern photon techniques for parotid glands, thyroid and pancreas. Following this technique, a wide range in dosimetry among centers using the same technique was observed (e.g., thyroid mean dose: VMAT: 5.6–24.6 Gy; PBS: 0.3–10.1 Gy). Conclusions: The investigated modern radiotherapy techniques demonstrate superior dosimetric results compared to 3D-CRT. The lowest mean dose for organs at risk is obtained with proton therapy. However, for a large number of organs ranges in mean doses were wide and overlapping between techniques making it difficult to recommend one radiotherapy technique over another.

Published

2018

30. Universal field matching in craniospinal irradiation by a background-dose gradient-optimized method

Author

Erik Traneus, Barbara Rombi, F. Fellin, Paolo Farace, Nicola Bizzocchi, Traneus E., Bizzocchi N., Fellin F., Rombi B., and Farace P.

Subjects

Organs at Risk, Photon, Materials science, Proton, Matching (graph theory), Field (physics), VMAT, Craniospinal Irradiation, 030218 nuclear medicine & medical imaging, 8755De, Brain Neoplasm, 03 medical and health sciences, 0302 clinical medicine, Optics, Radiation Oncology Physics, Humans, Radiology, Nuclear Medicine and imaging, Pencil-beam scanning, Child, Instrumentation, Proton therapy, Retrospective Studies, Radiation, business.industry, Brain Neoplasms, Radiotherapy Planning, Computer-Assisted, Craniospinal irradiation, Radiotherapy Dosage, 030220 oncology & carcinogenesis, Radiotherapy, Intensity-Modulated, Protons, Field junction, business, Nuclear medicine, Beam (structure), Human

Abstract

Purpose The gradient-optimized methods are overcoming the traditional feathering methods to plan field junctions in craniospinal irradiation. In this note, a new gradient-optimized technique, based on the use of a background dose, is described. Methods Treatment planning was performed by RayStation (RaySearch Laboratories, Stockholm, Sweden) on the CT scans of a pediatric patient. Both proton (by pencil beam scanning) and photon (by volumetric modulated arc therapy) treatments were planned with three isocenters. An ‘in silico’ ideal background dose was created first to cover the upper-spinal target and to produce a perfect dose gradient along the upper and lower junction regions. Using it as background, the cranial and the lower-spinal beams were planned by inverse optimization to obtain dose coverage of their relevant targets and of the junction volumes. Finally, the upper-spinal beam was inversely planned after removal of the background dose and with the previously optimized beams switched on. Results In both proton and photon plans, the optimized cranial and the lower-spinal beams produced a perfect linear gradient in the junction regions, complementary to that produced by the optimized upper-spinal beam. The final dose distributions showed a homogeneous coverage of the targets. Discussion Our simple technique allowed to obtain high-quality gradients in the junction region. Such technique universally works for photons as well as protons and could be applicable to the TPSs that allow to manage a background dose.

Published

2018

31. PO-0883: Early outcomes in patients with skull base chordomas and chondrosarcomas treated with proton therapy.

Author

Turkaj, A., Giacomelli, I., Cianchetti, M., Scartoni, D., Amelio, D., Vennarini, S., Rombi, B., Dionisi, F., and Amichetti, M.

Subjects

*SKULL base, *CHORDOMA, *PROTON therapy

Abstract

Poster: Clinical track: CNS PO-0883: Early outcomes in patients with skull base chordomas and chondrosarcomas treated with proton therapy A. Turkaj, I. Giacomelli, M. Cianchetti, D. Scartoni, D. Amelio, S. Vennarini, B. Rombi, F. Dionisi, M. Amichetti. [Extracted from the article]

Published

2020

32. EP-1134: Proton therapy re-irradiation for large-volume recurrent high-grade gliomas.

Author

Amelio, D., Widesott, L., Maines, F., Fellin, F., Righetto, R., Vennarini, S., Rombi, B., Cianchetti, M., Dionisi, F., Donner, D., Rozzanigo, U., Schwarz, M., Chierichetti, F., Galligioni, E., and Amichetti, M.

Subjects

*GLIOMA treatment, *PROTON therapy, *CANCER relapse, *CANCER radiotherapy, *ONCOLOGY research, *MEDICAL publishing

Published

2016

33. Clinical practice in European centres treating paediatric posterior fossa tumours with pencil beam scanning proton therapy.

Author

Toussaint L, Matysiak W, Alapetite C, Aristu J, Bannink-Gawryszuk A, Bolle S, Bolsi A, Calvo F, Cerron Campoo F, Charlwood F, Demoor-Goldschmidt C, Doyen J, Drosik-Rutowicz K, Dutheil P, Embring A, Engellau J, Goedgebeur A, Goudjil F, Harrabi S, Kopec R, Kristensen I, Lægsdmand P, Lütgendorf-Caucig C, Meijers A, Mirandola A, Missohou F, Montero Feijoo M, Muren LP, Ondrova B, Orlandi E, Pettersson E, Pica A, Plaude S, Righetto R, Rombi B, Timmermann B, Van Beek K, Vela A, Vennarini S, Vestergaard A, Vidal M, Vondracek V, Weber DC, Whitfield G, Zimmerman J, Maduro JH, and Lassen-Ramshad Y

