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157 papers • 7,966 citations • Sorted by year • Download PDF (PDF by citations)
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1Auto‐detection of necessity for MRI‐guided online adaptive replanning using a machine learning classifier
Medical Physics, 2023, 50, 440-448
3.46Citations (PDF)
2Deep learning based automatic contour refinement for inaccurate auto-segmentation in MR-guided adaptive radiotherapy
Physics in Medicine and Biology, 2023, 68, 055004
3.55Citations (PDF)
3Real‐time motion monitoring using orthogonal cine MRI during MR‐guided adaptive radiation therapy for abdominal tumors on 1.5T MR‐Linac
Medical Physics, 2023, 50, 3103-3116
3.434Citations (PDF)
4Automated deep learning auto-segmentation of air volumes for MRI-guided online adaptive radiation therapy of abdominal tumors
Physics in Medicine and Biology, 2023, 68, 125011
3.54Citations (PDF)
5Obtaining organ-specific radiobiological parameters from clinical data for radiation therapy planning of head and neck cancers
Physics in Medicine and Biology, 2023, 68, 245015
3.56Citations (PDF)
6Use of a DVH overlay technique for quality assurance of deformable image registration‐based dose accumulation
Medical Physics, 2022, 49, 611-623
3.412Citations (PDF)
7Magnetic resonance linear accelerator technology and adaptive radiation therapy: An overview for clinicians
Ca-A Cancer Journal for Clinicians, 2022, 72, 34-56
169.981Citations (PDF)
8General and custom deep learning autosegmentation models for organs in head and neck, abdomen, and male pelvis
Medical Physics, 2022, 49, 1686-1700
3.433Citations (PDF)
9Multi‐parametric magnetic resonance imaging for radiation treatment planning
Medical Physics, 2022, 49, 2836-2845
3.44Citations (PDF)
10Automatic Contour Refinement for Deep Learning Auto-segmentation of Complex Organs in MRI-guided Adaptive Radiation Therapy
Advances in Radiation Oncology, 2022, 7, 100968
1.421Citations (PDF)
11A Prior Knowledge-Guided, Deep Learning-Based Semiautomatic Segmentation for Complex Anatomy on Magnetic Resonance Imaging
International Journal of Radiation Oncology Biology Physics, 2022, 114, 349-359
0.810Citations (PDF)
12Development and implementation of an automatic air delineation technique for MRI-guided adaptive radiation therapy
Physics in Medicine and Biology, 2022, 67, 145011
3.54Citations (PDF)
13Deep Learning-Based Automatic Detection of Brain Metastases in Heterogenous Multi-Institutional Magnetic Resonance Imaging Sets: An Exploratory Analysis of NRG-CC001
International Journal of Radiation Oncology Biology Physics, 2022, 114, 529-536
0.817Citations (PDF)
14Organs at Risk Considerations for Thoracic Stereotactic Body Radiation Therapy: What Is Safe for Lung Parenchyma?
International Journal of Radiation Oncology Biology Physics, 2021, 110, 172-187
0.876Citations (PDF)
15Local Control After Stereotactic Body Radiation Therapy for Stage I Non-Small Cell Lung Cancer
International Journal of Radiation Oncology Biology Physics, 2021, 110, 160-171
0.850Citations (PDF)
16Adaptive Radiation Therapy (ART) Strategies and Technical Considerations: A State of the ART Review From NRG Oncology
International Journal of Radiation Oncology Biology Physics, 2021, 109, 1054-1075
0.8248Citations (PDF)
17Technical Note: Using virtual noncontrast images from dual‐energy CT to eliminate the need of precontrast CT for x‐ray radiation treatment planning of abdominal tumors<sup>†</sup>
Medical Physics, 2021, 48, 1365-1371
3.413Citations (PDF)
18Radiation-induced lung damage in patients treated with stereotactic body radiotherapy after EGFR-TKIs: is there any difference from stereotactic body radiotherapy alone?
