Journal of Medical Physics: Table of Contents

The official journal of AMPI, IOMP and AFOMP

Users online: 447

Article Cited by others

REVIEW ARTICLE

Tumor delineation: The weakest link in the search for accuracy in radiotherapy

Njeh C F

Year : 2008| Volume: 33| Issue : 4 | Page no: 136-140

This article has been cited by

1	Automatic segmentation software in locally advanced rectal cancer: READY (REsearch program in Auto Delineation sYstem)-RECTAL 02: prospective study

	Maria A. Gambacorta, Luca Boldrini, Chiara Valentini, Nicola Dinapoli, Gian C. Mattiucci, Giuditta Chiloiro, Danilo Pasini, Stefania Manfrida, Nicola Caria, Bruce D. Minsky, Vincenzo Valentini

	Oncotarget. 2106; 7(27): 42579

	[Pubmed] [Google Scholar] [DOI]

2	MR-guided radiotherapy for prostate cancer: state of the art and future perspectives

	Kobika Sritharan, Alison Tree

	The British Journal of Radiology. 2022;

	[Pubmed] [Google Scholar] [DOI]

3	Improved Survival Prediction by Combining Radiological Imaging and S-100B Levels Into a Multivariate Model in Metastatic Melanoma Patients Treated With Immune Checkpoint Inhibition

	Simon Burgermeister, Hubert S. Gabrys, Lucas Basler, Sabrina A. Hogan, Matea Pavic, Marta Bogowicz, Julia M. Martínez Gómez, Diem Vuong, Stephanie Tanadini-Lang, Robert Foerster, Martin W. Huellner, Reinhard Dummer, Mitchell P. Levesque, Matthias Guckenberger

	Frontiers in Oncology. 2022; 12

	[Pubmed] [Google Scholar] [DOI]

4	Evaluation of deep learning-based multiparametric MRI oropharyngeal primary tumor auto-segmentation and investigation of input channel effects: Results from a prospective imaging registry

	Kareem A. Wahid, Sara Ahmed, Renjie He, Lisanne V. van Dijk, Jonas Teuwen, Brigid A. McDonald, Vivian Salama, Abdallah S.R. Mohamed, Travis Salzillo, Cem Dede, Nicolette Taku, Stephen Y. Lai, Clifton D. Fuller, Mohamed A. Naser

	Clinical and Translational Radiation Oncology. 2022; 32: 6

	[Pubmed] [Google Scholar] [DOI]

5	Dosimetric comparison of automatically propagated prostate contours with manually drawn contours in MRI-guided radiotherapy: a step towards a contouring free workflow?

	Kobika Sritharan, Alex Dunlop, Jonathan Mohajer, Gillian Adair-Smith, Helen Barnes, Douglas Brand, Emily Greenlay, Adham Hijab, Uwe Oelfke, Angela Pathmanathan, Adam Mitchell, Julia Murray, Simeon Nill, Chris Parker, Nora Sundahl, Alison C. Tree

	Clinical and Translational Radiation Oncology. 2022;

	[Pubmed] [Google Scholar] [DOI]

6	Clinical utility of convolutional neural networks for treatment planning in radiotherapy for spinal metastases

	Sebastiaan R.S. Arends, Mark H.F. Savenije, Wietse S.C. Eppinga, Joanne M. van der Velden, Cornelis A.T. van den Berg, Joost J.C. Verhoeff

	Physics and Imaging in Radiation Oncology. 2022; 21: 42

	[Pubmed] [Google Scholar] [DOI]

7	Towards an integral clinical proton dose prediction uncertainty by considering delineation variation

	Nils Peters, Ludvig P. Muren

	Physics and Imaging in Radiation Oncology. 2022; 21: 134

	[Pubmed] [Google Scholar] [DOI]

8	Semi-automatic tumor segmentation of rectal cancer based on functional magnetic resonance imaging

	Franziska Knuth, Aurora R. Groendahl, René M. Winter, Turid Torheim, Anne Negård, Stein Harald Holmedal, Kine Mari Bakke, Sebastian Meltzer, Cecilia M. Futsæther, Kathrine R. Redalen

	Physics and Imaging in Radiation Oncology. 2022; 22: 77

	[Pubmed] [Google Scholar] [DOI]

9	Modern Radiation Oncology: From IMRT to Particle Therapy—Present Status and the Days to Come

	Sarbani Ghosh Laskar, Sangeeta Kakoti

	Indian Journal of Medical and Paediatric Oncology. 2022;

	[Pubmed] [Google Scholar] [DOI]