Subjects

Humans, Europe, Child, Child, Preschool, Male, Female, Organs at Risk radiation effects, Brain Stem radiation effects, Proton Therapy methods, Infratentorial Neoplasms radiotherapy, Radiotherapy Planning, Computer-Assisted methods, Radiotherapy Dosage

Abstract

Background and Purpose: As no guidelines for pencil beam scanning (PBS) proton therapy (PT) of paediatric posterior fossa (PF) tumours exist to date, this study investigated planning techniques across European PT centres, with special considerations for brainstem and spinal cord sparing., Materials and Methods: A survey and a treatment planning comparison were initiated across nineteen European PBS-PT centres treating paediatric patients. The survey assessed all aspects of the treatment chain, including but not limited to delineations, dose constraints and treatment planning. Each centre planned two PF tumour cases for focal irradiation, according to their own clinical practice but based on common delineations. The prescription dose was 54 Gy(RBE) for Case 1 and 59.4 Gy(RBE) for Case 2. For both cases, planning strategies and relevant dose metrics were compared., Results: Seventeen (89 %) centres answered the survey, and sixteen (80 %) participated in the treatment planning comparison. In the survey, thirteen (68 %) centres reported using the European Particle Therapy Network definition for brainstem delineation. In the treatment planning study, while most centres used three beam directions, their configurations varied widely across centres. Large variations were also seen in brainstem doses, with a brainstem near maximum dose (D2%) ranging from 52.7 Gy(RBE) to 55.7 Gy(RBE) (Case 1), and from 56.8 Gy(RBE) to 60.9 Gy(RBE) (Case 2)., Conclusion: This study assessed the European PBS-PT planning of paediatric PF tumours. Agreement was achieved in e.g. delineation-practice, while wider variations were observed in planning approach and consequently dose to organs at risk. Collaboration between centres is still ongoing, striving towards common guidelines., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

34. Patterns of practice of image guided particle therapy for cranio-spinal irradiation: A site specific multi-institutional survey of European Particle Therapy Network.

Author

Trnková P, Dasu A, Placidi L, Stock M, Toma-Dasu I, Brouwer CL, Gosling A, Jouglar E, Kristensen I, Martin V, Moinuddin S, Pasquie I, Peters S, Pica A, Plaude S, Righetto R, Rombi B, Thariat J, van der Weide H, Hoffmann A, and Bolsi A

Subjects

Humans, Europe, Craniospinal Irradiation methods, Surveys and Questionnaires, Radiotherapy Planning, Computer-Assisted methods, Tomography, X-Ray Computed, Delphi Technique, Magnetic Resonance Imaging, Radiotherapy, Image-Guided methods

Abstract

Purpose: To investigate the current practice patterns in image-guided particle therapy (IGPT) for cranio-spinal irradiation (CSI)., Methods: A multi-institutional survey was distributed to European particle therapy centres to analyse all aspects of IGPT. Based on the survey results, a Delphi consensus analysis was developed to define minimum requirements and optimal workflow for clinical practice. The centres participating in the institutional survey were invited to join the Delphi process., Results: Eleven centres participated in the survey. Imaging for treatment planning was rather similar among the centres with Computed Tomography (CT) being the main modality. For positioning verification, 2D IGPT was more commonly used than 3D IGPT. Two centres performed routinely imaging for plan adaptation, by the rest ad hoc. Eight centres participated in the Delphi consensus analysis. The full consensus was reached on the use of CT imaging without contrast for treatment planning and the role of magnetic resonance imaging (MRI) in target and organs-at-risk delineation. There was an agreement on the necessity to perform patient position verification and correction before each isocentre. The most important outcome was the clear need for standardization and harmonization of the workflow., Conclusion: There were differences in CSI IGPT clinical practice among the European particle therapy centres. Moreover, the optimal workflow as identified by experts was not yet reached. There is a strong need for consensus guidelines. The state-of-the-art imaging technology and protocols need to be implemented into clinical practice to improve the quality of IGPT for CSI., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Associazione Italiana di Fisica Medica e Sanitaria. Published by Elsevier Ltd. All rights reserved.)

Published

2024

35. Unforeseen cytomegalovirus retinopathy following high dose thiotepa and proton irradiation in a pediatric patient with high-risk medulloblastoma: A case report.

Author

Bigagli E, Agostiniani S, Pugi A, Rombi B, Tornaboni EE, Censullo ML, Gori CG, Pavone R, and Sardi I

