Your search keyword '"Lerousseau M"' showing total 29 results

1. Intelligence artificielle en radiothérapie : radiomique, pathomique, et prédiction de la survie et de la réponse aux traitements

Author

Sun, R., Lerousseau, M., Henry, T., Carré, A., Leroy, A., Estienne, T., Niyoteka, S., Bockel, S., Rouyar, A., Alvarez Andres, É., Benzazon, N., Battistella, E., Classe, M., Robert, C., Scoazec, J.Y., and Deutsch, É.

Published

2021

2. Investigation of radiomics based intra-patient inter-tumor heterogeneity and the impact of tumor subsampling strategies

Author

Henry, T., Sun, R., Lerousseau, M., Estienne, T., Robert, C., Besse, B., Robert, C., Paragios, N., and Deutsch, E.

Published

2022

3. Image-based multiplex immune profiling of cancer tissues: translational implications. A report of the International Immuno-oncology Biomarker Working Group on Breast Cancer

Author

Jahangir, CA, Page, DB, Broeckx, G, Gonzalez, CA, Burke, C, Murphy, C, Reis-Filho, JS, Ly, A, Harms, PW, Gupta, RR, Vieth, M, Hida, A, Kahila, M, Kos, Z, van Diest, PJ, Verbandt, S, Thagaard, J, Khiroya, R, Abduljabbar, K, Haab, GA, Acs, B, Adams, S, Almeida, JS, Alvarado-Cabrero, I, Azmoudeh-Ardalan, F, Badve, S, Baharun, NB, Bellolio, ER, Bheemaraju, V, Blenman, KRM, Fujimoto, LBM, Burgues, O, Chardas, A, Cheang, MCU, Ciompi, F, Cooper, LAD, Coosemans, A, Corredor, G, Portela, FLD, Deman, F, Demaria, S, Dudgeon, SN, Elghazawy, M, Fernandez-Martin, C, Fineberg, S, Fox, SB, Giltnane, JM, Gnjatic, S, Gonzalez-Ericsson, P, Grigoriadis, A, Halama, N, Hanna, MG, Harbhajanka, A, Hart, SN, Hartman, J, Hewitt, S, Horlings, HM, Husain, Z, Irshad, S, Janssen, EAM, Kataoka, TR, Kawaguchi, K, Khramtsov, A, Kiraz, U, Kirtani, P, Kodach, LL, Korski, K, Akturk, G, Scott, E, Kovacs, A, Laenkholm, A-V, Lang-Schwarz, C, Larsimont, D, Lennerz, JK, Lerousseau, M, Li, X, Madabhushi, A, Maley, SK, Narasimhamurthy, VM, Marks, DK, McDonald, ES, Mehrotra, R, Michiels, S, Kharidehal, D, Minhas, FUAA, Mittal, S, Moore, DA, Mushtaq, S, Nighat, H, Papathomas, T, Penault-Llorca, F, Perera, RD, Pinard, CJ, Pinto-Cardenas, JC, Pruneri, G, Pusztai, L, Rajpoot, NM, Rapoport, BL, Rau, TT, Ribeiro, JM, Rimm, D, Vincent-Salomon, A, Saltz, J, Sayed, S, Hytopoulos, E, Mahon, S, Siziopikou, KP, Sotiriou, C, Stenzinger, A, Sughayer, MA, Sur, D, Symmans, F, Tanaka, S, Taxter, T, Tejpar, S, Teuwen, J, Thompson, EA, Tramm, T, Tran, WT, van Der Laak, J, Verghese, GE, Viale, G, Wahab, N, Walter, T, Waumans, Y, Wen, HY, Yang, W, Yuan, Y, Bartlett, J, Loibl, S, Denkert, C, Savas, P, Loi, S, Stovgaard, ES, Salgado, R, Gallagher, WM, Rahman, A, Jahangir, CA, Page, DB, Broeckx, G, Gonzalez, CA, Burke, C, Murphy, C, Reis-Filho, JS, Ly, A, Harms, PW, Gupta, RR, Vieth, M, Hida, A, Kahila, M, Kos, Z, van Diest, PJ, Verbandt, S, Thagaard, J, Khiroya, R, Abduljabbar, K, Haab, GA, Acs, B, Adams, S, Almeida, JS, Alvarado-Cabrero, I, Azmoudeh-Ardalan, F, Badve, S, Baharun, NB, Bellolio, ER, Bheemaraju, V, Blenman, KRM, Fujimoto, LBM, Burgues, O, Chardas, A, Cheang, MCU, Ciompi, F, Cooper, LAD, Coosemans, A, Corredor, G, Portela, FLD, Deman, F, Demaria, S, Dudgeon, SN, Elghazawy, M, Fernandez-Martin, C, Fineberg, S, Fox, SB, Giltnane, JM, Gnjatic, S, Gonzalez-Ericsson, P, Grigoriadis, A, Halama, N, Hanna, MG, Harbhajanka, A, Hart, SN, Hartman, J, Hewitt, S, Horlings, HM, Husain, Z, Irshad, S, Janssen, EAM, Kataoka, TR, Kawaguchi, K, Khramtsov, A, Kiraz, U, Kirtani, P, Kodach, LL, Korski, K, Akturk, G, Scott, E, Kovacs, A, Laenkholm, A-V, Lang-Schwarz, C, Larsimont, D, Lennerz, JK, Lerousseau, M, Li, X, Madabhushi, A, Maley, SK, Narasimhamurthy, VM, Marks, DK, McDonald, ES, Mehrotra, R, Michiels, S, Kharidehal, D, Minhas, FUAA, Mittal, S, Moore, DA, Mushtaq, S, Nighat, H, Papathomas, T, Penault-Llorca, F, Perera, RD, Pinard, CJ, Pinto-Cardenas, JC, Pruneri, G, Pusztai, L, Rajpoot, NM, Rapoport, BL, Rau, TT, Ribeiro, JM, Rimm, D, Vincent-Salomon, A, Saltz, J, Sayed, S, Hytopoulos, E, Mahon, S, Siziopikou, KP, Sotiriou, C, Stenzinger, A, Sughayer, MA, Sur, D, Symmans, F, Tanaka, S, Taxter, T, Tejpar, S, Teuwen, J, Thompson, EA, Tramm, T, Tran, WT, van Der Laak, J, Verghese, GE, Viale, G, Wahab, N, Walter, T, Waumans, Y, Wen, HY, Yang, W, Yuan, Y, Bartlett, J, Loibl, S, Denkert, C, Savas, P, Loi, S, Stovgaard, ES, Salgado, R, Gallagher, WM, and Rahman, A

Published

2024

4. Pitfalls in machine learning-based assessment of tumor-infiltrating lymphocytes in breast cancer: a report of the international immuno-oncology biomarker working group