10	Modeling the propagation of tumor fronts with shortest path and diffusion models—implications for the definition of the clinical target volume

	Thomas Bortfeld, Gregory Buti

	Physics in Medicine & Biology. 2022; 67(15): 155014

	[Pubmed] [Google Scholar] [DOI]

11	Systematic Clinical Evaluation of a Deep Learning Method for Medical Image Segmentation: Radiosurgery Application

	Boris Shirokikh, Alexandra Dalechina, Alexey Shevtsov, Egor Krivov, Valery Kostjuchenko, Amayak Durgaryan, Mikhail Galkin, Andrey Golanov, Mikhail Belyaev

	IEEE Journal of Biomedical and Health Informatics. 2022; 26(7): 3037

	[Pubmed] [Google Scholar] [DOI]

12	Intra- and inter-physician variability in target volume delineation in radiation therapy

	Indra J Das, Julia J Compton, Amishi Bajaj, Peter A Johnstone

	Journal of Radiation Research. 2021;

	[Pubmed] [Google Scholar] [DOI]

13	Reduction of inter-observer contouring variability in daily clinical practice through a retrospective, evidence-based intervention

	H. M. Patrick, L. Souhami, J. Kildea

	Acta Oncologica. 2021; 60(2): 229

	[Pubmed] [Google Scholar] [DOI]

14	Probabilistic definition of the clinical target volume—implications for tumor control probability modeling and optimization

	Thomas Bortfeld, Nadya Shusharina, David Craft

	Physics in Medicine & Biology. 2021; 66(1): 01NT01

	[Pubmed] [Google Scholar] [DOI]

15	New target volume delineation and PTV strategies to further personalise radiotherapy

	David Bernstein, Alexandra Taylor, Simeon Nill, Uwe Oelfke

	Physics in Medicine & Biology. 2021; 66(5): 055024

	[Pubmed] [Google Scholar] [DOI]

16	Accounting for uncertainties in the position of anatomical barriers used to define the clinical target volume

	Nadya Shusharina, Jonas Söderberg, David Lidberg, Maximilian Niyazi, Helen A Shih, Thomas Bortfeld

	Physics in Medicine & Biology. 2021; 66(15): 15NT01

	[Pubmed] [Google Scholar] [DOI]

17	MRI-guided Radiation Therapy: An Emerging Paradigm in Adaptive Radiation Oncology

	Ricardo Otazo, Philippe Lambin, Jean-Philippe Pignol, Mark E. Ladd, Heinz-Peter Schlemmer, Michael Baumann, Hedvig Hricak

	Radiology. 2021; 298(2): 248

	[Pubmed] [Google Scholar] [DOI]

18	Clinical Acceptability of Automated Radiation Treatment Planning for Head and Neck Cancer Using the Radiation Planning Assistant

	Adenike Olanrewaju, Laurence E. Court, Lifei Zhang, Komeela Naidoo, Hester Burger, Sameera Dalvie, Julie Wetter, Jeannette Parkes, Christoph J. Trauernicht, Rachel E. McCarroll, Carlos Cardenas, Christine B. Peterson, Kathryn R.K. Benson, Monique du Toit, Ricus van Reenen, Beth M. Beadle

	Practical Radiation Oncology. 2021; 11(3): 177

	[Pubmed] [Google Scholar] [DOI]

19	Optimal delineation of the clinical target volume for thymomas in the post-resection setting: A multi-center study

	Florit Marcuse, Stephanie Peeters, Kato Herman, Femke Vaassen, Wouter van Elmpt, Alexander P.W.M. Maat, John Praag, Charlotte Billiet, Paul Van Schil, Maarten Lambrecht, Dirk Van Raemdonck, Kim Cao, Madalina Grigoroiu, Nicolas Girard, Monique Hochstenbag, Jos Maessen, Dirk De Ruysscher

	Radiotherapy and Oncology. 2021; 165: 8

	[Pubmed] [Google Scholar] [DOI]

20	Variability of gross tumour volume delineation: MRI and CT based tumour and lymph node delineation for Lung radiotherapy

	Shivani Kumar, Lois Holloway, Miriam Boxer, Mei Ling Yap, Phillip Chlap, Daniel Moses, Shalini Vinod

	Radiotherapy and Oncology. 2021;

	[Pubmed] [Google Scholar] [DOI]

21	Evaluation of the impact of teaching on delineation variation during a virtual stereotactic ablative radiotherapy contouring workshop