Abstract

In immunocompetent individuals, cytomegalovirus (CMV) infection is usually mild but may cause severe complications such as retinitis, pneumonitis, and encephalitis in immunocompromised individuals. So far, cases of CMV retinitis in patients with medulloblastoma undergoing chemotherapy and radiotherapy, have not been reported. We herein report the case of a pediatric patient with high-risk medulloblastoma who experienced an unexpected CMV retinopathy and leukoencephalopathy following high dose thiotepa and proton irradiation. The patient underwent a four-course induction therapy (1st cycle: methotrexate and vinorelbine; 2nd cycle: etoposide and hematopoietic stem cells apheresis; 3rd cycle: cyclophosphamide and vinorelbine; 4th cycle: carboplatin and vinorelbine) and then a consolidation phase consisting in high dose thiotepa followed by autologous HSC transplant and proton cranio-spinal irradiation plus boost to the primary tumor site and pituitary site with concomitant vinorelbine. After two months of maintenance treatment with lomustine and vinorelbine, the patient showed complete blindness and leukoencephalopathy. A diagnosis of CMV retinopathy was made and oral valganciclovir was administered. CMV retinopathy was judged to be possibly related to the use of high dose thiotepa worsened by radiotherapy. This case report suggests that in pediatric patients undergoing immunosuppressive chemo-radiotherapy, CMV reactivation should be carefully monitored to prevent serious complications such as retinopathy and visual loss., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (© 2023 Bigagli, Agostiniani, Pugi, Rombi, Tornaboni, Censullo, Gori, Pavone and Sardi.)

Published

2023

36. Toxicity and Clinical Results after Proton Therapy for Pediatric Medulloblastoma: A Multi-Centric Retrospective Study.

Author

Ruggi A, Melchionda F, Sardi I, Pavone R, Meneghello L, Kitanovski L, Zaletel LZ, Farace P, Zucchelli M, Scagnet M, Toni F, Righetto R, Cianchetti M, Prete A, Greto D, Cammelli S, Morganti AG, and Rombi B

Abstract

Medulloblastoma is the most common malignant brain tumor in children. Even if current treatment dramatically improves the prognosis, survivors often develop long-term treatment-related sequelae. The current radiotherapy standard for medulloblastoma is craniospinal irradiation with a boost to the primary tumor site and to any metastatic sites. Proton therapy (PT) has similar efficacy compared to traditional photon-based radiotherapy but might achieve lower toxicity rates. We report on our multi-centric experience with 43 children with medulloblastoma (median age at diagnosis 8.7 years, IQR 6.6, M/F 23/20; 26 high-risk, 14 standard-risk, 3 ex-infant), who received active scanning PT between 2015 and 2021, with a focus on PT-related acute-subacute toxicity, as well as some preliminary data on late toxicity. Most acute toxicities were mild and manageable with supportive therapy. Hematological toxicity was limited, even among HR patients who underwent hematopoietic stem-cell transplantation before PT. Preliminary data on late sequelae were also encouraging, although a longer follow-up is needed.

Published

2022

37. Technical challenges in the treatment of mediastinal lymphomas by proton pencil beam scanning and deep inspiration breath-hold.

Author

Righetto R, Fracchiolla F, Widesott L, Lorentini S, Dionisi F, Rombi B, Scartoni D, Vennarini S, Schwarz M, and Farace P

Subjects

Humans, Organs at Risk, Protons, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted methods, Reproducibility of Results, Lymphoma diagnostic imaging, Lymphoma radiotherapy, Mediastinal Neoplasms diagnostic imaging, Mediastinal Neoplasms radiotherapy, Proton Therapy methods, Radiotherapy, Intensity-Modulated methods

Abstract

Purpose: To comprehensively describe the treatment of mediastinal lymphoma by pencil beam scanning (PBS) proton therapy., Methods: Fourteen patients underwent PBS proton treatment in a supine position in deep inspiration breath-hold (DIBH). Three DIBH computed tomography (CT) scans were acquired for each patient to delineate the Internal Target Volume (ITV). Intensity-modulated proton therapy (IMPT) was planned by min-max robust optimization on the ITV, with a 6 mm setup and 3.5% range uncertainties. Robustness analysis was performed and dose coverage was visually inspected on the corresponding voxel-wise minimum map. Layer repainting was set equal to 5 to compensate for cardiac motion. Intra-fraction reproducibility during treatment was assessed by repeated daily DIBH X-ray imaging. Finally, an additional CT was acquired at half treatment to estimate the impact of inter-fraction dosimetric reproducibility., Results: IMPT guaranteed robust mediastinal target coverage and organs-at-risk sparing. However, visual voxel-wise robustness evaluation showed that in five patients a second optimization with focused objectives in the cost-function was necessary to achieve a robust coverage of the target regions at the interface between lungs and soft tissue. In six patients, repainting was not used due to excessive treatment time length and poor patient compliance. Intra-fraction average reproducibility was within 1 mm/1degree. On repeated CT scans, inter-fraction setup errors and/or anatomical changes showed minimal dosimetric differences in CTV coverage., Conclusion: IMPT in DIBH is effective and reproducible to treat mediastinal lymphomas. Caution is recommended to guarantee robust dose delivery to high-risk regions at the interface between lungs and soft tissue., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2022

38. Proton therapy: A therapeutic opportunity for aggressive pediatric meningioma.

Author

Rombi B, Ruggi A, Sardi I, Zucchelli M, Scagnet M, Toni F, Cammelli S, Giulietti G, Fabbri VP, Gianno F, Amichetti M, Yock TI, Morganti AG, Pession A, and Melchionda F

Subjects

Child, Humans, Infant, Male, Meningeal Neoplasms pathology, Meningioma pathology, Meningeal Neoplasms radiotherapy, Meningioma radiotherapy, Proton Therapy methods

Abstract

Meningiomas are an extremely rare histology among pediatric brain tumors, and there is a shortage of literature on their management. Proton therapy is currently used safely and effectively for many types of both pediatric and adult cancer, and its main advantage is the sparing of healthy tissues from radiation, which could translate in the reduction of late side effects. We review the literature on radiotherapy and proton therapy for pediatric meningiomas and report clinical outcomes for two aggressive pediatric meningiomas we treated with protons. Proton therapy might be a safe and effective therapeutic option for this rare subgroup of tumors., (© 2021 The Authors. Pediatric Blood & Cancer published by Wiley Periodicals LLC.)

