Your search keyword '"Jaehee Chun"' showing total 20 results

1. Evaluation of deep learning-based autosegmentation in breast cancer radiotherapy

Author

Jin Sung Kim, Yongjin Chang, Yong Bae Kim, Jinhong Jung, Jee Suk Chang, Jaehee Chun, Min Seo Choi, Seung Yeun Chung, Seungryul Lee, Hwa Kyung Byun, and Chiyoung Jeong

Subjects

Organs at Risk, medicine.medical_specialty, Autocontouring, R895-920, Breast radiotherapy, Breast Neoplasms, Breast cancer radiotherapy, Expert committee, Medical physics. Medical radiology. Nuclear medicine, Deep Learning, medicine, Image Processing, Computer-Assisted, Humans, Radiology, Nuclear Medicine and imaging, Medical physics, Breast, RC254-282, Observer Variation, Adjuvant radiotherapy, Contouring, Radiotherapy, business.industry, Deep learning, Research, Radiotherapy Planning, Computer-Assisted, User satisfaction, Radiation Oncologists, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Radiotherapy Dosage, Clinical Practice, Oncology, Female, Radiotherapy, Adjuvant, Artificial intelligence, Radiotherapy, Intensity-Modulated, business

Abstract

Purpose To study the performance of a proposed deep learning-based autocontouring system in delineating organs at risk (OARs) in breast radiotherapy with a group of experts. Methods Eleven experts from two institutions delineated nine OARs in 10 cases of adjuvant radiotherapy after breast-conserving surgery. Autocontours were then provided to the experts for correction. Overall, 110 manual contours, 110 corrected autocontours, and 10 autocontours of each type of OAR were analyzed. The Dice similarity coefficient (DSC) and Hausdorff distance (HD) were used to compare the degree of agreement between the best manual contour (chosen by an independent expert committee) and each autocontour, corrected autocontour, and manual contour. Higher DSCs and lower HDs indicated a better geometric overlap. The amount of time reduction using the autocontouring system was examined. User satisfaction was evaluated using a survey. Results Manual contours, corrected autocontours, and autocontours had a similar accuracy in the average DSC value (0.88 vs. 0.90 vs. 0.90). The accuracy of autocontours ranked the second place, based on DSCs, and the first place, based on HDs among the manual contours. Interphysician variations among the experts were reduced in corrected autocontours, compared to variations in manual contours (DSC: 0.89–0.90 vs. 0.87–0.90; HD: 4.3–5.8 mm vs. 5.3–7.6 mm). Among the manual delineations, the breast contours had the largest variations, which improved most significantly with the autocontouring system. The total mean times for nine OARs were 37 min for manual contours and 6 min for corrected autocontours. The results of the survey revealed good user satisfaction. Conclusions The autocontouring system had a similar performance in OARs as that of the experts’ manual contouring. This system can be valuable in improving the quality of breast radiotherapy and reducing interphysician variability in clinical practice.

Published

2021

2. Deep-Learning-Based Automatic Segmentation of Head and Neck Organs for Radiation Therapy in Dogs

Author

Jaehwan Kim, Jayon Kim, In Kyung Park, Jaeeun Ko, Jin Sung Kim, Byoungsu Choi, Kidong Eom, Jeongsu Park, Jaehee Chun, and Juyoung Lee

Subjects

dog head and neck, Contouring, Human studies, medicine.diagnostic_test, General Veterinary, business.industry, medicine.medical_treatment, Veterinary medicine, Computed tomography, artificial intelligence, radiation therapy, Standard deviation, Radiation therapy, deep-learning-based automatic segmentation, SF600-1100, Medicine, Automatic segmentation, Veterinary Science, head and neck cancer, Head and neck, business, Nuclear medicine, Original Research

Abstract

Purpose: This study was conducted to develop a deep learning-based automatic segmentation (DLBAS) model of head and neck organs for radiotherapy (RT) in dogs, and to evaluate the feasibility for delineating the RT planning.Materials and Methods: The segmentation indicated that there were potentially 15 organs at risk (OARs) in the head and neck of dogs. Post-contrast computed tomography (CT) was performed in 90 dogs. The training and validation sets comprised 80 CT data sets, including 20 test sets. The accuracy of the segmentation was assessed using both the Dice similarity coefficient (DSC) and the Hausdorff distance (HD), and by referencing the expert contours as the ground truth. An additional 10 clinical test sets with relatively large displacement or deformation of organs were selected for verification in cancer patients. To evaluate the applicability in cancer patients, and the impact of expert intervention, three methods–HA, DLBAS, and the readjustment of the predicted data obtained via the DLBAS of the clinical test sets (HA_DLBAS)–were compared.Results: The DLBAS model (in the 20 test sets) showed reliable DSC and HD values; it also had a short contouring time of ~3 s. The average (mean ± standard deviation) DSC (0.83 ± 0.04) and HD (2.71 ± 1.01 mm) values were similar to those of previous human studies. The DLBAS was highly accurate and had no large displacement of head and neck organs. However, the DLBAS in the 10 clinical test sets showed lower DSC (0.78 ± 0.11) and higher HD (4.30 ± 3.69 mm) values than those of the test sets. The HA_DLBAS was comparable to both the HA (DSC: 0.85 ± 0.06 and HD: 2.74 ± 1.18 mm) and DLBAS presented better comparison metrics and decreased statistical deviations (DSC: 0.94 ± 0.03 and HD: 2.30 ± 0.41 mm). In addition, the contouring time of HA_DLBAS (30 min) was less than that of HA (80 min).Conclusion: In conclusion, HA_DLBAS method and the proposed DLBAS was highly consistent and robust in its performance. Thus, DLBAS has great potential as a single or supportive tool to the key process in RT planning.