Annals of Palliative Medicine, 2021, 10, 2832-2842
1.48Citations (PDF)
19Machine QA for the Elekta Unity system: A Report from the Elekta MR‐linac consortium
Medical Physics, 2021, 48,
3.481Citations (PDF)
20Tumor Control Probability Modeling for Radiation Therapy of Keratinocyte Carcinoma
Frontiers in Oncology, 2021, 11,
2.77Citations (PDF)
21Stereotactic Body Radiation Therapy for Spinal Metastases: Tumor Control Probability Analyses and Recommended Reporting Standards
International Journal of Radiation Oncology Biology Physics, 2021, 110, 112-123
0.846Citations (PDF)
22Maximizing Tumor Control and Limiting Complications With Stereotactic Body Radiation Therapy for Pancreatic Cancer
International Journal of Radiation Oncology Biology Physics, 2021, 110, 206-216
0.841Citations (PDF)
23Clinical Implementation and Initial Experience of Real-Time Motion Tracking With Jaws and Multileaf Collimator During Helical Tomotherapy Delivery
Practical Radiation Oncology, 2021, 11, e486-e495
2.434Citations (PDF)
24Radiation Therapy for Treatment of Soft Tissue Sarcoma in Adults: Executive Summary of an ASTRO Clinical Practice Guideline
Practical Radiation Oncology, 2021, 11, 339-351
2.4137Citations (PDF)
25In Reply to Erguchi et al.
International Journal of Radiation Oncology Biology Physics, 2021, 111, 1089-1090
0.81Citations (PDF)
26Indications of Online Adaptive Replanning Based On Organ Deformation
Practical Radiation Oncology, 2020, 10, e95-e102
2.411Citations (PDF)
27High dose radiation therapy based on normal tissue constraints with concurrent chemotherapy achieves promising survival of patients with unresectable stage III non-small cell lung cancer
Radiotherapy and Oncology, 2020, 145, 7-12
0.65Citations (PDF)
28A daily end‐to‐end quality assurance workflow for MR‐guided online adaptive radiation therapy on MR‐Linac
Journal of Applied Clinical Medical Physics, 2020, 21, 205-212
2.234Citations (PDF)
29Patterns of Failure Observed in the 2-Step Institution Credentialing Process for NRG Oncology/Radiation Therapy Oncology Group 1005 (NCT01349322) and Lessons Learned
Practical Radiation Oncology, 2020, 10, 265-273
2.48Citations (PDF)
30Automated air region delineation on MRI for synthetic CT creation
Physics in Medicine and Biology, 2020, 65, 025009
3.55Citations (PDF)
31Improving Structure Delineation for Radiation Therapy Planning Using Dual-Energy CT
Frontiers in Oncology, 2020, 10,
2.717Citations (PDF)
32Initial clinical experience of Stereotactic Body Radiation Therapy (SBRT) for liver metastases, primary liver malignancy, and pancreatic cancer with 4D-MRI based online adaptation and real-time MRI monitoring using a 1.5 Tesla MR-Linac
PLoS ONE, 2020, 15, e0236570
2.555Citations (PDF)
33A Patient-Specific Autosegmentation Strategy Using Multi-Input Deformable Image Registration for Magnetic Resonance Imaging–Guided Online Adaptive Radiation Therapy: A Feasibility Study
Advances in Radiation Oncology, 2020, 5, 17-25
1.41Citations (PDF)
34A Patient-Specific Autosegmentation Strategy Using Multi-Input Deformable Image Registration for Magnetic Resonance Imaging–Guided Online Adaptive Radiation Therapy: A Feasibility Study
Advances in Radiation Oncology, 2020, 5, 1350-1358
1.428Citations (PDF)
354D-MRI driven MR-guided online adaptive radiotherapy for abdominal stereotactic body radiation therapy on a high field MR-Linac: Implementation and initial clinical experience
Clinical and Translational Radiation Oncology, 2020, 23, 72-79
1.085Citations (PDF)
36Feasibility of real‐time motion tracking using cine MRI during MR‐guided radiation therapy for abdominal targets
Medical Physics, 2020, 47, 3554-3566
3.454Citations (PDF)
37Automatic Seizure Detection using Fully Convolutional Nested LSTM
International Journal of Neural Systems, 2020, 30, 2050019
7.1130Citations (PDF)