Author

Thagaard, J, Broeckx, G, Page, DB, Jahangir, CA, Verbandt, S, Kos, Z, Gupta, R, Khiroya, R, Abduljabbar, K, Acosta Haab, G, Acs, B, Akturk, G, Almeida, JS, Alvarado-Cabrero, I, Amgad, M, Azmoudeh-Ardalan, F, Badve, S, Baharun, NB, Balslev, E, Bellolio, ER, Bheemaraju, V, Blenman, KRM, Botinelly Mendonca Fujimoto, L, Bouchmaa, N, Burgues, O, Chardas, A, Cheang, MU, Ciompi, F, Cooper, LAD, Coosemans, A, Corredor, G, Dahl, AB, Dantas Portela, FL, Deman, F, Demaria, S, Dore Hansen, J, Dudgeon, SN, Ebstrup, T, Elghazawy, M, Fernandez-Martin, C, Fox, SB, Gallagher, WM, Giltnane, JM, Gnjatic, S, Gonzalez-Ericsson, P, Grigoriadis, A, Halama, N, Hanna, MG, Harbhajanka, A, Hart, SN, Hartman, J, Hauberg, S, Hewitt, S, Hida, A, Horlings, HM, Husain, Z, Hytopoulos, E, Irshad, S, Janssen, EAM, Kahila, M, Kataoka, TR, Kawaguchi, K, Kharidehal, D, Khramtsov, A, Kiraz, U, Kirtani, P, Kodach, LL, Korski, K, Kovacs, A, Laenkholm, A-V, Lang-Schwarz, C, Larsimont, D, Lennerz, JK, Lerousseau, M, Li, X, Ly, A, Madabhushi, A, Maley, SK, Manur Narasimhamurthy, V, Marks, DK, McDonald, ES, Mehrotra, R, Michiels, S, Minhas, FUAA, Mittal, S, Moore, DA, Mushtaq, S, Nighat, H, Papathomas, T, Penault-Llorca, F, Perera, RD, Pinard, CJ, Pinto-Cardenas, JC, Pruneri, G, Pusztai, L, Rahman, A, Rajpoot, NM, Rapoport, BL, Rau, TT, Reis-Filho, JS, Ribeiro, JM, Rimm, D, Roslind, A, Vincent-Salomon, A, Salto-Tellez, M, Saltz, J, Sayed, S, Scott, E, Siziopikou, KP, Sotiriou, C, Stenzinger, A, Sughayer, MA, Sur, D, Fineberg, S, Symmans, F, Tanaka, S, Taxter, T, Tejpar, S, Teuwen, J, Thompson, EA, Tramm, T, Tran, WT, van Der Laak, J, van Diest, PJ, Verghese, GE, Viale, G, Vieth, M, Wahab, N, Walter, T, Waumans, Y, Wen, HY, Yang, W, Yuan, Y, Zin, RM, Adams, S, Bartlett, J, Loibl, S, Denkert, C, Savas, P, Loi, S, Salgado, R, Specht Stovgaard, E, Thagaard, J, Broeckx, G, Page, DB, Jahangir, CA, Verbandt, S, Kos, Z, Gupta, R, Khiroya, R, Abduljabbar, K, Acosta Haab, G, Acs, B, Akturk, G, Almeida, JS, Alvarado-Cabrero, I, Amgad, M, Azmoudeh-Ardalan, F, Badve, S, Baharun, NB, Balslev, E, Bellolio, ER, Bheemaraju, V, Blenman, KRM, Botinelly Mendonca Fujimoto, L, Bouchmaa, N, Burgues, O, Chardas, A, Cheang, MU, Ciompi, F, Cooper, LAD, Coosemans, A, Corredor, G, Dahl, AB, Dantas Portela, FL, Deman, F, Demaria, S, Dore Hansen, J, Dudgeon, SN, Ebstrup, T, Elghazawy, M, Fernandez-Martin, C, Fox, SB, Gallagher, WM, Giltnane, JM, Gnjatic, S, Gonzalez-Ericsson, P, Grigoriadis, A, Halama, N, Hanna, MG, Harbhajanka, A, Hart, SN, Hartman, J, Hauberg, S, Hewitt, S, Hida, A, Horlings, HM, Husain, Z, Hytopoulos, E, Irshad, S, Janssen, EAM, Kahila, M, Kataoka, TR, Kawaguchi, K, Kharidehal, D, Khramtsov, A, Kiraz, U, Kirtani, P, Kodach, LL, Korski, K, Kovacs, A, Laenkholm, A-V, Lang-Schwarz, C, Larsimont, D, Lennerz, JK, Lerousseau, M, Li, X, Ly, A, Madabhushi, A, Maley, SK, Manur Narasimhamurthy, V, Marks, DK, McDonald, ES, Mehrotra, R, Michiels, S, Minhas, FUAA, Mittal, S, Moore, DA, Mushtaq, S, Nighat, H, Papathomas, T, Penault-Llorca, F, Perera, RD, Pinard, CJ, Pinto-Cardenas, JC, Pruneri, G, Pusztai, L, Rahman, A, Rajpoot, NM, Rapoport, BL, Rau, TT, Reis-Filho, JS, Ribeiro, JM, Rimm, D, Roslind, A, Vincent-Salomon, A, Salto-Tellez, M, Saltz, J, Sayed, S, Scott, E, Siziopikou, KP, Sotiriou, C, Stenzinger, A, Sughayer, MA, Sur, D, Fineberg, S, Symmans, F, Tanaka, S, Taxter, T, Tejpar, S, Teuwen, J, Thompson, EA, Tramm, T, Tran, WT, van Der Laak, J, van Diest, PJ, Verghese, GE, Viale, G, Vieth, M, Wahab, N, Walter, T, Waumans, Y, Wen, HY, Yang, W, Yuan, Y, Zin, RM, Adams, S, Bartlett, J, Loibl, S, Denkert, C, Savas, P, Loi, S, Salgado, R, and Specht Stovgaard, E

Published

2023

5. Spatial analyses of immune cell infiltration in cancer: current methods and future directions. A report of the International Immuno-Oncology Biomarker Working Group on Breast Cancer

Author

Page, DB, Broeckx, G, Jahangir, CA, Jahangir, C, Verbandt, S, Gupta, RR, Thagaard, J, Khiroya, R, Kos, Z, Abduljabbar, K, Acosta Haab, G, Acs, B, Almeida, JS, Alvarado-Cabrero, I, Azmoudeh-Ardalan, F, Badve, S, Baharun, NB, Bellolio, ER, Bheemaraju, V, Blenman, KRM, Botinelly Mendonca Fujimoto, L, Burgues, O, Cheang, MCU, Ciompi, F, Cooper, LAD, Coosemans, A, Corredor, G, Dantas Portela, FL, Deman, F, Demaria, S, Dudgeon, SN, Elghazawy, M, Ely, S, Fernandez-Martin, C, Fineberg, S, Fox, SB, Gallagher, WM, Giltnane, JM, Gnjatic, S, Gonzalez-Ericsson, P, Grigoriadis, A, Halama, N, Hanna, MG, Harbhajanka, A, Hardas, A, Hart, SN, Hartman, J, Hewitt, S, Hida, A, Horlings, HM, Husain, Z, Hytopoulos, E, Irshad, S, Janssen, EAM, Kahila, M, Kataoka, TR, Kawaguchi, K, Kharidehal, D, Khramtsov, A, Kiraz, U, Kirtani, P, Kodach, LL, Korski, K, Kovacs, A, Laenkholm, A-V, Lang-Schwarz, C, Larsimont, D, Lennerz, JK, Lerousseau, M, Li, X, Ly, A, Madabhushi, A, Maley, SK, Manur Narasimhamurthy, V, Marks, DK, McDonald, ES, Mehrotra, R, Michiels, S, Minhas, FUAA, Mittal, S, Moore, DA, Mushtaq, S, Nighat, H, Papathomas, T, Penault-Llorca, F, Perera, RD, Pinard, CJ, Pinto-Cardenas, JC, Pruneri, G, Pusztai, L, Rahman, A, Rajpoot, NM, Rapoport, BL, Rau, TT, Reis-Filho, JS, Ribeiro, JM, Rimm, D, Salomon, A-V, Salto-Tellez, M, Saltz, J, Sayed, S, Siziopikou, KP, Sotiriou, C, Stenzinger, A, Sughayer, MA, Sur, D, Symmans, F, Tanaka, S, Taxter, T, Tejpar, S, Teuwen, J, Thompson, EA, Tramm, T, Tran, WT, van Der Laak, J, van Diest, PJ, Verghese, GE, Viale, G, Vieth, M, Wahab, N, Walter, T, Waumans, Y, Wen, HY, Yang, W, Yuan, Y, Adams, S, Bartlett, JMS, Loibl, S, Denkert, C, Savas, P, Loi, S, Salgado, R, Specht Stovgaard, E, Akturk, G, Bouchmaa, N, Page, DB, Broeckx, G, Jahangir, CA, Jahangir, C, Verbandt, S, Gupta, RR, Thagaard, J, Khiroya, R, Kos, Z, Abduljabbar, K, Acosta Haab, G, Acs, B, Almeida, JS, Alvarado-Cabrero, I, Azmoudeh-Ardalan, F, Badve, S, Baharun, NB, Bellolio, ER, Bheemaraju, V, Blenman, KRM, Botinelly Mendonca Fujimoto, L, Burgues, O, Cheang, MCU, Ciompi, F, Cooper, LAD, Coosemans, A, Corredor, G, Dantas Portela, FL, Deman, F, Demaria, S, Dudgeon, SN, Elghazawy, M, Ely, S, Fernandez-Martin, C, Fineberg, S, Fox, SB, Gallagher, WM, Giltnane, JM, Gnjatic, S, Gonzalez-Ericsson, P, Grigoriadis, A, Halama, N, Hanna, MG, Harbhajanka, A, Hardas, A, Hart, SN, Hartman, J, Hewitt, S, Hida, A, Horlings, HM, Husain, Z, Hytopoulos, E, Irshad, S, Janssen, EAM, Kahila, M, Kataoka, TR, Kawaguchi, K, Kharidehal, D, Khramtsov, A, Kiraz, U, Kirtani, P, Kodach, LL, Korski, K, Kovacs, A, Laenkholm, A-V, Lang-Schwarz, C, Larsimont, D, Lennerz, JK, Lerousseau, M, Li, X, Ly, A, Madabhushi, A, Maley, SK, Manur Narasimhamurthy, V, Marks, DK, McDonald, ES, Mehrotra, R, Michiels, S, Minhas, FUAA, Mittal, S, Moore, DA, Mushtaq, S, Nighat, H, Papathomas, T, Penault-Llorca, F, Perera, RD, Pinard, CJ, Pinto-Cardenas, JC, Pruneri, G, Pusztai, L, Rahman, A, Rajpoot, NM, Rapoport, BL, Rau, TT, Reis-Filho, JS, Ribeiro, JM, Rimm, D, Salomon, A-V, Salto-Tellez, M, Saltz, J, Sayed, S, Siziopikou, KP, Sotiriou, C, Stenzinger, A, Sughayer, MA, Sur, D, Symmans, F, Tanaka, S, Taxter, T, Tejpar, S, Teuwen, J, Thompson, EA, Tramm, T, Tran, WT, van Der Laak, J, van Diest, PJ, Verghese, GE, Viale, G, Vieth, M, Wahab, N, Walter, T, Waumans, Y, Wen, HY, Yang, W, Yuan, Y, Adams, S, Bartlett, JMS, Loibl, S, Denkert, C, Savas, P, Loi, S, Salgado, R, Specht Stovgaard, E, Akturk, G, and Bouchmaa, N

Published

2023

6. Pitfalls in machine learning-based assessment of tumor-infiltrating lymphocytes in breast cancer: a report of the international immuno-oncology biomarker working group.