Published

2021

3. Technical Note: Real‐time 3D MRI in the presence of motion for MRI‐guided radiotherapy: 3D Dynamic keyhole imaging with super‐resolution

Author

Justin C. Park, Sasa Mutic, H. Michael Gach, Taeho Kim, and Jaehee Chun

Subjects

Similarity (geometry), Image quality, Movement, Motion (geometry), Signal-To-Noise Ratio, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Imaging, Three-Dimensional, 0302 clinical medicine, Approximation error, medicine, Computer vision, Physics, medicine.diagnostic_test, business.industry, Air, Resolution (electron density), Water, Magnetic resonance imaging, General Medicine, Magnetic Resonance Imaging, Superresolution, 030220 oncology & carcinogenesis, Artificial intelligence, business, Monte Carlo Method, Keyhole, Radiotherapy, Image-Guided

Abstract

PURPOSE The purpose of this study was to present real-time three-dimensional (3D) magnetic resonance imaging (MRI) in the presence of motion for MRI-guided radiotherapy (MRgRT) using dynamic keyhole imaging for high-temporal acquisition and super-resolution generative (SRG) model for high-spatial reconstruction. METHOD We propose a unique real-time 3D MRI technique by combining a data sharing technique (3D dynamic keyhole imaging) with a SRG model using cascaded deep learning technique. 3D dynamic keyhole imaging utilizes the data sharing mechanism by combining keyhole central k-space data acquired in real-time with high-spatial, high-temporal resolution prior peripheral k-space data at various motion positions prepared by the SRG model. The efficacy of the 3D dynamic keyhole imaging with super-resolution (SR_dKeyhole) was compared to the ground-truth super-resolution images with the original full k-space data. It was also compared with the zero-filling reconstruction (zero-filling), conventional keyhole reconstruction with low-spatial high-temporal prior data (LR_cKeyhole), and conventional keyhole reconstruction with super-resolution prior data (SR_cKeyhole). RESULTS High-spatial, high-temporal resolution 3D MRI datasets (1.5 × 1.5 × 6 mm3 ) were generated from low-spatial, high-temporal resolution 3D MRI datasets (6 × 6 × 6 mm3 ) using the cascaded deep learning SRG framework (

Published

2019

4. Synthetic CT reconstruction using a deep spatial pyramid convolutional framework for MR‐only breast radiotherapy

Author

Maria A. Thomas, Vivian Rodriguez, Imran Zoberi, Olga Green, Sasa Mutic, Hao Zhang, William R. Kennedy, Sven Olberg, Justin C. Park, Jaehee Chun, and Jin Sung Kim

Subjects

Image quality, Computer science, medicine.medical_treatment, Breast Neoplasms, Breast radiotherapy, Computed tomography, Translation (geometry), 030218 nuclear medicine & medical imaging, Convolution, Set (abstract data type), 03 medical and health sciences, Deep Learning, 0302 clinical medicine, Pyramid, Image Processing, Computer-Assisted, medicine, Humans, Pyramid (image processing), Radiation treatment planning, medicine.diagnostic_test, business.industry, Radiotherapy Planning, Computer-Assisted, Radiotherapy Dosage, Magnetic resonance imaging, Pattern recognition, General Medicine, Magnetic Resonance Imaging, Radiation therapy, Generative model, 030220 oncology & carcinogenesis, Artificial intelligence, Tomography, X-Ray Computed, business, Encoder, Radiotherapy, Image-Guided

Abstract

Purpose The superior soft-tissue contrast achieved using magnetic resonance imaging (MRI) compared to x-ray computed tomography (CT) has led to the popularization of MRI-guided radiation therapy (MR-IGRT), especially in recent years with the advent of first and second generation MRI-based therapy delivery systems for MR-IGRT. The expanding use of these systems is driving interest in MRI-only RT workflows in which MRI is the sole imaging modality used for treatment planning and dose calculations. To enable such a workflow, synthetic CT (sCT) data must be generated based on a patient's MRI data so that dose calculations may be performed using the electron density information derived from CT images. In this study, we propose a novel deep spatial pyramid convolutional framework for the MRI-to-CT image-to-image translation task and compare its performance to the well established U-Net architecture in a generative adversarial network (GAN) framework. Methods Our proposed framework utilizes atrous convolution in a method named atrous spatial pyramid pooling (ASPP) to significantly reduce the total number of parameters required to describe the model while effectively capturing rich, multi-scale structural information in a manner that is not possible in the conventional framework. The proposed framework consists of a generative model composed of stacked encoders and decoders separated by the ASPP module, where atrous convolution is applied at increasing rates in parallel to encode large-scale features. The performance of the proposed method is compared to that of the conventional GAN framework in terms of the time required to train the model and the image quality of the generated sCT as measured by the root mean square error (RMSE), structural similarity index (SSIM), and peak signal-to-noise ratio (PSNR) depending on the size of the training data set. Dose calculations based on sCT data generated using the proposed architecture are also compared to clinical plans to evaluate the dosimetric accuracy of the method. Results Significant reductions in training time and improvements in image quality are observed at every training data set size when the proposed framework is adopted instead of the conventional framework. Over 1042 test images, values of 17.7 ± 4.3 HU, 0.9995 ± 0.0003, and 71.7 ± 2.3 are observed for the RMSE, SSIM, and PSNR metrics, respectively. Dose distributions calculated based on sCT data generated using the proposed framework demonstrate passing rates equal to or greater than 98% using the 3D gamma index with a 2%/2 mm criterion. Conclusions The deep spatial pyramid convolutional framework proposed here demonstrates improved performance compared to the conventional GAN framework that has been applied to the image-to-image translation task of sCT generation. Adopting the method is a first step toward an MRI-only RT workflow that enables widespread clinical applications for MR-IGRT including online adaptive therapy.

Published

2019

5. Evaluation of super-resolution on 50 pancreatic cancer patients with real-time cine MRI from 0.35T MRgRT

Author

Jaehee Chun, Justin C. Park, Benjamin C. Lewis, Taeho Kim, Zhen Ji, Jin Sung Kim, and J. I. Shin

Subjects

Physics, Pixel, Image quality, business.industry, Magnetic Resonance Imaging, Cine, Frame rate, Edge detection, Sagittal plane, Machine Learning, Pancreatic Neoplasms, medicine.anatomical_structure, Imaging, Three-Dimensional, Distortion, medicine, Humans, Computer vision, Noise (video), Artificial intelligence, business, Image resolution, General Nursing

