Your search keyword '"RADIOTHERAPY RESEARCH"' showing total 13 results

1. Response of the FBX aqueous chemical dosimeter to high energy proton and electron beams used for radiotherapy research.

Author

Kotb, Omar M., Solovev, Aleksei N., Saburov, Vyacheslav O., Potetnya, Vladimir I., Koryakina, Ekaterina V., Adarova, Alevtina I., Lepilina, Olga G., Koryakin, Sergei N., Ivanov, Sergei A., and Kaprin, Andrei D.

Subjects

*ELECTRON beams, *DOSIMETERS, *PROTON beams, *GAMMA rays, *CHEMICAL yield, *MEDICAL dosimetry

Abstract

The response of the FBX aqueous chemical dosimeter to 10 MeV electron and 100 MeV proton beams was investigated, and the results were compared with those obtained for cobalt-60 gamma rays over a dose range of 0–30 Gy. The sensitivities of the FBX dosimeter in which the absorbance values were measured at the wavelength of maximum absorption (λ max) and 548 nm are approximately the same and amount to 0.091, 0.088, and 0.081 Gy-1 for 10 MeV electrons, cobalt 60 γ-rays, and 100 MeV proton beams, respectively. The corresponding calibration coefficients are 10.99, 11.36, and 12.35 Gy, in their respective order. The molar absorption coefficients that were calculated for cobalt-60 gamma rays amount to 17824 ± 560, 16417 ± 248, and 17694 ± 437 M−1cm−1 at the wavelengths λ max , 540 nm, and 548 nm, respectively. The radiation chemical yield-G (Fe3+) at the wavelengths of λ max and 548 nm has approximately the same values and amounts to 51.1 × 10−7, 49.4 × 10−7, and 45.4 × 10−7 mol.J−1 for 10 MeV electrons, cobalt-60 γ-rays, and 100 MeV proton beams, respectively, and both of them are lower by ∼ 8% than that obtained at the wavelength of 540 nm. A linear response of the FBX dosimeters prepared in the current study was achieved up to 12 Gy, compared with the linear response up to 5 Gy reported in the previous literature. Furthermore, by measuring the absorbance values at the wavelength of the isobestic point, i.e., 555 nm, the linearity of the FBX dosimetric solution may be extended to cover the entire dose range used, i.e., 0.2–30 Gy. Consequently, with good reproducibility (less than 1%), the prepared FBX dosimeter can be utilized for radiotherapy research over the dose range of 0.2–30 Gy. • The response of the FBX dosimeter to different radiation beams was investigated. • A linear response of the FBX dosimeter over the dose range 0.2–12 Gy was obtained. • The radiation chemical yield at the wavelengths of λ max and 548 nm is the same. • The FBX dosimetric response should be investigated at 555 nm, the isobestic point. • The FBX linearity response may be extended to cover the entire dose range, 0.2–30 Gy. [ABSTRACT FROM AUTHOR]

Published

2024

2. A review in radiomics: Making personalized medicine a reality via routine imaging

Subjects

PET RADIOMICS, deep learning, personalized medicine, LEARNING HEALTH-CARE, SURVIVAL PREDICTION, DIAGNOSIS, artificial intelligence, CHEST CT, LUNG-CANCER, machine learning, radiomics, COMPUTED-TOMOGRAPHY, CANCER PATIENTS, FEDERATED DATABASES, RADIOTHERAPY RESEARCH, DECISION-SUPPORT-SYSTEMS

Abstract

Radiomics is the quantitative analysis of standard-of-care medical imaging; the information obtained can be applied within clinical decision support systems to create diagnostic, prognostic, and/or predictive models. Radiomics analysis can be performed by extracting hand-crafted radiomics features or via deep learning algorithms. Radiomics has evolved tremendously in the last decade, becoming a bridge between imaging and precision medicine. Radiomics exploits sophisticated image analysis tools coupled with statistical elaboration to extract the wealth of information hidden inside medical images, such as computed tomography (CT), magnetic resonance (MR), and/or Positron emission tomography (PET) scans, routinely performed in the everyday clinical practice. Many efforts have been devoted in recent years to the standardization and validation of radiomics approaches, to demonstrate their usefulness and robustness beyond any reasonable doubts. However, the booming of publications and commercial applications of radiomics approaches warrant caution and proper understanding of all the factors involved to avoid "scientific pollution" and overly enthusiastic claims by researchers and clinicians alike. For these reasons the present review aims to be a guidebook of sorts, describing the process of radiomics, its pitfalls, challenges, and opportunities, along with its ability to improve clinical decision-making, from oncology and respiratory medicine to pharmacological and genotyping studies.