	Finbar Slevin, Romélie Rieu, Matthew Beasley, Richard Speight, Katharine Aitken, James Good, Fiona McDonald, Thomas Rackley, Ganesh Radhakrishna, Anoop Haridass, Louise J. Murray, Alison C. Tree, Ann M. Henry

	Journal of Radiotherapy in Practice. 2021; : 1

	[Pubmed] [Google Scholar] [DOI]

22	Imaging for Target Delineation in Head and Neck Cancer Radiotherapy

	Kenneth Jensen, Gina Al-Farra, Danijela Dejanovic, Jesper G. Eriksen, Annika Loft, Christian R. Hansen, Frank A. Pameijer, Ruta Zukauskaite, Cai Grau

	Seminars in Nuclear Medicine. 2021; 51(1): 59

	[Pubmed] [Google Scholar] [DOI]

23	Correlation of in-vivo imaging with histopathology: A review

	Anando Sen, Patricia Troncoso, Aradhana Venkatesan, Mark D. Pagel, Jasper A. Nijkamp, Yulun He, Anne-Cecille Lesage, McKell Woodland, Kristy K. Brock

	European Journal of Radiology. 2021; 144: 109964

	[Pubmed] [Google Scholar] [DOI]

24	Assessing tumor centrality in lung stereotactic ablative body radiotherapy (SABR): the effects of variations in bronchial tree delineation and potential for automated methods

	Wsam Ghandourh, Jason Dowling, Phillip Chlap, Andrew Oar, Susannah Jacob, Vikneswary Batumalai, Lois Holloway

	Medical Dosimetry. 2021; 46(1): 94

	[Pubmed] [Google Scholar] [DOI]

25	Improved adaptive radiotherapy to adjust for anatomical alterations during curative treatment for locally advanced lung cancer

	Maria Moksnes Bjaanæs, Erlend Peter Skaug Sande, Øyvind Loe, Christina Ramberg, Tove Mette Næss, Andreas Ottestad, Lotte V. Rogg, Jørund Graadal Svestad, Vilde Drageset Haakensen

	Physics and Imaging in Radiation Oncology. 2021; 18: 51

	[Pubmed] [Google Scholar] [DOI]

26	Task group 284 report: magnetic resonance imaging simulation in radiotherapy: considerations for clinical implementation, optimization, and quality assurance

	Carri K. Glide-Hurst, Eric S. Paulson, Kiaran McGee, Neelam Tyagi, Yanle Hu, James Balter, John Bayouth

	Medical Physics. 2021; 48(7)

	[Pubmed] [Google Scholar] [DOI]

27	Improving generalization in MR-to-CT synthesis in radiotherapy by using an augmented cycle generative adversarial network with unpaired data

	Kévin N. D. Brou Boni, John Klein, Akos Gulyban, Nick Reynaert, David Pasquier

	Medical Physics. 2021; 48(6): 3003

	[Pubmed] [Google Scholar] [DOI]

28	MR-Guided Adaptive Radiotherapy for Bladder Cancer

	Adham Hijab, Boris Tocco, Ian Hanson, Hanneke Meijer, Christina Junker Nyborg, Anders Smedegaard Bertelsen, Robert Jan Smeenk, Gillian Smith, Jeff Michalski, Brian C. Baumann, Shaista Hafeez

	Frontiers in Oncology. 2021; 11

	[Pubmed] [Google Scholar] [DOI]

29	Quality Assurance in Modern Gynecological HDR-Brachytherapy (Interventional Radiotherapy): Clinical Considerations and Comments

	Tamer Soror, Frank-André Siebert, Valentina Lancellotta, Elisa Placidi, Bruno Fionda, Luca Tagliaferri, György Kovács

	Cancers. 2021; 13(4): 912

	[Pubmed] [Google Scholar] [DOI]

30	Key Technology Considerations in Developing and Deploying Machine Learning Models in Clinical Radiology Practice

	Viraj Kulkarni, Manish Gawali, Amit Kharat

	JMIR Medical Informatics. 2021; 9(9): e28776

	[Pubmed] [Google Scholar] [DOI]

31	FIELDRT: an open-source platform for the assessment of target volume delineation in radiation therapy

	Concetta Piazzese, Elin Evans, Betsan Thomas, John Staffurth, Sarah Gwynne, Emiliano Spezi

	The British Journal of Radiology. 2021; 94(1126): 20210356

	[Pubmed] [Google Scholar] [DOI]

32	Implementation of carbon fibre treatment couches in the XiO® and Monaco® Treatment Planning Systems

	Christoffel Jacobus Van Reenen, Christoph Jan Trauernicht

	Polish Journal of Medical Physics and Engineering. 2020; 26(4): 211

	[Pubmed] [Google Scholar] [DOI]