Abstract

MR-guided radiotherapy (MRgRT) systems provide excellent soft tissue imaging immediately prior to and in real time during radiation delivery for cancer treatment. However, 2D cine MRI often has limited spatial resolution due to high temporal resolution. This work applies a super resolution machine learning framework to 3.5 mm pixel edge length, low resolution (LR), sagittal 2D cine MRI images acquired on a MRgRT system to generate 0.9 mm pixel edge length, super resolution (SR), images originally acquired at 4 frames per second (FPS). LR images were collected from 50 pancreatic cancer patients treated on a ViewRay MR-LINAC. SR images were evaluated using three methods. 1) The first method utilized intrinsic image quality metrics for evaluation. 2) The second used relative metrics including edge detection and structural similarity index (SSIM). 3) Finally, automatically generated tumor contours were created on both low resolution and super resolution images to evaluate target delineation and compared with DICE and SSIM. Intrinsic image quality metrics all had statistically significant improvements for SR images versus LR images, with mean (±1 SD) BRISQUE scores of 29.65 ± 2.98 and 42.48 ± 0.98 for SR and LR, respectively. SR images showed good agreement with LR images in SSIM evaluation, indicating there was not significant distortion of the images. Comparison of LR and SR images with paired high resolution (HR) 3D images showed that SR images had a mean (±1 SD) SSIM value of 0.633 ± 0.063 and LR a value of 0.587 ± 0.067 (p ≪ 0.05). Contours generated on SR images were also more robust to noise addition than those generated on LR images. This study shows that super resolution with a machine learning framework can generate high spatial resolution images from 4fps low spatial resolution cine MRI acquired on the ViewRay MR-LINAC while maintaining tumor contour quality and without significant acquisition or post processing delay.

Published

2021

6. Intentional Deep Overfit Learning (IDOL): A Novel Deep Learning Strategy for Adaptive Radiation Therapy

Author

Jin Sung Kim, You Zhang, Justin C. Park, Sven Olberg, Jaehee Chun, Jing Wang, Dan Nguyen, and Steve B. Jiang

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Computer science, Computer Vision and Pattern Recognition (cs.CV), Computer Science - Computer Vision and Pattern Recognition, Overfitting, Machine learning, computer.software_genre, Task (project management), Machine Learning (cs.LG), Deep Learning, Image Processing, Computer-Assisted, FOS: Electrical engineering, electronic engineering, information engineering, Humans, Generalizability theory, business.industry, Radiotherapy Planning, Computer-Assisted, Deep learning, Supervised learning, Image and Video Processing (eess.IV), Radiotherapy Dosage, General Medicine, Electrical Engineering and Systems Science - Image and Video Processing, Magnetic Resonance Imaging, Term (time), Workflow, Proof of concept, Artificial intelligence, business, computer

Abstract

PURPOSE Applications of deep learning (DL) are essential to realizing an effective adaptive radiotherapy (ART) workflow. Despite the promise demonstrated by DL approaches in several critical ART tasks, there remain unsolved challenges to achieve satisfactory generalizability of a trained model in a clinical setting. Foremost among these is the difficulty of collecting a task-specific training dataset with high-quality, consistent annotations for supervised learning applications. In this study, we propose a tailored DL framework for patient-specific performance that leverages the behavior of a model intentionally overfitted to a patient-specific training dataset augmented from the prior information available in an ART workflow-an approach we term Intentional Deep Overfit Learning (IDOL). METHODS Implementing the IDOL framework in any task in radiotherapy consists of two training stages: (1) training a generalized model with a diverse training dataset of N patients, just as in the conventional DL approach, and (2) intentionally overfitting this general model to a small training dataset-specific the patient of interest ( N+1 ) generated through perturbations and augmentations of the available task- and patient-specific prior information to establish a personalized IDOL model. The IDOL framework itself is task-agnostic and is, thus, widely applicable to many components of the ART workflow, three of which we use as a proof of concept here: the autocontouring task on replanning CTs for traditional ART, the MRI super-resolution (SR) task for MRI-guided ART, and the synthetic CT (sCT) reconstruction task for MRI-only ART. RESULTS In the replanning CT autocontouring task, the accuracy measured by the Dice similarity coefficient improves from 0.847 with the general model to 0.935 by adopting the IDOL model. In the case of MRI SR, the mean absolute error (MAE) is improved by 40% using the IDOL framework over the conventional model. Finally, in the sCT reconstruction task, the MAE is reduced from 68 to 22 HU by utilizing the IDOL framework. CONCLUSIONS In this study, we propose a novel IDOL framework for ART and demonstrate its feasibility using three ART tasks. We expect the IDOL framework to be especially useful in creating personally tailored models in situations with limited availability of training data but existing prior information, which is usually true in the medical setting in general and is especially true in ART.

Published

2021

7. Patterns of Locoregional Recurrence after Radical Cystectomy for Stage T3-4 Bladder Cancer: A Radiation Oncologist's Point of View

Author

Jaehee Chun, Jae Hee Cheon, Won Sik Ham, Hyun Ju Kim, Tae Hyung Kim, Woong Sub Koom, Jin Sung Kim, Gowoon Yang, Sang Joon Shin, and Jaemoon Yang

Subjects

medicine.medical_specialty, recurrence, medicine.medical_treatment, Perineural invasion, Locally advanced, Planning target volume, 030204 cardiovascular system & hematology, Cystectomy, 03 medical and health sciences, 0302 clinical medicine, cystectomy, medicine, Humans, Stage (cooking), Radiation oncologist, Retrospective Studies, Adjuvant radiotherapy, Bladder cancer, business.industry, Radiation Oncologists, General Medicine, medicine.disease, Urinary Bladder Neoplasms, Oncology, 030220 oncology & carcinogenesis, Original Article, Radiology, Neoplasm Recurrence, Local, business, adjuvant radiotherapy

Abstract

PURPOSE Adjuvant radiotherapy (RT) has been performed to reduce locoregional failure (LRF) following radical cystectomy for locally advanced bladder cancer; however, its efficacy has not been well established. We analyzed the locoregional recurrence patterns of post-radical cystectomy to identify patients who could benefit from adjuvant RT and determine the optimal target volume. MATERIALS AND METHODS We retrospectively reviewed 160 patients with stage ≥ pT3 bladder cancer who were treated with radical cystectomy between January 2006 and December 2015. The impact of pathologic findings, including the stage, lympho-vascular invasion, perineural invasion, margin status, nodal involvement, and the number of nodes removed on failure patterns, was assessed. RESULTS Median follow-up period was 27.7 months. LRF was observed in 55 patients (34.3%), 12 of whom presented with synchronous local and regional failures as the first failure. The most common failure pattern was distant metastasis (40%). Among LRFs, the most common recurrence site was the cystectomy bed (15.6%). Patients with positive resection margins had a significantly higher recurrence rate compared to those without (28% vs. 10%, p=0.004). The pelvic nodal recurrence rate was < 5% in pN0 patients; the rate of recurrence in the external and common iliac nodes was 12.5% in pN+ patients. The rate of recurrence in the common iliac nodes was significantly higher in pN2-3 patients than in pN0-1 patients (15.2% vs. 4.4%, p=0.04). CONCLUSION Pelvic RT could be beneficial especially for those with positive resection margins or nodal involvement after radical cystectomy. Radiation fields should be optimized based on the patient-specific risk factors.

