MRIgRT real-time target tracking: TrackRAD2025 challenge report

Tom Julius Blöcker; Pia A W Görts; Yiling Wang; Elia Lombardo; Adrian Thummerer; Yu Fan; Yue Zhao; Christianna Iris Papadopoulou; Coen Hurkmans; Rob H N Tijssen; Davide Cusumano; Martijn Pw Intven; Pim Borman; Marco Riboldi; Denis Dudáš; Hilary L Byrne; Lorenzo Placidi; Marco Fusella; Michael Jameson; Miguel A Palacios; Paul Cobussen; Tobias Finazzi; Shyama U Tetar; Cornelis J A Haasbeek; Paul Keall; Matteo Maspero; Christopher Kurz; Amparo Soeli Betancourt Tarifa; Kailin He; Shengqian Zhu; Ying Song; Guangjun Li; Junjie Hu; Felix Knispel; Sergios Gatidis; Hung Chu; Jiapan Guo; Maximilian Nielsen; Thilo Sentker; Valentin Boussot; Cédric Hémon; Jing Ni; Konstantinos Georgas; Theodoros P Vagenas; George K Matsopoulos; Guillaume Landry

doi:10.1016/j.media.2026.104134

MRIgRT real-time target tracking: TrackRAD2025 challenge report

Tom Julius Blöcker
, Pia A W Görts
, Yiling Wang
, Elia Lombardo
, Adrian Thummerer
, Yu Fan
, Yue Zhao
, Christianna Iris Papadopoulou
, Coen Hurkmans
, Rob H N Tijssen
, Davide Cusumano
, Martijn Pw Intven
, Pim Borman
, Marco Riboldi
, Denis Dudáš
, Hilary L Byrne
, Lorenzo Placidi
, Marco Fusella
, Michael Jameson
, Miguel A Palacios

Paul Cobussen, Tobias Finazzi, Shyama U Tetar, Cornelis J A Haasbeek, Paul Keall, Matteo Maspero, Christopher Kurz, Amparo Soeli Betancourt Tarifa, Kailin He, Shengqian Zhu, Ying Song, Guangjun Li, Junjie Hu, Felix Knispel, Sergios Gatidis, Hung Chu, Jiapan Guo, Maximilian Nielsen, Thilo Sentker, Valentin Boussot, Cédric Hémon, Jing Ni, Konstantinos Georgas, Theodoros P Vagenas, George K Matsopoulos, Guillaume Landry^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Magnetic resonance imaging (MRI)-guided radiotherapy (MRIgRT) integrates MRI with linear accelerators (MRI-linacs), enabling real-time motion management based on temporally resolved 2D MRI (cine-MRI). Current systems rely on template matching or deformable image registration for radiotherapy target (typically the gross tumor volume) localization, which allows beam gating. Further advances in localization could support more precise and efficient delivery methods. https://trackrad2025.grand-challenge.org/ was organized to provide a common dataset to benchmark algorithms for MRIgRT target tracking in 2D+t cine-MRI. Participants propagated target segmentation masks from an initialization frame across subsequent frames. The dataset comprised sagittal cine-MRI scans of 585 cancer patients undergoing radiotherapy at 0.35 T and 1.5 T MRI-linacs at six different institutions, with expert-annotated targets in 108 sequences. Target sites included the thorax (179 cases), abdomen (266 cases), and pelvis (140 cases). A total of 477 unlabeled and 50 labeled cases were provided for training purposes, 58 cases were kept private for preliminary testing (8) and final evaluation (50). The algorithms submitted by participants were executed on the challenge platform and assessed using metrics in three categories: geometric accuracy, surrogate dose accuracy and execution speed. Rankings were derived via a Rank-Then-Mean scheme. TrackRAD2025 attracted 148 registrations from 28 countries, 100 preliminary submissions and 24 final submissions from 14 teams. The top five methods achieved mean Dice similarity coefficients >0.87 and Euclidean center distances <2.1 mm, comparable to interobserver variability. Leading top five solutions featured foundation models with (4) or without (1) finetuning. Field strength had minimal effect on performance and tracking worked better for the pelvis with reduced motion amplitude compared to the thorax and abdomen cases, which achieved equivalent performance. TrackRAD2025 established a benchmark for MRIgRT tracking on multi-institutional cine-MRI data, highlighting foundation models as promising for clinical translation.