33	A Deep Learning-Based Automated CT Segmentation of Prostate Cancer Anatomy for Radiation Therapy Planning-A Retrospective Multicenter Study

	Timo Kiljunen, Saad Akram, Jarkko Niemelä, Eliisa Löyttyniemi, Jan Seppälä, Janne Heikkilä, Kristiina Vuolukka, Okko-Sakari Kääriäinen, Vesa-Pekka Heikkilä, Kaisa Lehtiö, Juha Nikkinen, Eduard Gershkevitsh, Anni Borkvel, Merve Adamson, Daniil Zolotuhhin, Kati Kolk, Eric Pei Ping Pang, Jeffrey Kit Loong Tuan, Zubin Master, Melvin Lee Kiang Chua, Timo Joensuu, Juha Kononen, Mikko Myllykangas, Maigo Riener, Miia Mokka, Jani Keyriläinen

	Diagnostics. 2020; 10(11): 959

	[Pubmed] [Google Scholar] [DOI]

34	Applications of Artificial Intelligence to Prostate Multiparametric MRI (mpMRI): Current and Emerging Trends

	Michelle D. Bardis, Roozbeh Houshyar, Peter D. Chang, Alexander Ushinsky, Justin Glavis-Bloom, Chantal Chahine, Thanh-Lan Bui, Mark Rupasinghe, Christopher G. Filippi, Daniel S. Chow

	Cancers. 2020; 12(5): 1204

	[Pubmed] [Google Scholar] [DOI]

35	Contour Variability in Thyroid Eye Disease with Compressive Optic Neuropathy Treated with Radiation Therapy

	Tavish Nanda, Andrew Sanchez, Juhi Purswani, Cheng-Chia Wu, Michael Kazim, Tony J.C. Wang

	Advances in Radiation Oncology. 2020; 5(5): 804

	[Pubmed] [Google Scholar] [DOI]

36	Feasibility of magnetic resonance guided radiotherapy for the treatment of bladder cancer

	A. Hunt, I. Hanson, A. Dunlop, H. Barnes, L. Bower, J. Chick, C. Cruickshank, E. Hall, T. Herbert, R. Lawes, D. McQuaid, H. McNair, A. Mitchell, J. Mohajer, T. Morgan, U. Oelfke, G. Smith, S. Nill, R. Huddart, S. Hafeez

	Clinical and Translational Radiation Oncology. 2020; 25: 46

	[Pubmed] [Google Scholar] [DOI]

37	Impact of contouring variability on oncological PET radiomics features in the lung

	F. Yang, G. Simpson, L. Young, J. Ford, N. Dogan, L. Wang

	Scientific Reports. 2020; 10(1)

	[Pubmed] [Google Scholar] [DOI]

38	MRI-based radiomics in breast cancer: feature robustness with respect to inter-observer segmentation variability

	R. W. Y. Granzier, N. M. H. Verbakel, A. Ibrahim, J. E. van Timmeren, T. J. A. van Nijnatten, R. T. H. Leijenaar, M. B. I. Lobbes, M. L. Smidt, H. C. Woodruff

	Scientific Reports. 2020; 10(1)

	[Pubmed] [Google Scholar] [DOI]

39	The use of hyaluronic acid hydrogel as a tumour bed marker in breast-conserving therapy

	Judyta Wiercinska, Janusz Winiecki, Anna Wronczewska, Andrzej Lebioda, Krzysztof Plawski, Piotr Rhone, Roman Makarewicz

	Radiotherapy and Oncology. 2020; 152: 8

	[Pubmed] [Google Scholar] [DOI]

40	The role of computational methods for automating and improving clinical target volume definition

	Jan Unkelbach, Thomas Bortfeld, Carlos E. Cardenas, Vincent Gregoire, Wille Hager, Ben Heijmen, Robert Jeraj, Stine S. Korreman, Roman Ludwig, Bertrand Pouymayou, Nadya Shusharina, Jonas Söderberg, Iuliana Toma-Dasu, Esther G.C. Troost, Eliana Vasquez Osorio

	Radiotherapy and Oncology. 2020; 153: 15

	[Pubmed] [Google Scholar] [DOI]

41	Clinical implementation of MRI-based organs-at-risk auto-segmentation with convolutional networks for prostate radiotherapy

	Mark H. F. Savenije, Matteo Maspero, Gonda G. Sikkes, Jochem R. N. van der Voort van Zyp, Alexis N. T. J. Kotte, Gijsbert H. Bol, Cornelis A. T. van den Berg