Published

2021

8. Feasibility of Continual Deep Learning-Based Segmentation for Personalized Adaptive Radiation Therapy in Head and Neck Area

Author

Chang Geol Lee, Nalee Kim, Jaehee Chun, Ki Chang Keum, Jee Suk Chang, and Jin Sung Kim

Subjects

Cancer Research, Computer science, education, Image registration, lcsh:RC254-282, adaptive radiation therapy, Article, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Robustness (computer science), Segmentation, Adaptive radiotherapy, Head and neck, auto segmentation, business.industry, Deep learning, technology, industry, and agriculture, deep learning, Pattern recognition, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, artificial intelligence, Oncology, 030220 oncology & carcinogenesis, Test set, head and neck cancer, Artificial intelligence, business, Adaptive radiation therapy

Abstract

This study investigated the feasibility of deep learning-based segmentation (DLS) and continual training for adaptive radiotherapy (RT) of head and neck (H&amp, N) cancer. One-hundred patients treated with definitive RT were included. Based on 23 organs-at-risk (OARs) manually segmented in initial planning computed tomography (CT), modified FC-DenseNet was trained for DLS: (i) using data obtained from 60 patients, with 20 matched patients in the test set (DLSm), (ii) using data obtained from 60 identical patients with 20 unmatched patients in the test set (DLSu). Manually contoured OARs in adaptive planning CT for independent 20 patients were provided as test sets. Deformable image registration (DIR) was also performed. All 23 OARs were compared using quantitative measurements, and nine OARs were also evaluated via subjective assessment from 26 observers using the Turing test. DLSm achieved better performance than both DLSu and DIR (mean Dice similarity coefficient, 0.83 vs. 0.80 vs. 0.70), mainly for glandular structures, whose volume significantly reduced during RT. Based on subjective measurements, DLS is often perceived as a human (49.2%). Furthermore, DLSm is preferred over DLSu (67.2%) and DIR (96.7%), with a similar rate of required revision to that of manual segmentation (28.0% vs. 29.7%). In conclusion, DLS was effective and preferred over DIR. Additionally, continual DLS training is required for an effective optimization and robustness in personalized adaptive RT.

Published

2021

9. Clinical feasibility of deep learning-based auto-segmentation of target volumes and organs-at-risk in breast cancer patients after breast-conserving surgery

Author

Jin Sung Kim, Yong Bae Kim, Seung Yeun Chung, Ki Chang Keum, Jee Suk Chang, Yongjin Chang, Jaehee Chun, Byong Su Choi, and Min Seo Choi

Subjects

lcsh:Medical physics. Medical radiology. Nuclear medicine, Adult, Organs at Risk, medicine.medical_specialty, medicine.medical_treatment, lcsh:R895-920, Planning target volume, Breast Neoplasms, Mastectomy, Segmental, lcsh:RC254-282, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, medicine, Breast-conserving surgery, Humans, Radiology, Nuclear Medicine and imaging, Segmentation, Radiation treatment planning, Radiometry, Lymph node, Aged, Observer Variation, Auto-segmentation, business.industry, Deep learning, Research, Radiotherapy Planning, Computer-Assisted, Middle Aged, medicine.disease, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Radiation therapy, medicine.anatomical_structure, Clinical target volume, Oncology, 030220 oncology & carcinogenesis, Feasibility Studies, Female, Radiology, Artificial intelligence, Radiotherapy, Intensity-Modulated, Organs-at-risk, business, Tomography, X-Ray Computed

Abstract

Background In breast cancer patients receiving radiotherapy (RT), accurate target delineation and reduction of radiation doses to the nearby normal organs is important. However, manual clinical target volume (CTV) and organs-at-risk (OARs) segmentation for treatment planning increases physicians’ workload and inter-physician variability considerably. In this study, we evaluated the potential benefits of deep learning-based auto-segmented contours by comparing them to manually delineated contours for breast cancer patients. Methods CTVs for bilateral breasts, regional lymph nodes, and OARs (including the heart, lungs, esophagus, spinal cord, and thyroid) were manually delineated on planning computed tomography scans of 111 breast cancer patients who received breast-conserving surgery. Subsequently, a two-stage convolutional neural network algorithm was used. Quantitative metrics, including the Dice similarity coefficient (DSC) and 95% Hausdorff distance, and qualitative scoring by two panels from 10 institutions were used for analysis. Inter-observer variability and delineation time were assessed; furthermore, dose-volume histograms and dosimetric parameters were also analyzed using another set of patient data. Results The correlation between the auto-segmented and manual contours was acceptable for OARs, with a mean DSC higher than 0.80 for all OARs. In addition, the CTVs showed favorable results, with mean DSCs higher than 0.70 for all breast and regional lymph node CTVs. Furthermore, qualitative subjective scoring showed that the results were acceptable for all CTVs and OARs, with a median score of at least 8 (possible range: 0–10) for (1) the differences between manual and auto-segmented contours and (2) the extent to which auto-segmentation would assist physicians in clinical practice. The differences in dosimetric parameters between the auto-segmented and manual contours were minimal. Conclusions The feasibility of deep learning-based auto-segmentation in breast RT planning was demonstrated. Although deep learning-based auto-segmentation cannot be a substitute for radiation oncologists, it is a useful tool with excellent potential in assisting radiation oncologists in the future. Trial registration Retrospectively registered.

