Your search keyword '"George Starkschall"' showing total 239 results

1. Semi-automated CT segmentation using optic flow and Fourier interpolation techniques.

Author

Tzung-Chi Huang, Geoffrey G. Zhang, Thomas Guerrero, George Starkschall, Kang-Ping Lin, and Ken M. Forster

Published

2006

2. Foundations of Medical Physics

Author

Victor J. Montemayor, George Starkschall, Victor J. Montemayor, and George Starkschall

Subjects

Medical physics

Abstract

Covering topics in Radiobiology, Modern Physics, Medical Imaging and Radiation Therapy, Foundations of Medical Physics serves as an introduction to the field of Medical Physics, or Radiation Oncology Physics.An overview of the history of cancer and cancer treatment along with a brief introduction to the fundamental principles of Radiobiology constitute Part I of this book, which serves as the motivation for the principles of Radiation Therapy, or cancer treatment with radiation. Part II contains the fundamental ideas from Modern Physics that form the foundation for an understanding of the approaches to treatment used in Radiation Therapy. Finally, Part III shows the applications of Parts I and II to Medical Imaging and Radiation Therapy. This unusual introduction to Medical Physics is aimed at undergraduate physics majors along with other science majors who have taken at least one year of Physics and one year of calculus, although Medical Physics graduate students and radiation oncology residents may find this different approach to the subject illuminating. This text assumes that the instructor is a physicist who does not necessarily have a background in Medical Physics.

Published

2024

3. Navigating the medical physics education and training landscape

Author

Brenda Clark, Gary D. Fullerton, George Starkschall, J. I. Prisciandaro, Brian Loughery, Jay Burmeister, Edward F. Jackson, K Hendrickson, and Geoffrey S. Ibbott

Subjects

ABR certification, medicine.medical_specialty, education, Training (civil), Education, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, medicine, Humans, Radiology, Nuclear Medicine and imaging, Medical physics, DMP, Instrumentation, Medical education, Radiation, Graduate education, business.industry, 01.40.-D, Internship and Residency, Residency program, MedPhys match, Clinical Practice, Graduate students, Education, Medical, Graduate, 030220 oncology & carcinogenesis, Workforce, Radiation Oncology, Survey data collection, Clinical Competence, Educational Measurement, Credentialing, residency, business, education and training, Health Physics, Residency training, graduate program

Abstract

Purpose The education and training landscape has been profoundly reshaped by the ABR 2012/2014 initiative and the MedPhys Match. This work quantifies these changes and summarizes available reports, surveys, and statistics on education and training. Methods We evaluate data from CAMPEP-accredited program websites, annual CAMPEP graduate and residency program reports, and surveys on the MedPhys Match and Professional Doctorate degree (DMP). Results From 2009–2015, the number of graduates from CAMPEP-accredited graduate programs rose from 210 to 332, while CAMPEP-accredited residency positions rose from 60 to 134. We estimate that approximately 60% of graduates of CAMPEP-accredited graduate programs intend to enter clinical practice, however, only 36% of graduates were successful in acquiring a residency position in 2015. The maximum residency placement percentage for a graduate program is 70%, while the median for all programs is only 22%. Overall residency placement percentage for CAMPEP-accredited program graduates from 2011–2015 was approximately 38% and 25% for those with a PhD and MS, respectively. The disparity between the number of clinically oriented graduates and available residency positions is perceived as a significant problem by over 70% of MedPhys Match participants responding to a post-match survey. Approximately 32% of these respondents indicated that prior knowledge of this situation would have changed their decision to pursue graduate education in medical physics. Conclusion These data reveal a substantial disparity between the number of residency training positions and graduate students interested in these positions, and a substantial variability in residency placement percentage across graduate programs. Comprehensive data regarding current and projected supply and demand within the medical physics workforce are needed for perspective on these numbers. While the long-term effects of changes in the education and training infrastructure are still unclear, available survey data suggest that these changes could negatively affect potential entrants to the profession.

Published

2017

4. Relational database of treatment planning system information

Author

Michael Eugene Kantor, George Starkschall, and Peter Balter

Abstract

The purpose of the present work was to develop a relational database and associated applications to facilitate retrospective review of data present in radiation treatment plans. The data source was a commercial radiation treatment planning system (Pinnacle3, Philips Medical Systems, Milpitas CA), which is specifically characterized by an open data storage format and internal scripting capability. The database is an open-source, relational database (PostgreSQL, PostgreSQL Global Development Group, http://www.postgresql.org). The data is presented through a web interface in addition to being fully query-accessible using standard tools. A database schema was created to organize the large collection of parameters used to generate treatment plans as well as the parameters that characterized these plans. The system was implemented through a combination of the treatment planning systems internal scripting language and externally executed code. Data is exported in a way that is transparent to the user, through integration into an existing and routinely-used process. The system has been transparently incorporated into our radiation treatment planning workflow. The website-based database interface has allowed users with minimal training to extract information from the database.

Published

2017

5. Some considerations in optimizing the Medical Physics Match

Author

Richard V. Butler, John H. Huston, and George Starkschall

Subjects

Canada, Radiation, Students, Medical, Career Choice, Computer science, Management science, MEDLINE, Internship and Residency, United States, Editorial, Medical economics, Education, Medical, Graduate, Humans, Radiology, Nuclear Medicine and imaging, Match algorithm, Radiology, Instrumentation, Career choice, Algorithms, Schools, Medical

Published

2019

6. SU-E-E-02: The Use of Social Media in a Medical Physics Classroom

Author

George Starkschall

Subjects

medicine.medical_specialty, Class (computer programming), business.industry, Teaching method, media_common.quotation_subject, General Medicine, Audit, Teaching assistant, Presentation, ComputingMilieux_COMPUTERSANDEDUCATION, Medicine, Lack of knowledge, Medical physics, Social media, business, Anonymity, media_common

Abstract

Purpose: The purpose of this presentation is to provide an example of how Facebook has been used in a medical physics classroom. Methods: Facebook was used in an introductory course in radiation interactions taken by graduate students in a CAMPEP‐accredited medical physics program. Facebook served two major functions in the class, as a means for communicating announcements to students, and as a forum for discussion of unclear points in the course. At the end of every class, students were prompted to fill out a questionnaire asking them to identify points that were not clear. After class, all questions were posted by the instructor (so students maintained anonymity and did not have to be embarrassed by lack of knowledge). Students had 24 hr to post responses to their peers’ questions. Students who responded correctly to peers’ questions received additional in‐ class credit for their response, thus encouraging them to respond. After 24 hr, the instructor or a teaching assistant posted a response to the question. Results: 12/16 students participated in discussions. The students who did not respond were all postdoctoral fellows (3/4 foreign) auditing the course. From 3 to 9 students typically responded to questions. Students responding to questions received credit for their responses (0.4 points per response up to a maximum of 5 points added to an in‐class grade that counted for 10% of their final grade). Student evaluations of the use of Facebook were generally positive. Furthermore, use of Facebook for this application extended the time students were interacting with each other in medical physics.Conclusions: The use of social media in a medical physics classroom appears to be an effective tool to incorporate into a teaching methodology.

Published

2017

7. Hendee's Radiation Therapy Physics

Author

Todd Pawlicki, Daniel J. Scanderbeg, George Starkschall, Todd Pawlicki, Daniel J. Scanderbeg, and George Starkschall

Subjects

Physics, Medical physics, Radiotherapy

Abstract

The publication of this fourth edition, more than ten years on from the publication of Radiation Therapy Physics third edition, provides a comprehensive and valuable update to the educational offerings in this field. Led by a new team of highly esteemed authors, building on Dr Hendee's tradition, Hendee's Radiation Therapy Physics offers a succinctly written, fully modernised update. Radiation physics has undergone many changes in the past ten years: intensity-modulated radiation therapy (IMRT) has become a routine method of radiation treatment delivery, digital imaging has replaced film-screen imaging for localization and verification, image-guided radiation therapy (IGRT) is frequently used, in many centers proton therapy has become a viable mode of radiation therapy, new approaches have been introduced to radiation therapy quality assurance and safety that focus more on process analysis rather than specific performance testing, and the explosion in patient-and machine-related data has necessitated an increased awareness of the role of informatics in radiation therapy. As such, this edition reflects the huge advances made over the last ten years. This book: Provides state of the art content throughout Contains four brand new chapters; image-guided therapy, proton radiation therapy, radiation therapy informatics, and quality and safety improvement Fully revised and expanded imaging chapter discusses the increased role of digital imaging and computed tomography (CT) simulation The chapter on quality and safety contains content in support of new residency training requirements Includes problem and answer sets for self-test This edition is essential reading for radiation oncologists in training, students of medical physics, medical dosimetry, and anyone interested in radiation therapy physics, quality, and safety.

Published

2016

8. A serial 4DCT study to quantify range variations in charged particle radiotherapy of thoracic cancers

Author

Shinichiro Mori, Radhe Mohan, Lei Dong, George T.Y. Chen, and George Starkschall

Subjects

Male, charged particle radiotherapy, dose distribution perturbation, Health, Toxicology and Mutagenesis, Tissue thickness, Dose distribution, Sensitivity and Specificity, 030218 nuclear medicine & medical imaging, Disease course, Radiotherapy, High-Energy, 03 medical and health sciences, 0302 clinical medicine, Respiration, Proton Therapy, Humans, intrafractional range variation, Medicine, Radiology, Nuclear Medicine and imaging, Four-Dimensional Computed Tomography, Aged, interfractional range variation, Aged, 80 and over, Range (particle radiation), Radiation, business.industry, Radiotherapy Planning, Computer-Assisted, Reproducibility of Results, Radiotherapy Dosage, Charged particle radiotherapy, Middle Aged, Thoracic Neoplasms, Treatment Outcome, Oncology, 030220 oncology & carcinogenesis, Radiographic Image Interpretation, Computer-Assisted, Female, Radiography, Thoracic, business, Nuclear medicine, Wall thickness, Charged particle beam

Abstract

Weekly serial 4DCT scans were acquired under free breathing conditions to assess water-equivalent path length (WEL) variations due to both intrafractional and interfractional changes in tissue thickness and density and to calculate proton dose distributions resulting from anatomical variations observed in serial 4DCT. A template of region of interests (ROIs) was defined on the anterior–posterior (AP) beam's eye view, and WEL measurements were made over these ROIs to quantify chest wall thickness variations. Interfractional proton dose distributions were calculated to assess changes in the expected dose distributions caused by range variations. Mean intrafractional chest wall WEL changes during respiration varied by: −4.1 mm (

Published

2013

9. Hendee's Radiation Therapy Physics

Author

Daniel J. Scanderbeg, George Starkschall, and Todd Pawlicki

Subjects

Radiation therapy, Physics, medicine.medical_specialty, medicine.medical_treatment, medicine, Medical physics

Published

2016

10. Appendix: Answers to Selected Problems

Author

Daniel J. Scanderbeg, George Starkschall, and Todd Pawlicki

Subjects

medicine.anatomical_structure, Computer science, medicine, Calculus, Appendix

Published

2016

11. Dosimetric effects of jaw tracking in step‐and‐shoot intensity‐modulated radiation therapy

Author

Steven H. Lin, Sarah Joy, George Starkschall, Peter A Balter, Stephen F Kry, Mohammad Salehpour, and R. Allen White

Subjects

Step and shoot, treatment planning, medicine.medical_treatment, normal tissue dose reduction, Collimated light, law.invention, law, Medicine, Radiation Oncology Physics, Humans, Radiology, Nuclear Medicine and imaging, Jaw tracking, IMRT, Radiation treatment planning, Child, Radiometry, Instrumentation, Retrospective Studies, Radiation, business.industry, Radiotherapy Planning, Computer-Assisted, Head and neck cancer, jaw optimization, Collimator, Dose-Response Relationship, Radiation, Radiotherapy Dosage, Intensity-modulated radiation therapy, Thoracic Neoplasms, medicine.disease, Radiation therapy, Jaw, Head and Neck Neoplasms, Radiotherapy, Intensity-Modulated, business, Nuclear medicine