Author

Thagaard, J., Broeckx, G., Page, D.B., Jahangir, C.A., Verbandt, S., Kos, Z., Gupta, R., Khiroya, R., AbdulJabbar, K., Haab, G.A., Acs, B., Akturk, G., Almeida, J.S., Alvarado-Cabrero, I., Amgad, M., Azmoudeh-Ardalan, F., Badve, S., Baharun, N.B., Balslev, E., Bellolio, E.R., Bheemaraju, V., Blenman, K.R., Botinelly Mendonça Fujimoto, L., Bouchmaa, N., Burgues, O., Chardas, A., Chon U Cheang, M., Ciompi, F., Cooper, L.A., Coosemans, A., Corredor, G., Dahl, A.B., Dantas Portela, F.L., Deman, F., Demaria, S., Doré Hansen, J., Dudgeon, S.N., Ebstrup, T., Elghazawy, M., Fernandez-Martín, C., Fox, S.B., Gallagher, W.M., Giltnane, J.M., Gnjatic, S., Gonzalez-Ericsson, P.I., Grigoriadis, A., Halama, N., Hanna, M.G., Harbhajanka, A., Hart, S.N., Hartman, J., Hauberg, S., Hewitt, S., Hida, A.I., Horlings, H.M., Husain, Z., Hytopoulos, E., Irshad, S., Janssen, E.a, Kahila, M., Kataoka, T.R., Kawaguchi, K., Kharidehal, D., Khramtsov, A.I., Kiraz, U., Kirtani, P., Kodach, L.L., Korski, K., Kovács, A., Laenkholm, A.V., Lang-Schwarz, C., Larsimont, D., Lennerz, J.K., Lerousseau, M., Li, Xiaoxian, Ly, Amy, Madabhushi, A., Maley, S.K., Manur Narasimhamurthy, V., Marks, D.K., McDonald, E.S., Mehrotra, R., Michiels, S., Minhas, F.U.A.A., Mittal, S., Moore, D.A., Mushtaq, S., Nighat, H., Papathomas, T., Penault-Llorca, F., Perera, R.D., Pinard, C.J., Pinto-Cardenas, J.C., Pruneri, G., Pusztai, L., Rahman, A., Rajpoot, N.M., Rapoport, B.L., Rau, T.T., Reis-Filho, J.S., Ribeiro, J.M., Rimm, D., Roslind, A., Vincent-Salomon, A., Salto-Tellez, M., Saltz, J., Sayed, S., Scott, E., Siziopikou, K.P., Sotiriou, C., Stenzinger, A., Sughayer, M.A., Sur, D., Fineberg, S., Symmans, F., Tanaka, S., Taxter, T., Tejpar, S., Teuwen, J., Thompson, E.A., Tramm, T., Tran, W.T., Laak, J.A.W.M. van der, Diest, P.J. van, Verghese, G.E., Viale, G., Vieth, M., Wahab, N., Walter, T., Waumans, Y., Wen, H.Y., Yang, W, Yuan, Y., Zin, R.M., Adams, S., Bartlett, J., Loibl, S., Denkert, C., Savas, P., Loi, S., Salgado, R., Specht Stovgaard, E., Thagaard, J., Broeckx, G., Page, D.B., Jahangir, C.A., Verbandt, S., Kos, Z., Gupta, R., Khiroya, R., AbdulJabbar, K., Haab, G.A., Acs, B., Akturk, G., Almeida, J.S., Alvarado-Cabrero, I., Amgad, M., Azmoudeh-Ardalan, F., Badve, S., Baharun, N.B., Balslev, E., Bellolio, E.R., Bheemaraju, V., Blenman, K.R., Botinelly Mendonça Fujimoto, L., Bouchmaa, N., Burgues, O., Chardas, A., Chon U Cheang, M., Ciompi, F., Cooper, L.A., Coosemans, A., Corredor, G., Dahl, A.B., Dantas Portela, F.L., Deman, F., Demaria, S., Doré Hansen, J., Dudgeon, S.N., Ebstrup, T., Elghazawy, M., Fernandez-Martín, C., Fox, S.B., Gallagher, W.M., Giltnane, J.M., Gnjatic, S., Gonzalez-Ericsson, P.I., Grigoriadis, A., Halama, N., Hanna, M.G., Harbhajanka, A., Hart, S.N., Hartman, J., Hauberg, S., Hewitt, S., Hida, A.I., Horlings, H.M., Husain, Z., Hytopoulos, E., Irshad, S., Janssen, E.a, Kahila, M., Kataoka, T.R., Kawaguchi, K., Kharidehal, D., Khramtsov, A.I., Kiraz, U., Kirtani, P., Kodach, L.L., Korski, K., Kovács, A., Laenkholm, A.V., Lang-Schwarz, C., Larsimont, D., Lennerz, J.K., Lerousseau, M., Li, Xiaoxian, Ly, Amy, Madabhushi, A., Maley, S.K., Manur Narasimhamurthy, V., Marks, D.K., McDonald, E.S., Mehrotra, R., Michiels, S., Minhas, F.U.A.A., Mittal, S., Moore, D.A., Mushtaq, S., Nighat, H., Papathomas, T., Penault-Llorca, F., Perera, R.D., Pinard, C.J., Pinto-Cardenas, J.C., Pruneri, G., Pusztai, L., Rahman, A., Rajpoot, N.M., Rapoport, B.L., Rau, T.T., Reis-Filho, J.S., Ribeiro, J.M., Rimm, D., Roslind, A., Vincent-Salomon, A., Salto-Tellez, M., Saltz, J., Sayed, S., Scott, E., Siziopikou, K.P., Sotiriou, C., Stenzinger, A., Sughayer, M.A., Sur, D., Fineberg, S., Symmans, F., Tanaka, S., Taxter, T., Tejpar, S., Teuwen, J., Thompson, E.A., Tramm, T., Tran, W.T., Laak, J.A.W.M. van der, Diest, P.J. van, Verghese, G.E., Viale, G., Vieth, M., Wahab, N., Walter, T., Waumans, Y., Wen, H.Y., Yang, W, Yuan, Y., Zin, R.M., Adams, S., Bartlett, J., Loibl, S., Denkert, C., Savas, P., Loi, S., Salgado, R., and Specht Stovgaard, E.

Abstract

01 augustus 2023, Contains fulltext : 296181.pdf (Publisher’s version ) (Open Access), The clinical significance of the tumor-immune interaction in breast cancer is now established, and tumor-infiltrating lymphocytes (TILs) have emerged as predictive and prognostic biomarkers for patients with triple-negative (estrogen receptor, progesterone receptor, and HER2-negative) breast cancer and HER2-positive breast cancer. How computational assessments of TILs might complement manual TIL assessment in trial and daily practices is currently debated. Recent efforts to use machine learning (ML) to automatically evaluate TILs have shown promising results. We review state-of-the-art approaches and identify pitfalls and challenges of automated TIL evaluation by studying the root cause of ML discordances in comparison to manual TIL quantification. We categorize our findings into four main topics: (1) technical slide issues, (2) ML and image analysis aspects, (3) data challenges, and (4) validation issues. The main reason for discordant assessments is the inclusion of false-positive areas or cells identified by performance on certain tissue patterns or design choices in the computational implementation. To aid the adoption of ML for TIL assessment, we provide an in-depth discussion of ML and image analysis, including validation issues that need to be considered before reliable computational reporting of TILs can be incorporated into the trial and routine clinical management of patients with triple-negative breast cancer. © 2023 The Authors. The Journal of Pathology published by John Wiley & Sons Ltd on behalf of The Pathological Society of Great Britain and Ireland.