38A Fast Online Replanning Algorithm Based on Intensity Field Projection for Adaptive Radiotherapy
Frontiers in Oncology, 2020, 10,
2.73Citations (PDF)
39Mapping transient hypoxia from in situ activation of 15O by photon beams: A simulation study
Radiation Physics and Chemistry, 2020, 172, 108815
3.00Citations (PDF)
40Auto-segmentation of pancreatic tumor in multi-parametric MRI using deep convolutional neural networks
Radiotherapy and Oncology, 2020, 145, 193-200
0.679Citations (PDF)
41Improving Treatment Response Prediction for Chemoradiation Therapy of Pancreatic Cancer Using a Combination of Delta-Radiomics and the Clinical Biomarker CA19-9
Frontiers in Oncology, 2020, 9,
2.747Citations (PDF)
42Technical Note: Comprehensive performance tests of the first clinical real‐time motion tracking and compensation system using MLC and jaws
Medical Physics, 2020, 47, 2814-2825
3.444Citations (PDF)
43Texture‐based, automatic contour validation for online adaptive replanning: A feasibility study on abdominal organs
Medical Physics, 2019, 46, 4010-4020
3.421Citations (PDF)
44Measurement validation of treatment planning for a MR‐Linac
Journal of Applied Clinical Medical Physics, 2019, 20, 28-38
2.220Citations (PDF)
45The transformation of radiation oncology using real-time magnetic resonance guidance: A review
European Journal of Cancer, 2019, 122, 42-52
2.9170Citations (PDF)
46A machine learning based delta-radiomics process for early prediction of treatment response of pancreatic cancer
Npj Precision Oncology, 2019, 3,
7.0138Citations (PDF)
47Estimation of changing gross tumor volume from longitudinal CTs during radiation therapy delivery based on a texture analysis with classifier algorithms: a proof-of-concept study
Quantitative Imaging in Medicine and Surgery, 2019, 9, 1189-1200
1.60Citations (PDF)
48Correlation of CT texture changes with treatment response during radiation therapy for esophageal cancer: An exploratory study
PLoS ONE, 2019, 14, e0223140
2.57Citations (PDF)
49Time stability of delta‐radiomics features and the impact on patient analysis in longitudinal CT images
Medical Physics, 2019, 46, 1663-1676
3.419Citations (PDF)
50Assessment and management of interfraction variations of lumpectomy cavities in accelerated partial breast irradiation
Therapeutic Radiology and Oncology, 2019, 3, 13-13
0.40Citations (PDF)
51NCTN Assessment on Current Applications of Radiomics in Oncology
International Journal of Radiation Oncology Biology Physics, 2019, 104, 302-315
0.857Citations (PDF)
52A Technique to Rapidly Generate Synthetic Computed Tomography for Magnetic Resonance Imaging–Guided Online Adaptive Replanning: An Exploratory Study
International Journal of Radiation Oncology Biology Physics, 2019, 103, 1261-1270
0.815Citations (PDF)
53A preferred patient decubitus positioning for magnetic resonance image guided online adaptive radiation therapy of pancreatic cancer
Physics and Imaging in Radiation Oncology, 2019, 12, 22-29
2.11Citations (PDF)
54The Dosimetric Impact of Interfractional Organ-at-Risk Movement During Liver Stereotactic Body Radiation Therapy
Practical Radiation Oncology, 2019, 9, e549-e558
2.47Citations (PDF)
55A fast 4D <scp>IMRT</scp>/<scp>VMAT</scp> planning method based on segment aperture morphing
Medical Physics, 2018, 45, 1594-1602
3.45Citations (PDF)
56Correlation of ADC With Pathological Treatment Response for Radiation Therapy of Pancreatic Cancer
Translational Oncology, 2018, 11, 391-398
3.843Citations (PDF)
57Precision Oncology and Genomically Guided Radiation Therapy: A Report From the American Society for Radiation Oncology/American Association of Physicists in Medicine/National Cancer Institute Precision Medicine Conference
International Journal of Radiation Oncology Biology Physics, 2018, 101, 274-284
0.860Citations (PDF)
58Magnetic Resonance Imaging-Guided Adaptive Radiation Therapy: A “Game Changer” for Prostate Treatment?