Published

2021

10. Abdominal synthetic CT reconstruction with intensity projection prior for MRI-only adaptive radiotherapy

Author

Olga L. Green, Sven Olberg, Byong Su Choi, Tae Ho Kim, Hyun Kim, Justin C. Park, Jin Sung Kim, In Kyung Park, and Jaehee Chun

Subjects

Paired Data, Training set, Radiological and Ultrasound Technology, business.industry, Radiotherapy Planning, Computer-Assisted, FOS: Physical sciences, Radiotherapy Dosage, Physics - Medical Physics, Magnetic Resonance Imaging, Intensity (physics), Soft tissue contrast, Dose escalation, Humans, Medicine, Radiology, Nuclear Medicine and imaging, Radiotherapy, Intensity-Modulated, Medical Physics (physics.med-ph), Adaptive radiotherapy, Tomography, X-Ray Computed, Nuclear medicine, business, Projection (set theory), Ct reconstruction

Abstract

Objective. Owing to the superior soft tissue contrast of MRI, MRI-guided adaptive radiotherapy (ART) is well-suited to managing interfractional changes in anatomy. An MRI-only workflow is desirable, but producing synthetic CT (sCT) data through paired data-driven deep learning (DL) for abdominal dose calculations remains a challenge due to the highly variable presence of intestinal gas. We present the preliminary dosimetric evaluation of our novel approach to sCT reconstruction that is well suited to handling intestinal gas in abdominal MRI-only ART.Approach. We utilize a paired data DL approach enabled by the intensity projection prior, in which well-matching training pairs are created by propagating air from MRI to corresponding CT scans. Evaluations focus on two classes: patients with (1) little involvement of intestinal gas, and (2) notable differences in intestinal gas presence between corresponding scans. Comparisons between sCT-based plans and CT-based clinical plans for both classes are made at the first treatment fraction to highlight the dosimetric impact of the variable presence of intestinal gas.Main results. Class 1 patients (n= 13) demonstrate differences in prescribed dose coverage of the PTV of 1.3 ± 2.1% between clinical plans and sCT-based plans. Mean DVH differences in all structures for Class 1 patients are found to be statistically insignificant. In Class 2 (n= 20), target coverage is 13.3 ± 11.0% higher in the clinical plans and mean DVH differences are found to be statistically significant.Significance. Significant deviations in calculated doses arising from the variable presence of intestinal gas in corresponding CT and MRI scans result in uncertainty in high-dose regions that may limit the effectiveness of adaptive dose escalation efforts. We have proposed a paired data-driven DL approach to sCT reconstruction for accurate dose calculations in abdominal ART enabled by the creation of a clinically unavailable training data set with well-matching representations of intestinal gas.

Published

2021

11. Clinical evaluation of atlas- and deep learning-based automatic segmentation of multiple organs and clinical target volumes for breast cancer

Author

Seung Yeun Chung, Jin Sung Kim, Nalee Kim, Jaehee Chun, Min Seo Choi, Jee Suk Chang, Yong Bae Kim, and Byeong Su Choi

Subjects

Organs at Risk, Computer science, medicine.medical_treatment, Breast Neoplasms, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, Deep Learning, Similarity (network science), medicine, Humans, Radiology, Nuclear Medicine and imaging, Segmentation, Radiation treatment planning, business.industry, Deep learning, Radiotherapy Planning, Computer-Assisted, Pattern recognition, Hematology, Gold standard (test), medicine.disease, Radiation therapy, Hausdorff distance, Oncology, 030220 oncology & carcinogenesis, Artificial intelligence, business, Tomography, X-Ray Computed

Abstract

Manual segmentation is the gold standard method for radiation therapy planning; however, it is time-consuming and prone to inter- and intra-observer variation, giving rise to interests in auto-segmentation methods. We evaluated the feasibility of deep learning-based auto-segmentation (DLBAS) in comparison to commercially available atlas-based segmentation solutions (ABAS) for breast cancer radiation therapy. This study used contrast-enhanced planning computed tomography scans from 62 patients with breast cancer who underwent breast-conservation surgery. Contours of target volumes (CTVs), organs, and heart substructures were generated using two commercial ABAS solutions and DLBAS using fully convolutional DenseNet. The accuracy of the segmentation was assessed using 14 test patients using the Dice Similarity Coefficient and Hausdorff Distance referencing the expert contours. A sensitivity analysis was performed using non-contrast planning CT from 14 additional patients. Compared to ABAS, the proposed DLBAS model yielded more consistent results and the highest average Dice Similarity Coefficient values and lowest Hausdorff Distances, especially for CTVs and the substructures of the heart. ABAS showed limited performance in soft-tissue-based regions, such as the esophagus, cardiac arteries, and smaller CTVs. The results of sensitivity analysis between contrast and non-contrast CT test sets showed little difference in the performance of DLBAS and conversely, a large discrepancy for ABAS. The proposed DLBAS algorithm was more consistent and robust in its performance than ABAS across the majority of structures when examining both CTVs and normal organs. DLBAS has great potential to aid a key process in the radiation therapy workflow, helping optimise and reduce the clinical workload.

Published

2020

12. Cardiac Substructure Delineation Based on Synthetic Contrast-Enhanced CT Generation Using Deep Convolutional Neural Network in Breast Cancer Radiation Therapy

Author

Jae Seung Chang, In Suh Park, Jin Soo Kim, and Jaehee Chun

Subjects

Cancer Research, Radiation, Enhanced ct, business.industry, medicine.medical_treatment, media_common.quotation_subject, Image registration, medicine.disease, Convolutional neural network, Radiation therapy, Breast cancer, Oncology, Right coronary artery, medicine.artery, medicine, Contrast (vision), Substructure, Radiology, Nuclear Medicine and imaging, Nuclear medicine, business, media_common