	Radiation Oncology. 2020; 15(1)

	[Pubmed] [Google Scholar] [DOI]

42	End-to-end test of an online adaptive treatment procedure in MR-guided radiotherapy using a phantom with anthropomorphic structures

	A Elter, S Dorsch, P Mann, A Runz, W Johnen, C K Spindeldreier, S Klüter, C P Karger

	Physics in Medicine & Biology. 2019; 64(22): 225003

	[Pubmed] [Google Scholar] [DOI]

43	How rapid advances in imaging are defining the future of precision radiation oncology

	Laura Beaton, Steve Bandula, Mark N. Gaze, Ricky A. Sharma

	British Journal of Cancer. 2019; 120(8): 779

	[Pubmed] [Google Scholar] [DOI]

44	Prospective International Pilot Study Evaluating the Efficacy of a Self-Guided Contouring Teaching Module With Integrated Feedback for Transitioning From 2D to 3D Treatment Planning

	Mustafa Abugideiri, Eduard Schreibmann, Jeffrey Switchenko, Mark W. McDonald, Jonathan J. Beitler, Walter J. Curran, Deborah Bruner, Pretesh Patel, Wondemagegnhu Tigeneh, Miressa Mijena, Sibo Tian, Anees Dhabaan, Natia Esiashvili, Tian Liu, Arif N. Ali

	Journal of Global Oncology. 2019; (5): 1

	[Pubmed] [Google Scholar] [DOI]

45	Retrospective Validation and Clinical Implementation of Automated Contouring of Organs at Risk in the Head and Neck: A Step Toward Automated Radiation Treatment Planning for Low- and Middle-Income Countries

	Rachel E. McCarroll, Beth M. Beadle, Peter A. Balter, Hester Burger, Carlos E. Cardenas, Sameera Dalvie, David S. Followill, Kelly D. Kisling, Michael Mejia, Komeela Naidoo, Chris L. Nelson, Christine B. Peterson, Karin Vorster, Julie Wetter, Lifei Zhang, Laurence E. Court, Jinzhong Yang

	Journal of Global Oncology. 2018; (4): 1

	[Pubmed] [Google Scholar] [DOI]

46	Compared planning dosimetry of TOMO, VMAT and IMRT in rectal cancer with different simulated positions

	Jang-Chun Lin, Jo-Ting Tsai, Li-Jhen Chen, Ming-Hsien Li, Wei-Hsiu Liu

	Oncotarget. 2017; 8(26): 42020

	[Pubmed] [Google Scholar] [DOI]

47	Uncertainties in target volume delineation in radiotherapy – are they relevant and what can we do about them?

	Barbara Segedin, Primoz Petric

	Radiology and Oncology. 2016; 50(3): 254

	[Pubmed] [Google Scholar] [DOI]

48	Impact of the introduction of weekly radiotherapy quality assurance meetings at one UK cancer centre

	C V Brammer,L Pettit,R Allerton,M Churn,M Joseph,P Koh,I Sayers,M King

	The British Journal of Radiology. 2014; 87(1043): 20140422

	[Pubmed] [Google Scholar] [DOI]

49	Benchmarking of a treatment planning system for spot scanning proton therapy: Comparison and analysis of robustness to setup errors of photon IMRT and proton SFUD treatment plans of base of skull meningioma

	R. Harding,P. Trnková,S. J. Weston,J. Lilley,C. M. Thompson,S. C. Short,C. Loughrey,V. P. Cosgrove,A. J. Lomax,D. I. Thwaites

	Medical Physics. 2014; 41(11): 111710

	[Pubmed] [Google Scholar] [DOI]

50	Imaging of oesophageal cancer with FDG-PET/CT and MRI

	P.S.N. van Rossum,A.L.H.M.W. van Lier,I.M. Lips,G.J. Meijer,O. Reerink,M. van Vulpen,M.G.E.H. Lam,R. van Hillegersberg,J.P. Ruurda

	Clinical Radiology. 2014;

	[Pubmed] [Google Scholar] [DOI]

51	The effect of image-guided radiation therapy on the margin between the clinical target volume and planning target volume in lung cancer

	Jun Liang,Minghui Li,Tao Zhang,Wei Han,Dongfu Chen,Zhouguang Hui,Jima Lv,Zhong Zhang,Yin Zhang,Liansheng Zhang,Rong Zheng,Jianrong Dai,Luhua Wang

	Journal of Medical Radiation Sciences. 2014; 61(1): 30

	[Pubmed] [Google Scholar] [DOI]

52	Target volume delineation and margins in the management of lung cancers in the era of image guided radiation therapy

	Robert Lin

	Journal of Medical Radiation Sciences. 2014; 61(1): 1

	[Pubmed] [Google Scholar] [DOI]

53	IGRT has limited clinical value due to lack of accurate tumor delineation

	Njeh, C.F. and Dong, L. and Orton, C.G.