Published

2023

7. Spatial analyses of immune cell infiltration in cancer: current methods and future directions. A report of the International Immuno-Oncology Biomarker Working Group on Breast Cancer.

Author

Page, D.B., Broeckx, G., Jahangir, C.A., Verbandt, S., Gupta, R.R., Thagaard, J., Khiroya, R., Kos, Z., AbdulJabbar, K., Acosta Haab, G., Acs, B., Akturk, G., Almeida, J.S., Alvarado-Cabrero, I., Azmoudeh-Ardalan, F., Badve, S., Baharun, N.B., Bellolio, E.R., Bheemaraju, V., Blenman, K.R., Botinelly Mendonça Fujimoto, L., Bouchmaa, N., Burgues, O., Cheang, M.C.U., Ciompi, F., Cooper, L.A., Coosemans, A., Corredor, G., Dantas Portela, F.L., Deman, F., Demaria, S., Dudgeon, S.N., Elghazawy, M., Ely, S., Fernandez-Martín, C., Fineberg, S., Fox, S.B., Gallagher, W.M., Giltnane, J.M., Gnjatic, S., Gonzalez-Ericsson, P.I., Grigoriadis, A., Halama, N., Hanna, M.G., Harbhajanka, A., Hardas, A., Hart, S.N., Hartman, J., Hewitt, S., Hida, A.I., Horlings, H.M., Husain, Z., Hytopoulos, E., Irshad, S., Janssen, E.a, Kahila, M., Kataoka, T.R., Kawaguchi, K., Kharidehal, D., Khramtsov, A.I., Kiraz, U., Kirtani, P., Kodach, L.L., Korski, K., Kovács, A., Laenkholm, A.V., Lang-Schwarz, C., Larsimont, D., Lennerz, J.K., Lerousseau, M., Li, Xiaoxian, Ly, Amy, Madabhushi, A., Maley, S.K., Manur Narasimhamurthy, V., Marks, D.K., McDonald, E.S., Mehrotra, R., Michiels, S., Minhas, F.U.A.A., Mittal, S., Moore, D.A., Mushtaq, S., Nighat, H., Papathomas, T., Penault-Llorca, F., Perera, R.D., Pinard, C.J., Pinto-Cardenas, J.C., Pruneri, G., Pusztai, L., Rahman, A., Rajpoot, N.M., Rapoport, B.L., Rau, T.T., Reis-Filho, J.S., Ribeiro, J.M., Rimm, D., Vincent-Salomon, A., Salto-Tellez, M., Saltz, J., Sayed, S., Siziopikou, K.P., Sotiriou, C., Stenzinger, A., Sughayer, M.A., Sur, D., Symmans, F., Tanaka, S., Taxter, T., Tejpar, S., Teuwen, J., Thompson, E.A., Tramm, T., Tran, W.T., Laak, J.A.W.M. van der, Diest, P.J. van, Verghese, G.E., Viale, G., Vieth, M., Wahab, N., Walter, T., Waumans, Y., Wen, H.Y., Yang, W, Yuan, Y., Adams, S., Bartlett, J.M.S., Loibl, S., Denkert, C., Savas, P., Loi, S., Salgado, R., Specht Stovgaard, E., Page, D.B., Broeckx, G., Jahangir, C.A., Verbandt, S., Gupta, R.R., Thagaard, J., Khiroya, R., Kos, Z., AbdulJabbar, K., Acosta Haab, G., Acs, B., Akturk, G., Almeida, J.S., Alvarado-Cabrero, I., Azmoudeh-Ardalan, F., Badve, S., Baharun, N.B., Bellolio, E.R., Bheemaraju, V., Blenman, K.R., Botinelly Mendonça Fujimoto, L., Bouchmaa, N., Burgues, O., Cheang, M.C.U., Ciompi, F., Cooper, L.A., Coosemans, A., Corredor, G., Dantas Portela, F.L., Deman, F., Demaria, S., Dudgeon, S.N., Elghazawy, M., Ely, S., Fernandez-Martín, C., Fineberg, S., Fox, S.B., Gallagher, W.M., Giltnane, J.M., Gnjatic, S., Gonzalez-Ericsson, P.I., Grigoriadis, A., Halama, N., Hanna, M.G., Harbhajanka, A., Hardas, A., Hart, S.N., Hartman, J., Hewitt, S., Hida, A.I., Horlings, H.M., Husain, Z., Hytopoulos, E., Irshad, S., Janssen, E.a, Kahila, M., Kataoka, T.R., Kawaguchi, K., Kharidehal, D., Khramtsov, A.I., Kiraz, U., Kirtani, P., Kodach, L.L., Korski, K., Kovács, A., Laenkholm, A.V., Lang-Schwarz, C., Larsimont, D., Lennerz, J.K., Lerousseau, M., Li, Xiaoxian, Ly, Amy, Madabhushi, A., Maley, S.K., Manur Narasimhamurthy, V., Marks, D.K., McDonald, E.S., Mehrotra, R., Michiels, S., Minhas, F.U.A.A., Mittal, S., Moore, D.A., Mushtaq, S., Nighat, H., Papathomas, T., Penault-Llorca, F., Perera, R.D., Pinard, C.J., Pinto-Cardenas, J.C., Pruneri, G., Pusztai, L., Rahman, A., Rajpoot, N.M., Rapoport, B.L., Rau, T.T., Reis-Filho, J.S., Ribeiro, J.M., Rimm, D., Vincent-Salomon, A., Salto-Tellez, M., Saltz, J., Sayed, S., Siziopikou, K.P., Sotiriou, C., Stenzinger, A., Sughayer, M.A., Sur, D., Symmans, F., Tanaka, S., Taxter, T., Tejpar, S., Teuwen, J., Thompson, E.A., Tramm, T., Tran, W.T., Laak, J.A.W.M. van der, Diest, P.J. van, Verghese, G.E., Viale, G., Vieth, M., Wahab, N., Walter, T., Waumans, Y., Wen, H.Y., Yang, W, Yuan, Y., Adams, S., Bartlett, J.M.S., Loibl, S., Denkert, C., Savas, P., Loi, S., Salgado, R., and Specht Stovgaard, E.

Abstract

01 augustus 2023, Contains fulltext : 296131.pdf (Publisher’s version ) (Closed access), Modern histologic imaging platforms coupled with machine learning methods have provided new opportunities to map the spatial distribution of immune cells in the tumor microenvironment. However, there exists no standardized method for describing or analyzing spatial immune cell data, and most reported spatial analyses are rudimentary. In this review, we provide an overview of two approaches for reporting and analyzing spatial data (raster versus vector-based). We then provide a compendium of spatial immune cell metrics that have been reported in the literature, summarizing prognostic associations in the context of a variety of cancers. We conclude by discussing two well-described clinical biomarkers, the breast cancer stromal tumor infiltrating lymphocytes score and the colon cancer Immunoscore, and describe investigative opportunities to improve clinical utility of these spatial biomarkers. © 2023 The Pathological Society of Great Britain and Ireland.

Published

2023

8. 1070P Previous viral infections assessed by pan-virus phage immunoprecipitation sequencing (PhIP-Seq) predict response to immune checkpoint blockers (ICBs) in non-small cell lung cancer (NSCLC)

Author

Dall'Olio, F.G., primary, Lerousseau, M., additional, Roman, G., additional, Danlos, F-X., additional, Aldea, M., additional, Chaput-Gras, N., additional, Planchard, D., additional, Barlesi, F., additional, Hulett, T., additional, Marabelle, A., additional, and Besse, B., additional

Published

2022

9. PO-1623 Characterisation of synthetic CTs clinical quality: which gamma indices to evaluate in practice?

Author

Alvarez Andres, E., Gasnier, A., Veres, C., Dhermain, F., Corbin, S., Auville, F., Biron, B., Vatonne, A., Henry, T., Estienne, T., Lerousseau, M., Carré, A., Fidon, L., Deutsch, E., Paragios, N., and Robert, C.

Published

2022

10. PO-1613 AI-driven combined deformable registration and image synthesis between radiology and histopathology

Author

Leroy, A., primary, Lerousseau, M., additional, Henry, T., additional, Estienne, T., additional, Classe, M., additional, Paragios, N., additional, Deutsch, E., additional, and Grégoire, V., additional

Published

2022

11. PH-0652 Synthetic CT from MRI with deep learning: Assessing the clinical impact of generated errors

Author

Alvarez Andres, E., Gasnier, A., Veres, C., Dhermain, F., Corbin, S., Auville, F., Biron, B., Vatonne, A., Henry, T., Estienne, T., Lerousseau, M., Fidon, L., Deutsch, E., Paragios, N., and Robert, C.