Original language	English
Article number	104134
Journal	Medical Image Analysis
Volume	112
Early online date	23 May 2026
DOIs	https://doi.org/10.1016/j.media.2026.104134
Publication status	E-pub ahead of print - 23 May 2026

Keywords

Deep learning
Respiratory motion
MRI-linac
MRI-guidance
Motion management

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1-s2.0-S1361841526002033-mainFinal published version, 2.45 MBLicence: CC BY

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Blöcker, T. J., Görts, P. A. W., Wang, Y., Lombardo, E., Thummerer, A., Fan, Y., Zhao, Y., Papadopoulou, C. I., Hurkmans, C., Tijssen, R. H. N., Cusumano, D., Intven, M. P., Borman, P., Riboldi, M., Dudáš, D., Byrne, H. L., Placidi, L., Fusella, M., Jameson, M., ... Landry, G. (2026). MRIgRT real-time target tracking: TrackRAD2025 challenge report. Medical Image Analysis, 112, Article 104134. Advance online publication. https://doi.org/10.1016/j.media.2026.104134

@article{27d91d8bb43a4163941bb4473e94d60d,

title = "MRIgRT real-time target tracking: TrackRAD2025 challenge report",

abstract = "Magnetic resonance imaging (MRI)-guided radiotherapy (MRIgRT) integrates MRI with linear accelerators (MRI-linacs), enabling real-time motion management based on temporally resolved 2D MRI (cine-MRI). Current systems rely on template matching or deformable image registration for radiotherapy target (typically the gross tumor volume) localization, which allows beam gating. Further advances in localization could support more precise and efficient delivery methods. https://trackrad2025.grand-challenge.org/ was organized to provide a common dataset to benchmark algorithms for MRIgRT target tracking in 2D+t cine-MRI. Participants propagated target segmentation masks from an initialization frame across subsequent frames. The dataset comprised sagittal cine-MRI scans of 585 cancer patients undergoing radiotherapy at 0.35 T and 1.5 T MRI-linacs at six different institutions, with expert-annotated targets in 108 sequences. Target sites included the thorax (179 cases), abdomen (266 cases), and pelvis (140 cases). A total of 477 unlabeled and 50 labeled cases were provided for training purposes, 58 cases were kept private for preliminary testing (8) and final evaluation (50). The algorithms submitted by participants were executed on the challenge platform and assessed using metrics in three categories: geometric accuracy, surrogate dose accuracy and execution speed. Rankings were derived via a Rank-Then-Mean scheme. TrackRAD2025 attracted 148 registrations from 28 countries, 100 preliminary submissions and 24 final submissions from 14 teams. The top five methods achieved mean Dice similarity coefficients >0.87 and Euclidean center distances <2.1 mm, comparable to interobserver variability. Leading top five solutions featured foundation models with (4) or without (1) finetuning. Field strength had minimal effect on performance and tracking worked better for the pelvis with reduced motion amplitude compared to the thorax and abdomen cases, which achieved equivalent performance. TrackRAD2025 established a benchmark for MRIgRT tracking on multi-institutional cine-MRI data, highlighting foundation models as promising for clinical translation.",

keywords = "Deep learning, Respiratory motion, MRI-linac, MRI-guidance, Motion management",