Published

2021

39. Usefulness of 18f-FDG PET-CT in Staging, Restaging, and Response Assessment in Pediatric Rhabdomyosarcoma.

Author

Donner D, Feraco P, Meneghello L, Rombi B, Picori L, and Chierichetti F

Abstract

Rhabdomyosarcoma is the most common soft-tissue sarcoma of childhood. Despite clinical advances, subsets of these patients continue to suffer high morbidity and mortality rates associated with their disease. Following the European guidelines for 18 F-FDG PET and PET-CT imaging in pediatric oncology, the routine use of 18 F-FDG PET-CT may be useful for patients affected by rhabdomyosarcoma, in staging, in the evaluation of response to therapy, and for restaging/detection of relapse. The European Pediatric Protocols are very old, and for staging and restaging, they recommend only radionuclide bone scan. The 18 F-FDG PET-CT exam is listed as an optional investigation prescribed according to local availability and local protocols in the investigations panel required at the end of the treatment. We present two cases highlighting the usefulness of 18 F-FDG PET-CT in managing pediatric patients affected by rhabdomyosarcoma, providing some bibliographic references.

Published

2020

40. An advanced junction concept in pediatric craniospinal irradiation by proton pencil beam scanning.

Author

Fellin F, Fracchiolla F, Rombi B, Lipparini M, Vennarini S, and Farace P

Subjects

Child, Humans, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Craniospinal Irradiation methods, Proton Therapy methods

Abstract

Purpose: To present an advanced junction concept in craniospinal irradiation (CSI) by proton pencil beam scanning (PBS)., Materials and Methods: In PBS CSI, whole brain irradiation (WBI) is commonly delivered by opposed lateral-beams, whereas spine irradiation is delivered by posterior entrances. Since lateral-beams would cross a large portion of the patient at the shoulder level, the junction between WBI and spine irradiation cannot extend below that level, thus the size of the lateral-beams needs to be limited and the number of required isocenters can increase. To overcome such limitation, a pseudo-junction was introduced below the posterior fossa, to turn in this region the WBI beam arrangement to a single posterior beam pointed at the same isocenter, that was matched to the posterior spinal beam more caudally, below shoulder level, in the true-junction. After assessing robustness of the technique to range and setup uncertainties, twenty-three treated patients were reviewed to estimate the percentage that might benefit of being treated by two instead of three isocenters., Results: Target coverage at the junction levels resulted robust, with D95% > 95% on pseudo-junction and D95% > 90% on the true-junction. By the advanced junction concept, 91% of patients might by treated with only two isocenters, whereas, by the conventional method, 83% of patients required three isocenters., Conclusion: With the presented junction concept the number of isocenters can be reduced, with a consequent relevant reduction of treatment time, which is particularly valuable in the management of pediatric patients under anesthesia., (Copyright © 2019. Published by Elsevier Ltd.)

Published

2019

41. Patterns of proton therapy use in pediatric cancer management in 2016: An international survey.

Author

Journy N, Indelicato DJ, Withrow DR, Akimoto T, Alapetite C, Araya M, Chang A, Chang JH, Chon B, Confer ME, Demizu Y, Dendale R, Doyen J, Ermoian R, Gurtner K, Hill-Kayser C, Iwata H, Kim JY, Kwok Y, Laack NN, Lee C, Lim DH, Loredo L, Mangona VS, Mansur DB, Murakami M, Murayama S, Ogino T, Ondrová B, Parikh RR, Paulino AC, Perkins S, Ramakrishna NR, Richter R, Rombi B, Shibata S, Shimizu S, Timmermann B, Vern-Gross T, Wang CJ, Weber DC, Wilkinson JB, Witt Nyström P, Yock TI, Kleinerman RA, and Berrington de Gonzalez A

Subjects

Adolescent, Adult, Child, Child, Preschool, Female, Humans, Infant, Male, Neoplasms epidemiology, Pediatrics methods, Pediatrics statistics & numerical data, Proton Therapy methods, Radiotherapy Dosage, Surveys and Questionnaires, Young Adult, Neoplasms radiotherapy, Proton Therapy statistics & numerical data