Abstract

The purpose of this work was to determine the dosimetric benefit to normal tissues by tracking the multi‐leaf collimator (MLC) apertures with the photon jaws in step‐and‐shoot intensity‐modulated radiation therapy (IMRT) on the Varian 2100 platform. Radiation treatment plans for ten thoracic, three pediatric, and three head and neck cancer patients were converted to plans with the jaws tracking each segment's MLC apertures, and compared to the original plans in a commercial radiation treatment planning system (TPS). The change in normal tissue dose was evaluated in the new plan by using the parameters V5, V10, and V20 (volumes receiving 5, 10 and 20 Gy, respectively) in the cumulative dose‐volume histogram for the following structures: total lung minus gross target volume, heart, esophagus, spinal cord, liver, parotids, and brainstem. To validate the accuracy of our beam model, MLC transmission was measured and compared to that predicted by the TPS. The greatest changes between the original and new plans occurred at lower dose levels. In all patients, the reduction in V20 was never more than 6.3% and was typically less than 1%; the maximum reduction in V5 was 16.7% and was typically less than 3%. The variation in normal tissue dose reduction was not predictable, and we found no clear parameters that indicated which patients would benefit most from jaw tracking. Our TPS model of MLC transmission agreed with measurements with absolute transmission differences of less than 0.1% and, thus, uncertainties in the model did not contribute significantly to the uncertainty in the dose determination. We conclude that the amount of dose reduction achieved by collimating the jaws around each MLC aperture in step‐and‐shoot IMRT is probably not clinically significant. PACS numbers: 87.55.D‐ 87.55.de 87.55.dk

Published

2012

12. Interfractional Reproducibility of Lung Tumor Location Using Various Methods of Respiratory Motion Mitigation

Author

James D. Cox, Radhe Mohan, K. Britton, Mary Frances McAleer, George Starkschall, and Peter A Balter

Subjects

Cancer Research, medicine.medical_specialty, Lung Neoplasms, Movement, Bone and Bones, Standard deviation, Carcinoma, Non-Small-Cell Lung, Humans, Medicine, Radiology, Nuclear Medicine and imaging, Four-Dimensional Computed Tomography, Reproducibility, Radiation, business.industry, Respiration, Respiratory motion, Reproducibility of Results, Tumor Burden, Data set, Inhalation, Oncology, Exhalation, Lung tumor, Dose Fractionation, Radiation, Radiology, Tomography, business, Fiducial marker, Nuclear medicine

Abstract

Purpose To determine interfractional reproducibility of the location of lung tumors using respiratory motion mitigation. Methods and Materials Free-breathing four-dimensional computed tomography (CT) data sets and CT data sets during breath hold were acquired weekly for 17 patients undergoing treatment for non–small-cell lung cancer. Distances between the center of the gross tumor volume (GTV) and a reproducible bony reference point under conditions of breath hold on end inspiration (EI) and end expiration (EE) and during free breathing on the 0% phase (corresponding to EI) and 50% phase (corresponding to EE) were analyzed for interfractional reproducibility. Systematic uncertainties in tumor location were determined as the difference in distance between the GTV center on the first CT data set and the mean location of GTV centers on the subsequent data sets. Random uncertainties in tumor location were determined as the standard deviation of the distances between the GTV centers and the bony reference points. Margins to account for systematic and random interfractional variations were estimated based on these uncertainties. Results Mean values of interfractional setup uncertainties were as follows: systematic uncertainties—EI, 0.3 cm; EE, 0.2 cm; 0% phase, 0.3 cm; and 50% phase, 0.3 cm; and random uncertainties—EI, 0.3 cm; EE, 0.3 cm; 0% phase, 0.3 cm; and 50% phase, 0.3 cm. There does not appear to be any correlation between uncertainties and GTV size, but there appears to be a weak positive correlation between uncertainties and the magnitude of GTV excursion. Conclusions Voluntary breath hold and gating on either EI or EE appear to be equally reliable methods of ensuring the reproducibility of lung tumor position. We recommend setup margins of 0.3 cm if using cone-beam CT or kilovoltage X-ray with fiducials and aligning directly to the tumor and 0.8 cm when aligning to a nearby bony surrogate using cone-beam CT or kilovoltage X-ray.

Published

2011

13. Thoracic target volume delineation using various maximum-intensity projection computed tomography image sets for radiotherapy treatment planning

Author

Adam C. Riegel, Osama Mawlawi, George Starkschall, Xiaojun Sun, Peter A Balter, David A. Zamora, and Tinsu Pan

Subjects

Data set, Contouring, Four-Dimensional Computed Tomography, business.industry, Maximum intensity projection, Medical imaging, Medicine, Image processing, General Medicine, Tomography, Radiation treatment planning, business, Nuclear medicine

Abstract

Purpose: Four-dimensional computed tomography (4D-CT) is commonly used to account for respiratory motion of target volumes in radiotherapy to the thorax. From the 4D-CT acquisition, a maximum-intensity projection (MIP) image set can be created and used to help define the tumor motion envelope or the internal gross tumor volume (iGTV). The purpose of this study was to quantify the differences in automatically contoured target volumes for usage in the delivery of stereotactic body radiation therapy using MIP data sets generated from one of the four methods: (1) 4D-CT phase-binned (PB) based on retrospective phase calculations, (2) 4D-CT phase-corrected phase-binned (PC-PB) based on motion extrema, (3) 4D-CT amplitude-binned (AB), and (4) cine CT built from all available images. Methods: MIP image data sets using each of the four methods were generated for a cohort of 28 patients who had prior thoracic 4D-CT scans that exhibited lung tumor motion of at least 1 cm. Each MIP image set was automatically contoured on commercial radiation treatment planning system. Margins were added to the iGTV to observe differences in the final simulated planning target volumes (PTVs). Results: For all patients, the iGTV measured on the MIP generated from the entire cine CT data set (iGTVcine) was the largest. Expressed as a percentage of iGTVcine, 4D-CT iGTV (all sorting methods) ranged from 83.8% to 99.1%, representing differences in the absolute volume ranging from 0.02 to 4.20 cm3; the largest average and range of 4D-CT iGTV measurements was from the PC-PB data set. Expressed as a percentage of PTVcine (expansions applied to iGTVcine), the 4D-CT PTV ranged from 87.6% to 99.6%, representing differences in the absolute volume ranging from 0.08 to 7.42 cm3. Regions of the measured respiratory waveform corresponding to a rapid change of phase or amplitude showed an increased susceptibility to the selection of identical images for adjacent bins. Duplicate image selection was most common in the AB implementation, followed by the PC-PB method. The authors also found that the image associated with the minimum amplitude measurement did not always correlate with the image that showed maximum tumor motion extent. Conclusions: The authors identified cases in which the MIP generated from a 4D-CT sorting process under-represented the iGTV by more than 10% or up to 4.2 cm3 when compared to the iGTVcine. They suggest utilization of a MIP generated from the full cine CT data set to ensure maximum inclusive tumor extent.

Published

2010

14. Lack of Correlation Between External Fiducial Positions and Internal Tumor Positions During Breath-Hold CT

Author

Peter A Balter, Lei Dong, S. Hunjan, George Starkschall, and Karl Prado

Subjects

Male, Respiratory-Gated Imaging Techniques, Cancer Research, Lung Neoplasms, Movement, End-expiration, Absolute difference, Correlation, Humans, Medicine, Radiology, Nuclear Medicine and imaging, Four-Dimensional Computed Tomography, Aged, Aged, 80 and over, Radiation, business.industry, Radiotherapy Planning, Computer-Assisted, Respiration, Centroid, Prostheses and Implants, Middle Aged, Tumor Burden, Gross tumor volume, Inhalation, Oncology, Exhalation, Calibration, Female, Tomography, Tomography, X-Ray Computed, business, Nuclear medicine, Fiducial marker

Abstract

Purpose For thoracic tumors, if four-dimensional computed tomography (4DCT) is unavailable, the internal margin can be estimated by use of breath-hold (BH) CT scans acquired at end inspiration (EI) and end expiration (EE). By use of external surrogates for tumor position, BH accuracy is estimated by minimizing the difference between respiratory extrema BH and mean equivalent-phase free breathing (FB) positions. We tested the assumption that an external surrogate for BH accuracy correlates with internal tumor positional accuracy during BH CT. Methods and Materials In 16 lung cancer patients, 4DCT images, as well as BH CT images at EI and EE, were acquired. Absolute differences between BH and mean equivalent-phase (FB) positions were calculated for both external fiducials and gross tumor volume (GTV) centroids as metrics of external and internal BH accuracy, respectively, and the results were correlated. Results At EI, the absolute difference between mean FB and BH fiducial displacement correlated poorly with the absolute difference between FB and BH GTV centroid positions on CT images ( R 2 = 0.11). Similarly, at EE, the absolute difference between mean FB and BH fiducial displacements correlated poorly with the absolute difference between FB and BH GTV centroid positions on CT images ( R 2 = 0.18). Conclusions External surrogates for tumor position are not an accurate metric of BH accuracy for lung cancer patients. This implies that care should be taken when using such an approach because an incorrect internal margin could be generated.

Published

2010

15. Comparing the accuracy of four-dimensional photon dose calculations with three-dimensional calculations using moving and deforming phantoms

Author

George Starkschall, Peter A Balter, R. Allen White, Yevgeniy Vinogradskiy, Paola Alvarez, and David S Followill

Subjects

Physics, Dosimeter, Photon, Dose calculation, business.industry, Medical imaging, Dosimetry, General Medicine, Thermoluminescent dosimeter, Radiation treatment planning, Nuclear medicine, business, Imaging phantom

Abstract

Purpose: Four-dimensional (4D) dose calculation algorithms, which explicitly incorporate respiratory motion in the calculation of doses, have the potential to improve the accuracy of dose calculations in thoracic treatment planning; however, they generally require greater computing power and resources than currently used for three-dimensional (3D) dose calculations. The purpose of this work was to quantify the increase in accuracy of 4D dose calculations versus 3D dose calculations. Methods: The accuracy of each dose calculation algorithm was assessed using measurements made with two phantoms. Specifically, the authors used a rigid moving anthropomorphic thoracic phantom and an anthropomorphic thoracic phantom with a deformable lung insert. To incorporate a clinically relevant range of scenarios, they programed the phantoms to move and deform with two motion patterns: A sinusoidal motion pattern and an irregular motion pattern that was extracted from an actual patient's breathing profile. For each combination of phantom and motion pattern, three plans were created: A single-beam plan, a multiple-beam plan, and an intensity-modulated radiation therapy plan. Doses were calculated using 4D dose calculation methods as well as conventional 3D dose calculation methods. The rigid moving and deforming phantoms were irradiated according to the three treatment plans and doses were measured usingmore » thermoluminescent dosimeters (TLDs) and radiochromic film. The accuracy of each dose calculation algorithm was assessed using measured-to-calculated TLD doses and a {gamma} analysis. Results: No significant differences were observed between the measured-to-calculated TLD ratios among 4D and 3D dose calculations. The {gamma} results revealed that 4D dose calculations had significantly greater percentage of pixels passing the 5%/3 mm criteria than 3D dose calculations. Conclusions: These results indicate no significant differences in the accuracy between the 4D and the 3D dose calculation methods inside the gross tumor volume. On the other hand, the film results demonstrated that the 4D dose calculations provided greater accuracy than 3D dose calculations in heterogeneous dose regions. The increase in accuracy of the 4D dose calculations was evident throughout the planning target volume.« less

Published

2009

16. Verification of four-dimensional photon dose calculations

Author

R. Allen White, David S Followill, Yevgeniy Vinogradskiy, George Starkschall, Paola Alvarez, and Peter A Balter

Subjects

Dosimeter, Photon, medicine.diagnostic_test, Computer science, business.industry, medicine.medical_treatment, Image registration, Cancer, Computed tomography, General Medicine, Intensity-modulated radiation therapy, medicine.disease, Imaging phantom, Radiation therapy, Dose calculation algorithm, Organ Motion, medicine, Medical imaging, Dosimetry, Thermoluminescent dosimeter, Nuclear medicine, business, Radiation treatment planning

Abstract

Recent work in the area of thoracic treatment planning has been focused on trying to explicitly incorporate patient-specific organ motion in the calculation of dose. Four-dimensional (4D) dose calculation algorithms have been developed and incorporated in a research version of a commercial treatment planning system (Pinnacle3, Philips Medical Systems, Milpitas, CA). Before these 4D dose calculations can be used clinically, it is necessary to verify their accuracy with measurements. The primary purpose of this study therefore was to evaluate and validate the accuracy of a 4D dose calculation algorithm with phantom measurements. A secondary objective was to determine whether the performance of the 4D dose calculation algorithm varied between different motion patterns and treatment plans. Measurements were made using two phantoms: A rigid moving phantom and a deformable phantom. The rigid moving phantom consisted of an anthropomorphic thoracic phantom that rested on a programmable motion platform. The deformable phantom used the same anthropomorphic thoracic phantom with a deformable insert for one of the lungs. Two motion patterns were investigated for each phantom: A sinusoidal motion pattern and an irregular motion pattern extracted from a patient breathing profile. A single-beam plan, a multiple-beam plan, and an intensity-modulated radiation therapy plan were created. Doses were calculated in the treatment planning system using the 4D dose calculation algorithm. Then each plan was delivered to the phantoms and delivered doses were measured using thermoluminescent dosimeters(TLDs) and film. The measured doses were compared to the 4D-calculated doses using a measured-to-calculated TLD ratio and a γ analysis. A relevant passing criteria (3% for the TLD and 5 % ∕ 3 mm for the γ metric) was applied to determine if the 4D dose calculations were accurate to within clinical standards. All the TLD measurements in both phantoms satisfied the passing criteria. Furthermore, 42 of the 48 evaluated films fulfilled the passing criteria. All films that did not pass the criteria were from the rigid phantom moving with irregular motion. The author concluded that if patient breathing is reproducible, the 4D dose calculations are accurate to within clinically acceptable standards. Furthermore, they found no statistically significant differences in the performance of the 4D dose calculation algorithm between treatment plans.