author = "Bl{\"o}cker, \{Tom Julius\} and G{\"o}rts, \{Pia A W\} and Yiling Wang and Elia Lombardo and Adrian Thummerer and Yu Fan and Yue Zhao and Papadopoulou, \{Christianna Iris\} and Coen Hurkmans and Tijssen, \{Rob H N\} and Davide Cusumano and Intven, \{Martijn Pw\} and Pim Borman and Marco Riboldi and Denis Dud{\'a}{\v s} and Byrne, \{Hilary L\} and Lorenzo Placidi and Marco Fusella and Michael Jameson and Palacios, \{Miguel A\} and Paul Cobussen and Tobias Finazzi and Tetar, \{Shyama U\} and Haasbeek, \{Cornelis J A\} and Paul Keall and Matteo Maspero and Christopher Kurz and Tarifa, \{Amparo Soeli Betancourt\} and Kailin He and Shengqian Zhu and Ying Song and Guangjun Li and Junjie Hu and Felix Knispel and Sergios Gatidis and Hung Chu and Jiapan Guo and Maximilian Nielsen and Thilo Sentker and Valentin Boussot and C{\'e}dric H{\'e}mon and Jing Ni and Konstantinos Georgas and Vagenas, \{Theodoros P\} and Matsopoulos, \{George K\} and Guillaume Landry",

year = "2026",

month = may,

day = "23",

doi = "10.1016/j.media.2026.104134",

language = "English",

volume = "112",

journal = "Medical Image Analysis",

issn = "1361-8415",

publisher = "Elsevier",

}

Blöcker, TJ, Görts, PAW, Wang, Y, Lombardo, E, Thummerer, A, Fan, Y, Zhao, Y, Papadopoulou, CI, Hurkmans, C, Tijssen, RHN, Cusumano, D, Intven, MP, Borman, P, Riboldi, M, Dudáš, D, Byrne, HL, Placidi, L, Fusella, M, Jameson, M, Palacios, MA, Cobussen, P, Finazzi, T, Tetar, SU, Haasbeek, CJA, Keall, P, Maspero, M, Kurz, C, Tarifa, ASB, He, K, Zhu, S, Song, Y, Li, G, Hu, J, Knispel, F, Gatidis, S, Chu, H, Guo, J, Nielsen, M, Sentker, T, Boussot, V, Hémon, C, Ni, J, Georgas, K, Vagenas, TP, Matsopoulos, GK & Landry, G 2026, 'MRIgRT real-time target tracking: TrackRAD2025 challenge report', Medical Image Analysis, vol. 112, 104134. https://doi.org/10.1016/j.media.2026.104134