Abstract

PURPOSE/OBJECTIVE(S) Although radiation-induced cardiac toxicity is an important issue in breast radiation therapy (RT), the dose relationship between cardiac structures and its toxicity has not been fully elucidated, partially because many centers do not routinely administer intravenous (IV) contrast for breast RT, which preclude substructure delineation and detection of potential correlations. In this study, we attempted to generate the synthetic contrast-enhanced CT (CECTsyn) from the non-contrast CT (NCTreal) using deep convolutional neural network (DCNN) and to investigate whether CECTsyn can take a supportive role in case the studies for the cardiac toxicity induced by radiation is needed for the patient whose CECTreal cannot be obtained. MATERIALS/METHODS For this study, 22 NCTreal-CECTreal cardiac scan-pairs have been prepared of which the volume size was ∼512 × 512 × 400 and the resolution was ∼0.75 × 0.75 × 1 mm3 on average. Of the 22 datasets, 13/2/7 were used for training, validation, and testing, respectively. After matching the structure of paired scans using the deformable image registration (DIR), the area near the heart was cropped and used for training the deep learning model. We adopted the modified 2D fully convolution DenseNet (FC-DenseNet) as our backbone and trained it in the conditional generative adversarial network (cGAN) framework. The similarity between CECTsyn and CECTreal was evaluated first, and all NCTreal,CECTsyn, and CECTreal were applied to pre-trained cardiac auto-segmentation models to obtain the substructures of the heart, which is used for dose assessments in each of them. Finally, dose evaluations were conducted on CECTsyn and CECTreal with the dose distributions which are from clinical treatment plans and the manually modified contours of cardiac substructures. RESULTS Firstly, the peak signal-to-noise ratio (PSNR) and the structural similarity index measure (SSIM) between CECTsyn and CECTreal were 23.96 and 0.772, whereas those of NCTreal and CECTreal were 22.25and 0.748, respectively. Secondly, the results of applying the pre-trained cardiac auto-segmentation model were obtained, and the dice similarity coefficient (DSC) of CECTsyn was 0.762 on average which is superior to 0.267 of NCTreal and comparable to 0.843 of CECTreal. We could distinguish the L/R ventricles, L/R atriums, left anterior descending artery (LAD), and right coronary artery (RCA) clearly on CECTsyn. Finally, the dose differences between CECTsyn and CECTreal were on average 0.4/2.0 Gy in Dmean and Dmax, and 2.1/1.3/0.6/0.4/0.3/0.1/0.0% in V5 Gy, V10 Gy, V20 Gy, V30 Gy, V40 Gy, V50 Gy, and V60 Gy, respectively. CONCLUSION DCNN model proposed here showed the feasibility of CECTsyn generation from NCTreal and potential for cardiac substructure delineation such as ventricles, atriums, LAD, and RCA on NCTreal for breast RT. Furthermore, it is shown that CECTsyn can play a supportive role when the studies for the radiation-induced cardiac toxicity is needed.

Published

2021

13. Deep Learning-Based Automatic Detection and Segmentation of Gross Tumor for Stereotactic Ablative Radiotherapy in Small-Volume Brain Metastases

Author

Jaehee Chun, H.J. Kim, Jin Soo Kim, T.H. Kim, Seung Choul Yang, B.S. Choi, S. Yoo, and Hong In Yoon

Subjects

Cancer Research, Contouring, Radiation, medicine.diagnostic_test, business.industry, medicine.medical_treatment, Magnetic resonance imaging, SABR volatility model, Radiosurgery, Radiation therapy, Oncology, Sørensen–Dice coefficient, medicine, Radiology, Nuclear Medicine and imaging, Segmentation, False positive rate, business, Nuclear medicine

Abstract

PURPOSE/OBJECTIVE(S) Brain metastases (BM) are the most common intracranial tumors in adults. Benefiting from efficient local control, stereotactic ablative radiotherapy (SABR) is becoming popular in the treatment of BM. Detection and manual delineation of BM are labor-intense processes, and BM are occasionally mistaken for normal brain, especially if volumes are very small. Recently, several efforts have been made to develop automatic detection and segmentation for BM using advanced deep learning (DL) algorithms. In this study, we investigated the efficacy and accuracy of a DL model for the detection and segmentation of BM. MATERIALS/METHODS To train and validate the DL model, magnetic resonance imaging (MRI) for 65 patients and 603 BM were collected and analyzed. Manual contouring for BM was done by a radiation oncologist. We utilized 2.5-dimensional training using a two-dimensional U-Net as the DL architecture to avoid inefficiencies of the three-dimensional architecture. Because of MRI characteristic, we applied N4 bias field correction and gamma correction as pre-processing techniques. Also, we utilized the overlapping patch technique and under-sampling technique to extract small-volume BM from the normal brain that occupies most of the slice. During the training, data augmentations (horizontal flip, vertical flip, random rotation, random blur) were applied on the fly randomly. The detection performance was measured with sensitivity and average false positive rate and the segmentation performance with the Dice coefficient with dilation (DWD) with dilation factor set to a radius of 4 pixels. BMs with volumes 0.04 cc and 49.7% in BM with volumes < 0.04 cc. For all BM, the DWD value was 63%. CONCLUSION Our DL model can detect and segment BM with good performance; it is especially effective even for small-volume BM, suggesting its considerable benefit for gross tumor volume detection and segmentation for stereotactic radiosurgery or SABR.

Published

2021

14. Evaluation of Deep Learning-Based Auto-Segmentation of Organs-at-Risk for Breast Cancer Radiation Therapy

Author

Jin-Ah Jung, Yong Bae Kim, Jae Seung Chang, Chiyoung Jeong, Jin Soo Kim, S.H. Lee, Hwa Kyung Byun, Jaehee Chun, Min Seo Choi, and Y. Chang

Subjects

Cancer Research, medicine.medical_specialty, Contouring, Radiation, genetic structures, business.industry, Auto segmentation, medicine.medical_treatment, Deep learning, Planning target volume, Breast radiotherapy, medicine.disease, Radiation therapy, Clinical Practice, Breast cancer, Oncology, medicine, Radiology, Nuclear Medicine and imaging, Radiology, Artificial intelligence, business

Abstract

Purpose/Objective(s) A large inter-physician variation can be seen when delineating organ-at-risks (OARs) for breast radiotherapy. This study aimed to externally validate the performance of deep learning-based auto-contouring system (ACS) for breast radiotherapy. Materials/Methods Eleven experts from two institutions were asked to delineate 9 OARs of 10 cases of breast radiotherapy. Then, auto-contours were provided to the experts for correction. To compare the performance of auto-, corrected-auto-, and experts’ manual contours, Dice similarity coefficient (DSC) and Hausdorff distance (HD) between each contour and the best manual contour were used, where higher DSC and lower HD means better geometric overlap. Results Total mean time for 9 OARs was 37 ± 20 min for manual and 6 ± 5 min for corrected-auto-contours. Among the DSC of experts’ manual contours and an auto-contour, DSC of an auto-contour ranked the second place and HD ranked the first place. Better performance was shown in corrected-auto-contours than in manual contours (median DSC: 0.90 vs. 0.88; median HD: 4.5 vs. 6.5 mm). The inter-physician variations among experts were reduced in corrected-auto-contours, compared with manual contours (DSC range: 0.86–0.90 vs. 0.89–0.90; HD range: 5.1–9.1 mm vs. 4.3–5.7 mm). Among manual OARs, breast contours had the largest variations, which were most significantly improved with an aid of ACS. Conclusion ACS showed at least similar performance in OARs compared with experts’ manual contouring, which anticipates further applications of ACS to target volumes. ACS can be a valuable tool for improving the quality of breast radiotherapy and reducing inter-physician variability in clinical practice.