	Medical Physics. 2013; 40(4)

	[Pubmed] [Google Scholar]

54	Dosimetric impact of inter-observer variability for 3D conformal radiotherapy and volumetric modulated arc therapy: The rectal tumor target definition case

	Lobefalo, F. and Bignardi, M. and Reggiori, G. and Tozzi, A. and Tomatis, S. and Alongi, F. and Fogliata, A. and Gaudino, A. and Navarria, P. and Cozzi, L. and Scorsetti, M. and Mancosu, P.

	Radiation Oncology. 2013; 8(1)

	[Pubmed] [Google Scholar]

55	Imaging strategies in the management of oesophageal cancer: Whatæs the role of MRI?

	Van Rossum, P.S.N. and Van Hillegersberg, R. and Lever, F.M. and Lips, I.M. and Van Lier, A.L.H.M.W. and Meijer, G.J. and Van Leeuwen, M.S. and Van Vulpen, M. and Ruurda, J.P.

	European Radiology. 2013; 23(7): 1753-1765

	[Pubmed] [Google Scholar]

56	Variability in prostate and seminal vesicle delineations defined on magnetic resonance images, a multi-observer, -center and -sequence study

	Nyholm, T. and Jonsson, J. and SÃ¶derstrÃ¶m, K. and BergstrÃ¶m, P. and Carlberg, A. and Frykholm, G. and Behrens, C.F. and Geertsen, P.F. and Trepiakas, R. and Hanvey, S. and Sadozye, A. and Ansari, J. and McCallum, H. and Frew, J. and McMenemin, R. and Zackrisson, B.

	Radiation Oncology. 2013; 8(1)

	[Pubmed] [Google Scholar]

57	Uncertainties of target volume delineation in MRI guided adaptive brachytherapy of cervix cancer: A multi-institutional study

	PetriÄ, P. and Hudej, R. and Rogelj, P. and Blas, M. and Tanderup, K. and Fidarova, E. and Kirisits, C. and Berger, D. and Dimopoulos, J.C.A. and PÃ¶tter, R. and Hellebust, T.P.

	Radiotherapy and Oncology. 2013; 107(1): 6-12

	[Pubmed] [Google Scholar]

58	A multiphase validation of atlas-based automatic and semiautomatic segmentation strategies for prostate MRI

	Martin, S. and Rodrigues, G. and Patil, N. and Bauman, G. and DæSouza, D. and Sexton, T. and Palma, D. and Louie, A.V. and Khalvati, F. and Tizhoosh, H.R. and Gaede, S.

	International Journal of Radiation Oncology Biology Physics. 2013; 85(1): 95-100

	[Pubmed] [Google Scholar]

59	Imaging strategies in the management of oesophageal cancer: what’s the role of MRI?

	Peter S. N. Rossum,Richard Hillegersberg,Frederiek M. Lever,Irene M. Lips,Astrid L. H. M. W. Lier,Gert J. Meijer,Maarten S. Leeuwen,Marco Vulpen,Jelle P. Ruurda

	European Radiology. 2013; 23(7): 1753

	[Pubmed] [Google Scholar] [DOI]

60	A Multiphase Validation of Atlas-Based Automatic and Semiautomatic Segmentation Strategies for Prostate MRI

	Spencer Martin,George Rodrigues,Nikhilesh Patil,Glenn Bauman,David DæSouza,Tracy Sexton,David Palma,Alexander V. Louie,Farzad Khalvati,Hamid R. Tizhoosh,Stewart Gaede

	International Journal of Radiation OncologyBiologyPhysics. 2013; 85(1): 95

	[Pubmed] [Google Scholar] [DOI]

61	IGRT has limited clinical value due to lack of accurate tumor delineation

	Christopher F. Njeh,Lei Dong,Colin G. Orton

	Medical Physics. 2013; 40(4): 040601

	[Pubmed] [Google Scholar] [DOI]

62	Functional Imaging for Radiation Treatment Planning, Response Assessment, and Adaptive Therapy in Head and Neck Cancer

	Priya Bhatnagar,Manil Subesinghe,Chirag Patel,Robin Prestwich,Andrew F. Scarsbrook