Published

2009

17. Respiratory gating with EPID-based verification: the MDACC experience

Author

Sunil Krishnan, Ravi Murthy, Peter A Balter, Christopher Lee Nelson, Sanjay Gupta, George Starkschall, Sam Beddar, Michael Gillin, and Tina Marie Briere

Subjects

Systematic error, Radiotherapy, Radiological and Ultrasound Technology, business.industry, Radiotherapy Planning, Computer-Assisted, Respiration, medicine.medical_treatment, Liver Neoplasms, Respiratory gating, Implanted Fiducial, Radiation therapy, Motion, Portal imaging, Treatment delivery, medicine, Humans, Radiology, Nuclear Medicine and imaging, In patient, Tomography, X-Ray Computed, Fiducial marker, business, Nuclear medicine, Software

Abstract

We have investigated the feasibility and accuracy of using a combination of internal and external fiducials for respiratory-gated image-guided radiotherapy of liver tumors after screening for suitable patients using a mock treatment. Five patients were enrolled in the study. Radio-opaque fiducials implanted adjacent to the liver tumor were used for daily online positioning using either electronic portal or kV images. Patient eligibility was assessed by determining the degree of correlation between the external and internal fiducials as analyzed during a mock treatment. Treatment delivery was based on the modification of conventional amplitude-based gating. Finally, the accuracy of respiratory-gated treatment using an external fiducial was verified offline using the cine mode of an electronic portal imaging device. For all patients, interfractional contribution to the random error was 2.0 mm in the supero-inferior direction, which is the dominant direction of motion due to respiration, while the interfractional contribution to the systematic error was 0.9 mm. The intrafractional contribution to the random error was 1.0 mm. One of the significant advantages to this technique is improved patient set-up using implanted fiducials and gated imaging. Daily assessment of images acquired during treatment verifies the accuracy of the delivered treatment and uncovers problems in patient set-up.

Published

2009

18. Potential Dosimetric Benefits of Four-Dimensional Radiation Treatment Planning

Author

Radhe Mohan, George Starkschall, Melenda Jeter, K. Britton, James D. Cox, Michael Kaus, Karl Bzdusek, and Mary Frances McAleer

Subjects

Cancer Research, medicine.medical_specialty, Lung Neoplasms, Dose calculation, Movement, Planning target volume, Computed tomography, Dose distribution, Imaging, Three-Dimensional, Carcinoma, Non-Small-Cell Lung, Humans, Medicine, Radiology, Nuclear Medicine and imaging, Radiation treatment planning, Retrospective Studies, Radiation, medicine.diagnostic_test, business.industry, Radiotherapy Planning, Computer-Assisted, Respiration, Respiratory motion, Heart, Radiotherapy Dosage, Tumor Burden, Gross tumor volume, Spinal Cord, Oncology, Radiology, Tomography, business, Nuclear medicine, Tomography, Spiral Computed, Algorithms

Abstract

Purpose: To determine the extent of dosimetric differences between conventional three-dimensional (3D) dose calculations and four-dimensional (4D) dose calculations based on deformation of organ models. Methods and Materials: Four-dimensional dose calculations were retrospectively performed on computed tomography data sets for 15 patients with Stage III non-small-cell lung cancer, using a model-based deformable registration algorithm on a research version of a commercial radiation treatment planning system. Target volume coverage and doses to critical structures calculated using the 4D methodology were compared with those calculated using conventional 3D methodology. Results: For 11 of 15 patients, clinical target volume coverage was comparable in the 3D and 4D calculations, whereas for 7 of 15 patients, planning target volume coverage was comparable. For the other patients, the 4D calculation indicated a difference in target volume dose sufficiently great to warrant replanning. No correlations could be established between differences in 3D and 4D calculations and gross tumor volume size or extent of motion. Negligible differences were observed between 3D and 4D dose-volume relationships for normal anatomic structures. Conclusions: Use of 4D dose calculations, when possible, helps ensure that target volumes will not be underirradiated when respiratory motion may affect the dose distribution.

Published

2009

19. Consequences of Anatomic Changes and Respiratory Motion on Radiation Dose Distributions in Conformal Radiotherapy for Locally Advanced Non–Small-Cell Lung Cancer

Author

K. Britton, Michael E. Kantor, George Starkschall, Stephen D. Bilton, Muthuveni Ezhil, James D. Cox, Joe Y. Chang, Helen Liu, Sandra C. John-Baptiste, Ritsuko Komaki, and Radhe Mohan

Subjects

Male, Cancer Research, medicine.medical_specialty, Lung Neoplasms, medicine.medical_treatment, Locally advanced, Standard deviation, Motion, Radiation Protection, Carcinoma, Non-Small-Cell Lung, medicine, Humans, Radiology, Nuclear Medicine and imaging, Lung volumes, Radiometry, Lung cancer, Aged, Aged, 80 and over, Radiation, Four-Dimensional Computed Tomography, Lung, business.industry, Radiotherapy Planning, Computer-Assisted, Radiotherapy Dosage, Middle Aged, medicine.disease, Radiography, Radiation therapy, medicine.anatomical_structure, Oncology, Respiratory Mechanics, Body Burden, Female, Tomography, Radiology, business, Nuclear medicine, Relative Biological Effectiveness

Abstract

Purpose To determine the effect of interfractional changes in anatomy on the target and normal tissue dose distributions during course of radiotherapy in non–small-cell lung cancer patients. Methods and Materials Weekly respiration-correlated four-dimensional computed tomography scans were acquired for 10 patients. Original beam arrangements from conventional and inverse treatment plans were transferred into each of the weekly four-dimensional computed tomography data sets, and the dose distributions were recalculated. Dosimetric changes to the target volumes and relevant normal structures relative to the baseline treatment plans were analyzed by dose–volume histograms. Results The overall difference in the mean ± standard deviation of the doses to 95% of the planning target volume and internal target volume between the initial and weekly treatment plans was −11.9% ± 12.1% and −2.5% ± 3.9%, respectively. The mean ± standard deviation change in the internal target volume receiving 95% of the prescribed dose was −2.3% ± 4.1%. The overall differences in the mean ± standard deviation between the initial and weekly treatment plans was 3.1% ± 6.8% for the total lung volume exceeding 20 Gy, 2.2% ± 4.8% for mean total lung dose, and 34.3% ± 43.0% for the spinal cord maximal dose. Conclusion Serial four-dimensional computed tomography scans provided useful anatomic information and dosimetric changes during radiotherapy. Although the observed dosimetric variations were small, on average, the interfractional changes in tumor volume, mobility, and patient setup was sometimes associated with dramatic dosimetric consequences. Therefore, for locally advanced lung cancer patients, efforts to include image-guided treatment and to perform repeated imaging during the treatment course are recommended.

Published

2009

20. Effects of Interfractional Motion and Anatomic Changes on Proton Therapy Dose Distribution in Lung Cancer

Author

Zhouguang Hui, Yupeng Li, Radhe Mohan, George Starkschall, James D. Cox, Xiaodong Zhang, Joe Y. Chang, and Ritsuko Komaki

Subjects

Cancer Research, medicine.medical_specialty, Lung Neoplasms, medicine.medical_treatment, Article, Carcinoma, Non-Small-Cell Lung, Proton Therapy, medicine, Carcinoma, Humans, Radiology, Nuclear Medicine and imaging, Stage (cooking), Lung cancer, Lung, Proton therapy, Neoplasm Staging, Skin, Radiation, business.industry, medicine.disease, Radiation therapy, Fractals, medicine.anatomical_structure, Oncology, Breathing, Tomography, Radiology, Tomography, X-Ray Computed, business, Nuclear medicine

Abstract

Purpose Proton doses are sensitive to intra- and interfractional anatomic changes. We analyzed the effects of interfractional anatomic changes in doses to lung tumors treated with proton therapy. Methods and Materials Weekly four-dimensional computed tomography (4D-CT) scans were acquired for 8 patients with mobile Stage III non–small cell lung cancer who were actually treated with intensity-modulated photon radiotherapy. A conformal proton therapy passive scattering plan was designed for each patient. Dose distributions were recalculated at end-inspiration and end-expiration breathing phases on each weekly 4D-CT data set using the same plans with alignment based on bone registration. Results Clinical target volume (CTV) coverage was compromised (from 99% to 90.9%) in 1 patient because of anatomic changes and motion pattern variation. For the rest of the patients, the mean CTV coverage on the repeated weekly 4D-CT data sets was 98.4%, compared with 99% for the original plans. For all 8 patients, however, a mean 4% increase in the volume of the contralateral lung receiving a dose of at least 5 Gy (V5) and a mean 4.4-Gy increase in the spinal cord maximum dose was observed in the repeated 4D-CT data sets. A strong correlation between the CTV density change resulting from tumor shrinkage or anatomic variations and mean contralateral lung dose was observed. Conclusions Adaptive re-planning during proton therapy may be indicated in selected patients with non–small cell lung cancer. For most patients, however, CTV coverage is adequate if tumor motion is taken into consideration in the original simulation and planning processes.

Published

2008

21. Validation of a Model-Based Segmentation Approach to Propagating Normal Anatomic Regions of Interest Through the 10 Phases of Respiration

Author

Muthuveni Ezhil, James D. Cox, Radhe Mohan, George Starkschall, and Ritsuko Komaki

Subjects

Cancer Research, Lung Neoplasms, Computed tomography, Image processing, Models, Biological, Sensitivity and Specificity, Carcinoma, Non-Small-Cell Lung, Humans, Medicine, Computer Simulation, Radiology, Nuclear Medicine and imaging, Segmentation, Radiometry, Radiation treatment planning, Left lung, Contouring, Radiation, medicine.diagnostic_test, business.industry, Radiotherapy Planning, Computer-Assisted, Reproducibility of Results, Radiotherapy Dosage, Data set, Oncology, Respiratory Mechanics, Radiographic Image Interpretation, Computer-Assisted, Model based segmentation, Tomography, X-Ray Computed, business, Nuclear medicine, Biomedical engineering

Abstract

Purpose To validate a model-based segmentation (MBS) algorithm in a commercial radiation treatment planning system for use in propagating the contours of normal anatomic regions of interest (ROIs) through the respiratory phases that constitute a four-dimensional (4D) computed tomography (CT) image data set. Methods and Materials The 4D CT data sets for 12 patients treated for non–small-cell lung cancer were acquired. Five ROIs were selected for delineation: right and left lungs, spinal cord, heart, and esophagus. These ROIs were manually delineated on the CT data set corresponding to the end-inspiration respiratory phase (0%). An MBS algorithm implemented on the treatment planning system propagated the ROIs sequentially through the respiratory phases that constituted the 4D CT data sets, concluding with the 0% phase data set, which was propagated from the 90% phase data set. The propagated ROIs on the 0% phase were compared with the original ROIs on that phase by using visual assessment and a quantitative measure of coincidence. Results Acceptable propagation accuracy within 1 mm of uncertainty was achieved for lungs and spinal cord. Propagation of the heart produced slightly larger contours that were similar to interphysician variations in contouring the heart. The esophagus was poorly propagated because of lack of tissue contrast and definitive shape. Conclusions The MBS propagation is a promising tool for efficiently propagating contours through the different phases of respiration. However, propagating the esophagus through this technique may be difficult because of the lack of definitive shape and clearer boundaries from surrounding tissue.