International Journal of Radiation Oncology Biology Physics, 2018, 100, 361-373
0.8152Citations (PDF)
59Kinetic modeling of tumor regression incorporating the concept of cancer stem-like cells for patients with locally advanced lung cancer
Theoretical Biology and Medical Modelling, 2018, 15,
2.24Citations (PDF)
60Variations of MRI-assessed peristaltic motions during radiation therapy
PLoS ONE, 2018, 13, e0205917
2.544Citations (PDF)
61Magnetic Resonance-based Response Assessment and Dose Adaptation in Human Papilloma Virus Positive Tumors of the Oropharynx treated with Radiotherapy (MR-ADAPTOR): An R-IDEAL stage 2a-2b/Bayesian phase II trial
Clinical and Translational Radiation Oncology, 2018, 13, 19-23
1.044Citations (PDF)
62Appropriate magnetic resonance imaging techniques for gross tumor volume delineation in external beam radiation therapy of locally advanced cervical cancer
Oncotarget, 2018, 9, 10100-10109
1.77Citations (PDF)
63Technical Note: Enhancing soft tissue contrast and radiation‐induced image changes with dual‐energy CT for radiation therapy
Medical Physics, 2018, 45, 4238-4245
3.412Citations (PDF)
64Feasibility of real‐time lung tumor motion monitoring using intrafractional ultrasound and <scp>kV</scp> cone beam projection images
Medical Physics, 2018, 45, 4619-4626
3.410Citations (PDF)
65PET-based Treatment Response Assessment for Neoadjuvant Chemoradiation in Pancreatic Adenocarcinoma: An Exploratory Study
Translational Oncology, 2018, 11, 1104-1109
3.821Citations (PDF)
66Technical Note: Acceleration of online adaptive replanning with automation and parallel operations
Medical Physics, 2018, 45, 4370-4376
3.49Citations (PDF)
67Early Assessment of Treatment Responses During Radiation Therapy for Lung Cancer Using Quantitative Analysis of Daily Computed Tomography
International Journal of Radiation Oncology Biology Physics, 2017, 98, 463-472
0.820Citations (PDF)
68Technical Note: Is bulk electron density assignment appropriate for MRI-only based treatment planning for lung cancer?
Medical Physics, 2017, 44, 3437-3443
3.424Citations (PDF)
69A graphical approach to optimizing variable-kernel smoothing parameters for improved deformable registration of CT and cone beam CT images
Physics in Medicine and Biology, 2017, 62, 6246-6260
3.53Citations (PDF)
70Reducing radiation dose and enhancing imaging quality of 4DCT for radiation therapy using iterative reconstruction algorithms
Advances in Radiation Oncology, 2017, 2, 515-521
1.416Citations (PDF)
71Improving CT quality with optimized image parameters for radiation treatment planning and delivery guidance
Physics and Imaging in Radiation Oncology, 2017, 4, 6-11
2.129Citations (PDF)
72Management of independent motion between multiple targets in lung cancer radiation therapy
Practical Radiation Oncology, 2017, 7, 26-34
2.45Citations (PDF)
73Tumor control probability modeling for stereotactic body radiation therapy of early-stage lung cancer using multiple bio-physical models
Radiotherapy and Oncology, 2017, 122, 286-294
0.652Citations (PDF)
74Anatomic, functional and molecular imaging in lung cancer precision radiation therapy: treatment response assessment and radiation therapy personalization
Translational Lung Cancer Research, 2017, 6, 670-688
2.123Citations (PDF)
75Assessment of treatment response during chemoradiation therapy for pancreatic cancer based on quantitative radiomic analysis of daily CTs: An exploratory study
PLoS ONE, 2017, 12, e0178961
2.572Citations (PDF)
76An analysis of tumor control probability of stereotactic body radiation therapy for lung cancer with a regrowth model
Physics in Medicine and Biology, 2016, 61, 3903-3913
3.521Citations (PDF)
77MRI-based IMRT planning for MR-linac: comparison between CT- and MRI-based plans for pancreatic and prostate cancers
Physics in Medicine and Biology, 2016, 61, 3819-3842
3.539Citations (PDF)