Published

2021

15. Clinical Evaluation of Commercial Atlas-Based Auto-Segmentation in the Head and Neck Region

Author

Nalee Kim, Ho Lee, Jin Sung Kim, Jaehee Chun, Jee Suk Chang, Kwangwoo Park, J. I. Shin, Joo Ho Kim, Eungman Lee, and Hyothaek Lee

Subjects

0301 basic medicine, Cancer Research, atlas segmentation, Population, lcsh:RC254-282, 03 medical and health sciences, 0302 clinical medicine, Atlas (anatomy), medicine, Segmentation, education, Head and neck, Mathematics, Original Research, education.field_of_study, Contouring, atlas-based auto-segmentation, contouring, business.industry, Auto segmentation, segmentation, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, 030104 developmental biology, Hausdorff distance, medicine.anatomical_structure, Oncology, 030220 oncology & carcinogenesis, Nuclear medicine, business, Clinical evaluation, auto-contouring

Abstract

Background: While atlas segmentation (AS) has proven to be a time-saving and promising method for radiation therapy contouring, optimal methods for its use have not been well-established. Therefore, we investigated the relationship between the size of the atlas patient population and the atlas segmentation auto contouring (AC) performance. Methods: A total of 110 patients' head planning CT images were selected. The mandible and thyroid were selected for this study. The mandibles and thyroids of the patient population were carefully segmented by two skilled clinicians. Of the 110 patients, 100 random patients were registered to 5 different atlas libraries as atlas patients, in groups of 20 to 100, with increments of 20. AS was conducted for each of the remaining 10 patients, either by simultaneous atlas segmentation (SAS) or independent atlas segmentation (IAS). The AS duration of each target patient was recorded. To validate the accuracy of the generated contours, auto contours were compared to manually generated contours (MC) using a volume-overlap-dependent metric, Dice Similarity Coefficient (DSC), and a distance-dependent metric, Hausdorff Distance (HD). Results: In both organs, as the population increased from n = 20 to n = 60, the results showed better convergence. Generally, independent cases produced better performance than simultaneous cases. For the mandible, the best performance was achieved by n = 60 [DSC = 0.92 (0.01) and HD = 6.73 (1.31) mm] and the worst by n = 100 [DSC = 0.90 (0.03) and HD = 10.10 (6.52) mm] atlas libraries. Similar results were achieved with the thyroid; the best performance was achieved by n = 60 [DSC = 0.79 (0.06) and HD = 10.17 (2.89) mm] and the worst by n = 100 [DSC = 0.72 (0.13) and HD = 12.88 (3.94) mm] atlas libraries. Both IAS and SAS showed similar results. Manual contouring of the mandible and thyroid required an average of 1,044 (±170.15) seconds, while AS required an average of 46.4 (±2.8) seconds. Conclusions: The performance of AS AC generally increased as the population of the atlas library increased. However, the performance does not drastically vary in the larger atlas libraries in contrast to the logic that bigger atlas library should lead to better results. In fact, the results do not vary significantly toward the larger atlas library. It is necessary for the institutions to independently research the optimal number of subjects.

Published

2019

16. MRI super-resolution reconstruction for MRI-guided adaptive radiotherapy using cascaded deep learning: In the presence of limited training data and unknown translation model

Author

Jin Sung Kim, Justin C. Park, Hao Zhang, Jaehee Chun, Sven Olberg, Hyun Kim, Sasa Mutic, Taeho Kim, H. Michael Gach, Thomas R. Mazur, and Olga Green

Subjects

Normalization (statistics), Computer science, medicine.medical_treatment, Signal-To-Noise Ratio, Translation (geometry), 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Deep Learning, Imaging, Three-Dimensional, medicine, Image Processing, Computer-Assisted, Humans, Image resolution, medicine.diagnostic_test, business.industry, Deep learning, Respiration, Magnetic resonance imaging, Pattern recognition, General Medicine, Filter (signal processing), Superresolution, Magnetic Resonance Imaging, Radiation therapy, Generative model, 030220 oncology & carcinogenesis, Noise (video), Artificial intelligence, business, Radiotherapy, Image-Guided

Abstract

PURPOSE Deep learning (DL)-based super-resolution (SR) reconstruction for magnetic resonance imaging (MRI) has recently been receiving attention due to the significant improvement in spatial resolution compared to conventional SR techniques. Challenges hindering the widespread implementation of these approaches remain, however. Low-resolution (LR) MRIs captured in the clinic exhibit complex tissue structures obfuscated by noise that are difficult for a simple DL framework to handle. Moreover, training a robust network for a SR task requires abundant, perfectly matched pairs of LR and high-resolution (HR) images that are often unavailable or difficult to collect. The purpose of this study is to develop a novel SR technique for MRI based on the concept of cascaded DL that allows for the reconstruction of high-quality SR images in the presence of insufficient training data, an unknown translation model, and noise. METHODS The proposed framework, based on the concept named cascaded deep learning, consists of three components: (a) a denoising autoencoder (DAE) trained using clinical LR noisy MRI scans that have been processed with a nonlocal means filter that generates denoised LR data; (b) a down-sampling network (DSN) trained with a small amount of paired LR/HR data from volunteers that allows for the generation of perfectly paired LR/HR data for the training of a generative model; and (c) the proposed SR generative model (p-SRG) trained with data generated by the DSN that maps from LR inputs to HR outputs. After training, LR clinical images may be fed through the DAE and p-SRG to yield SR reconstructions of the LR input. The application of this framework was explored in two settings: 3D breath-hold MRI axial SR reconstruction from LR axial scans (

Published

2019

17. Evaluation of Deep Learning-Based Auto-Segmentation of Target Volume and Organs-at-Risk in Breast Cancer Patients

Author

Y. Chang, Jae Seung Chang, B.S. Choi, Soo Yoon Chung, Yong Beom Kim, J.S. Kim, and Jaehee Chun

Subjects

Cancer Research, medicine.medical_specialty, Radiation, Auto segmentation, business.industry, Deep learning, Planning target volume, medicine.disease, Breast cancer, Oncology, medicine, Radiology, Nuclear Medicine and imaging, Artificial intelligence, Radiology, business

Published

2020

18. 3D Non-Rigid Registration for Abdominal PET-CT and MR Images Using Mutual Information and Independent Component Analysis