Abstract

Purpose: To facilitate the initiation of observational studies on late effects of proton therapy in pediatric patients, we report on current patterns of proton therapy use worldwide in patients aged less than 22 years., Materials & Methods: Fifty-four proton centers treating pediatric patients in 2016 in 11 countries were invited to respond to a survey about the number of patients treated during that year by age group, intent of treatment, delivery technique and tumor types., Results: Among the 40 participating centers (participation rate: 74%), a total of 1,860 patients were treated in 2016 (North America: 1205, Europe: 432, Asia: 223). The numbers of patients per center ranged from 1 to 206 (median: 29). Twenty-four percent of the patients were <5 years of age, and 50% <10 years. More than 30 pediatric tumor types were identified, mainly treated with curative intent: 48% were CNS, 25% extra-cranial sarcomas, 7% neuroblastoma, and 5% hematopoietic tumors. About half of the patients were treated with pencil beam scanning. Treatment patterns were broadly similar across the three continents., Conclusion: To our knowledge, this survey provides the first worldwide assessment of proton therapy use for pediatric cancer management. Since previous estimates in the United States and Europe, CNS tumors remain the cancer types most commonly treated with protons in 2016. However, the proportion of extra-cranial tumors is growing worldwide. The typically low numbers of patients treated in each center indicate the need for international research collaborations to assess long-term outcomes of proton therapy in pediatric patients., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2019

42. Management of vertebral radiotherapy dose in paediatric patients with cancer: consensus recommendations from the SIOPE radiotherapy working group.

Author

Hoeben BA, Carrie C, Timmermann B, Mandeville HC, Gandola L, Dieckmann K, Ramos Albiac M, Magelssen H, Lassen-Ramshad Y, Ondrová B, Ajithkumar T, Alapetite C, Balgobind BV, Bolle S, Cameron AL, Davila Fajardo R, Dietzsch S, Dumont Lecomte D, van den Heuvel-Eibrink MM, Kortmann RD, Laprie A, Melchior P, Padovani L, Rombi B, Scarzello G, Schwarz R, Seiersen K, Seravalli E, Thorp N, Whitfield GA, Boterberg T, and Janssens GO

Subjects

Child, Child, Preschool, Female, Humans, Male, Neoplasms pathology, Radiation Oncology standards, Neoplasms radiotherapy, Pediatrics standards, Radiotherapy Dosage standards, Radiotherapy, Conformal standards

Abstract

Inhomogeneities in radiotherapy dose distributions covering the vertebrae in children can produce long-term spinal problems, including kyphosis, lordosis, scoliosis, and hypoplasia. In the published literature, many often interrelated variables have been reported to affect the extent of potential radiotherapy damage to the spine. Articles published in the 2D and 3D radiotherapy era instructed radiation oncologists to avoid dose inhomogeneity over growing vertebrae. However, in the present era of highly conformal radiotherapy, steep dose gradients over at-risk structures can be generated and thus less harm is caused to patients. In this report, paediatric radiation oncologists from leading centres in 11 European countries have produced recommendations on how to approach dose coverage for target volumes that are adjacent to vertebrae to minimise the risk of long-term spinal problems. Based on available information, it is advised that homogeneous vertebral radiotherapy doses should be delivered in children who have not yet finished the pubertal growth spurt. If dose fall-off within vertebrae cannot be avoided, acceptable dose gradients for different age groups are detailed here. Vertebral delineation should include all primary ossification centres and growth plates, and therefore include at least the vertebral body and arch. For partial spinal radiotherapy, the number of irradiated vertebrae should be restricted as much as achievable, particularly at the thoracic level in young children (<6 years old). There is a need for multicentre research on vertebral radiotherapy dose distributions for children, but until more valid data become available, these recommendations can provide a basis for daily practice for radiation oncologists who have patients that require vertebral radiotherapy., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

43. Dosimetric comparison of five different techniques for craniospinal irradiation across 15 European centers: analysis on behalf of the SIOP-E-BTG (radiotherapy working group) .

Author

Seravalli E, Bosman M, Lassen-Ramshad Y, Vestergaard A, Oldenburger F, Visser J, Koutsouveli E, Paraskevopoulou C, Horan G, Ajithkumar T, Timmermann B, Fuentes CS, Whitfield G, Marchant T, Padovani L, Garnier E, Gandola L, Meroni S, Hoeben BAW, Kusters M, Alapetite C, Losa S, Goudjil F, Magelssen H, Evensen ME, Saran F, Smyth G, Rombi B, Righetto R, Kortmann RD, and Janssens GO

Subjects

Adolescent, Advisory Committees organization & administration, Craniospinal Irradiation statistics & numerical data, Europe epidemiology, Humans, Male, Organs at Risk radiation effects, Radiometry methods, Radiometry standards, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted methods, Radiotherapy Planning, Computer-Assisted standards, Craniospinal Irradiation methods, Practice Patterns, Physicians' statistics & numerical data, Radiation Oncology methods, Radiation Oncology organization & administration

