Your search keyword '"Karin M. Meijer"' showing total 4 results

1. Timing matters: diurnal spine length variation in pediatric patients during radiotherapy

Author

Karin M. Meijer, Irma W.E.M. van Dijk, Tamara J. Schonk, Brian V. Balgobind, Anna Loginova, Niek van Wieringen, and Arjan Bel

Subjects

Pediatric cancer, Radiotherapy, Diurnal spine length variation, Geometrical uncertainties, Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background During the day-night cycle, gravity and applied stress to the body mass and spine causes a decrease in body height, which is restored overnight. This diurnal spine length variation has not yet been quantified during radiotherapy. Therefore, we aimed to quantify diurnal spine length variation on cone beam CTs (CBCTs) of pediatric patients (

Published

2024

2. Diaphragm and abdominal organ motion during radiotherapy: a comprehensive multicenter study in 189 children

Author

Karin M. Meijer, Irma W. E. M. van Dijk, Marije Frank, Arnout D. van den Hoek, Brian V. Balgobind, Geert O. Janssens, Markus Wendling, John H. Maduro, Abigail Bryce-Atkinson, Anna Loginova, and Arjan Bel

Subjects

Pediatric cancer, Organ motion, Systematic and random errors, Safety margins, Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background For accurate thoracic and abdominal radiotherapy, inter- and intrafractional geometrical uncertainties need to be considered to enable accurate margin sizes. We aim to quantify interfractional diaphragm and abdominal organ position variations, and intrafractional diaphragm motion in a large multicenter cohort of pediatric cancer patients (

Published

2023

3. Pediatric radiotherapy for thoracic and abdominal targets: Organ motion, reported margin sizes, and delineation variations – A systematic review

Author

Karin M, Meijer, Irma W E M, van Dijk, Sophie C, Huijskens, Joost G, Daams, Brian V, Balgobind, and Arjan, Bel

Subjects

Pediatric thoracic and abdominal cancer, Radiotherapy Planning, Computer-Assisted, Pediatric IGRT, Radiotherapy Dosage, Hematology, Safety margins, Oncology, Humans, Delineation variability, Organ Motion, Radiology, Nuclear Medicine and imaging, Dose Fractionation, Radiation, Child, Radiotherapy, Image-Guided

Abstract

For radiotherapy of thoracic and abdominal tumors safety margins are applied to address geometrical uncertainties caused by e.g. set-up errors, organ motion and delineation variability. For pediatric patients no standardized margins are defined. Moreover, studies on these geometrical uncertainties are relatively scarce. Therefore, this systematic review presents an overview of organ motion, applied margin sizes and delineation variability in patients

Published

2022

4. Design and evaluation of a modular multimodality imaging phantom to simulate heterogeneous uptake and enhancement patterns for radiomic quantification in hybrid imaging: A feasibility study

Author

Gijsbert M. Kalisvaart, Floris H.P. van Velden, Irene Hernández‐Girón, Karin M. Meijer, Laura M.H. Ghesquiere‐Dierickx, Wyger M. Brink, Andrew Webb, Lioe‐Fee de Geus‐Oei, Cornelis H. Slump, Dimitri V. Kuznetsov, Dennis R. Schaart, Willem Grootjans, Biomedical Photonic Imaging, Robotics and Mechatronics, and TechMed Centre

Subjects

Fluorodeoxyglucose F18, Phantoms, Imaging, hybrid imaging, radiomics, Positron-Emission Tomography, Image Processing, Computer-Assisted, Feasibility Studies, phantom studies, General Medicine, 3D printing, repeatability, Multimodal Imaging, multimodality imaging

Abstract

Background: Accuracy and precision assessment in radiomic features is important for the determination of their potential to characterize cancer lesions. In this regard, simulation of different imaging conditions using specialized phantoms is increasingly being investigated. In this study, the design and evaluation of a modular multimodality imaging phantom to simulate heterogeneous uptake and enhancement patterns for radiomics quantification in hybrid imaging is presented. Methods: A modular multimodality imaging phantom was constructed that could simulate different patterns of heterogeneous uptake and enhancement patterns in positron emission tomography (PET), single-photon emission computed tomography (SPECT), computed tomography (CT), and magnetic resonance (MR) imaging. The phantom was designed to be used as an insert in the standard NEMA-NU2 IEC body phantom casing. The entire phantom insert is composed of three segments, each containing three separately fillable compartments. The fillable compartments between segments had different sizes in order to simulate heterogeneous patterns at different spatial scales. The compartments were separately filled with different ratios of Tc-99m-pertechnetate, F-18-fluorodeoxyglucose ([F-18]FDG), iodine- and gadolinium-based contrast agents for SPECT, PET, CT, and T-1-weighted MR imaging respectively. Image acquisition was performed using standard oncological protocols on all modalities and repeated five times for repeatability assessment. A total of 93 radiomic features were calculated. Variability was assessed by determining the coefficient of quartile variation (CQV) of the features. Comparison of feature repeatability at different modalities and spatial scales was performed using Kruskal-Wallis-, Mann-Whitney U-, one-way ANOVA- and independent t-tests. Results: Heterogeneous uptake and enhancement could be simulated on all four imaging modalities. Radiomic features in SPECT were significantly less stable than in all other modalities. Features in PET were significantly less stable than in MR and CT. A total of 20 features, particularly in the gray-level co-occurrence matrix (GLCM) and gray-level run-length matrix (GLRLM) class, were found to be relatively stable in all four modalities for all three spatial scales of heterogeneous patterns (with CQV < 10%). Conclusion: The phantom was suitable for simulating heterogeneous uptake and enhancement patterns in [F-18]FDG-PET, Tc-99m-SPECT, CT, and T-1-weighted MR images. The results of this work indicate that the phantom might be useful for the further development and optimization of imaging protocols for radiomic quantification in hybrid imaging modalities.

Published

2022