Published

2008

22. Comparison of breath-hold and free-breathing positions of an external fiducial by analysis of respiratory traces

Author

George Starkschall, Peter A Balter, Naresh Tolani, S. Hunjan, Karl Prado, and Isaac I. Rosen

Subjects

Lung Neoplasms, Movement, ITV, Planning target volume, lung tumor, breath‐hold, Carcinoma, Non-Small-Cell Lung, Significant error, Radiation Oncology Physics, Humans, Medicine, Radiology, Nuclear Medicine and imaging, Respiratory system, Instrumentation, Tumor motion, Radiation, business.industry, Respiration, Radiography, Ct technique, Non small cell, respiratory monitoring, business, Fiducial marker, Nuclear medicine, psychological phenomena and processes, Free breathing

Abstract

An internal target volume (ITV) accounting for respiratory‐induced tumor motion is best obtained using 4DCT. However, when 4DCT is not available, inspiratory/expiratory breath‐hold (BHinsp, BHexp) CT images have been suggested as an alternative. In such cases, an external fiducial on the abdomen can be used as a substitute for tumor motion and CT images are acquired when the marker position matches – as judged by the therapist/physicist ‐ its positions at previously determined free‐breathing (FB) respiratory extrema (FBinsp, FBexp). In this study we retrospectively determined the accuracy of these matches. Free breathing 4DCT images were acquired, followed by BHinsp and BHexp CT images for 25 patients with non‐small‐cell lung cancer. Respiration was monitored using a commercial external fiducial system, which generates positional information while CT studies are conducted. Software was written for statistically analyzing the displacement of the external fiducial during BHinsp and BHexp CT acquisition and comparing these displacements with corresponding mean FB extrema positions (FBinsp and FBexp, respectively) using a Student's t‐test. In 72% of patients, mean positions at BHinsp differed significantly from mean positions at FBinsp (p

Published

2008

23. Determination of an optimal organ set to implement deformations to support four‐dimensional dose calculations in radiation therapy planning

Author

Wafa Soofi, K. Britton, Sastry Vedam, and George Starkschall

Subjects

medicine.medical_specialty, Dose calculation, respiratory motion, Image registration, Dose distribution, Deformation (meteorology), Set (abstract data type), Body surface, medicine, Histologic type, Humans, Radiation Oncology Physics, Radiology, Nuclear Medicine and imaging, Medical physics, Radiation treatment planning, deformable image registration, Instrumentation, Mathematics, Radiation, Radiotherapy Planning, Computer-Assisted, Thoracic Neoplasms, Biomechanical Phenomena, Subtraction Technique, 4D treatment planning, Algorithms, Biomedical engineering

Abstract

Surface‐based deformable image registration to generate a four‐dimensional (4D) dose calculation in radiation treatment planning requires the selection of a set of organ contours representing a basis set from which to generate anatomic deformation. The purpose of the present work was to determine the optimal set of organs needed to generate a basis set for deformation in treatment planning for thoracic tumors, such that the required computations are minimized, but that dose accuracy is high. Using retrospectively reviewed records and a deformable model algorithm in a research version of a commercial radiation treatment planning system, we calculated 4D dose distributions based on treatment plans for 10 patients with thoracic tumors. Various combinations of organs (total lungs, heart, spinal cord, external body surface) were used to generate the basis set used in the calculations for deformations. The external surface contour did not have a noticeable effect on the dose calculation. Total lung, heart, and spinal cord together provided an adequate set of deformation organs to generate accurate dose deformations. The magnitude of the calculated dose differences had no obvious relationship to tumor parameters, including site, histologic type, disease stage, extent of motion, or degree of centralization. PACS numbers: 87.55.D‐, 87.55.dk, 87.55.kh

Published

2008

24. Use of three-dimensional (3D) optical flow method in mapping 3D anatomic structure and tumor contours across four-dimensional computed tomography data

Author

Kang-Ping Lin, Thomas Guerrero, Tzung Chi Huang, Craig W. Stevens, George Starkschall, Geoffrey Zhang, and K. Forster

Subjects

Optical flow, computer.software_genre, Models, Biological, Imaging phantom, 3D optical flow, Imaging, Three-Dimensional, Voxel, Humans, Radiation Oncology Physics, Computer Simulation, Radiology, Nuclear Medicine and imaging, Displacement (orthopedic surgery), Radiometry, deformable image registration, Instrumentation, Mathematics, 4D treatment planning, radiotherapy, Radiation, Four-Dimensional Computed Tomography, business.industry, Radiotherapy Planning, Computer-Assisted, Thoracic Neoplasms, Feature (computer vision), Radiographic Image Interpretation, Computer-Assisted, Tomography, Radiotherapy, Conformal, Tomography, X-Ray Computed, Nuclear medicine, business, computer, Volume (compression), Biomedical engineering

Abstract

A three‐dimensional (3D) optical flow program that includes a multi‐resolution feature has been developed and applied to 3D anatomic structure and gross tumor volume (GTV) contour mapping for four‐dimensional computed tomography (4D CT) data. The present study includes contour mapping for actual CT data sets from 3 patients and also for a thoracic phantom in which the displacement for each voxel was known. Of the CT data sets for the actual patients, one set was used to map lung and GTV contours over all respiration phases, and the other two were studied using only the end inspiration and end expiration phases, in which the displacements between phases were the largest. Including the residual motion in the 4D CT data and motion from table shaking, the optical flow calculation agrees with the known displacement to within 1 mm. Excluding errors not introduced by the optical flow algorithm, agreement for a displacement magnitude of 24 mm can be within 0.1 mm. The mapped contours in 4D CT images of lungs, liver, esophagus, GTV, and other structures for actual patients were acceptable to clinicians. The 3D optical flow program is a good tool for contour mapping of anatomic structure and tumor volume across 4D CT scans. PACS numbers: 87.55.D‐, 87.59.bd

Published

2008

25. Image–Guided Radiation Therapy for Non–small Cell Lung Cancer

Author

Zhongxing Liao, Joe Y. Chang, Ritsuko Komaki, George Starkschall, Peter A Balter, Helen Liu, Lei Dong, James D. Cox, and Radhe Mohan

Subjects

Pulmonary and Respiratory Medicine, image-guided radiation therapy, medicine.medical_specialty, Lung Neoplasms, PET/CT, medicine.medical_treatment, Radiosurgery, Carcinoma, Non-Small-Cell Lung, medicine, Humans, Lung cancer, Image-guided radiation therapy, PET-CT, 4-D CT, medicine.diagnostic_test, target volume delineation, business.industry, Cancer, intensity-modulated radiotherapy, medicine.disease, adapted radiotherapy, Radiotherapy, Computer-Assisted, Radiation therapy, Clinical trial, stereotactic body radiotherapy, Oncology, Positron emission tomography, Positron-Emission Tomography, Radiotherapy, Intensity-Modulated, Radiology, Tomography, X-Ray Computed, business, Nuclear medicine, nonsmall cell lung cancer

Abstract

Recent developments in image-guided radiotherapy are ushering in a new era of radiotherapy for lung cancer. Positron emission tomography/computed tomography (PET/CT) has been shown to improve targeting accuracy in 25 to 50% of cases, and four-dimensional CT scanning helps to individualize radiotherapy by accounting for tumor motion. Daily on-board imaging reduces treatment set-up uncertainty and provides information about daily organ motion and variations in anatomy. Image-guided intensity-modulated radiotherapy may allow for the escalation of radiotherapy dose with no increase in toxicity. More importantly, treatment adaptations based on anatomic changes during the course of radiotherapy and dose painting within involved lesions using functional imaging such as PET may further improve clinical outcomes of lung cancer patients and potentially lead to new clinical trials. Image-guided stereotactic radiotherapy can achieve local control rates exceeding 90% through the use of focused, hypofractionated, highly biologically effective doses. These novel approaches were considered experimental just a few years ago, but accumulating evidence of their potential for significantly improving clinical outcomes is leading to their inclusion in standard treatments for lung cancer at major cancer centers. In this review article, we focus on novel image-guided radiotherapy approaches, particularly PET/CT and four-dimensional CT-based radiotherapy planning and on-board image-guided delivery, stereotactic radiotherapy, and intensity-modulated radiotherapy for mobile nonsmall cell lung cancer.

Published

2008

26. Informatics in Radiation Oncology

Author

George Starkschall, R. Alfredo C. Siochi, George Starkschall, and R. Alfredo C. Siochi

Subjects

Medicine--Data processing, Medical informatics, Cancer--Radiotherapy

Abstract

Reflecting the increased importance of the collaborations between radiation oncology and informatics professionals, Informatics in Radiation Oncology discusses the benefits of applying informatics principles to the processes within radiotherapy. It explores how treatment and imaging information is represented, stored, and retrieved as well as how t

Published

2014

27. Anniversary Paper: Roles of medical physicists and health care applications of informatics

Author

George C. Kagadis, Michael J. Flynn, Steve G. Langer, George Starkschall, and Paul Nagy

Subjects

medicine.medical_specialty, business.industry, Information technology, General Medicine, DICOM, Health Administration Informatics, Informatics, Health care, Medical imaging, medicine, Information system, Medical physics, Medical diagnosis, business

Abstract

Over the past 100 years, both diagnostic radiology and radiation therapy have grown from infancy to maturity. Accompanying this growth, the discipline of medical physics has evolved and advanced accordingly. New diagnostic and therapeutic procedures continue to be developed, for example, multidetector computed tomography, multileaf collimation, magnetic resonance imaging, dual-source computed tomography, and intensity-modulated radiation therapy. These are now incorporated in health care facilities throughout the world. Modern technologies such as these provide information on underlying pathology at increasingly higher resolutions, generating more information; thus requiring complex methods of image recording and storage. The management of the storage and retrieval of accumulated information is a domain of informatics. In this short review, we describe the different roles of medical physicists and the effective contribution of the American Association of Physicists in Medicine in the evolution of informatics. Medical physicists have contributed to the development of informatics in numerous ways, such as designing hospital information systems and infrastructures that better serve radiologists and other physicians. In addition, the positive exploitation of knowledge gathered in medical settings and effective interdisciplinary collaborations between scientists of different backgrounds have increased. These developments provide future medical physicists the opportunity to develop strategic roles in information technology and thus better contribute to health care.

Published

2007

28. Determination of prospective displacement-based gate threshold for respiratory-gated radiation delivery from retrospective phase-based gate threshold selected at 4D CT simulation

Author

George Starkschall, Radhe Mohan, L. Archambault, Sam Beddar, and Sastry Vedam

Subjects

Materials science, Duty cycle, business.industry, Medical imaging, Phase (waves), General Medicine, Gating, Computed radiography, Radiation treatment planning, Nuclear medicine, business, Displacement (vector), Imaging phantom

Abstract

Four-dimensional (4D) computed tomography(CT)imaging has found increasing importance in the localization of tumor and surrounding normal structures throughout the respiratory cycle. Based on such tumor motion information, it is possible to identify the appropriate phase interval for respiratory gated treatment planning and delivery. Such a gating phase interval is determined retrospectively based on tumor motion from internal tumor displacement. However, respiratory-gated treatment is delivered prospectively based on motion determined predominantly from an external monitor. Therefore, the simulation gate threshold determined from the retrospective phase interval selected for gating at 4D CT simulation may not correspond to the delivery gate threshold that is determined from the prospective external monitor displacement at treatmentdelivery. The purpose of the present work is to establish a relationship between the thresholds for respiratory gating determined at CT simulation and treatmentdelivery, respectively. One hundred fifty external respiratory motion traces, from 90 patients, with and without audio-visual biofeedback, are analyzed. Two respiratory phase intervals, 40%–60% and 30%–70%, are chosen for respiratory gating from the 4D CT-derived tumor motion trajectory. From residual tumor displacements within each such gating phase interval, a simulation gate threshold is defined based on (a) the average and (b) the maximum respiratory displacement within the phase interval. The duty cycle for prospective gated delivery is estimated from the proportion of external monitor displacement data points within both the selected phase interval and the simulation gate threshold. The delivery gate threshold is then determined iteratively to match the above determined duty cycle. The magnitude of the difference between such gate thresholds determined at simulation and treatmentdelivery is quantified in each case. Phantom motion tests yielded coincidence of simulation and delivery gate thresholds to within 0.3%. For patient data analysis, differences between simulation and delivery gate thresholds are reported as a fraction of the total respiratory motion range. For the smaller phase interval, the differences between simulation and delivery gate thresholds are 8 ± 11 % and 14 ± 21 % with and without audio-visual biofeedback, respectively, when the simulation gate threshold is determined based on the mean respiratory displacement within the 40%–60% gating phase interval. For the longer phase interval, corresponding differences are 4 ± 7 % and 8 ± 15 % with and without audio-visual biofeedback, respectively. Alternatively, when the simulation gate threshold is determined based on the maximum average respiratory displacement within the gating phase interval, greater differences between simulation and delivery gate thresholds are observed. A relationship between retrospective simulation gate threshold and prospective delivery gate threshold for respiratory gating is established and validated for regular and nonregular respiratory motion. Using this relationship, the delivery gate threshold can be reliably estimated at the time of 4D CT simulation, thereby improving the accuracy and efficiency of respiratory-gated radiation delivery.