Abstract

Purpose: Conventional techniques (3D-CRT) for craniospinal irradiation (CSI) are still widely used. Modern techniques (IMRT, VMAT, TomoTherapy ® , proton pencil beam scanning [PBS]) are applied in a limited number of centers. For a 14-year-old patient, we aimed to compare dose distributions of five CSI techniques applied across Europe and generated according to the participating institute protocols, therefore representing daily practice., Material and Methods: A multicenter (n = 15) dosimetric analysis of five different techniques for CSI (3D-CRT, IMRT, VMAT, TomoTherapy ® , PBS; 3 centers per technique) was performed using the same patient data, set of delineations and dose prescription (36.0/1.8 Gy). Different treatment plans were optimized based on the same planning target volume margin. All participating institutes returned their best treatment plan applicable in clinic., Results: The modern radiotherapy techniques investigated resulted in superior conformity/homogeneity-indices (CI/HI), particularly in the spinal part of the target (CI: 3D-CRT:0.3 vs. modern:0.6; HI: 3D-CRT:0.2 vs. modern:0.1), and demonstrated a decreased dose to the thyroid, heart, esophagus and pancreas. Dose reductions of >10.0 Gy were observed with PBS compared to modern photon techniques for parotid glands, thyroid and pancreas. Following this technique, a wide range in dosimetry among centers using the same technique was observed (e.g., thyroid mean dose: VMAT: 5.6-24.6 Gy; PBS: 0.3-10.1 Gy)., Conclusions: The investigated modern radiotherapy techniques demonstrate superior dosimetric results compared to 3D-CRT. The lowest mean dose for organs at risk is obtained with proton therapy. However, for a large number of organs ranges in mean doses were wide and overlapping between techniques making it difficult to recommend one radiotherapy technique over another.

Published

2018

44. SIOPE - Brain tumor group consensus guideline on craniospinal target volume delineation for high-precision radiotherapy.

Author

Ajithkumar T, Horan G, Padovani L, Thorp N, Timmermann B, Alapetite C, Gandola L, Ramos M, Van Beek K, Christiaens M, Lassen-Ramshad Y, Magelssen H, Nilsson K, Saran F, Rombi B, Kortmann R, and Janssens GO

Subjects

Adult, Brain diagnostic imaging, Brain radiation effects, Brain Neoplasms diagnostic imaging, Child, Consensus, Female, Humans, Magnetic Resonance Imaging methods, Male, Young Adult, Brain Neoplasms radiotherapy, Radiotherapy Planning, Computer-Assisted methods

Abstract

Objective: To develop a consensus guideline for craniospinal target volume (TV) delineation in children and young adults participating in SIOPE studies in the era of high-precision radiotherapy., Methods and Materials: During four consensus meetings (Cambridge, Essen, Liverpool, and Marseille), conventional field-based TV has been translated into image-guided high-precision craniospinal TV by a group of expert paediatric radiation oncologists and enhanced by MRI images of liquor distribution., Results: The CTV cranial should include the whole brain, cribriform plate, most inferior part of the temporal lobes, and the pituitary fossa. If the full length of both optic nerves is not included, the dose received by different volumes of optic nerve should be recorded to correlate with future patterns of relapse (no consensus). The CTV cranial should be modified to include the dural cuffs of cranial nerves as they pass through the skull base foramina. Attempts to spare the cochlea by excluding CSF within the internal auditory canal should be avoided. The CTV spinal should include the entire subarachnoid space, including nerve roots laterally. The lower limit of the spinal CTV is at the lower limit of the thecal sac, best visible on MRI scan. There is no need to include sacral root canals in the spinal CTV., Conclusion: This consensus guideline has the potential to improve consistency of craniospinal TV delineation in an era of high-precision radiotherapy. This proposal will be incorporated in the RTQA guidelines of future SIOPE-BTG trials using CSI., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

45. Universal field matching in craniospinal irradiation by a background-dose gradient-optimized method.

Author

Traneus E, Bizzocchi N, Fellin F, Rombi B, and Farace P

Subjects

Child, Humans, Organs at Risk radiation effects, Protons, Radiotherapy Dosage, Retrospective Studies, Brain Neoplasms radiotherapy, Craniospinal Irradiation methods, Craniospinal Irradiation standards, Radiotherapy Planning, Computer-Assisted methods, Radiotherapy, Intensity-Modulated methods, Radiotherapy, Intensity-Modulated standards

Abstract

Purpose: The gradient-optimized methods are overcoming the traditional feathering methods to plan field junctions in craniospinal irradiation. In this note, a new gradient-optimized technique, based on the use of a background dose, is described., Methods: Treatment planning was performed by RayStation (RaySearch Laboratories, Stockholm, Sweden) on the CT scans of a pediatric patient. Both proton (by pencil beam scanning) and photon (by volumetric modulated arc therapy) treatments were planned with three isocenters. An 'in silico' ideal background dose was created first to cover the upper-spinal target and to produce a perfect dose gradient along the upper and lower junction regions. Using it as background, the cranial and the lower-spinal beams were planned by inverse optimization to obtain dose coverage of their relevant targets and of the junction volumes. Finally, the upper-spinal beam was inversely planned after removal of the background dose and with the previously optimized beams switched on., Results: In both proton and photon plans, the optimized cranial and the lower-spinal beams produced a perfect linear gradient in the junction regions, complementary to that produced by the optimized upper-spinal beam. The final dose distributions showed a homogeneous coverage of the targets., Discussion: Our simple technique allowed to obtain high-quality gradients in the junction region. Such technique universally works for photons as well as protons and could be applicable to the TPSs that allow to manage a background dose., (© 2017 The Authors. Journal of Applied Clinical Medical Physics published by Wiley Periodicals, Inc. on behalf of American Association of Physicists in Medicine.)