TY - JOUR

T1 - MRIgRT real-time target tracking

T2 - TrackRAD2025 challenge report

AU - Blöcker, Tom Julius

AU - Görts, Pia A W

AU - Wang, Yiling

AU - Lombardo, Elia

AU - Thummerer, Adrian

AU - Fan, Yu

AU - Zhao, Yue

AU - Papadopoulou, Christianna Iris

AU - Hurkmans, Coen

AU - Tijssen, Rob H N

AU - Cusumano, Davide

AU - Intven, Martijn Pw

AU - Borman, Pim

AU - Riboldi, Marco

AU - Dudáš, Denis

AU - Byrne, Hilary L

AU - Placidi, Lorenzo

AU - Fusella, Marco

AU - Jameson, Michael

AU - Palacios, Miguel A

AU - Cobussen, Paul

AU - Finazzi, Tobias

AU - Tetar, Shyama U

AU - Haasbeek, Cornelis J A

AU - Keall, Paul

AU - Maspero, Matteo

AU - Kurz, Christopher

AU - Tarifa, Amparo Soeli Betancourt

AU - He, Kailin

AU - Zhu, Shengqian

AU - Song, Ying

AU - Li, Guangjun

AU - Hu, Junjie

AU - Knispel, Felix

AU - Gatidis, Sergios

AU - Chu, Hung

AU - Guo, Jiapan

AU - Nielsen, Maximilian

AU - Sentker, Thilo

AU - Boussot, Valentin

AU - Hémon, Cédric

AU - Ni, Jing

AU - Georgas, Konstantinos

AU - Vagenas, Theodoros P

AU - Matsopoulos, George K

AU - Landry, Guillaume

PY - 2026/5/23

Y1 - 2026/5/23

N2 - Magnetic resonance imaging (MRI)-guided radiotherapy (MRIgRT) integrates MRI with linear accelerators (MRI-linacs), enabling real-time motion management based on temporally resolved 2D MRI (cine-MRI). Current systems rely on template matching or deformable image registration for radiotherapy target (typically the gross tumor volume) localization, which allows beam gating. Further advances in localization could support more precise and efficient delivery methods. https://trackrad2025.grand-challenge.org/ was organized to provide a common dataset to benchmark algorithms for MRIgRT target tracking in 2D+t cine-MRI. Participants propagated target segmentation masks from an initialization frame across subsequent frames. The dataset comprised sagittal cine-MRI scans of 585 cancer patients undergoing radiotherapy at 0.35 T and 1.5 T MRI-linacs at six different institutions, with expert-annotated targets in 108 sequences. Target sites included the thorax (179 cases), abdomen (266 cases), and pelvis (140 cases). A total of 477 unlabeled and 50 labeled cases were provided for training purposes, 58 cases were kept private for preliminary testing (8) and final evaluation (50). The algorithms submitted by participants were executed on the challenge platform and assessed using metrics in three categories: geometric accuracy, surrogate dose accuracy and execution speed. Rankings were derived via a Rank-Then-Mean scheme. TrackRAD2025 attracted 148 registrations from 28 countries, 100 preliminary submissions and 24 final submissions from 14 teams. The top five methods achieved mean Dice similarity coefficients >0.87 and Euclidean center distances <2.1 mm, comparable to interobserver variability. Leading top five solutions featured foundation models with (4) or without (1) finetuning. Field strength had minimal effect on performance and tracking worked better for the pelvis with reduced motion amplitude compared to the thorax and abdomen cases, which achieved equivalent performance. TrackRAD2025 established a benchmark for MRIgRT tracking on multi-institutional cine-MRI data, highlighting foundation models as promising for clinical translation.

AB - Magnetic resonance imaging (MRI)-guided radiotherapy (MRIgRT) integrates MRI with linear accelerators (MRI-linacs), enabling real-time motion management based on temporally resolved 2D MRI (cine-MRI). Current systems rely on template matching or deformable image registration for radiotherapy target (typically the gross tumor volume) localization, which allows beam gating. Further advances in localization could support more precise and efficient delivery methods. https://trackrad2025.grand-challenge.org/ was organized to provide a common dataset to benchmark algorithms for MRIgRT target tracking in 2D+t cine-MRI. Participants propagated target segmentation masks from an initialization frame across subsequent frames. The dataset comprised sagittal cine-MRI scans of 585 cancer patients undergoing radiotherapy at 0.35 T and 1.5 T MRI-linacs at six different institutions, with expert-annotated targets in 108 sequences. Target sites included the thorax (179 cases), abdomen (266 cases), and pelvis (140 cases). A total of 477 unlabeled and 50 labeled cases were provided for training purposes, 58 cases were kept private for preliminary testing (8) and final evaluation (50). The algorithms submitted by participants were executed on the challenge platform and assessed using metrics in three categories: geometric accuracy, surrogate dose accuracy and execution speed. Rankings were derived via a Rank-Then-Mean scheme. TrackRAD2025 attracted 148 registrations from 28 countries, 100 preliminary submissions and 24 final submissions from 14 teams. The top five methods achieved mean Dice similarity coefficients >0.87 and Euclidean center distances <2.1 mm, comparable to interobserver variability. Leading top five solutions featured foundation models with (4) or without (1) finetuning. Field strength had minimal effect on performance and tracking worked better for the pelvis with reduced motion amplitude compared to the thorax and abdomen cases, which achieved equivalent performance. TrackRAD2025 established a benchmark for MRIgRT tracking on multi-institutional cine-MRI data, highlighting foundation models as promising for clinical translation.

KW - Deep learning

KW - Respiratory motion

KW - MRI-linac

KW - MRI-guidance

KW - Motion management

UR - https://www.scopus.com/pages/publications/105039889545

U2 - 10.1016/j.media.2026.104134

DO - 10.1016/j.media.2026.104134

M3 - Article

C2 - 42191418

SN - 1361-8415

VL - 112

JO - Medical Image Analysis

JF - Medical Image Analysis

M1 - 104134

ER -

MRIgRT real-time target tracking: TrackRAD2025 challenge report

Abstract

Keywords

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