Author

Hakjae Lee, Kisung Lee, Jaehee Chun, and Kyeong Min Kim

Subjects

PET-CT, medicine.diagnostic_test, Computer science, business.industry, Geometric transformation, Image registration, Magnetic resonance imaging, Mutual information, Independent component analysis, Transformation (function), Positron emission tomography, Signal Processing, medicine, Computer vision, Artificial intelligence, Electrical and Electronic Engineering, business

Abstract

The aim of this study is to develop a 3D registration algorithm for positron emission tomography/computed tomography (PET/CT) and magnetic resonance (MR) images acquired from independent PET/CT and MR imaging systems. Combined PET/CT images provide anatomic and functional information, and MR images have high resolution for soft tissue. With the registration technique, the strengths of each modality image can be combined to achieve higher performance in diagnosis and radiotherapy planning. The proposed method consists of two stages: normalized mutual information (NMI)-based global matching and independent component analysis (ICA)-based refinement. In global matching, the field of view of the CT and MR images are adjusted to the same size in the preprocessing step. Then, the target image is geometrically transformed, and the similarities between the two images are measured with NMI. The optimization step updates the transformation parameters to efficiently find the best matched parameter set. In the refinement stage, ICA planes from the windowed image slices are extracted and the similarity between the images is measured to determine the transformation parameters of the control points. B-spline–based freeform deformation is performed for the geometric transformation. The results show good agreement between PET/CT and MR images.

Published

2015

19. High-Performing Thin-Film Transistors in Large Spherulites of Conjugated Polymer Formed by Epitaxial Growth on Removable Organic Crystalline Templates

Author

Jinsang Kim, Da Seul Yang, Seungmoon Pyo, Kyeongwoon Chung, Min Ju Cho, David Bilby, Donghoon Choi, Hyun Ah Um, Jaehee Chun, Jae Yoon Kim, and Jicheol Shin

Subjects

chemistry.chemical_classification, Materials science, business.industry, Transistor, Crystal growth, Polymer, Epitaxy, law.invention, chemistry, Thin-film transistor, law, Electrode, Perpendicular, Optoelectronics, General Materials Science, Crystallite, business

Abstract

Diketopyrrolopyrrole (DPP)-based conjugated polymer PDTDPPQT was synthesized and was used to perform epitaxial polymer crystal growth on removable 1,3,5-trichlorobenzene crystallite templates. A thin-film transistor (TFT) was successfully fabricated in well-grown large spherulites of PDTDPPQT. The charge carrier mobility along the radial direction of the spherulites was measured to be 5.46-12.04 cm(2) V(-1) s(-1), which is significantly higher than that in the direction perpendicular to the radial direction. The dynamic response of charge transport was also investigated by applying a pulsed bias to TFTs loaded with a resistor (∼20 MΩ). The charge-transport behaviors along the radial direction and perpendicular to the radial direction were investigated by static and dynamic experiments through a resistor-loaded (RL) inverter. The RL inverter made of PDTDPPQT-based TFT operates well, maintaining a fairly high switching voltage ratio (Vout(ON)/Vout(OFF)) at a relatively high frequency when the source-drain electrodes are aligned parallel to the radial direction.

Published

2015

20. Simulation study of a novel target oriented SPECT design using a variable pinhole collimator

Author

Seungbin Bae, Hakjae Lee, Kisung Lee, Jaehee Chun, Hyemi Cha, and Jung Yeol Yeom

Subjects

Models, Anatomic, Computer science, Aperture, Single-photon emission computed tomography, Scintillator, 01 natural sciences, Imaging phantom, Rod, Tungsten, 030218 nuclear medicine & medical imaging, law.invention, 03 medical and health sciences, Mice, 0302 clinical medicine, Optics, law, 0103 physical sciences, medicine, Animals, Computer Simulation, Sensitivity (control systems), Image resolution, Tomography, Emission-Computed, Single-Photon, medicine.diagnostic_test, 010308 nuclear & particles physics, business.industry, Phantoms, Imaging, Collimator, Heart, General Medicine, Equipment Design, Feasibility Studies, Acceptance angle, Pinhole (optics), business, Rotation (mathematics)

Abstract

Purpose In the past decade, demands for organ specific (target oriented) single photon emission computed tomography (SPECT) is increasing, and several groups have conducted studies on developing clinical dedicated SPECT with pinhole collimator in order to improve the spatial resolution. However acceptance angle of the collimator cannot be adjusted to fit the different ROIs of target objects because the shape of pinhole could not be changed, and the magnifying factor cannot be maximized as the collimator-to-detector distance are fixed. Furthermore, those dedicated pinhole-SPECTs are typically made for a single purpose, and therefore possess a drawback in that it cannot be utilized for any other purpose. In this study we propose a novel SPECT system using variable pinhole collimator (VP SPECT) whose parameters are flexible. Methods The proposed variable pinhole collimator is modeled on conventional pinhole by piling several tungsten layers of different apertures. Depending on the combination of the holes in each layer, a variety of hole diameters and acceptance angles of the pinhole can be made. In addition, VP SPECT system allows attaching the collimator to the object as close as possible to maximize the sensitivity, and adjust the distance of the pinhole from the scintillation detector to optimize the system resolution for each rotation angle, automatically. For quantitative measurement, we compared the sensitivity and spatial resolution of VP SPECT with those of conventional pinhole-SPECT. To determine the possibility of the clinical and preclinical use of proposed system, a digital mouse whole body (MOBY) phantom is used for simulating the live mouse model. Results The result of simulation using ultra-micro hot spot phantom shows that the sensitivity of the proposed VP SPECT system is about 297% of that of the conventional system. While hot rods of diameter 0.6 mm can be distinguished in the image with the proposed VP SPECT system, 1.2 mm hot rods are barely discernible in the conventional pinhole-SPECT image. According to the result of MOBY phantom simulation, heart walls separated by 3 mm were not distinguished in conventional pinhole-SPECT images, but were clearly discerned in VP SPECT images. Conclusions In this study, we designed a novel pinhole collimator for SPECT and presented preliminary results of target oriented imaging with a simulation study. Currently, we are pursuing strategies to realize the proposed system, with the goal to apply the technology into a high sensitivity and high resolution preclinical SPECT. Should VP SPECT be applied to the clinical setting, we anticipate a high-sensitivity, high-resolution system for applications such as heart dedicated SPECT or related fields. This article is protected by copyright. All rights reserved.

Published

2016