	RadioGraphics. 2013; 33(7): 1909

	[Pubmed] [Google Scholar] [DOI]

63	Contour Propagation Using Feature-Based Deformable Registration for Lung Cancer

	Yuhan Yang,Shoujun Zhou,Peng Shang,En Qi,Shibin Wu,Yaoqin Xie

	BioMed Research International. 2013; 2013: 1

	[Pubmed] [Google Scholar] [DOI]

64	Variability in prostate and seminal vesicle delineations defined on magnetic resonance images, a multi-observer, -center and -sequence study

	Tufve Nyholm,Joakim Jonsson,Karin Söderström,Per Bergström,Andreas Carlberg,Gunilla Frykholm,Claus F Behrens,Poul Geertsen,Redas Trepiakas,Scott Hanvey,Azmat Sadozye,Jawaher Ansari,Hazel McCallum,John Frew,Rhona McMenemin,Björn Zackrisson

	Radiation Oncology. 2013; 8(1): 126

	[Pubmed] [Google Scholar] [DOI]

65	Dosimetric impact of inter-observer variability for 3D conformal radiotherapy and volumetric modulated arc therapy: the rectal tumor target definition case

	Francesca Lobefalo, Mario Bignardi, Giacomo Reggiori, Angelo Tozzi, Stefano Tomatis, Filippo Alongi, Antonella Fogliata, Anna Gaudino, Piera Navarria, Luca Cozzi, Marta Scorsetti, Pietro Mancosu

	Radiation Oncology. 2013; 8(1)

	[Pubmed] [Google Scholar] [DOI]

66	Uncertainties of target volume delineation in MRI guided adaptive brachytherapy of cervix cancer: A multi-institutional study

	Primož Petric,Robert Hudej,Peter Rogelj,Mateja Blas,Kari Tanderup,Elena Fidarova,Christian Kirisits,Daniel Berger,Johannes Carl Athanasios Dimopoulos,Richard Pötter,Taran Paulsen Hellebust

	Radiotherapy and Oncology. 2013; 107(1): 6

	[Pubmed] [Google Scholar] [DOI]

67	Quantitative Metrics for Assessing Plan Quality

	Kevin L. Moore, R. Scott Brame, Daniel A. Low, Sasa Mutic

	Seminars in Radiation Oncology. 2012; 22(1): 62

	[HTML Full text] [Google Scholar] [DOI]

68	PET based volume segmentation with emphasis on the iterative TrueX algorithm

	Barbara Knäusl,Albert Hirtl,Georg Dobrozemsky,Helmar Bergmann,Kurt Kletter,Robert Dudczak,Dietmar Georg

	Zeitschrift für Medizinische Physik. 2012; 22(1): 29

	[Pubmed] [Google Scholar] [DOI]

69	Internal Fiducial Markers and Susceptibility Effects in MRI—Simulation and Measurement of Spatial Accuracy

	Joakim H. Jonsson,Anders Garpebring,Magnus G. Karlsson,Tufve Nyholm

	International Journal of Radiation OncologyBiologyPhysics. 2012; 82(5): 1612

	[Pubmed] [Google Scholar] [DOI]

70	Vendor provided machine data should never be used as a substitute for fully commissioning a linear accelerator

	Indra J. Das, Christopher F. Njeh, Colin G. Orton

	Medical Physics. 2012; 39(2): 569

	[HTML Full text] [Google Scholar] [DOI]

71	Accuracy in contouring of small and low contrast lesions: Comparison between diagnostic quality computed tomography scanner and computed tomography simulation scanner—A phantom study

	Yick Wing Ho,Wing Kei Rebecca Wong,Siu Ki Yu,Wai Wang Lam,Hui Geng

	Medical Dosimetry. 2012; 37(4): 401

	[Pubmed] [Google Scholar] [DOI]

72	Accelerated partial breast irradiation using external beam conformal radiation therapy: A review

	Christopher F. Njeh, Mark W. Saunders, Christian M. Langton

	Critical Reviews in Oncology/Hematology. 2012; 81(1): 1

	[HTML Full text] [Google Scholar] [DOI]

73	Improving Target Definition for Head and Neck Radiotherapy: A Place for Magnetic Resonance Imaging and 18-Fluoride Fluorodeoxyglucose Positron Emission Tomography?