Published

2018

46. Supine craniospinal irradiation in pediatric patients by proton pencil beam scanning.

Author

Farace P, Bizzocchi N, Righetto R, Fellin F, Fracchiolla F, Lorentini S, Widesott L, Algranati C, Rombi B, Vennarini S, Amichetti M, and Schwarz M

Subjects

Adolescent, Child, Child, Preschool, Female, Humans, Male, Organs at Risk, Quality Assurance, Health Care, Radiotherapy Planning, Computer-Assisted methods, Radiotherapy, Image-Guided, Craniospinal Irradiation methods, Patient Positioning, Proton Therapy methods

Abstract

Background and Purpose: Proton therapy is the emerging treatment modality for craniospinal irradiation (CSI) in pediatric patients. Herein, special methods adopted for CSI at proton Therapy Center of Trento by pencil beam scanning (PBS) are comprehensively described., Materials and Methods: Twelve pediatric patients were treated by proton PBS using two/three isocenters. Special methods refer to: (i) patient positioning in supine position on immobilization devices crossed by the beams; (ii) planning field-junctions via the ancillary-beam technique; (iii) achieving lens-sparing by three-beams whole-brain-irradiation; (iv) applying a movable-snout and beam-splitting technique to reduce the lateral penumbra. Patient-specific quality assurance (QA) program was performed using two-dimensional ion chamber array and γ-analysis. Daily kilovoltage alignment was performed., Results: PBS allowed to obtain optimal target coverage (mean D98%>98%) with reduced dose to organs-at-risk. Lens sparing was obtained (mean D1∼730cGyE). Reducing lateral penumbra decreased the dose to the kidneys (mean Dmean<600cGyE). After kilovoltage alignment, potential dose deviations in the upper and lower junctions were small (average 0.8% and 1.2% respectively). Due to imperfect modeling of range shifter, QA showed better agreements between measurements and calculations at depths >4cm (mean γ>95%) than at depths<4cm., Conclusions: The reported methods allowed to effectively perform proton PBS CSI., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

47. Proton radiotherapy for pediatric tumors: review of first clinical results.

Author

Rombi B, Vennarini S, Vinante L, Ravanelli D, and Amichetti M

Subjects

Child, Humans, Radiotherapy Dosage, Neoplasms radiotherapy, Proton Therapy

Abstract

Radiation therapy is a part of multidisciplinary management of several childhood cancers. Proton therapy is a new method of irradiation, which uses protons instead of photons. Proton radiation has been used safely and effectively for medulloblastoma, primitive neuro-ectodermal tumors, craniopharyngioma, ependymoma, germ cell intracranial tumors, low-grade glioma, retinoblastoma, rhabdomyosarcoma and other soft tissue sarcomas, Ewing's sarcoma and other bone sarcomas. Moreover, other possible applications are emerging, in particular for lymphoma and neuroblastoma. Although both photon and proton techniques allow similar target volume coverage, the main advantage of proton radiation therapy is to sparing of intermediate-to-low-dose to healthy tissues. This characteristic could translate into clinical reduction of side effects, including a lower risk for secondary cancers. The following review presents the state of the art of proton therapy in the treatment of pediatric malignancies.

Published

2014

48. Spot-scanning proton radiation therapy for pediatric chordoma and chondrosarcoma: clinical outcome of 26 patients treated at paul scherrer institute.

Author

Rombi B, Ares C, Hug EB, Schneider R, Goitein G, Staab A, Albertini F, Bolsi A, Lomax AJ, and Timmermann B

Subjects

Adolescent, Bone Neoplasms mortality, Bone Neoplasms pathology, Child, Child, Preschool, Chondrosarcoma mortality, Chondrosarcoma pathology, Chordoma mortality, Chordoma pathology, Dose Fractionation, Radiation, Female, Humans, Male, Proton Therapy adverse effects, Proton Therapy mortality, Relative Biological Effectiveness, Skull Base Neoplasms mortality, Skull Base Neoplasms pathology, Skull Base Neoplasms radiotherapy, Switzerland, Treatment Outcome, Tumor Burden, Young Adult, Bone Neoplasms radiotherapy, Chondrosarcoma radiotherapy, Chordoma radiotherapy, Proton Therapy methods

Abstract

Purpose: To evaluate the clinical results of fractionated spot-scanning proton radiation therapy (PT) in 26 pediatric patients treated at Paul Scherrer Institute for chordoma (CH) or chondrosarcoma (CS) of the skull base or axial skeleton., Methods and Materials: Between June 2000 and June 2010, 19 CH and 7 CS patients with tumors originating from the skull base (17) and the axial skeleton (9) were treated with PT. Mean age at the time of PT was 13.2 years. The mean prescribed dose was 74 Gy (relative biological effectiveness [RBE]) for CH and 66 Gy (RBE) for CS, at a dose of 1.8-2.0 Gy (RBE) per fraction., Results: Mean follow-up was 46 months. Actuarial 5-year local control (LC) rates were 81% for CH and 80% for CS. Actuarial 5-year overall survival (OS) was 89% for CH and 75% for CS. Two CH patients had local failures: one is alive with evidence of disease, while the other patient succumbed to local recurrence in the surgical pathway. One CS patient died of local progression of the disease. No high-grade late toxicities were observed., Conclusions: Spot-scanning PT for pediatric CH and CS patients resulted in excellent clinical outcomes with acceptable rates of late toxicity. Longer follow-up time and larger cohort are needed to fully assess tumor control and late effects of treatment., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