Published

2022

3. A review in radiomics: Making personalized medicine a reality via routine imaging

Author

Pierre Lovinfosse, Nathan Tsoutzidis, Wim Vos, Denis Danthine, Roland Hustinx, Akshayaa Vaidyanathan, Louis Deprez, Fadila Zerka, Ralph T.H. Leijenaar, Marta Ferreira, Benjamin Miraglio, Julien Guiot, Anne-Noëlle Frix, Philippe Lambin, Sean Walsh, and Fabio Bottari

Subjects

Standardization, PET RADIOMICS, Computer science, SURVIVAL PREDICTION, DIAGNOSIS, Medical Oncology, Clinical decision support system, CHEST CT, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, LUNG-CANCER, 0302 clinical medicine, Radiomics, Drug Discovery, Image Processing, Computer-Assisted, Medical imaging, Humans, COMPUTED-TOMOGRAPHY, CANCER PATIENTS, Precision Medicine, Pharmacology, business.industry, deep learning, personalized medicine, LEARNING HEALTH-CARE, artificial intelligence, Precision medicine, Magnetic Resonance Imaging, Data science, 3. Good health, Respiratory Medicine, machine learning, radiomics, Positron-Emission Tomography, 030220 oncology & carcinogenesis, Molecular Medicine, Personalized medicine, Analysis tools, FEDERATED DATABASES, business, RADIOTHERAPY RESEARCH, DECISION-SUPPORT-SYSTEMS

Abstract

Radiomics is the quantitative analysis of standard-of-care medical imaging; the information obtained can be applied within clinical decision support systems to create diagnostic, prognostic, and/or predictive models. Radiomics analysis can be performed by extracting hand-crafted radiomics features or via deep learning algorithms. Radiomics has evolved tremendously in the last decade, becoming a bridge between imaging and precision medicine. Radiomics exploits sophisticated image analysis tools coupled with statistical elaboration to extract the wealth of information hidden inside medical images, such as computed tomography (CT), magnetic resonance (MR), and/or Positron emission tomography (PET) scans, routinely performed in the everyday clinical practice. Many efforts have been devoted in recent years to the standardization and validation of radiomics approaches, to demonstrate their usefulness and robustness beyond any reasonable doubts. However, the booming of publications and commercial applications of radiomics approaches warrant caution and proper understanding of all the factors involved to avoid "scientific pollution" and overly enthusiastic claims by researchers and clinicians alike. For these reasons the present review aims to be a guidebook of sorts, describing the process of radiomics, its pitfalls, challenges, and opportunities, along with its ability to improve clinical decision-making, from oncology and respiratory medicine to pharmacological and genotyping studies.

Published

2021

4. Radiomics

Subjects

BODY RADIATION-THERAPY, CELL LUNG-CANCER, INTRINSIC RADIOSENSITIVITY, BREAST-CANCER, PROGNOSTIC-FACTOR, F-18-FDG PET, LEARNING HEALTH-CARE, RADIOTHERAPY RESEARCH, DECISION-SUPPORT-SYSTEMS, GENE-EXPRESSION

Abstract

Radiomics, the high-throughput mining of quantitative image features from standard-of-care medical imaging that enables data to be extracted and applied within clinical-decision support systems to improve diagnostic, prognostic, and predictive accuracy, is gaining importance in cancer research. Radiomic analysis exploits sophisticated image analysis tools and the rapid development and validation of medical imaging data that uses image-based signatures for precision diagnosis and treatment, providing a powerful tool in modern medicine. Herein, we describe the process of radiomics, its pitfalls, challenges, opportunities, and its capacity to improve clinical decision making, emphasizing the utility for patients with cancer. Currently, the field of radiomics lacks standardized evaluation of both the scientific integrity and the clinical relevance of the numerous published radiomics investigations resulting from the rapid growth of this area. Rigorous evaluation criteria and reporting guidelines need to be established in order for radiomics to mature as a discipline. Herein, we provide guidance for investigations to meet this urgent need in the field of radiomics.