Published

2021

12. OC-0522 Cell-Rad: Towards Histology-driven Radiation Oncology from Multi-Parametric MRI

Author

Leroy, A., primary, Shreshtha, K., additional, Lerousseau, M., additional, Henry, T., additional, Estienne, T., additional, Classe, M., additional, Paragios, N., additional, Deutsch, E., additional, and Grégoire, V., additional

Published

2021

13. PO-1872 Implementation of semi-automated restricted IMRT and comparison to 3DCRT and VMAT for breast cancer

Author

Milewski, C., primary, Chéve, M., additional, Fournier-Bidoz, N., additional, Lerousseau, M., additional, Deutsch, E., additional, Louvel, G., additional, Rivera, S., additional, and Auzac, G., additional

Published

2021

14. PO-1702: Optimizing the generation of brain pseudo-CT from MRI based on a highly efficient 3D neural network

Author

Alvarez Andres, E., primary, Fidon, L., additional, Vakalopoulou, M., additional, Lerousseau, M., additional, Carré, A., additional, Sun, R., additional, Beaudre, A., additional, Deutsch, E., additional, Paragios, N., additional, and Robert, C., additional

Published

2020

15. PH-0532: Standardization of brain MRI across machines and protocols: bridging the gap for MRI-based radiomics

Author

Carré, A., primary, Klausner, G., additional, Edjlali, M., additional, Lerousseau, M., additional, Briend-Diop, J., additional, Sun, R., additional, Ammari, S., additional, Reuzé, S., additional, Alvarez-Andres, E., additional, Estienne, T., additional, Niyoteka, S., additional, Battistella, E., additional, Vakalopoulou, M., additional, Dhermain, F., additional, Paragios, N., additional, Deutsch, E., additional, Oppenheim, C., additional, Pallud, J., additional, and Robert, C., additional

Published

2020

16. PD-0425: Radiomics for selection of patients treated with immuno-radiotherapy: pooled analysis from 6 studies

Author

Sun, R., primary, Sundahl, N., additional, Hecht, M., additional, Putz, F., additional, Lancia, A., additional, Milic, M., additional, Carré, A., additional, Lerousseau, M., additional, Theo, E., additional, Battistella, E., additional, Andres, E. Alvarez, additional, Louvel, G., additional, Durand-Labrunie, J., additional, Bockel, S., additional, Bahleda, R., additional, Robert, C., additional, Boutros, C., additional, Vakalopoulou, M., additional, Paragios, N., additional, Frey, B., additional, Massard, C., additional, Fietkau, R., additional, Ost, P., additional, Gaipl, U., additional, and Deutsch, E., additional

Published

2020

17. Evaluation of a radiomic signature of CD8 cells in patients treated with immunotherapy-radiotherapy in three clinical trials

Author

Sun, R., primary, Lancia, A., additional, Sundahl, N.L., additional, Milic, M., additional, Carre, A., additional, Lerousseau, M., additional, Estienne, T., additional, Battistella, E., additional, Klausner, G., additional, Bahleda, R., additional, Alvarez-Andres, E., additional, Robert, C., additional, Boutros, C., additional, Vakalopoulou, M., additional, Paragios, N., additional, Ost, P., additional, Massard, C., additional, and Deutsch, E., additional

Published

2019

18. 136P - Evaluation of a radiomic signature of CD8 cells in patients treated with immunotherapy-radiotherapy in three clinical trials

Author

Sun, R., Lancia, A., Sundahl, N.L., Milic, M., Carre, A., Lerousseau, M., Estienne, T., Battistella, E., Klausner, G., Bahleda, R., Alvarez-Andres, E., Robert, C., Boutros, C., Vakalopoulou, M., Paragios, N., Ost, P., Massard, C., and Deutsch, E.

Published

2019

19. Integration of clinical, pathological, radiological, and transcriptomic data improves prediction for first-line immunotherapy outcome in metastatic non-small cell lung cancer.

Author

Captier N, Lerousseau M, Orlhac F, Hovhannisyan-Baghdasarian N, Luporsi M, Woff E, Lagha S, Salamoun Feghali P, Lonjou C, Beaulaton C, Zinovyev A, Salmon H, Walter T, Buvat I, Girard N, and Barillot E

Subjects

Humans, Female, Male, Middle Aged, Aged, Machine Learning, Treatment Outcome, B7-H1 Antigen metabolism, B7-H1 Antigen genetics, Positron-Emission Tomography methods, Gene Expression Profiling, Carcinoma, Non-Small-Cell Lung genetics, Carcinoma, Non-Small-Cell Lung pathology, Carcinoma, Non-Small-Cell Lung therapy, Carcinoma, Non-Small-Cell Lung diagnostic imaging, Lung Neoplasms genetics, Lung Neoplasms pathology, Lung Neoplasms therapy, Lung Neoplasms diagnostic imaging, Lung Neoplasms immunology, Immunotherapy methods, Transcriptome, Biomarkers, Tumor genetics, Biomarkers, Tumor metabolism

Abstract

Immunotherapy is improving the survival of patients with metastatic non-small cell lung cancer (NSCLC), yet reliable biomarkers are needed to identify responders prospectively and optimize patient care. In this study, we explore the benefits of multimodal approaches to predict immunotherapy outcome using multiple machine learning algorithms and integration strategies. We analyze baseline multimodal data from a cohort of 317 metastatic NSCLC patients treated with first-line immunotherapy, including positron emission tomography images, digitized pathological slides, bulk transcriptomic profiles, and clinical information. Testing multiple integration strategies, most of them yield multimodal models surpassing both the best unimodal models and established univariate biomarkers, such as PD-L1 expression. Additionally, several multimodal combinations demonstrate improved patient risk stratification compared to models built with routine clinical features only. Our study thus provides evidence of the superiority of multimodal over unimodal approaches, advocating for the collection of large multimodal NSCLC datasets to develop and validate robust and powerful immunotherapy biomarkers., Competing Interests: Competing interests: Nicolas Girard has a consulting or advisory role for the following companies: Abbvie, AMGEN, AstraZeneca, BeiGene, Bristol-Myers Squibb, Daiichi Sankyo/Astra Zeneca, Gilead Sciences, Ipsen, Janssen, LEO Pharma, Lilly, MSD, Novartis, Pfizer, Roche, Sanofi, Takeda. The other authors declare no competing interests., (© 2025. The Author(s).)

Published

2025

20. TREM2-Expressing Multinucleated Giant Macrophages Are a Biomarker of Good Prognosis in Head and Neck Squamous Cell Carcinoma.

Author

Gessain G, Anzali AA, Lerousseau M, Mulder K, Bied M, Auperin A, Stockholm D, Signolle N, Sassi F, Marques Da Costa ME, Marchais A, Sayadi A, Weidner D, Uderhardt S, Blampey Q, Nakkireddy SR, Broutin S, Dutertre CA, Busson P, Walter T, Marhic A, Moya-Plana A, Guerlain J, Breuskin I, Casiraghi O, Gorphe P, Classe M, Scoazec JY, Blériot C, and Ginhoux F

Subjects

Humans, Prognosis, Giant Cells pathology, Giant Cells metabolism, Membrane Glycoproteins metabolism, Biomarkers, Tumor metabolism, Receptors, Immunologic metabolism, Receptors, Immunologic genetics, Macrophages metabolism, Squamous Cell Carcinoma of Head and Neck metabolism, Squamous Cell Carcinoma of Head and Neck pathology, Squamous Cell Carcinoma of Head and Neck genetics, Head and Neck Neoplasms metabolism, Head and Neck Neoplasms pathology, Head and Neck Neoplasms diagnosis, Head and Neck Neoplasms genetics

Abstract

Significance: Novel individual biomarkers are needed to guide therapeutic decisions for patients with head and neck cancer. We report for the first time, granulomas of TREM2-expressing multinucleated giant macrophages in keratin-rich tumor niches, as a biomarker of favorable prognosis and developed a deep-learning model to automate its quantification on routinely stained pathological slides., (©2024 The Authors; Published by the American Association for Cancer Research.)

Published

2024

21. Image-based multiplex immune profiling of cancer tissues: translational implications. A report of the International Immuno-oncology Biomarker Working Group on Breast Cancer.

