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24,629 results on '"surface imaging"'

201. Detection and Classification of Concrete Patches by Integrating GPR and Surface Imaging

Author

Cheng, Peng, Krogmeier, James V., Bell, Mark R., Wang, Kelvin, Li, Joshua, Yang, Guangwei, Cheng, Peng, Krogmeier, James V., Bell, Mark R., Wang, Kelvin, Li, Joshua, and Yang, Guangwei

Abstract

This research considers the detection, location, and classification of patches in concrete and asphalt-on-concrete pavements using data taken from ground penetrating radar (GPR) and the WayLink 3D Imaging System. In particular, the project seeks to develop a patching table for “inverted-T” patches. A number of deep neural net methods were investigated for patch detection from 3D elevation and image observation, but the success was inconclusive, partly because of a dearth of training data. Later, a method based on thresholding IRI values computed on a 12-foot window was used to localize pavement distress, particularly as seen by patch settling. This method was far more promising. In addition, algorithms were developed for segmentation of the GPR data and for classification of the ambient pavement and the locations and types of patches found in it. The results so far are promising but far from perfect, with a relatively high rate of false alarms. The two project parts were combined to produce a fused patching table. Several hundred miles of data was captured with the Waylink System to compare with a much more limited GPR dataset. The primary dataset was captured on I-74. A software application for MATLAB has been written to aid in automation of patch table creation.

Published
2021

204. Three-dimensional Surface Imaging for Clinical Decision Making in Pectus Excavatum.

Author

Daemen JHT, Coorens NA, Hulsewé KWE, Maal TJJ, Maessen JG, Vissers YLJ, and de Loos ER

Subjects
Humans, Prospective Studies, Severity of Illness Index, Treatment Outcome, Clinical Decision-Making, Funnel Chest diagnostic imaging, Funnel Chest surgery
Abstract

To evaluate pectus excavatum, 3-dimensional surface imaging is a promising radiation-free alternative to computed tomography and plain radiographs. Given that 3-dimensional images concern the external surface, the conventional Haller index, and correction index are not applicable as these are based on internal diameters. Therefore, external equivalents have been introduced for 3-dimensional images. However, cut-off values to help determine surgical candidacy using external indices are lacking. A prospective cohort study was conducted. Consecutive patients referred for suspected pectus excavatum received a computed tomography (≥18 years) or plain radiographs (<18 years). The external Haller index and external correction index were calculated from additionally acquired 3-dimensional images. Cut-off values for the 3-dimensional image derived indices were obtained by receiver-operating characteristic curve analyses, using a conventional Haller index ≥3.25, and computed tomography derived correction index ≥28.0% as indicative for surgery. Sixty-one and 63 patients were included in the computed tomography and radiograph group, respectively. To determine potential surgical candidacy, receiver-operating characteristic analyses found an optimum cut-off of ≥1.83 for the external Haller index in both the computed tomography and radiograph group with a positive predictive value between 0.90 and 0.97 and a negative predictive value between 0.72 and 0.81. The optimal cut-off for the external correction index was ≥15.2% with a positive predictive value of 0.86 and negative predictive value of 0.93. The 3-dimensional image derived external Haller index and external correction index are accurate radiation-free alternatives to facilitate surgical decision-making among patients suspected of pectus excavatum with values of ≥1.83 and ≥15.2% indicative for surgery., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published
2022
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205. Intrafractional accuracy and efficiency of a surface imaging system for deep inspiration breath hold during ablative gastrointestinal cancer treatment.

Author

Zeng C, Lu W, Reyngold M, Cuaron JJ, Li X, Cerviño L, and Li T

Subjects
Humans, Breath Holding, Motion, Movement, Radiotherapy Planning, Computer-Assisted methods, Pancreatic Neoplasms diagnostic imaging, Pancreatic Neoplasms radiotherapy, Gastrointestinal Neoplasms diagnostic imaging, Gastrointestinal Neoplasms radiotherapy
Abstract