49. Proton radiotherapy for high-risk pediatric neuroblastoma: early outcomes and dose comparison.

Author

Hattangadi JA, Rombi B, Yock TI, Broussard G, Friedmann AM, Huang M, Chen YL, Lu HM, Kooy H, and MacDonald SM

Subjects

Child, Preschool, Combined Modality Therapy adverse effects, Combined Modality Therapy methods, Female, Humans, Induction Chemotherapy methods, Infant, Male, Neoplasm, Residual, Neuroblastoma diagnostic imaging, Neuroblastoma genetics, Neuroblastoma pathology, Neuroblastoma therapy, Organ Sparing Treatments methods, Organs at Risk, Photons therapeutic use, Protons adverse effects, Radiography, Radiotherapy Dosage, Radiotherapy, Conformal adverse effects, Radiotherapy, Intensity-Modulated adverse effects, Radiotherapy, Intensity-Modulated methods, Treatment Outcome, Tumor Burden, Neuroblastoma radiotherapy, Proton Therapy, Radiotherapy, Conformal methods

Abstract

Purpose: To report the early outcomes for children with high-risk neuroblastoma treated with proton radiotherapy (RT) and to compare the dose distributions for intensity-modulated photon RT (IMRT), three-dimensional conformal proton RT (3D-CPT), and intensity-modulated proton RT to the postoperative tumor bed., Methods and Materials: All patients with high-risk (International Neuroblastoma Staging System Stage III or IV) neuroblastoma treated between 2005 and 2010 at our institution were included. All patients received induction chemotherapy, surgical resection of residual disease, high-dose chemotherapy with stem cell rescue, and adjuvant 3D-CPT to the primary tumor sites. The patients were followed with clinical examinations, imaging, and laboratory testing every 6 months to monitor disease control and side effects. IMRT, 3D-CPT, and intensity-modulated proton RT plans were generated and compared for a representative case of adjuvant RT to the primary tumor bed followed by a boost., Results: Nine patients were treated with 3D-CPT. The median age at diagnosis was 2 years (range 10 months to 4 years), and all patients had Stage IV disease. All patients had unfavorable histologic characteristics (poorly differentiated histologic features in 8, N-Myc amplification in 6, and 1p/11q chromosomal abnormalities in 4). The median tumor size at diagnosis was 11.4 cm (range 7-16) in maximal dimension. At a median follow-up of 38 months (range 11-70), there were no local failures. Four patients developed distant failure, and, of these, two died of disease. Acute side effects included Grade 1 skin erythema in 5 patients and Grade 2 anorexia in 2 patients. Although comparable target coverage was achieved with all three modalities, proton therapy achieved substantial normal tissue sparing compared with IMRT. Intensity-modulated proton RT allowed additional sparing of the kidneys, lungs, and heart., Conclusions: Preliminary outcomes reveal excellent local control with proton therapy for high-risk neuroblastoma, although distant failures continu to occur. Dosimetric comparisons demonstrate the advantage of proton RT compared with IMRT in this setting, allowing more conformal treatment and better normal tissue sparing., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

50. Experimental verification of IMPT treatment plans in an anthropomorphic phantom in the presence of delivery uncertainties.

Author

Albertini F, Casiraghi M, Lorentini S, Rombi B, and Lomax AJ

Subjects

Humans, Radiotherapy Dosage, Phantoms, Imaging, Proton Therapy, Radiotherapy Planning, Computer-Assisted instrumentation, Radiotherapy, Intensity-Modulated methods, Uncertainty

Abstract

Clinically relevant intensity modulated proton therapy (IMPT) treatment plans were measured in a newly developed anthropomorphic phantom (i) to assess plan accuracy in the presence of high heterogeneity and (ii) to measure plan robustness in the case of treatment uncertainties (range and spatial). The new phantom consists of five different tissue substitute materials simulating different tissue types and was cut into sagittal planes so as to facilitate the verification of co-planar proton fields. GafChromic films were positioned in the different planes of the phantom, and 3D-IMPT and distal edge tracking (DET) plans were delivered to a volume simulating a skull base chordoma. In addition, treatments planned on CTs of the phantom with HU units modified were delivered to simulate systematic range uncertainties (range-error treatments). Finally, plans were delivered with the phantom rotated to simulate spatial errors. Results show excellent agreement between the calculated and the measured dose distribution: >99% and 98% of points with a gamma value <1 (3%/3 mm) for the 3D-IMPT and the DET plan, respectively. For both range and spatial errors, the 3D-IMPT plan was more robust than the DET plan. Both plans were more robust to range than to the spatial uncertainties. Finally, for range error treatments, measured distributions were compared to a model for predicting delivery errors in the treatment planning system. Good agreement has been found between the model and the measurements for both types of IMPT plan.

Published

2011