Author

Jahangir CA, Page DB, Broeckx G, Gonzalez CA, Burke C, Murphy C, Reis-Filho JS, Ly A, Harms PW, Gupta RR, Vieth M, Hida AI, Kahila M, Kos Z, van Diest PJ, Verbandt S, Thagaard J, Khiroya R, Abduljabbar K, Acosta Haab G, Acs B, Adams S, Almeida JS, Alvarado-Cabrero I, Azmoudeh-Ardalan F, Badve S, Baharun NB, Bellolio ER, Bheemaraju V, Blenman KR, Botinelly Mendonça Fujimoto L, Burgues O, Chardas A, Cheang MCU, Ciompi F, Cooper LA, Coosemans A, Corredor G, Dantas Portela FL, Deman F, Demaria S, Dudgeon SN, Elghazawy M, Fernandez-Martín C, Fineberg S, Fox SB, Giltnane JM, Gnjatic S, Gonzalez-Ericsson PI, Grigoriadis A, Halama N, Hanna MG, Harbhajanka A, Hart SN, Hartman J, Hewitt S, Horlings HM, Husain Z, Irshad S, Janssen EA, Kataoka TR, Kawaguchi K, Khramtsov AI, Kiraz U, Kirtani P, Kodach LL, Korski K, Akturk G, Scott E, Kovács A, Laenkholm AV, Lang-Schwarz C, Larsimont D, Lennerz JK, Lerousseau M, Li X, Madabhushi A, Maley SK, Manur Narasimhamurthy V, Marks DK, McDonald ES, Mehrotra R, Michiels S, Kharidehal D, Minhas FUAA, Mittal S, Moore DA, Mushtaq S, Nighat H, Papathomas T, Penault-Llorca F, Perera RD, Pinard CJ, Pinto-Cardenas JC, Pruneri G, Pusztai L, Rajpoot NM, Rapoport BL, Rau TT, Ribeiro JM, Rimm D, Vincent-Salomon A, Saltz J, Sayed S, Hytopoulos E, Mahon S, Siziopikou KP, Sotiriou C, Stenzinger A, Sughayer MA, Sur D, Symmans F, Tanaka S, Taxter T, Tejpar S, Teuwen J, Thompson EA, Tramm T, Tran WT, van der Laak J, Verghese GE, Viale G, Wahab N, Walter T, Waumans Y, Wen HY, Yang W, Yuan Y, Bartlett J, Loibl S, Denkert C, Savas P, Loi S, Specht Stovgaard E, Salgado R, Gallagher WM, and Rahman A

Subjects

Humans, Female, Biomarkers, Tumor genetics, Prognosis, Phenotype, United Kingdom, Tumor Microenvironment, Breast Neoplasms

Abstract

Recent advances in the field of immuno-oncology have brought transformative changes in the management of cancer patients. The immune profile of tumours has been found to have key value in predicting disease prognosis and treatment response in various cancers. Multiplex immunohistochemistry and immunofluorescence have emerged as potent tools for the simultaneous detection of multiple protein biomarkers in a single tissue section, thereby expanding opportunities for molecular and immune profiling while preserving tissue samples. By establishing the phenotype of individual tumour cells when distributed within a mixed cell population, the identification of clinically relevant biomarkers with high-throughput multiplex immunophenotyping of tumour samples has great potential to guide appropriate treatment choices. Moreover, the emergence of novel multi-marker imaging approaches can now provide unprecedented insights into the tumour microenvironment, including the potential interplay between various cell types. However, there are significant challenges to widespread integration of these technologies in daily research and clinical practice. This review addresses the challenges and potential solutions within a structured framework of action from a regulatory and clinical trial perspective. New developments within the field of immunophenotyping using multiplexed tissue imaging platforms and associated digital pathology are also described, with a specific focus on translational implications across different subtypes of cancer. © 2024 The Authors. The Journal of Pathology published by John Wiley & Sons Ltd on behalf of The Pathological Society of Great Britain and Ireland., (© 2024 The Authors. The Journal of Pathology published by John Wiley & Sons Ltd on behalf of The Pathological Society of Great Britain and Ireland.)

Published

2024

22. Spatial analyses of immune cell infiltration in cancer: current methods and future directions: A report of the International Immuno-Oncology Biomarker Working Group on Breast Cancer.

Author

Page DB, Broeckx G, Jahangir CA, Verbandt S, Gupta RR, Thagaard J, Khiroya R, Kos Z, Abduljabbar K, Acosta Haab G, Acs B, Akturk G, Almeida JS, Alvarado-Cabrero I, Azmoudeh-Ardalan F, Badve S, Baharun NB, Bellolio ER, Bheemaraju V, Blenman KR, Botinelly Mendonça Fujimoto L, Bouchmaa N, Burgues O, Cheang MCU, Ciompi F, Cooper LA, Coosemans A, Corredor G, Dantas Portela FL, Deman F, Demaria S, Dudgeon SN, Elghazawy M, Ely S, Fernandez-Martín C, Fineberg S, Fox SB, Gallagher WM, Giltnane JM, Gnjatic S, Gonzalez-Ericsson PI, Grigoriadis A, Halama N, Hanna MG, Harbhajanka A, Hardas A, Hart SN, Hartman J, Hewitt S, Hida AI, Horlings HM, Husain Z, Hytopoulos E, Irshad S, Janssen EA, Kahila M, Kataoka TR, Kawaguchi K, Kharidehal D, Khramtsov AI, Kiraz U, Kirtani P, Kodach LL, Korski K, Kovács A, Laenkholm AV, Lang-Schwarz C, Larsimont D, Lennerz JK, Lerousseau M, Li X, Ly A, Madabhushi A, Maley SK, Manur Narasimhamurthy V, Marks DK, McDonald ES, Mehrotra R, Michiels S, Minhas FUAA, Mittal S, Moore DA, Mushtaq S, Nighat H, Papathomas T, Penault-Llorca F, Perera RD, Pinard CJ, Pinto-Cardenas JC, Pruneri G, Pusztai L, Rahman A, Rajpoot NM, Rapoport BL, Rau TT, Reis-Filho JS, Ribeiro JM, Rimm D, Vincent-Salomon A, Salto-Tellez M, Saltz J, Sayed S, Siziopikou KP, Sotiriou C, Stenzinger A, Sughayer MA, Sur D, Symmans F, Tanaka S, Taxter T, Tejpar S, Teuwen J, Thompson EA, Tramm T, Tran WT, van der Laak J, van Diest PJ, Verghese GE, Viale G, Vieth M, Wahab N, Walter T, Waumans Y, Wen HY, Yang W, Yuan Y, Adams S, Bartlett JMS, Loibl S, Denkert C, Savas P, Loi S, Salgado R, and Specht Stovgaard E

Subjects

Humans, Biomarkers, Benchmarking, Lymphocytes, Tumor-Infiltrating, Spatial Analysis, Tumor Microenvironment, Colonic Neoplasms

Abstract

Modern histologic imaging platforms coupled with machine learning methods have provided new opportunities to map the spatial distribution of immune cells in the tumor microenvironment. However, there exists no standardized method for describing or analyzing spatial immune cell data, and most reported spatial analyses are rudimentary. In this review, we provide an overview of two approaches for reporting and analyzing spatial data (raster versus vector-based). We then provide a compendium of spatial immune cell metrics that have been reported in the literature, summarizing prognostic associations in the context of a variety of cancers. We conclude by discussing two well-described clinical biomarkers, the breast cancer stromal tumor infiltrating lymphocytes score and the colon cancer Immunoscore, and describe investigative opportunities to improve clinical utility of these spatial biomarkers. © 2023 The Pathological Society of Great Britain and Ireland., (© 2023 The Pathological Society of Great Britain and Ireland.)