Published

2007

29. Assessment of Gross Tumor Volume Regression and Motion Changes During Radiotherapy for Non–Small-Cell Lung Cancer as Measured by Four-Dimensional Computed Tomography

Author

Susan L. Tucker, Ritsuko Komaki, Joe Y. Chang, Radhe Mohan, Tinsu Pan, Christopher Lee Nelson, James D. Cox, George Starkschall, and K. Britton

Subjects

Male, Cancer Research, medicine.medical_specialty, Lung Neoplasms, Movement, medicine.medical_treatment, Carcinoma, Non-Small-Cell Lung, medicine, Humans, Radiology, Nuclear Medicine and imaging, Prospective Studies, Lung cancer, Tumor motion, Aged, Aged, 80 and over, Radiation, Four-Dimensional Computed Tomography, business.industry, Middle Aged, medicine.disease, Regression, Data set, Radiation therapy, Oncology, Female, Tomography, Non small cell, Radiology, Radiotherapy, Conformal, Tomography, X-Ray Computed, Nuclear medicine, business

Abstract

To investigate the magnitudes of the changes in mobility and volume of locally advanced non-small-cell lung cancer (NSCLC) tumors during radiotherapy, using four-dimensional computed tomography (4DCT).Five to ten 4DCT data sets were acquired weekly for each of 8 patients throughout treatment. Gross tumor volumes (GTVs) were outlined on each data set. Volumes and coordinates of the GTV centroids were calculated at the 0 (end-inspiration) and 50% (end-expiration) respiration phases. Trends in magnitudes of intrafraction and interfraction positional variations were assessed for the GTV and internal target volume (ITV) during treatment.Tumor volume reduction ranged from 20% to 71% (end-inspiration) and from 15% to 70% (end-expiration). Increased tumor mobility was observed in the superior-inferior and anterior-posterior directions. However, no trends in tumor motion were observed. Motion along the superior-inferior direction was significantly greater (p0.001), with mean +/- SD values of 0.86 +/- 0.19 cm, as compared with 0.39 +/- 0.08 cm and 0.19 +/- 0.05 cm in the anterior-posterior and right-left directions, respectively. A marginally significant (p = 0.049) increase in total GTV positional variation was observed with increasing treatment weeks, and similar results were seen for the interfractional ITV mobility.Because of changes in tumor size and mobility, an explicit initial determination of the ITV may not be sufficient, especially where small setup margins are used. Repeat 4DCT scans might be warranted for highly mobile tumors to reduce the potential for missing the tumor.

Published

2007

30. Quantitative assessment of four-dimensional computed tomography image acquisition quality

Author

Karl Prado, George Starkschall, Neil Desai, Peter A Balter, Tinsu Pan, Dianna D. Cody, and Dershan Luo

Subjects

medicine.medical_specialty, Quality Assurance, Health Care, Image quality, Movement, Image registration, Iterative reconstruction, Sensitivity and Specificity, Imaging phantom, Imaging, Three-Dimensional, medicine, Radiology, Nuclear Medicine and imaging, Computer vision, Multislice, Instrumentation, Mathematics, Radiation, Four-Dimensional Computed Tomography, Phantoms, Imaging, business.industry, Reproducibility of Results, Radiographic Image Enhancement, Subtraction Technique, Rotational angiography, Radiographic Image Interpretation, Computer-Assisted, Radiology, Artificial intelligence, Tomography, Artifacts, Tomography, X-Ray Computed, business

Abstract

The purpose of the present work was to describe the development and validation of a series of tests to assess the quality of four-dimensional (4D) computed-tomography (CT) imaging as it is applied to radiation treatment planning. Using a commercial respiratory motion phantom and a programmable moving platform with a CT phantom, we acquired 4D CT datasets on two commercial multislice helical CT scanners that use different approaches to 4D CT image reconstruction. Datasets were obtained as the platform moved in various patterns designed to simulate breathing. Known inserts in the phantom were contoured, and statistics were generated to evaluate properties important to radiation therapy--namely, accuracy of phase-binning, shape, volume, and CT number. Phase-binning accuracy varied by as much as 5% for a 4D procedure in which images were reconstructed and then binned, but exhibited no variation for a 4D procedure in which projections were binned before reconstruction. The magnitude of geometric distortion was found to be small for both approaches, as was the magnitude of volume error. Partial-volume effects in the direction perpendicular to the transverse planes of reconstruction affected volume accuracy, however. Computed tomography numbers were reproduced accurately, but 4D images exhibited more variation in CT number than static CT images did. Characterization of such properties can be used to better understand and optimize the various parameters that affect 4D CT image quality.

Published

2007

31. Evaluation of the accuracy of fetal dose estimates using TG-36 data

Author

George Starkschall, Mohammad Salehpour, John A. Antolak, and Stephen F Kry

Subjects

Treatment field, Fetus, Task group, business.industry, medicine.medical_treatment, General Medicine, Radiation therapy, Relative biological effectiveness, Medicine, Fetal dose, Dosimetry, Radiation protection, business, Nuclear medicine

Abstract

The American Association of Physicists in Medicine Radiation Therapy Committee Task Group 36 report (TG-36) provides guidelines for managing radiation therapy of pregnant patients. Included in the report are data that can be used to estimate the dose to the fetus. The purpose of this study is to evaluate the accuracy of these fetal dose estimates as compared to clinically measured values. TG-36 calculations were performed and compared with measurements of the fetal dose made in vivo or in appropriately-designed phantoms. Calculation and measurement data was collected for eight pregnant patients who underwent radiation therapy at the MD Anderson Cancer Center as well as for several fetal dose studies in the literature. The maximum measured unshielded fetal dose was 47 cGy, which was 1.5% of the prescription dose. For all cases, TG-36 calculations and measured fetal doses differed by up to a factor of 3--the ratio of the calculated to measured dose ranged from 0.34 to 2.93. On average, TG-36 calculations underestimated the measured dose by 31%. No significant trends in the relationship between the calculated and measured fetal doses were found based on the distance from, or the size of, the treatment field.

Published

2007

32. Determination of output factors for small proton therapy fields

Author

Uwe Titt, Wayne D. Newhauser, Jonas D. Fontenot, Charles Bloch, R. Allen White, and George Starkschall

Subjects

Physics, Monitor unit, Dosimeter, business.industry, Monte Carlo method, General Medicine, Imaging phantom, Optics, Calibration, Range (statistics), Dosimetry, Nuclear medicine, business, Proton therapy

Abstract

Current protocols for the measurement of proton dose focus on measurements under reference conditions; methods for measuring dose under patient-specific conditions have not been standardized. In particular, it is unclear whether dose in patient-specific fields can be determined more reliably with or without the presence of the patient-specific range compensator. The aim of this study was to quantitatively assess the reliability of two methods for measuring dose per monitor unit (DIMU) values for small-field treatment portals: one with the range compensator and one without the range compensator. A Monte Carlo model of the Proton Therapy Center-Houston double-scattering nozzle was created, and estimates of D/MU values were obtained from 14 simulated treatments of a simple geometric patient model. Field-specific D/MU calibration measurements were simulated with a dosimeter in a water phantom with and without the range compensator. D/MU values from the simulated calibration measurements were compared with D/MU values from the corresponding treatment simulation in the patient model. To evaluate the reliability of the calibration measurements, six metrics and four figures of merit were defined to characterize accuracy, uncertainty, the standard deviations of accuracy and uncertainty, worst agreement, and maximum uncertainty. Measuring D/MU without the range compensator provided superior results for five of the six metrics and for all four figures of merit. The two techniques yielded different results primarily because of high-dose gradient regions introduced into the water phantom when the range compensator was present. Estimated uncertainties (approximately 1 mm) in the position of the dosimeter in these regions resulted in large uncertainties and high variability in D/MU values. When the range compensator was absent, these gradients were minimized and D/MU values were less sensitive to dosimeter positioning errors. We conclude that measuring D/MU without the range compensator present provides more reliable results than measuring it with the range compensator in place.

Published

2007

33. Semi-automated CT segmentation using optic flow and Fourier interpolation techniques

Author

Thomas Guerrero, Kan-Ping Lin, Tzung Chi Huang, Geoffrey Zhang, George Starkschall, and K. Forster

Subjects

Fourier Analysis, genetic structures, Pixel, business.industry, Computer science, Optical flow, Image registration, Health Informatics, Curvature, Models, Biological, Computer Science Applications, symbols.namesake, Fourier analysis, Image Interpretation, Computer-Assisted, symbols, Humans, Segmentation, Computer vision, Artificial intelligence, Tomography, Tomography, X-Ray Computed, business, Algorithms, Software, Interpolation

Abstract

In radiotherapy treatment planning, tumor volumes and anatomical structures are manually contoured for dose calculation, which takes time for clinicians. This study examines the use of semi-automated segmentation of CT images. A few high curvature points are manually drawn on a CT slice. Then Fourier interpolation is used to complete the contour. Consequently, optical flow, a deformable image registration method, is used to map the original contour to other slices. This technique has been applied successfully to contour anatomical structures and tumors. The maximum difference between the mapped contours and manually drawn contours was 6 pixels, which is similar in magnitude to difference one would see in manually drawn contours by different clinicians. The technique fails when the region to contour is topologically different between two slices. A solution is recommended to manually delineate contours on a sparse subset of slices and then map in both directions to fill the remaining slices.

Published

2006

34. Application of the electron pencil beam redefinition algorithm to electron arc therapy

Author

Robert A. Boyd, Kenneth R. Hogstrom, Susan L. Tucker, George Starkschall, John A. Antolak, and Pai Chun M. Chi

Subjects

Physics, business.industry, Quantitative Biology::Tissues and Organs, Physics::Medical Physics, Collimator, General Medicine, Imaging phantom, Collimated light, Percentage depth dose curve, law.invention, Arc (geometry), Optics, law, Calibration, Dosimetry, business, Algorithm, Beam (structure)

Abstract

This project investigated the potential of summing fixed-beam dose distributions calculated using the pencil-beam redefinition algorithm (PBRA) at small angular steps ( 1 ° ) to model an electron arc therapy beam. The PRBA, previously modified to model skincollimation, was modified further by incorporating two correction factors. One correction factor that is energy, SSD (source-to-surface distance), and field-width dependent constrained the calculated dose output to be the same as the measureddose output for fixed-beam geometries within the range of field widths and SSDs encountered in arc therapy. Another correction factor (single field-width correction factor for each energy) compensated for large-angle scattering not being modeled, allowing a more accurate calculation of dose output at mid arc. The PBRA was commissioned to accurately calculate dose in a water phantom for fixed-beam geometries typical of electron arc therapy. Calculated central-axis depth doses agreed with measureddoses to within 2% in the low-dose gradient regions and within 1- mm in the high-dose gradient regions. Off-axis doses agreed to within 2 mm in the high-dose gradient regions and within 3% in the low-dose gradient regions. Arced-beam calculations of dose output and depth dose at mid arc were evaluated by comparing to data measured using two cylindrical water phantoms with radii of 12 and 15 cm at 10 and 15 MeV . Dose output was measured for all combinations of phantom radii of curvature, collimator widths (4, 5, and 6 cm ), and arc angles ( 0 ° , 20 ° , 40 ° , 60 ° , 80 ° , and 90 ° ) for both beam energies. Results showed the calculated mid-arc dose output to agree within 2% of measurement for all combinations. For a 90 ° arc angle and 5 × 20 cm 2 field size, the calculated mid-arc depth dose in the low-dose gradient region agreed to within 2% of measurement for all depths at 10 MeV and for depths greater than depth of dose maximum R 100 at 15 MeV . For depths in the buildup region at 15 MeV the calculations overestimated the measureddose by as much as 3.4%. Mid-arc depth dose in the high-dose gradient region agreed to within 2.2 mm of measureddose. Calculated two-dimensional relative dose distributions in the plane of rotation were compared to dosemeasurements using film in a cylindrical polystyrene phantom for a 90 ° arc angle and field widths of 4, 5, and 6 cm at 10 and 15 MeV . Results showed that off-axis dose at the ends of arc (without skincollimation) agreed to within 2% in the low-dose gradient region and to within 1.2 mm in the high-dose gradient region. This work showed that the accuracy of the PBRA arced-beam dose model met the criteria specified by Van Dyk et al. [Int. J. Radiat. Oncol. Biol. Phys.26, 261–273 (1993)] with the exception of the buildup region of the 15 MeV beam. Based on the present results, results of a previous study showing acceptable accuracy in the presence of skincollimation, and results of a previous study showing acceptable accuracy in the presence of internal heterogeneities, it is concluded that the PBRA arced-beam dose model should be adequate for planning electron arc therapy.