78Preliminary results on the feasibility of using ultrasound to monitor intrafractional motion during radiation therapy for pancreatic cancer
Medical Physics, 2016, 43, 5252-5260
3.416Citations (PDF)
79Technical Note: Development and performance of a software tool for quality assurance of online replanning with a conventional Linac or MR‐Linac
Medical Physics, 2016, 43, 1713-1719
3.434Citations (PDF)
80Technical Note: A fast online adaptive replanning method for VMAT using flattening filter free beams
Medical Physics, 2016, 43, 2756-2764
3.414Citations (PDF)
81Technical Note: Dose effects of 1.5 T transverse magnetic field on tissue interfaces in MRI-guided radiotherapy
Medical Physics, 2016, 43, 4797-4802
3.451Citations (PDF)
82Simple Factors Associated With Radiation-Induced Lung Toxicity After Stereotactic Body Radiation Therapy of the Thorax: A Pooled Analysis of 88 Studies
International Journal of Radiation Oncology Biology Physics, 2016, 95, 1357-1366
0.8164Citations (PDF)
83Radiation-induced CT number changes in GTV and parotid glands during the course of radiation therapy for nasopharyngeal cancer
British Journal of Radiology, 2016, 89, 20140819
2.69Citations (PDF)
84Margin reduction from image guided radiation therapy for soft tissue sarcoma: Secondary analysis of Radiation Therapy Oncology Group 0630 results
Practical Radiation Oncology, 2016, 6, e135-e140
2.420Citations (PDF)
85A Comparison of Lumpectomy Cavity Delineations Between Use of Magnetic Resonance Imaging and Computed Tomography Acquired With Patient in Prone Position for Radiation Therapy Planning of Breast Cancer
International Journal of Radiation Oncology Biology Physics, 2016, 94, 832-840
0.814Citations (PDF)
86SU-G-JeP2-05: Dose Effects of a 1.5T Magnetic Field On Air-Tissue and Lung-Tissue Interfaces in MRI-Guided Radiotherapy
Medical Physics, 2016, 43, 3660-3660
3.40Citations (PDF)
87Comprehensive MRI simulation methodology using a dedicated MRI scanner in radiation oncology for external beam radiation treatment planning
Medical Physics, 2015, 42, 28-39
3.4132Citations (PDF)
88Sensorineural Hearing Loss after Combined Intensity Modulated Radiation Therapy and Cisplatin-Based Chemotherapy for Nasopharyngeal Carcinoma
Translational Oncology, 2015, 8, 456-462
3.829Citations (PDF)
89Gradient maintenance: A new algorithm for fast online replanning
Medical Physics, 2015, 42, 2863-2876
3.417Citations (PDF)
90Significant Reduction of Late Toxicities in Patients With Extremity Sarcoma Treated With Image-Guided Radiation Therapy to a Reduced Target Volume: Results of Radiation Therapy Oncology Group RTOG-0630 Trial
Journal of Clinical Oncology, 2015, 33, 2231-2238
14.2265Citations (PDF)
91Computed Tomography Number Changes Observed During Computed Tomography–Guided Radiation Therapy for Head and Neck Cancer
International Journal of Radiation Oncology Biology Physics, 2015, 91, 1041-1047
0.826Citations (PDF)
92A planning comparison of 7 irradiation options allowed in RTOG 1005 for early-stage breast cancer
Medical Dosimetry, 2015, 40, 21-25
1.032Citations (PDF)
93Online adaptive planning for prostate cancer radiotherapy is necessary and ready now
Medical Physics, 2014, 41,
3.48Citations (PDF)
94Adaptive Replanning to Account for Lumpectomy Cavity Change in Sequential Boost After Whole-Breast Irradiation
International Journal of Radiation Oncology Biology Physics, 2014, 90, 1208-1215
0.815Citations (PDF)
95Variability of Target and Normal Structure Delineation Using Multimodality Imaging for Radiation Therapy of Pancreatic Cancer
International Journal of Radiation Oncology Biology Physics, 2014, 89, 633-640
0.842Citations (PDF)
96Determination of Internal Target Volume for Radiation Treatment Planning of Esophageal Cancer by Using 4-Dimensional Computed Tomography (4DCT)
International Journal of Radiation Oncology Biology Physics, 2014, 90, 102-109
0.814Citations (PDF)
97Consolidating duodenal and small bowel toxicity data via isoeffective dose calculations based on compiled clinical data