Published

2023

23. Pitfalls in machine learning-based assessment of tumor-infiltrating lymphocytes in breast cancer: A report of the International Immuno-Oncology Biomarker Working Group on Breast Cancer

Author

Thagaard J, Broeckx G, Page DB, Jahangir CA, Verbandt S, Kos Z, Gupta R, Khiroya R, Abduljabbar K, Acosta Haab G, Acs B, Akturk G, Almeida JS, Alvarado-Cabrero I, Amgad M, Azmoudeh-Ardalan F, Badve S, Baharun NB, Balslev E, Bellolio ER, Bheemaraju V, Blenman KR, Botinelly Mendonça Fujimoto L, Bouchmaa N, Burgues O, Chardas A, Chon U Cheang M, Ciompi F, Cooper LA, Coosemans A, Corredor G, Dahl AB, Dantas Portela FL, Deman F, Demaria S, Doré Hansen J, Dudgeon SN, Ebstrup T, Elghazawy M, Fernandez-Martín C, Fox SB, Gallagher WM, Giltnane JM, Gnjatic S, Gonzalez-Ericsson PI, Grigoriadis A, Halama N, Hanna MG, Harbhajanka A, Hart SN, Hartman J, Hauberg S, Hewitt S, Hida AI, Horlings HM, Husain Z, Hytopoulos E, Irshad S, Janssen EA, Kahila M, Kataoka TR, Kawaguchi K, Kharidehal D, Khramtsov AI, Kiraz U, Kirtani P, Kodach LL, Korski K, Kovács A, Laenkholm AV, Lang-Schwarz C, Larsimont D, Lennerz JK, Lerousseau M, Li X, Ly A, Madabhushi A, Maley SK, Manur Narasimhamurthy V, Marks DK, McDonald ES, Mehrotra R, Michiels S, Minhas FUAA, Mittal S, Moore DA, Mushtaq S, Nighat H, Papathomas T, Penault-Llorca F, Perera RD, Pinard CJ, Pinto-Cardenas JC, Pruneri G, Pusztai L, Rahman A, Rajpoot NM, Rapoport BL, Rau TT, Reis-Filho JS, Ribeiro JM, Rimm D, Roslind A, Vincent-Salomon A, Salto-Tellez M, Saltz J, Sayed S, Scott E, Siziopikou KP, Sotiriou C, Stenzinger A, Sughayer MA, Sur D, Fineberg S, Symmans F, Tanaka S, Taxter T, Tejpar S, Teuwen J, Thompson EA, Tramm T, Tran WT, van der Laak J, van Diest PJ, Verghese GE, Viale G, Vieth M, Wahab N, Walter T, Waumans Y, Wen HY, Yang W, Yuan Y, Zin RM, Adams S, Bartlett J, Loibl S, Denkert C, Savas P, Loi S, Salgado R, and Specht Stovgaard E

Subjects

Humans, Animals, Lymphocytes, Tumor-Infiltrating, Biomarkers, Machine Learning, Triple Negative Breast Neoplasms, Mammary Neoplasms, Animal

Abstract

The clinical significance of the tumor-immune interaction in breast cancer is now established, and tumor-infiltrating lymphocytes (TILs) have emerged as predictive and prognostic biomarkers for patients with triple-negative (estrogen receptor, progesterone receptor, and HER2-negative) breast cancer and HER2-positive breast cancer. How computational assessments of TILs might complement manual TIL assessment in trial and daily practices is currently debated. Recent efforts to use machine learning (ML) to automatically evaluate TILs have shown promising results. We review state-of-the-art approaches and identify pitfalls and challenges of automated TIL evaluation by studying the root cause of ML discordances in comparison to manual TIL quantification. We categorize our findings into four main topics: (1) technical slide issues, (2) ML and image analysis aspects, (3) data challenges, and (4) validation issues. The main reason for discordant assessments is the inclusion of false-positive areas or cells identified by performance on certain tissue patterns or design choices in the computational implementation. To aid the adoption of ML for TIL assessment, we provide an in-depth discussion of ML and image analysis, including validation issues that need to be considered before reliable computational reporting of TILs can be incorporated into the trial and routine clinical management of patients with triple-negative breast cancer. © 2023 The Authors. The Journal of Pathology published by John Wiley & Sons Ltd on behalf of The Pathological Society of Great Britain and Ireland., (© 2023 The Authors. The Journal of Pathology published by John Wiley & Sons Ltd on behalf of The Pathological Society of Great Britain and Ireland.)

Published

2023

24. COMBING: Clustering in Oncology for Mathematical and Biological Identification of Novel Gene Signatures.

Author

Battistella E, Vakalopoulou M, Sun R, Estienne T, Lerousseau M, Nikolaev S, Andres EA, Carre A, Niyoteka S, Robert C, Paragios N, and Deutsch E

Subjects

Humans, Cluster Analysis, Genomics, Pattern Recognition, Automated methods, Gene Expression Profiling methods, Algorithms, Neoplasms genetics

Abstract

Precision medicine is a paradigm shift in healthcare relying heavily on genomics data. However, the complexity of biological interactions, the large number of genes as well as the lack of comparisons on the analysis of data, remain a tremendous bottleneck regarding clinical adoption. In this paper, we introduce a novel, automatic and unsupervised framework to discover low-dimensional gene biomarkers. Our method is based on the LP-Stability algorithm, a high dimensional center-based unsupervised clustering algorithm. It offers modularity as concerns metric functions and scalability, while being able to automatically determine the best number of clusters. Our evaluation includes both mathematical and biological criteria to define a quantitative metric. The recovered signature is applied to a variety of biological tasks, including screening of biological pathways and functions, and characterization relevance on tumor types and subtypes. Quantitative comparisons among different distance metrics, commonly used clustering methods and a referential gene signature used in the literature, confirm state of the art performance of our approach. In particular, our signature, based on 27 genes, reports at least 30 times better mathematical significance (average Dunn's Index) and 25% better biological significance (average Enrichment in Protein-Protein Interaction) than those produced by other referential clustering methods. Finally, our signature reports promising results on distinguishing immune inflammatory and immune desert tumors, while reporting a high balanced accuracy of 92% on tumor types classification and averaged balanced accuracy of 68% on tumor subtypes classification, which represents, respectively 7% and 9% higher performance compared to the referential signature.

Published

2022

25. Radiomics to evaluate interlesion heterogeneity and to predict lesion response and patient outcomes using a validated signature of CD8 cells in advanced melanoma patients treated with anti-PD1 immunotherapy.

Author

Sun R, Lerousseau M, Briend-Diop J, Routier E, Roy S, Henry T, Ka K, Jiang R, Temar N, Carré A, Laville A, Hamaoui A, Laurent PA, Rouyar A, Robert C, Robert C, and Deutsch E

Subjects

Humans, CD8-Positive T-Lymphocytes, Prognosis, Immunotherapy methods, Melanoma diagnostic imaging, Melanoma drug therapy

Abstract

Purpose: While there is still a significant need to identify potential biomarkers that can predict which patients are most likely to respond to immunotherapy treatments, radiomic approaches have shown promising results. The objectives of this study were to evaluate whether a previously validated radiomics signature of CD8 T-cells could predict progressions at a lesion level and whether the spatial heterogeneity of this radiomics score could be used at a patient level to assess the clinical response and survival of melanoma patients., Methods: Clinical data from patients with advanced melanoma treated in our center with immunotherapy were retrieved. Radiomic features were extracted and the CD8 radiomics signature was applied. A progressive lesion was defined by an increase in lesion size of 20% or more. Dispersion metrics of the radiomics signature were estimated to evaluate the impact of interlesion heterogeneity on patient's response. Fine-tuned cut-offs for predicting overall survival were evaluated after splitting data into training and test sets., Results: A total of 136 patients were included in this study, with 1120 segmented lesions at baseline, and 1052 lesions at first evaluation. A low CD8 radiomics score at baseline was associated with a significantly higher risk of lesion progression (AUC=0.55, p=0.0091), especially for lesions larger than >1 mL (AUC=0.59 overall, p=0.0035, with AUC=0.75, p=0.002 for subcutaneous lesions, AUC=0.68, p=0.01, for liver lesions and AUC=0.62, p=0.03 for nodes). The least infiltrated lesion according to the radiomics score of CD8 T-cells was positively associated with overall survival (training set HR=0.31, p=0.00062, test set HR=0.28, p=0.016), which remained significant in a multivariate analysis including clinical and biological variables., Conclusions: These results confirm the predictive value at a lesion level of the biologically inspired CD8 radiomics score in melanoma patients treated with anti-PD1-based immunotherapy and may be interesting to assess the disease spatial heterogeneity to evaluate the patient prognosis with potential clinical implication such as tumor selection for focal ablative therapies., Competing Interests: Competing interests: ED has declared consulting fees and support from Roche, BMS, Boehringer, Astrazeneca, Lilly Amgen and Merck-Serono. CaR declares consulting fees from Roche, BMS, MSD, AstraZeneca, Pierre Fabre, Sanofi, Novartis., (© Author(s) (or their employer(s)) 2022. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ.)