Published

2006

35. Displacement-based binning of time-dependent computed tomography image data sets

Author

Paul J. Keall, Himanshu P. Shukla, Radhe Mohan, Paul Klahr, George Starkschall, Mathew J. Fitzpatrick, John A. Antolak, and Jun Fu

Subjects

business.industry, Image registration, Image processing, General Medicine, Iterative reconstruction, Data set, Medical imaging, Medicine, Computer vision, Multislice, Artificial intelligence, Computed radiography, business, Fiducial marker, Nuclear medicine

Abstract

Respiration can cause tumors in the thorax or abdomen to move by as much as 3 cm; this movement can adversely affect the planning and delivery of radiation treatment. Several techniques have been used to compensate for respiratory motion, but all have shortcomings. Manufacturers of computed tomography (CT) equipment have recently used a technique developed for cardiac CT imaging to track respiratory-induced anatomical motion and to sort images according to the phase of the respiratory cycle they represent. Here we propose a method of generating CT images that accounts for respiratory-induced anatomical motion on the basis of displacement, i.e., displacement-binned CT image sets. This technique has shown great promise, however, it is not fully supported by currently used CT image reconstruction software. As an interim solution, we have developed a method for extracting displacement-binned CT image data sets from data sets assembled on the basis of a prospectively determined breathing phase acquired on a multislice helical CT scanner. First, the projection data set acquired from the CT scanner was binned at small phase intervals before reconstruction. The manufacturer's software then generated image sets identified as belonging to particular phases of the respiratory cycle. All images were then individually correlated tomore » the displacement of an external fiducial marker. Next, CT image data sets were resorted on the basis of the displacement and assigned an appropriate phase. Finally, displacement-binned image data sets were transferred to a treatment-planning system for analysis. Although the technique is currently limited by the phase intervals allowed by the CT software, some improvement in image reconstruction was seen, indicating that this technique is useful at least as an interim measure.« less

Published

2005

36. Modeling skin collimation using the electron pencil beam redefinition algorithm

Author

Kenneth R. Hogstrom, Robert A. Boyd, Pai Chun M. Chi, John A. Antolak, and George Starkschall

Subjects

Physics, business.industry, Isocenter, Collimator, General Medicine, Radiation, Collimated light, Imaging phantom, law.invention, Optics, law, Electron Beam Therapy, Dosimetry, business, Algorithm, Beam (structure)

Abstract

Skin collimation is an important tool for electron beam therapy that is used to minimize the penumbra when treating near critical structures, at extended treatment distances, with bolus, or using arc therapy. It is usually made of lead or lead alloy material that conforms to and is placed on patient surface. Presently, commercially available treatment-planning systems lack the ability to model skin collimation and to accurately calculate dose in its presence. The purpose of the present work was to evaluate the use of the pencil beam redefinition algorithm (PBRA) in calculating dose in the presence of skin collimation. Skin collimation was incorporated into the PBRA by terminating the transport of electrons once they enter the skin collimator. Both fixed- and arced-beam dose calculations for arced-beam geometries were evaluated by comparing them with measured dose distributions for 10- and 15-MeV beams. Fixed-beam dose distributions were measured in water at 88-cm source-to-surface distance with an air gap of 32 cm. The 6 x 20-cm2 field (dimensions projected to isocenter) had a 10-mm thick lead collimator placed on the surface of the water with its edge 5 cm inside the field's edge located at +10 cm. Arced-beam dose distributions were measured in a 13.5-cm radius polystyrene circular phantom. The beam was arced 90 degrees (-45 degrees to +45 degrees), and 10-mm thick lead collimation was placed at +/- 30 degrees. For the fixed beam at 10 MeV, the PBRA- calculated dose agreed with measured dose to within 2.0-mm distance to agreement (DTA) in the regions of high-dose gradient and 2.0% in regions of low dose gradient. At 15 MeV, the PBRA agreed to within a 2.0-mm DTA in the regions of high-dose gradient; however, the PBRA underestimated the dose by as much as 5.3% over small regions at depths less than 2 cm because it did not model electrons scattered from the edge of the skin collimation. For arced beams at 10 MeV, the agreement was 1-mm DTA in the high-dose gradient regions, and 2% in the low-dose gradient regions. For arced beams at 15 MeV, the agreement was 1 mm in the high-dose gradient regions, and in the low-dose gradient region at depth less than 2 cm, as much as 5% dose difference was observed. This study demonstrated the ease with which skin collimation can be incorporated into the PBRA. The good agreement of PBRA calculated with measured dose shows that the PBRA is likely sufficiently accurate for clinical use in the presence of skin collimation for electron arc therapy. To further improve the accuracy of the PBRA in regions having significant electrons scattered from the edge of the skin collimation would require transporting the electrons through the lead skin collimation near its edges.

Published

2005

37. Semiautomated four-dimensional computed tomography segmentation using deformable models

Author

George Starkschall, Craig W. Stevens, Michael Kaus, Thomas Guerrero, Todd McNutt, and Dustin K. Ragan

Subjects

Thorax, Four-Dimensional Computed Tomography, medicine.diagnostic_test, Computer science, business.industry, Computed tomography, Image processing, General Medicine, Image segmentation, Data set, medicine.anatomical_structure, Atlas (anatomy), medicine, Medical imaging, Segmentation, Computer vision, Artificial intelligence, Computed radiography, Nuclear medicine, business

Abstract

The purpose of this work is to demonstrate a proof of feasibility of the application of a commercial prototype deformable model algorithm to the problem of delineation of anatomic structures on four-dimensional (4D) computed tomography (CT) image data sets. We acquired a 4D CT image data set of a patient's thorax that consisted of three-dimensional (3D) image data sets from eight phases in the respiratory cycle. The contours of the right and left lungs, cord, heart, and esophagus were manually delineated on the end inspiration data set. An interactive deformable model algorithm, originally intended for deforming an atlas-based model surface to a 3D CT image data set, was applied in an automated fashion. Triangulations based on the contours generated on each phase were deformed to the CT data set on the succeeding phase to generate the contours on that phase. Deformation was propagated through the eight phases, and the contours obtained on the end inspiration data set were compared with the original manually delineated contours. Structures defined by high-density gradients, such as lungs, cord, and heart, were accurately reproduced, except in regions where other gradient boundaries may have confused the algorithm, such as near bronchi. The algorithm failed to accurately contour the esophagus, a soft-tissue structure completely surrounded by tissue of similar density, without manual interaction. This technique has the potential to facilitate contour delineation in 4D CT image data sets; and future evolution of the software is expected to improve the process.

Published

2005

38. Respiration-correlated treatment delivery using feedback-guided breath hold: A technical study

Author

Karl Prado, George Starkschall, Mathew J. Fitzpatrick, John A. Antolak, Naresh Tolani, Peter A Balter, and Christopher Lee Nelson

Subjects

medicine.medical_specialty, business.industry, Respiratory motion, Detector, Tracking system, General Medicine, Gating, Treatment delivery, Breathing, Medicine, Computer vision, Medical physics, Artificial intelligence, business, Fiducial marker, Quality assurance

Abstract

Respiratory motion causes movement of internal structures in the thorax and abdomen, making accurate delivery of radiation therapy to tumors in those areas a challenge. To reduce the uncertainties caused by this motion, we have developed feedback-guided breath hold (FGBH), a novel delivery technique in which radiation is delivered only during a voluntary breath hold that is sustained for as long as the patient feels comfortable. Here we present the technical aspects of FGBH, which involve (1) fabricating the hardware so the respiratory trace can be displayed to the patient, (2) assembling a delay box to be used as a breath-hold detector, and (3) performing quality control tests to ensure that FGBH can be delivered accurately and safely. A commercial respiratory tracking system that uses an external fiducial to monitor abdominal wall motion generates and displays the breathing trace and specific positions in the breathing cycle where a breath hold needs to occur. Hardware was developed to present this display to the patient in the treatment position. Patients view the presentation either on a liquid crystal display or through a pair of virtual reality goggles. Using the respiratory trace as a visual aid, the patient performs a breath hold so that the position representing the location of a fiducial is held within a specified gating window. A delay box was fabricated to differentiate between gating signals received during free breathing and those received during breath hold, allowing radiation delivery only when the fiducial was within the breath-hold gating window. A quality control analysis of the gating delay box and the integrated system was performed to ensure that all of the hardware and components were ready for clinical use.

Published

2004

39. Evaluation of internal lung motion for respiratory-gated radiotherapy using MRI: Part I—correlating internal lung motion with skin fiducial motion

Author

Craig W. Stevens, Ritsuko Komaki, Marc G. Jacobson, George Starkschall, H. Helen Liu, N Koch, Zhongxing Liao, and Kenneth M. Forster

Subjects

Adult, Male, Cancer Research, medicine.medical_specialty, Lung Neoplasms, Movement, Match moving, medicine, Humans, Radiology, Nuclear Medicine and imaging, Lung volumes, Lung cancer, Lung, Skin, Radiation, medicine.diagnostic_test, business.industry, Respiration, Magnetic resonance imaging, Middle Aged, medicine.disease, Magnetic Resonance Imaging, Sagittal plane, medicine.anatomical_structure, Oncology, Breathing, Female, Radiology, Nuclear medicine, business, Fiducial marker

Abstract

Purpose To measure the internal lung motion due to respiration using magnetic resonance images (MRIs); to evaluate the correlation between lung motion and skin surface motion and the reliability of tracking lung motion with external fiducials. Methods and materials An MRI protocol using fast gradient-echo sequences was developed to acquire dynamic cine images of the thoracoabdominal region along the axial, sagittal, and coronal planes. The subjects (3 healthy volunteers and 4 lung cancer patients) were instructed to perform normal or altered breathing during MRI. Lung vessels identified on MRI were used as anatomic landmarks for internal lung structures. From sagittal cine MRI scans, the positions of the lung vessels and skin surface were tracked and their movements measured. Correlation between the movements of the external markers and internal structures was then calculated and analyzed. Results Lung vessel motion in the superior–inferior (SI) direction correlated best with mid-upper abdominal skin surface movement (correlation coefficient, 0.89 ± 0.09 and 0.87 ± 0.23 for volunteers and patients, respectively). The anterior-posterior (AP) vessel motion generally correlated poorly with the skin surface movement, with marker placement on the upper chest yielding the strongest results (correlation coefficient, 0.72 ± 0.23 and 0.44 ± 0.27 for volunteers and patients, respectively). The strength of the correlation depended on the locations of the tracked vessels, locations of the skin surface, and subjects' breathing patterns. The best correlation was seen between the motion of an abdominal fiducial and SI lung motion. Significant intersubject variability was also observed. Conclusion Movement of an external fiducial may not correlate fully with, or predict, internal lung motion. Effective monitoring of respiration may have to rely on a combination of multiple fiducials and other physiologic parameters, such as lung volume and/or air flow.