Practical Radiation Oncology, 2014, 4, e125-e131
2.411Citations (PDF)
98Statistical Modeling Approach to Quantitative Analysis of Interobserver Variability in Breast Contouring
International Journal of Radiation Oncology Biology Physics, 2014, 89, 214-221
0.824Citations (PDF)
99Combined online and offline adaptive radiation therapy: A dosimetric feasibility study
Practical Radiation Oncology, 2014, 4, e75-e83
2.415Citations (PDF)
100Radiation dose responses for chemoradiation therapy of pancreatic cancer: An analysis of compiled clinical data using biophysical models
Practical Radiation Oncology, 2014, 4, 13-19
2.439Citations (PDF)
101Assessment and management of interfractional variations in daily diagnostic‐quality‐CT guided prostate‐bed irradiation after prostatectomy
Medical Physics, 2014, 41,
3.427Citations (PDF)
102Comparison of Various Online Strategies to Account for Interfractional Variations for Pancreatic Cancer
International Journal of Radiation Oncology Biology Physics, 2013, 86, 914-921
0.813Citations (PDF)
103Management of Respiration-Induced Motion With 4-Dimensional Computed Tomography (4DCT) for Pancreas Irradiation
International Journal of Radiation Oncology Biology Physics, 2013, 86, 908-913
0.833Citations (PDF)
104Evaluation of interfraction patient setup errors for image-guided prostate and head-and-neck radiotherapy using kilovoltage cone beam and megavoltage fan beam computed tomography
Journal of Radiotherapy in Practice, 2013, 12, 334-343
0.66Citations (PDF)
105The use and QA of biologically related models for treatment planning: Short report of the TG-166 of the therapy physics committee of the AAPM
Medical Physics, 2012, 39, 1386-1409
3.4227Citations (PDF)
106Accumulating daily‐varied dose distributions of prostate radiation therapy with soft‐tissue–based kV CT guidance
Journal of Applied Clinical Medical Physics, 2012, 13, 98-107
2.219Citations (PDF)
107Impact of Computed Tomography Image Quality on Image-Guided Radiation Therapy Based on Soft Tissue Registration
International Journal of Radiation Oncology Biology Physics, 2012, 82, e733-e738
0.849Citations (PDF)
108Characterization and Management of Interfractional Anatomic Changes for Pancreatic Cancer Radiotherapy
International Journal of Radiation Oncology Biology Physics, 2012, 83, e423-e429
0.895Citations (PDF)
109Development of an online adaptive solution to account for inter- and intra-fractional variations
Radiotherapy and Oncology, 2011, 100, 370-374
0.649Citations (PDF)
110Internal margin assessment using cine MRI analysis of deglutition in head and neck cancer radiotherapy
Medical Physics, 2011, 38, 1740-1747
3.418Citations (PDF)
111Characterizing Interfraction Variations and Their Dosimetric Effects in Prostate Cancer Radiotherapy
International Journal of Radiation Oncology Biology Physics, 2011, 79, 909-914
0.873Citations (PDF)
112Validation of an online replanning technique for prostate adaptive radiotherapy
Physics in Medicine and Biology, 2011, 56, 3659-3668
3.520Citations (PDF)
113SU-E-T-814: Dosimetric Feasibility of Dose Escalation with Gated IG-IMRT for Pancreatic Cancer
Medical Physics, 2011, 38, 3678-3678
3.40Citations (PDF)
114Radiation Dose–Volume Effects in the Stomach and Small Bowel
International Journal of Radiation Oncology Biology Physics, 2010, 76, S101-S107
0.8501Citations (PDF)
115Online Adaptive Replanning Method for Prostate Radiotherapy
International Journal of Radiation Oncology Biology Physics, 2010, 77, 1561-1572
0.887Citations (PDF)
116Tools for consensus analysis of experts’ contours for radiotherapy structure definitions
Radiotherapy and Oncology, 2010, 97, 572-578
0.6100Citations (PDF)
117The Role of Image Guided Radiotherapy in the Treatment of Soft Tissue Sarcoma
Current Cancer Therapy Reviews, 2010, 6, 207-213
0.93Citations (PDF)
118Automated registration of large deformations for adaptive radiation therapy of prostate cancer