Published

2017

5. Getting started with research.

Author

Probst, Heidi and Harris, Rachel

Abstract

Do you have an enquiring mind and an enthusiasm or thirst for knowledge? Do you want to get involved in radiotherapy research or develop your research expertise? Research should underpin the clinical and educational activities undertaken by Radiation Therapists. For many, research can seem a daunting process that is beyond their expertise or capabilities. All health care practitioners can use research evidence and some may want to undertake their own research but may feel unsure where to start.This article is aimed at novice researchers (or those with limited research experience) and those wanting to develop their research potential. The discussion should help practitioners identify the necessary skills required to undertake research, where to go for help, the research process (including where research ideas come from), and what to consider when putting together a project team or applying for research funding.The discussion concludes on the importance of research training and support (or mentoring) for novice researchers or those at the start of their research careers. The national professional body for therapists can play an important role in helping researchers to network with likeminded individuals. Some professional bodies (such as the College of radiographers in the UK) may also provide small research grants to help build research activity, and as such can be a useful starting point when considering research funding. [ABSTRACT FROM PUBLISHER]

Published

2009

6. Radiotherapy research activity and radiographer involvement in the UK.

Author

Davies, Julie and Rawlings, Christine

Abstract

In the UK, radiotherapy research is being conducted at national and international levels which include multi-centre clinical trials. Local initiatives and trials are also ongoing where work is being performed to develop techniques or protocols for new technologies and service development. Active participation within these studies is now leading to a culture change with radiographers (radiation therapists) becoming an integral part of the research process. There are currently 70 radiographers in the UK participating in research. This accounts for 2.5% of the UK profession. With the extension of role diversification, research radiographers are undertaking many new roles; however, there is still scope for further development. The therapists’ role in working within this research environment is to ensure improved standards of care focussed on evidence-based practice. [ABSTRACT FROM PUBLISHER]

Published

2009

7. Treatment data and technical process challenges for practical big data efforts in radiation oncology

Author

Mayo, C. S., Mayo, C. S., Phillips, M., McNutt, T. R., Palta, J., Dekker, A., Miller, R. C., Xiao, Y., Moran, J. M., Matuszak, M. M., Gabriel, P., Ayan, A. S., Prisciandaro, J., Thor, M., Dixit, N., Popple, R., Killoran, J., Kaleba, E., Kantor, M., Ruan, D., Kapoor, R., Kessler, M. L., Lawrence, T. S., Mayo, C. S., Mayo, C. S., Phillips, M., McNutt, T. R., Palta, J., Dekker, A., Miller, R. C., Xiao, Y., Moran, J. M., Matuszak, M. M., Gabriel, P., Ayan, A. S., Prisciandaro, J., Thor, M., Dixit, N., Popple, R., Killoran, J., Kaleba, E., Kantor, M., Ruan, D., Kapoor, R., Kessler, M. L., and Lawrence, T. S.

Abstract

The term Big Data has come to encompass a number of concepts and uses within medicine. This paper lays out the relevance and application of large collections of data in the radiation oncology community. We describe the potential importance and uses in clinical practice. The important concepts are then described and how they have been or could be implemented are discussed. Impediments to progress in the collection and use of sufficient quantities of data are also described. Finally, recommendations for how the community can move forward to achieve the potential of big data in radiation oncology are provided.

Published

2018

8. Treatment data and technical process challenges for practical big data efforts in radiation oncology

Author

Y. Xiao, Andre Dekker, Mark Phillips, Charles S. Mayo, Joseph H. Killoran, Peter Gabriel, Dan Ruan, Richard A. Popple, R Kapoor, Todd McNutt, Jatinder R. Palta, Ahmet S. Ayan, M Kantor, Theodore S. Lawrence, Robert C. Miller, E Kaleba, Marc L. Kessler, Jean M. Moran, Maria Thor, Nayha Dixit, Martha M. Matuszak, Joann I. Prisciandaro, Radiotherapie, and RS: GROW - R3 - Innovative Cancer Diagnostics & Therapy