Published

2004

40. Correlation of gross tumor volume excursion with potential benefits of respiratory gating

Author

Alex Cardenas, Kei Kitamura, Kenneth M. Forster, Susan L. Tucker, Craig W. Stevens, and George Starkschall

Subjects

Cancer Research, medicine.medical_specialty, Lung Neoplasms, Movement, Radiography, Gating, Correlation, medicine, Humans, Radiology, Nuclear Medicine and imaging, Radiation oncologist, Tidal volume, Radiation, Lung, business.industry, Patient Selection, Radiotherapy Planning, Computer-Assisted, Respiration, Excursion, Tumor Burden, Data set, medicine.anatomical_structure, Oncology, Practice Guidelines as Topic, Radiology, business, Nuclear medicine

Abstract

Purpose To test the hypothesis that the magnitude of thoracic tumor motion can be used to determine the desirability of respiratory gating. Methods and materials Twenty patients to be treated for lung tumors had computed tomography image data sets acquired under assisted breath hold at normal inspiration (100% tidal volume), at full expiration (0% tidal volume), and under free breathing. A radiation oncologist outlined gross tumor volumes (GTVs) on the breath-hold computed tomographic images. These data sets were registered to the free-breathing image data set. Two sets of treatment plans were generated: one based on an internal target volume explicitly formed from assessment of the excursion of the clinical target volume (CTV) through the respiratory cycle, representing an ungated treatment, and the other based on the 0% tidal volume CTV, representing a gated treatment with little margin for residual motion. Dose-volume statistics were correlated to the magnitude of the motion of the center of the GTV during respiration. Results Patients whose GTVs were >100 cm 3 showed little decrease in lung dose under gating. The other patients showed a correlation between the excursion of the center of the GTV and a reduction in potential lung toxicity. As residual motion increased, the benefits of respiratory gating increased. Conclusion Gating seems to be advantageous for patients whose GTVs are 3 and for whom the center of the GTV exhibits significant motion, provided residual motion under gating is kept small.

Published

2004

41. Dosimetric uncertainties of three‐dimensional dose reconstruction from two‐dimensional data in a multi‐institutional study

Author

Hak Choy, Robert MacRae, George Starkschall, Rebecca Weinberg, Chandra P. Belani, Susan L. Tucker, Walter J. Curran, Darryl G.L. Kaurin, Jae Sung Kim, Philip Bonomi, and Jae Chul Kim

Subjects

medicine.medical_specialty, Lung Neoplasms, conformal radiation therapy, Image quality, medicine.medical_treatment, Planning target volume, Radiation Dosage, Sensitivity and Specificity, Digital image, Imaging, Three-Dimensional, medicine, Relative biological effectiveness, Radiation Oncology Physics, Humans, Radiology, Nuclear Medicine and imaging, Medical physics, multi‐institutional trials, Radiation treatment planning, Radiometry, Instrumentation, Protocol (science), Contouring, Radiation, business.industry, Radiotherapy Planning, Computer-Assisted, Reproducibility of Results, Radiotherapy Dosage, three‐dimensional (3D) reconstruction image processing, United States, Radiation therapy, three‐dimensional (3D) plans, thoracic treatment planning, Body Burden, Radiographic Image Interpretation, Computer-Assisted, business, Nuclear medicine, Relative Biological Effectiveness

Abstract

Inconsistencies in the treatment planning process leading to dosimetric uncertainties may affect conclusions drawn from interinstitutional radiation oncology clinical trials. The purpose of this study was to assess the dosimetric uncertainties resulting from the process of reconstructing three‐dimensional dose distributions from two‐dimensional treatment plan information provided by participating institutions in a randomized clinical trial. This study was based on American College of Radiology Protocol #427, Locally Advanced Multi‐Modality Protocol; a multi‐institutional phase II randomized study involving radiation therapy for patients with inoperable non‐small cell lung cancer. Several sources of dosimetric uncertainty were identified and analyzed, including image quality of hard‐copy computed tomography (CT) images, slice spacing of CT scans, treatment position, interpretations of target volumes by radiation oncologists, the contouring of normal anatomic structures, and the use of common beam models for all dose calculations. Each source of uncertainty was investigated using a set of plans, with the ideal characteristics of digital images with 3‐mm axial slice spacing and a flat couch, consisting of eight cases from Vanderbilt University Medical Center with electronically transferred CT data. The target volume DVH values were dependent on the additional uncertainty introduced by differences in delineation of the target volumes by the participating radiation oncologists. The DVH values for the lungs and heart were dependent on image quality and treatment position. Esophagus DVH values were not dependent on any of the sources of uncertainty. None of the structure DVH values were dependent on slice thickness or variations in the contouring of normal anatomic structures. Reconstruction of three‐dimensional dose distributions from two‐dimensional treatment plan information may be useful in cases for which digital CT data is not available or for historical data review. However, dosimetric accuracy will depend on image quality of the treatment planning CT data and consistency in the delineation of tumor volumes. PACS number: 87.53.‐j

Published

2004

42. Quality assurance evaluation of delivery of respiratory‐gated treatments

Author

Alex Cardenas, Craig W. Stevens, George Starkschall, Kenneth M. Forster, and Jonas D. Fontenot

Subjects

Lung Neoplasms, Quality Assurance, Health Care, Computer science, Respiratory gating, Gating, quality assurance, Sensitivity and Specificity, Motion, Image Interpretation, Computer-Assisted, Radiation Oncology Physics, Humans, Radiology, Nuclear Medicine and imaging, Respiratory cycle, Hardware_ARITHMETICANDLOGICSTRUCTURES, Instrumentation, Radiation, business.industry, Radiotherapy Planning, Computer-Assisted, Reproducibility of Results, United States, respiratory gating, Treatment delivery, Duty cycle, Respiratory Mechanics, business, Fiducial marker, Artifacts, Quality assurance, Biomedical engineering

Abstract

We describe a method for evaluating the quality of respiratory‐gated radiation delivery using a commercially available device. During irradiation, gating traces for one field for each treatment were extracted from the system for each of 14 patients. The data were then transferred to a spreadsheet. Software was developed to evaluate the following parameters: duty cycle, amplitude of fiducial motion, fraction of amplitude of motion during gated delivery, and respiratory cycle time. Criteria were established for acceptability of gating traces. In our sample, over 85% of the traces indicated acceptability. An example of results for one patient extracted from analyzed gating traces is as follows: mean duty cycle, 57%; average amplitude of motion, 0.89 cm; average fraction of motion during gated delivery, 0.45; mean respiratory cycle time, 4.5 s. This technique can be used to evaluate delivery of respiratory‐gated radiation therapy for quality assurance purposes and to assess various techniques for improving delivery of gated therapy. A hard copy of the gating traces can be used to document gated treatment delivery for potential billing of the gated delivery process. PACS numbers: 87.53‐j, 87.53.Tf

Published

2004

43. Dosimetric uncertainties of three-dimensional dose reconstruction from two-dimensional data in a multi-institutional study

Author

Rebecca Weinberg, Darryl G.L. Kaurin, Hak Choy, Walter J. Curran, Robert MacRae, Jae Sung Kim, Jaechul Kim, Susan L. Tucker, Philip D. Bonomi, Chandra Belani, and George Starkschall

Subjects

Radiation, Radiology, Nuclear Medicine and imaging, Instrumentation

Published

2004

44. A deformable-model approach to semi-automatic segmentation of CT images demonstrated by application to the spinal canal

Author

George Starkschall, Craig W. Stevens, Stuart S. C. Burnett, and Zhongxing Liao

Subjects

Computer science, Edge detection, Wavelet, Neoplasms, Image Processing, Computer-Assisted, medicine, Medical imaging, Humans, Segmentation, Spinal canal, Computer vision, Computed radiography, Radiometry, Radiation treatment planning, Models, Statistical, Fourier Analysis, business.industry, Wavelet transform, General Medicine, Image segmentation, Models, Theoretical, Spine, medicine.anatomical_structure, Artificial intelligence, Tomography, X-Ray Computed, business, Spinal Canal, Algorithms

Abstract

Because of the importance of accurately defining the target in radiation treatment planning, we have developed a deformable-template algorithm for the semi-automatic delineation of normal tissue structures on computed tomography (CT) images. We illustrate the method by applying it to the spinal canal. Segmentation is performed in three steps: (a) partial delineation of the anatomic structure is obtained by wavelet-based edge detection; (b) a deformable-model template is fitted to the edge set by chamfer matching; and (c) the template is relaxed away from its original shape into its final position. Appropriately chosen ranges for the model parameters limit the deformations of the template, accounting for interpatient variability. Our approach differs from those used in other deformable models in that it does not inherently require the modeling of forces. Instead, the spinal canal was modeled using Fourier descriptors derived from four sets of manually drawn contours. Segmentation was carried out, without manual intervention, on five CT data sets and the algorithm's performance was judged subjectively by two radiation oncologists. Two assessments were considered: in the first, segmentation on a random selection of 100 axial CT images was compared with the corresponding contours drawn manually by one of six dosimetrists, also chosen randomly; in the second assessment, the segmentation of each image in the five evaluable CT sets (a total of 557 axial images) was rated as either successful, unsuccessful, or requiring further editing. Contours generated by the algorithm were more likely than manually drawn contours to be considered acceptable by the oncologists. The mean proportions of acceptable contours were 93% (automatic) and 69% (manual). Automatic delineation of the spinal canal was deemed to be successful on 91% of the images, unsuccessful on 2% of the images, and requiring further editing on 7% of the images. Our deformable template algorithm thus gives a robust segmentation of the spinal canal on CT images. The method can be extended to other structures, although it remains to be shown that chamfer matching is sufficiently robust for the delineation of soft-tissue structures surrounded by soft tissue.

Published

2004

45. Dosimetric benefits of respiratory gating: a preliminary study

Author

Zhongxing Liao, George Starkschall, H. Helen Liu, Craig W. Stevens, Susan L. Tucker, Ritsuko Komaki, Laura E. Butler, Charles Bloch, and Kenneth M. Forster

Subjects

treatment planning, Lung Neoplasms, Movement, Respiratory gating, Pilot Projects, Gating, Sensitivity and Specificity, Radiation Protection, Treatment plan, Radiation Oncology Physics, Humans, Medicine, Radiology, Nuclear Medicine and imaging, Radiometry, Radiation treatment planning, Instrumentation, Tidal volume, Radiation, business.industry, Radiotherapy Planning, Computer-Assisted, Reproducibility of Results, Radiotherapy Dosage, Radiographic Image Enhancement, respiratory gating, Normal lung, During expiration, Respiratory Mechanics, Body Burden, Feasibility Studies, Disease characteristics, Artifacts, Nuclear medicine, business, Relative Biological Effectiveness

Abstract

In this study, we compared the amount of lung tissue irradiated when respiratory gating was imposed during expiration with the amount of lung tissue irradiated when gating was imposed during inspiration. Our hypothesis was that the amount of lung tissue spared increased as inspiration increased. Computed tomography (CT) image data sets were acquired for 10 patients who had been diagnosed with primary bronchogenic carcinoma. Data sets were acquired during free breathing and during breath-holds at 0% tidal volume and 100% tidal volume, and, when possible, at deep inspiration, corresponding to approximately 60% vital capacity. Two treatment plans were developed on the basis of each of the gated data sets: one in which the treatment portals were those of the free-breathing plan, and the other in which the treatment portals were based on the gated planning target volumes. Dose-mass histograms of the lungs calculated at 0% tidal volume were compared to those calculated at deep inspiration and at 100% tidal volume. Data extracted from the dose-mass histograms were used to determine the most dosimetrically beneficial point to gate, the reduction in the amount of irradiated lung tissue that resulted from gating, and any disease characteristics that might predict a greater need for gating. The data showed a reduction in the mass of normal tissue irradiated when treatment portals based on the gated planning target volume were used. More normal lung tissue was spared at deep inspiration than at the other two gating points for all patients, but normal lung tissue was spared at every point in the respiratory cycle. No significant differences in the amount of irradiated tissue by disease characteristic were identified. Respiratory gating of thoracic radiation treatments can often improve the quality of the treatment plan, but it may not be possible to determine which patients may benefit from gating prior to performing the actual treatment planning.