Medical Physics, 2009, 36, 1433-1441
3.446Citations (PDF)
119Improved critical structure sparing with biologically based IMRT optimization
Medical Physics, 2009, 36, 1790-1799
3.448Citations (PDF)
120Variability of Target and Normal Structure Delineation for Breast Cancer Radiotherapy: An RTOG Multi-Institutional and Multiobserver Study
International Journal of Radiation Oncology Biology Physics, 2009, 73, 944-951
0.8358Citations (PDF)
121An on‐line replanning method for head and neck adaptive radiotherapya)
Medical Physics, 2009, 36, 4776-4790
3.449Citations (PDF)
122Estimate of Radiobiologic Parameters From Clinical Data for Biologically Based Treatment Planning for Liver Irradiation
International Journal of Radiation Oncology Biology Physics, 2008, 70, 900-907
0.860Citations (PDF)
123Evaluation of a commercial biologically based IMRT treatment planning system
Medical Physics, 2008, 35, 5851-5860
3.4106Citations (PDF)
124An on-line replanning scheme for interfractional variationsa)
Medical Physics, 2008, 35, 3607-3615
3.4113Citations (PDF)
125A Comparison of daily megavoltage CT and ultrasound image guided radiation therapy for prostate cancer
Medical Physics, 2008, 35, 5619-5628
3.423Citations (PDF)
126Respiratory gating for radiation therapy is not ready for prime time
Medical Physics, 2007, 34, 867-870
3.425Citations (PDF)
127BGRT: Biologically guided radiation therapy—The future is fast approaching!
Medical Physics, 2007, 34, 3739-3751
3.463Citations (PDF)
128Development of an inverse optimization package to plan nonuniform dose distributions based on spatially inhomogeneous radiosensitivity extracted from biological images
Medical Physics, 2007, 34, 1198-1205
3.421Citations (PDF)
129Radiation Oncology Physicists Will Need to Better Understand Medical Imaging
Journal of the American College of Radiology, 2007, 4, 40-44
2.44Citations (PDF)
130Interfractional Variations in Patient Setup and Anatomic Change Assessed by Daily Computed Tomography
International Journal of Radiation Oncology Biology Physics, 2007, 68, 581-591
0.8120Citations (PDF)
131Intra- and Interfractional Variations for Prone Breast Irradiation: An Indication for Image-Guided Radiotherapy
International Journal of Radiation Oncology Biology Physics, 2007, 69, 910-917
0.861Citations (PDF)
132Technical and dosimetric aspects of respiratory gating using a pressure-sensor motion monitoring system
Medical Physics, 2006, 33, 145-154
3.4164Citations (PDF)
133An estimation of radiobiologic parameters from clinical outcomes for radiation treatment planning of brain tumor
International Journal of Radiation Oncology Biology Physics, 2006, 64, 1570-1580
0.857Citations (PDF)
134Dosimetric advantages of IMRT simultaneous integrated boost for high-risk prostate cancer
International Journal of Radiation Oncology Biology Physics, 2005, 61, 1251-1257
0.865Citations (PDF)
135Improving patient-specific dosimetry for intravascular brachytherapy
Brachytherapy, 2005, 4, 291-297
0.58Citations (PDF)
136Over the next decade the success of radiation treatment planning will be judged by the immediate biological response of tumor cells rather than by surrogate measures such as dose maximization and uniformity
Medical Physics, 2005, 32, 2189-2192
3.434Citations (PDF)
137Extending the linear–quadratic model for large fraction doses pertinent to stereotactic radiotherapy
Physics in Medicine and Biology, 2004, 49, 4825-4835
3.5326Citations (PDF)
138Evaluation of external beam radiotherapy and brachytherapy for localized prostate cancer using equivalent uniform dose
Medical Physics, 2003, 30, 34-40
3.455Citations (PDF)
139Impact of prolonged fraction delivery times on tumor control: A note of caution for intensity-modulated radiation therapy (IMRT)
International Journal of Radiation Oncology Biology Physics, 2003, 57, 543-552
0.8203Citations (PDF)
140How low is the α/β ratio for prostate cancer?