Subjects

Databases, Factual, Standardization, INFORMATION, Computer science, Big data, Information Storage and Retrieval, Ontology (information science), DATABASES, THERAPY, 030218 nuclear medicine & medical imaging, 0302 clinical medicine, big data, Neoplasms, Data Mining, informatics, ontology, POPULATION, Cancer, education.field_of_study, General Medicine, Other Physical Sciences, Nuclear Medicine & Medical Imaging, machine learning, Networking and Information Technology R&D (NITRD), 030220 oncology & carcinogenesis, RADIOTHERAPY RESEARCH, Process (engineering), Population, Oncology and Carcinogenesis, Biomedical Engineering, CANCER-PATIENTS, Article, 03 medical and health sciences, Databases, Clinical Research, Radiation oncology, Humans, Relevance (information retrieval), education, Factual, Neoplasm Staging, standardization, Motivation, business.industry, MEDICINE, Data science, Term (time), Informatics, Radiation Oncology, business, Medical Informatics

Abstract

The term Big Data has come to encompass a number of concepts and uses within medicine. This paper lays out the relevance and application of large collections of data in the radiation oncology community. We describe the potential importance and uses in clinical practice. The important concepts are then described and how they have been or could be implemented are discussed. Impediments to progress in the collection and use of sufficient quantities of data are also described. Finally, recommendations for how the community can move forward to achieve the potential of big data in radiation oncology are provided.

Published

2018

9. Radiomics: the bridge between medical imaging and personalized medicine

Author

Lambin, Philippe, Lambin, Philippe, Leijenaar, Ralph T. H., Deist, Timo M., Peerlings, Jurgen, de Jong, Evelyn E. C., van Timmeren, Janita, Sanduleanu, Sebastian, Larue, Ruben T. H. M., Even, Aniek J. G., Jochems, Arthur, van Wijk, Yvonka, Woodruff, Henry, van Soest, Johan, Lustberg, Tim, Roelofs, Erik, van Elmpt, Wouter, Dekker, Andre, Mottaghy, Felix M., Wildberger, Joachim E., Walsh, Sean, Lambin, Philippe, Lambin, Philippe, Leijenaar, Ralph T. H., Deist, Timo M., Peerlings, Jurgen, de Jong, Evelyn E. C., van Timmeren, Janita, Sanduleanu, Sebastian, Larue, Ruben T. H. M., Even, Aniek J. G., Jochems, Arthur, van Wijk, Yvonka, Woodruff, Henry, van Soest, Johan, Lustberg, Tim, Roelofs, Erik, van Elmpt, Wouter, Dekker, Andre, Mottaghy, Felix M., Wildberger, Joachim E., and Walsh, Sean

Abstract

Radiomics, the high-throughput mining of quantitative image features from standard-of-care medical imaging that enables data to be extracted and applied within clinical-decision support systems to improve diagnostic, prognostic, and predictive accuracy, is gaining importance in cancer research. Radiomic analysis exploits sophisticated image analysis tools and the rapid development and validation of medical imaging data that uses image-based signatures for precision diagnosis and treatment, providing a powerful tool in modern medicine. Herein, we describe the process of radiomics, its pitfalls, challenges, opportunities, and its capacity to improve clinical decision making, emphasizing the utility for patients with cancer. Currently, the field of radiomics lacks standardized evaluation of both the scientific integrity and the clinical relevance of the numerous published radiomics investigations resulting from the rapid growth of this area. Rigorous evaluation criteria and reporting guidelines need to be established in order for radiomics to mature as a discipline. Herein, we provide guidance for investigations to meet this urgent need in the field of radiomics.