Published

2004

46. Hazards of dose escalation in prostate cancer radiotherapy

Author

Isaac I. Rosen, Eugene Huang, George Starkschall, Lei Dong, Larry B. Levy, Alan Pollack, and Deborah A. Kuban

Subjects

Male, Cancer Research, medicine.medical_specialty, Multivariate analysis, medicine.medical_treatment, Urology, Adenocarcinoma, Prostate cancer, Prostate, medicine, Humans, Radiology, Nuclear Medicine and imaging, Stage (cooking), Neoplasm Staging, Radiation, business.industry, Hazard ratio, Prostatic Neoplasms, Dose-Response Relationship, Radiation, Radiotherapy Dosage, Prostate-Specific Antigen, medicine.disease, Surgery, Radiation therapy, medicine.anatomical_structure, Oncology, Multivariate Analysis, Hormonal therapy, Radiotherapy, Conformal, business, Follow-Up Studies

Abstract

To assess the benefit of escalating the dose in definitive prostate cancer radiotherapy vs. the associated risk of complications.Between 1987 and 1999, 1087 patients with clinical Stage T1b-T3 adenocarcinoma of the prostate were definitively irradiated without hormonal therapy and had a pretreatment serum prostate-specific antigen (PSA) and Gleason score recorded. The median follow-up was 65 months. Doses ranged from 64 to 78 Gy, with the treatment techniques corresponding to the year of therapy and the prescribed dose. A total of 301 patients were treated on a randomized protocol to either 70 or 78 Gy. Also, 163 patients were treated with three-dimensional conformal therapy and had dose-volume histograms available for review.Tumor stage, grade, pretreatment PSA level, and radiation dose were all independent predictors of PSA disease-free survival (PSA-DFS) in multivariate analysis. The hazard rate for biochemical failure peaked at 1.5-3 years after radiotherapy. Although a statistically significant dose effect on PSA-DFS was found in the pretreatment PSA levels of those with bothor =10 ng/mL and10 ng/mL, in those with a pretreatment PSAor =10 ng/mL, the improvement in outcome was only seen going from a dose level of 64-66 Gy to 68-70 Gy with a 5-year PSA-DFS rate of 66% vs. 81% (p0.0001). This was also confirmed by the data from the randomized patients who showed no difference in outcome whether treated to 70 Gy or 78 Gy. In patients with a pretreatment PSA level10 ng/mL, a statistically significant improvement was found in disease-free outcome among the 64-66-Gy, 68-70-Gy, and 78-Gy levels. PSA-DFS was approximately 50% better at each higher dose level at 5 and 8 years after treatment. The dose had a statistically significant impact in both intermediate- and high-risk groups. Rectal morbidity was both dose and volume related. Although at 5 years after therapy, the Grade 2-3 rectal complication rate was twice as high for patients treated to 78 Gy than to 70 Gy, 26% vs. 12%, this risk could be markedly diminished by adhering to dose-volume constraints.In intermediate- and high-risk prostate cancer patients, although it appears that radiation-dose escalation may improve PSA-DF outcome, the price paid in treatment morbidity can be high without adequate attention to dose-volume constraints of normal tissue. Care must be taken to consider not only the hazard of tumor recurrence but also that of complications.

Published

2003

47. Intensity-modulated radiotherapy following extrapleural pneumonectomy for the treatment of malignant mesothelioma: clinical implementation

Author

Anesa Ahamad, Craig W. Stevens, Zhongxing Liao, Ritsuko Komaki, W. Roy Smythe, Jason F. Kelly, George Starkschall, Tsuyoshi Takanaka, Ara A. Vaporciyan, Kenneth M. Forster, Mohammad Salehpour, and Lei Dong

Subjects

Mesothelioma, Extrapleural Pneumonectomy, Cancer Research, medicine.medical_specialty, Pleural Neoplasms, medicine.medical_treatment, Pilot Projects, Radiation Dosage, Pneumonectomy, medicine, Humans, Radiology, Nuclear Medicine and imaging, Postoperative Period, Pleural Neoplasm, Radiation treatment planning, Radiation, Phantoms, Imaging, business.industry, Radiotherapy Planning, Computer-Assisted, Mediastinum, medicine.disease, Surgery, Diaphragm (structural system), Radiation therapy, Treatment Outcome, medicine.anatomical_structure, Oncology, Radiology, Radiotherapy, Conformal, Tomography, X-Ray Computed, business

Abstract

Purpose: New insight into the extent of the target volume for the postoperative irradiation of malignant pleural mesothelioma as determined during surgery has indicated that standard conformal radiotherapy (IMRT) is not sufficient for curative treatment. We describe a novel technique for implementing intensity-modulated radiotherapy (IMRT) to deliver higher doses to treat the full extent of these complex target volumes. Methods and Materials: After extrapleural pneumonectomy, 7 patients underwent simulation, treatment planning, and treatment with IMRT to the involved hemithorax and adjacent abdomen. The target volumes encompassed the entire operative bed, including the ipsilateral mediastinum, anterior pleural reflection, and ipsilateral pericardium and the insertion of the diaphragm and crura. These were extensively marked during surgery with radiopaque markers to facilitate target delineation. Results: Setup uncertainty and respiratory-dependent motion were found to be small. Coverage of the planning target volume was very good, with the crus of the diaphragm the most difficult volume to irradiate. The radiation doses to normal structures were acceptable. Conclusion: IMRT for treatment of malignant mesothelioma after extrapleural pneumonectomy results in more potentially curative doses to large, complex target volumes with acceptable doses to normal tissues. © 2003 Elsevier Science Inc.

Published

2003

48. Assessment of consistency in contouring of normal‐tissue anatomic structures

Author

George Starkschall, Christopher L. Brooks, Stephen D. Bilton, Stuart S. C. Burnett, Danny Tran, Mayankkumar V. Amin, Dawn C. Collier, Dominique L. Roniger, and Amanda Ryan

Subjects

Models, Anatomic, medicine.medical_specialty, Anatomical structures, Normal tissue, Computed tomography, Esophagus, Consistency (statistics), medicine, Radiation Oncology Physics, Humans, Radiology, Nuclear Medicine and imaging, Instrumentation, Observer Variation, Contouring, Radiation, medicine.diagnostic_test, business.industry, Radiotherapy Planning, Computer-Assisted, Reproducibility of Results, Heart, Radiotherapy Dosage, Surgery, Spinal Cord, contour delineation, Manual segmentation, manual segmentation, Nuclear medicine, business, Tomography, X-Ray Computed

Abstract

The purpose of this work is to estimate the uncertainty in the manual contouring of normal anatomical structures. The heart, esophagus, and spinal cord were contoured manually on six sets of computed tomography images by six dosimetrists whose experience ranged from 1 year to over 15 years. To determine the differences between inter‐ and intraobserver variations, each data set was contoured by one of the dosimetrists five times and once each by the five other dosimetrists. The magnitude of the discrepancies in delineating the contours was assessed. Intradosimetrist contouring discrepancies were as follows: esophagus, average 0.3 cm and maximum 2.9 cm; heart, average 0.5 cm and maximum 7.6 cm; and spinal cord, average 0.1 cm and maximum 0.7 cm. Interdosimetrist contouring discrepancies were as follows: esophagus, average 0.4 cm and maximum 3.1 cm; heart, average 0.7 cm and maximum 8.1 cm; and spinal cord, average 0.2 cm and maximum 0.9 cm. Significant discrepancies can occur when normal anatomic structures are contoured manually. Interdosimetrist discrepancies are typically slightly greater than intradosimetrist discrepancies. The magnitude of the discrepancies does not appear to be correlated to the experience of the dosimetrist. © 2003 American College of Medical Physics. PACS number(s): 87.53.–j, 87.66.–a

Published

2003

49. Verification of the accuracy of a photon dose-calculation algorithm

Author

David S Followill, Kent A Gifford, H. Helen Liu, and George Starkschall

Subjects

medicine.medical_specialty, Lung Neoplasms, Photon, photon‐dose calculations, quality assurance, Collimated light, Linear particle accelerator, Imaging phantom, algorithm verification, Radiotherapy, High-Energy, Optics, medicine, Humans, Scattering, Radiation, Radiation Oncology Physics, Radiology, Nuclear Medicine and imaging, Medical physics, radiation treatment planning, Instrumentation, Physics, Photons, Monitor unit, Radiation, Dosimeter, Phantoms, Imaging, business.industry, Radiotherapy Planning, Computer-Assisted, Water, Radiotherapy Dosage, Models, Theoretical, Data set, Ionization chamber, business, Algorithms

Abstract

An extensive set of measured data was developed for the purpose of verifying the accuracy of a photon dose-calculation algorithm. Dose distributions from a linear accelerator were measured using an ion chamber in a water phantom and thermoluminescent dosimeters in a heterogeneous anthropomorphic phantom. Test cases included square fields, rectangular fields, fields having different source-to-surface distances, wedged fields, irregular fields, obliquely incident fields, asymmetrically collimated fields with wedges, multileaf collimator-shaped fields, and two heterogeneous density cases. The data set was used to validate the photon dose-calculation algorithm in a commercial radiation treatment planning system. The treatment planning system calculated photon doses to within the American Association of Physicists in Medicine (AAPM) Task Group 53 (TG-53) criteria for 99 of points in the buildup region, 90 of points in the inner region, 88 of points in the outer region, and 93 of points in the penumbra. For the heterogeneous phantoms, calculations agreed with actual measurements to within 3. The monitor unit tests revealed that the 18-MV open square fields, oblique incidence, oblique incidence with wedge, and mantle field test cases did not meet the TG-53 criteria but were within 2.5 of measurements. It was concluded that (i) the photon dose calculation algorithm used by the treatment planning system did not meet the TG-53 criteria 100 of the time; (ii) some of the TG-53 criteria may need to be modified, and (iii) the generally stated goal of accuracy in dose delivery of within 5 cannot be met in all situations using this beam model in the treatment planning system. 2002 American College of Medical Physics.

Published

2002

50. Correlation between Lung Fibrosis and Radiation Therapy Dose after Concurrent Radiation Therapy and Chemotherapy for Limited Small Cell Lung Cancer

Author

George Starkschall, John A. Antolak, Teresa A. Fischer, Susan L. Tucker, Ritsuko Komaki, James D. Cox, Isaac I. Rosen, Kenneth R. Hogstrom, and Elizabeth L. Travis

Subjects

medicine.medical_specialty, Pathology, Lung Neoplasms, Pulmonary Fibrosis, medicine.medical_treatment, Small-cell carcinoma, Absorptiometry, Photon, Fibrosis, Antineoplastic Combined Chemotherapy Protocols, medicine, Humans, Radiology, Nuclear Medicine and imaging, Prospective Studies, Carcinoma, Small Cell, Radiation Injuries, Radiation treatment planning, Lung, Probability, Chemotherapy, business.industry, Dose fractionation, Radiotherapy Dosage, medicine.disease, Combined Modality Therapy, Radiation therapy, medicine.anatomical_structure, Dose Fractionation, Radiation, Radiology, Small Cell Lung Carcinoma, Tomography, X-Ray Computed, business

Abstract

To evaluate the relationship between physician-identified radiographic fibrosis, lung tissue physical density change, and radiation dose after concurrent radiation therapy and chemotherapy for limited small cell lung cancer.Fibrosis volumes of different severity levels were delineated on computed tomography (CT) images obtained at 1-year follow-up of 21 patients with complete response to concurrent radiation therapy and chemotherapy for limited small cell lung carcinoma. Delivered treatments were reconstructed with a three-dimensional treatment planning system and geometrically registered to the follow-up CT images. Tissue physical density change and radiation dose were computed for each voxel within each fibrosis volume and within normal lung. Patient responses were grouped per radiation and chemotherapy protocol.A significant correlation was noted between fibrosis grade and tissue physical density change and fibrosis grade. For doses less than 30 Gy, the probability of observing fibrosis was less than 2% with conventional fractionation and less than 4% with accelerated fractionation. Physical lung density change also showed a threshold of 30-35 Gy. For doses of 30-55 Gy and cisplatin and etoposide (PE) chemotherapy, fibrosis probability was 2.0 times greater for accelerated fractionation compared with conventional fractionation (P.005) and was correlated to increasing dose for both fractionation schedules.Lung tissue physical density changes correlated well with fibrosis incidence, and both increased with increasing dose greater than a threshold of 30-35 Gy. With concurrent PE chemotherapy, fibrosis probability was twice as great with accelerated fractionation as with once-daily fractionation.

Published

2001