International Journal of Radiation Oncology Biology Physics, 2003, 55, 194-203
0.8302Citations (PDF)
141Dose effects of stents in intravascular brachytherapy for in-stent restenosis: a Monte Carlo calculation
International Journal of Radiation Oncology Biology Physics, 2003, 55, 842-848
0.810Citations (PDF)
142Analysis of a large number of clinical studies for breast cancer radiotherapy: estimation of radiobiological parameters for treatment planning
Physics in Medicine and Biology, 2003, 48, 3307-3326
3.545Citations (PDF)
143Dose escalation in permanent brachytherapy for prostate cancer: dosimetric and biological considerations
Physics in Medicine and Biology, 2003, 48, 2753-2765
3.547Citations (PDF)
144Dose effect of guidewire position in intravascular brachytherapy
Physics in Medicine and Biology, 2002, 47, 1733-1740
3.58Citations (PDF)
145Dosimetric effects of source-offset in intravascular brachytherapy
Medical Physics, 2002, 29, 530-537
3.414Citations (PDF)
146Radiotherapy dose perturbation of metallic esophageal stents
International Journal of Radiation Oncology Biology Physics, 2002, 54, 1276-1285
0.851Citations (PDF)
147Optimized intensity-modulated arc therapy for prostate cancer treatment
International Journal of Cancer, 2001, 96, 379-384
4.547Citations (PDF)
148Monte Carlo dose calculations of beta-emitting sources for intravascular brachytherapy: A comparison between EGS4, EGSnrc, and MCNP
Medical Physics, 2001, 28, 134-141
3.452Citations (PDF)
149Monte Carlo characterization of a 32P source for intravascular brachytherapy
Medical Physics, 2001, 28, 1776-1785
3.418Citations (PDF)
150Dynamic wedge versus physical wedge: A Monte Carlo study
Medical Physics, 2001, 28, 612-619
3.421Citations (PDF)
151Reducing loss in lateral charged-particle equilibrium due to air cavities present in x-ray irradiated media by using longitudinal magnetic fields
Medical Physics, 2001, 28, 603-611
3.419Citations (PDF)
152Conformal photon-beam therapy with transverse magnetic fields: A Monte Carlo study
Medical Physics, 2001, 28, 127-133
3.422Citations (PDF)
153Dosimetric effects of contrast media for catheter-based intravascular brachytherapy
Medical Physics, 2001, 28, 757-763
3.415Citations (PDF)
154A Monte Carlo calculation of dosimetric parameters of 90Sr/90Y and 192Ir SS sources for intravascular brachytherapy
Medical Physics, 2000, 27, 2528-2535
3.455Citations (PDF)
155A systematic evaluation of air cavity dose perturbation in megavoltage x-ray beams
Medical Physics, 2000, 27, 1011-1017
3.454Citations (PDF)
156Peak scatter factors for high energy photon beams
Medical Physics, 1999, 26, 962-966
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0, ,
0Citations (PDF)