Published

2017

10. Radiomics: the bridge between medical imaging and personalized medicine

Author

Jurgen Peerlings, Ruben T. H. M. Larue, Henry C. Woodruff, Yvonka van Wijk, Sebastian Sanduleanu, Tim Lustberg, Ralph T.H. Leijenaar, Aniek J.G. Even, Janita E. van Timmeren, Sean Walsh, Erik Roelofs, Johan van Soest, Joachim E. Wildberger, Evelyn E.C. de Jong, Felix M. Mottaghy, Arthur Jochems, Andre Dekker, Timo M. Deist, Philippe Lambin, and Wouter van Elmpt

Subjects

Diagnostic Imaging, Patient-Specific Modeling, Modern medicine, Pathology, medicine.medical_specialty, Decision support system, BODY RADIATION-THERAPY, CELL LUNG-CANCER, Clinical Decision-Making, MEDLINE, Bridge (nautical), Decision Support Techniques, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Predictive Value of Tests, Neoplasms, Medical imaging, BREAST-CANCER, Data Mining, Humans, Medicine, F-18-FDG PET, Precision Medicine, GENE-EXPRESSION, business.industry, INTRINSIC RADIOSENSITIVITY, LEARNING HEALTH-CARE, Prognosis, Precision medicine, Data science, 3. Good health, Oncology, 030220 oncology & carcinogenesis, PROGNOSTIC-FACTOR, Personalized medicine, Diffusion of Innovation, business, RADIOTHERAPY RESEARCH, DECISION-SUPPORT-SYSTEMS

Abstract

Radiomics, the high-throughput mining of quantitative image features from standard-of-care medical imaging that enables data to be extracted and applied within clinical-decision support systems to improve diagnostic, prognostic, and predictive accuracy, is gaining importance in cancer research. Radiomic analysis exploits sophisticated image analysis tools and the rapid development and validation of medical imaging data that uses image-based signatures for precision diagnosis and treatment, providing a powerful tool in modern medicine. Herein, we describe the process of radiomics, its pitfalls, challenges, opportunities, and its capacity to improve clinical decision making, emphasizing the utility for patients with cancer. Currently, the field of radiomics lacks standardized evaluation of both the scientific integrity and the clinical relevance of the numerous published radiomics investigations resulting from the rapid growth of this area. Rigorous evaluation criteria and reporting guidelines need to be established in order for radiomics to mature as a discipline. Herein, we provide guidance for investigations to meet this urgent need in the field of radiomics.

Published

2017

11. Distributed learning: Developing a predictive model based on data from multiple hospitals without data leaving the hospital - A real life proof of concept

Author

Johan van Soest, Andre Dekker, P. Bulens, Philippe Lambin, Michael J. Eble, Timo M. Deist, Wim Dries, Arthur Jochems, Philippe Coucke, RS: GROW - R3 - Innovative Cancer Diagnostics & Therapy, Radiotherapie, and Promovendi ODB

Subjects

Male, EXTERNAL VALIDATION, Lung Neoplasms, Privacy laws of the United States, TOXICITY, 030218 nuclear medicine & medical imaging, 0302 clinical medicine, Health care, Medicine, Data Mining, Precision Medicine, Hematology, Europe, Oncology, Proof of concept, Radiology Nuclear Medicine and imaging, 030220 oncology & carcinogenesis, Bayesian networks, distributed learning, privacy preserving data-mining, dyspnea, machine learning, Female, RADIOTHERAPY RESEARCH, Confidentiality, 03 medical and health sciences, LUNG-CANCER, Predictive Value of Tests, Machine learning, Humans, Radiology, Nuclear Medicine and imaging, Operations management, ddc:610, Radiation Injuries, Distributed learning, Radiotherapy, business.industry, Information Dissemination, External validation, Bayesian network, Bayes Theorem, Models, Theoretical, Privacy preserving data-mining, Data sharing, BAYESIAN NETWORK, Dyspnea, ROC Curve, CLINICAL-DATA, HEALTH-CARE, Personalized medicine, business

Abstract

Radiotherapy and oncology 121(3), 459-467 (2016). doi:10.1016/j.radonc.2016.10.002, Published by Elsevier Science, Amsterdam

Published

2016

12. Intracoronary radiation therapy health technologoy scientific literature review.

Author

Ontario. Ministry of Health and Long-Term Care. Medical Advisory Secretariat. and Ontario. Ministry of Health and Long-Term Care. Medical Advisory Secretariat.

Abstract

Archived by Library: Aug. 4, 2004., "Completed December 2001, under review for update."

Published

2004

13. Effects of Polyporus umbellatus on the leukocyte count in gamma ray-irradiated mice

Author

Chen, Tai-Hei, Song, Fu-Chuang, Hau, Dou-Mong, and You, Jyu-Sheng

Published

1990