Published

2022

26. Perspectives in pathomics in head and neck cancer.

Author

Classe M, Lerousseau M, Scoazec JY, and Deutsch E

Subjects

Biomarkers, Tumor analysis, Head and Neck Neoplasms diagnosis, Humans, Image Processing, Computer-Assisted methods, Pathology methods, Tumor Microenvironment, Artificial Intelligence, Head and Neck Neoplasms pathology

Abstract

Purpose of Review: Pathology is the cornerstone of cancer care. Pathomics, which represents the use of artificial intelligence in digital pathology, is an emerging and promising field that will revolutionize medical and surgical pathology in the coming years. This review provides an overview of pathomics, its current and future applications and its most relevant applications in Head and Neck cancer care., Recent Findings: The number of studies investigating the use of artificial intelligence in pathology is rapidly growing, especially as the utilization of deep learning has shown great potential with Whole Slide Images. Even though numerous steps still remain before its clinical use, Pathomics has been used for varied applications comprising of computer-assisted diagnosis, molecular anomalies prediction, tumor microenvironment and biomarker identification as well as prognosis evaluation. The majority of studies were performed on the most frequent cancers, notably breast, prostate, and lung. Interesting results were also found in Head and Neck cancers., Summary: Even if its use in Head and Neck cancer care is still low, Pathomics is a powerful tool to improve diagnosis, identify prognostic factors and new biomarkers. Important challenges lie ahead before its use in a clinical practice, notably the lack of information on how AI makes its decisions, the slow deployment of digital pathology, and the need for extensively validated data in order to obtain authorities approval. Regardless, pathomics will most likely improve pathology in general, including Head and Neck cancer care in the coming years., (Copyright © 2021 Wolters Kluwer Health, Inc. All rights reserved.)

Published

2021

27. Dosimetry-Driven Quality Measure of Brain Pseudo Computed Tomography Generated From Deep Learning for MRI-Only Radiation Therapy Treatment Planning.

Author

Alvarez Andres E, Fidon L, Vakalopoulou M, Lerousseau M, Carré A, Sun R, Klausner G, Ammari S, Benzazon N, Reuzé S, Estienne T, Niyoteka S, Battistella E, Rouyar A, Noël G, Beaudre A, Dhermain F, Deutsch E, Paragios N, and Robert C

Subjects

Brain diagnostic imaging, Brain Neoplasms radiotherapy, Contrast Media, Humans, Magnetic Resonance Imaging standards, Neural Networks, Computer, Radiometry, Radiotherapy standards, Retrospective Studies, Skull diagnostic imaging, Brain Neoplasms diagnostic imaging, Deep Learning, Magnetic Resonance Imaging methods, Tomography, X-Ray Computed methods

Abstract

Purpose: This study aims to evaluate the impact of key parameters on the pseudo computed tomography (pCT) quality generated from magnetic resonance imaging (MRI) with a 3-dimensional (3D) convolutional neural network., Methods and Materials: Four hundred two brain tumor cases were retrieved, yielding associations between 182 computed tomography (CT) and T1-weighted MRI (T1) scans, 180 CT and contrast-enhanced T1-weighted MRI (T1-Gd) scans, and 40 CT, T1, and T1-Gd scans. A 3D CNN was used to map T1 or T1-Gd onto CT scans and evaluate the importance of different components. First, the training set size's influence on testing set accuracy was assessed. Moreover, we evaluated the MRI sequence impact, using T1-only and T1-Gd-only cohorts. We then investigated 4 MRI standardization approaches (histogram-based, zero-mean/unit-variance, white stripe, and no standardization) based on training, validation, and testing cohorts composed of 242, 81, and 79 patients cases, respectively, as well as a bias field correction influence. Finally, 2 networks, namely HighResNet and 3D UNet, were compared to evaluate the architecture's impact on the pCT quality. The mean absolute error, gamma indices, and dose-volume histograms were used as evaluation metrics., Results: Generating models using all the available cases for training led to higher pCT quality. The T1 and T1-Gd models had a maximum difference in gamma index means of 0.07 percentage point. The mean absolute error obtained with white stripe was 78 ± 22 Hounsfield units, which slightly outperformed histogram-based, zero-mean/unit-variance, and no standardization (P < .0001). Regarding the network architectures, 3%/3 mm gamma indices of 99.83% ± 0.19% and 99.74% ± 0.24% were obtained for HighResNet and 3D UNet, respectively., Conclusions: Our best pCTs were generated using more than 200 samples in the training data set. Training with T1 only and T1-Gd only did not significantly affect performance. Regardless of the preprocessing applied, the dosimetry quality remained equivalent and relevant for potential use in clinical practice., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

28. Standardization of brain MR images across machines and protocols: bridging the gap for MRI-based radiomics.

Author

Carré A, Klausner G, Edjlali M, Lerousseau M, Briend-Diop J, Sun R, Ammari S, Reuzé S, Alvarez Andres E, Estienne T, Niyoteka S, Battistella E, Vakalopoulou M, Dhermain F, Paragios N, Deutsch E, Oppenheim C, Pallud J, and Robert C

Subjects

Female, Humans, Male, Middle Aged, Brain diagnostic imaging, Brain Neoplasms diagnostic imaging, Glioma diagnostic imaging, Magnetic Resonance Imaging standards

Abstract

Radiomics relies on the extraction of a wide variety of quantitative image-based features to provide decision support. Magnetic resonance imaging (MRI) contributes to the personalization of patient care but suffers from being highly dependent on acquisition and reconstruction parameters. Today, there are no guidelines regarding the optimal pre-processing of MR images in the context of radiomics, which is crucial for the generalization of published image-based signatures. This study aims to assess the impact of three different intensity normalization methods (Nyul, WhiteStripe, Z-Score) typically used in MRI together with two methods for intensity discretization (fixed bin size and fixed bin number). The impact of these methods was evaluated on first- and second-order radiomics features extracted from brain MRI, establishing a unified methodology for future radiomics studies. Two independent MRI datasets were used. The first one (DATASET1) included 20 institutional patients with WHO grade II and III gliomas who underwent post-contrast 3D axial T1-weighted (T1w-gd) and axial T2-weighted fluid attenuation inversion recovery (T2w-flair) sequences on two different MR devices (1.5 T and 3.0 T) with a 1-month delay. Jensen-Shannon divergence was used to compare pairs of intensity histograms before and after normalization. The stability of first-order and second-order features across the two acquisitions was analysed using the concordance correlation coefficient and the intra-class correlation coefficient. The second dataset (DATASET2) was extracted from the public TCIA database and included 108 patients with WHO grade II and III gliomas and 135 patients with WHO grade IV glioblastomas. The impact of normalization and discretization methods was evaluated based on a tumour grade classification task (balanced accuracy measurement) using five well-established machine learning algorithms. Intensity normalization highly improved the robustness of first-order features and the performances of subsequent classification models. For the T1w-gd sequence, the mean balanced accuracy for tumour grade classification was increased from 0.67 (95% CI 0.61-0.73) to 0.82 (95% CI 0.79-0.84, P = .006), 0.79 (95% CI 0.76-0.82, P = .021) and 0.82 (95% CI 0.80-0.85, P = .005), respectively, using the Nyul, WhiteStripe and Z-Score normalization methods compared to no normalization. The relative discretization makes unnecessary the use of intensity normalization for the second-order radiomics features. Even if the bin number for the discretization had a small impact on classification performances, a good compromise was obtained using the 32 bins considering both T1w-gd and T2w-flair sequences. No significant improvements in classification performances were observed using feature selection. A standardized pre-processing pipeline is proposed for the use of radiomics in MRI of brain tumours. For models based on first- and second-order features, we recommend normalizing images with the Z-Score method and adopting an absolute discretization approach. For second-order feature-based signatures, relative discretization can be used without prior normalization. In both cases, 32 bins for discretization are recommended. This study may pave the way for the multicentric development and validation of MR-based radiomics biomarkers.

Published

2020

29. Deep Learning-Based Concurrent Brain Registration and Tumor Segmentation.

Author

Estienne T, Lerousseau M, Vakalopoulou M, Alvarez Andres E, Battistella E, Carré A, Chandra S, Christodoulidis S, Sahasrabudhe M, Sun R, Robert C, Talbot H, Paragios N, and Deutsch E

Abstract

Image registration and segmentation are the two most studied problems in medical image analysis. Deep learning algorithms have recently gained a lot of attention due to their success and state-of-the-art results in variety of problems and communities. In this paper, we propose a novel, efficient, and multi-task algorithm that addresses the problems of image registration and brain tumor segmentation jointly. Our method exploits the dependencies between these tasks through a natural coupling of their interdependencies during inference. In particular, the similarity constraints are relaxed within the tumor regions using an efficient and relatively simple formulation. We evaluated the performance of our formulation both quantitatively and qualitatively for registration and segmentation problems on two publicly available datasets (BraTS 2018 and OASIS 3), reporting competitive results with other recent state-of-the-art methods. Moreover, our proposed framework reports significant amelioration ( p < 0.005) for the registration performance inside the tumor locations, providing a generic method that does not need any predefined conditions (e.g., absence of abnormalities) about the volumes to be registered. Our implementation is publicly available online at https://github.com/TheoEst/joint&#95;registration&#95;tumor&#95;segmentation., (Copyright © 2020 Estienne, Lerousseau, Vakalopoulou, Alvarez Andres, Battistella, Carré, Chandra, Christodoulidis, Sahasrabudhe, Sun, Robert, Talbot, Paragios and Deutsch.)

Published

2020