	R.J.D. Prestwich,J. Sykes,B. Carey,M. Sen,K.E. Dyker,A.F. Scarsbrook

	Clinical Oncology. 2012; 24(8): 577

	[Pubmed] [Google Scholar] [DOI]

74	Critical discussion of evaluation parameters for inter-observer variability in target definition for radiation therapy

	I. Fotina, C. Lütgendorf-Caucig, M. Stock, R. Pötter, D. Georg

	Strahlentherapie und Onkologie. 2012; 188(2): 160

	[HTML Full text] [Google Scholar] [DOI]

75	Accuracy in contouring of small and low contrast lesions: Comparison between diagnostic quality computed tomography scanner and computed tomography simulation scanner-A phantom study

	Ho, Y.W. and Wong, W.K.R. and Yu, S.K. and Lam, W.W. and Geng, H.

	Medical Dosimetry. 2012; 37(4): 401-405

	[Pubmed] [Google Scholar]

76	Internal fiducial markers and susceptibility effects in MRI - Simulation and measurement of spatial accuracy

	Jonsson, J.H. and Garpebring, A. and Karlsson, M.G. and Nyholm, T.

	International Journal of Radiation Oncology Biology Physics. 2012; 82(5): 1612-1618

	[Pubmed] [Google Scholar]

77	PET based volume segmentation with emphasis on the iterative TrueX algorithm

	KnÃ¤usl, B. and Hirtl, A. and Dobrozemsky, G. and Bergmann, H. and Kletter, K. and Dudczak, R. and Georg, D.

	Zeitschrift fur Medizinische Physik. 2012; 22(1): 29-39

	[Pubmed] [Google Scholar]

78	Improving Target Definition for Head and Neck Radiotherapy: A Place for Magnetic Resonance Imaging and 18-Fluoride Fluorodeoxyglucose Positron Emission Tomography?

	Prestwich, R.J.D. and Sykes, J. and Carey, B. and Sen, M. and Dyker, K.E. and Scarsbrook, A.F.

	Clinical Oncology. 2012; 24(8): 577-589

	[Pubmed] [Google Scholar]

79	Prospective randomized double-blind pilot study of site-specific consensus atlas implementation for rectal cancer target volume delineation in the cooperative group setting

	Fuller, C.D., Nijkamp, J., Duppen, J.C., Rasch, C.R.N., Thomas Jr., C.R., Wang, S.J., Okunieff, P., (...), Kachnic, L.A.

	International Journal of Radiation Oncology Biology Physics. 2011; 79(2): 481-489

	[Pubmed] [Google Scholar]

80	Evaluation of tomotherapy MVCT image enhancement program for tumor volume delineation

	Martin, S. and Rodrigues, G. and Chen, Q. and Pavamani, S. and Read, N. and Ahmad, B. and Hammond, J.A. and Venkatesan, V. and Renaud, J. and Yartsev, S.

	Journal of Applied Clinical Medical Physics. 2011; 12(3): 112-121

	[Pubmed] [Google Scholar]

81	Prospective Randomized Double-Blind Pilot Study of Site-Specific Consensus Atlas Implementation for Rectal Cancer Target Volume Delineation in the Cooperative Group Setting

	Clifton D. Fuller,Jasper Nijkamp,Joop C. Duppen,Coen R.N. Rasch,Charles R. Thomas,Samuel J. Wang,Paul Okunieff,William E. Jones,Daniel Baseman,Shilpen Patel,Carlo G.N. Demandante,Anna M. Harris,Benjamin D. Smith,Alan W. Katz,Camille McGann,Jennifer L. Harper,Daniel T. Chang,Stephen Smalley,David T. Marshall,Karyn A. Goodman,Niko Papanikolaou,Lisa A. Kachnic

	International Journal of Radiation OncologyBiologyPhysics. 2011; 79(2): 481

	[Pubmed] [Google Scholar] [DOI]

82	Sensitivity of postplanning target and OAR coverage estimates to dosimetric margin distribution sampling parameters

	Huijun Xu, J. James Gordon, Jeffrey V. Siebers

	Medical Physics. 2011; 38(2): 1018

	[HTML Full text] [Google Scholar] [DOI]

83	Accelerated Partial Breast Irradiation (APBI): A review of available techniques

	Njeh, C.F., Saunders, M.W., Langton, C.M.

	Radiation Oncology. 2010; 5(1): art 90

	[Pubmed] [Google Scholar]

84	Technological advances in radiotherapy for esophageal cancer

	Vosmik, M., Petera, J., Sirak, I., Hodek, M., Paluska, P., Dolezal, J., Kopacova, M.

	World Journal of Gastroenterology. 2010; 16(44): 5555-5564

	[Pubmed] [Google Scholar]