Purpose: Beam gating with deep inspiration breath hold (DIBH) usually depends on some external surrogate to infer internal target movement, and the exact internal movement is unknown. In this study, we tracked internal targets and characterized residual motion during DIBH treatment, guided by a surface imaging system, for gastrointestinal cancer. We also report statistics on treatment time., Methods and Materials: We included 14 gastrointestinal cancer patients treated with surface imaging-guided DIBH volumetrically modulated arc therapy, each with at least one radiopaque marker implanted near or within the target. They were treated in 25, 15, or 10 fractions. Thirteen patients received treatment for pancreatic cancer, and one underwent separate treatments for two liver metastases. The surface imaging system monitored a three-dimensional surface with ± 3 mm translation and ± 3° rotation threshold. During delivery, a kilovolt image was automatically taken every 20° or 40° gantry rotation, and the internal marker was identified from the image. The displacement and residual motion of the markers were calculated. To analyze the treatment efficiency, the treatment time of each fraction was obtained from the imaging and treatment timestamps in the record and verify system., Results: Although the external surface was monitored and limited to ± 3 mm and ± 3°, significant residual internal target movement was observed in some patients. The range of residual motion was 3-21 mm. The average displacement for this cohort was 0-3 mm. In 19% of the analyzed images, the magnitude of the instantaneous displacement was > 5 mm. The mean treatment time was 17 min with a standard deviation of 4 min., Conclusions: Precaution is needed when applying surface image guidance for gastrointestinal cancer treatment. Using it as a solo DIBH technique is discouraged when the correlation between internal anatomy and patient surface is limited. Real-time radiographic verification is critical for safe treatments., (© 2022 The Authors. Journal of Applied Clinical Medical Physics published by Wiley Periodicals, LLC on behalf of The American Association of Physicists in Medicine.)

Published
2022
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207. Verification of patient-setup accuracy using a surface imaging system with steep measurement angle.

Author

Sasaki F, Yamashita Y, Nakano S, and Ishikawa M

Subjects
Humans, Head diagnostic imaging, Neck, Cone-Beam Computed Tomography, Thorax diagnostic imaging, Radiotherapy Planning, Computer-Assisted methods, Radiotherapy, Image-Guided methods
Abstract

Purpose: We evaluate an SGRT device (Voxelan HEV-600 M/RMS) installed with Radixact, with the view angle of the Voxelan's camera at 74 degrees. The accuracy of Voxelan with this steep angle was evaluated with phantom experiments and inter-fractional setup errors of patients., Methods: In the phantom experiments, the difference between the measured values of Voxelan from the truth was evaluated for translations and rotations. The inter-fractional setup error between the setup using skin markers with laser localizer (laser setup: LS) and the setup using Voxelan (surface setup: SS) was compared for head and neck (N = 19), chest (N = 7) and pelvis (N = 9) cases. The inter-fractional setup error was calculated by subtracting from bone matching by megavoltage computed tomography (MVCT) as ground truth., Results: From the phantom experiments, the average difference between the measured values of Voxelan from the truth was within 1 mm and 1 degree. In all cases, inter-fractional setup error based on MVCT was not significantly different between LS and SS by Welch's t-test (P > 0.05). The vector offset of the LS for head and neck, chest, and pelvis were 6.5, 9.6, and 9.6 mm, respectively, and that of the SS were 5.8, 8.6, and 12.6 mm, respectively. Slight improvement was observed for the head and neck, and chest cases, however, pelvis cases were not improved because the umbilical region could not be clearly visualized as a reference., Conclusion: The results show that SS in Voxelan with an installation angle of 74 degrees is equal to or better than LS., (© 2022 The Authors. Journal of Applied Clinical Medical Physics published by Wiley Periodicals, LLC on behalf of The American Association of Physicists in Medicine.)

Published
2023
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211. Supply, Installation, Commissioning And Maintenance Of Surface Imaging Systems

Subjects
Image processing -- Equipment and supplies, Imaging systems, Simulation methods, Imaging technology, Image processor, Business, international
Abstract

Contract notice: supply, installation, commissioning and maintenance of surface imaging systems Supply, installation, commissioning and maintenance of surface imaging systems. the tenderer proposes two surface imaging systems (sgrt): a system [...]

Published
2023

215. PO-1300 Tattoo-less Chest Wall Irradiation (VMAT) using Surface Imaging

Author

Mueller, B., primary, Song, Y., additional, Chia-Ko, W., additional, Hsu, H., additional, Zhai, X., additional, Tamas, P., additional, Powell, S., additional, McCormick, B., additional, Khan, A., additional, Hong, L., additional, Cervino-Arriba, L., additional, Zhao, B., additional, and Braunstein, L., additional

Published
2023
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216. The Handbook of Surface Imaging and Visualization

Author

Arthur T. Hubbard and Arthur T. Hubbard

Subjects
Surfaces (Technology)--Analysis, Spectroscopic imaging, Surface chemistry
Abstract

This exciting new handbook investigates the characterization of surfaces. It emphasizes experimental techniques for imaging of solid surfaces and theoretical strategies for visualization of surfaces, areas in which rapid progress is currently being made. This comprehensive, unique volume is the ideal reference for researchers needing quick access to the latest developments in the field and an excellent introduction to students who want to acquaint themselves with the behavior of electrons, atoms, molecules, and thin-films at surfaces. It's all here, under one cover!The Handbook of Surface Imaging and Visualization is filled with sixty-four of the most powerful techniques for characterization of surfaces and interfaces in the material sciences, medicine, biology, geology, chemistry, and physics. Each discussion is easy to understand, succinct, yet incredibly informative. Data illustrate present research in each area of study. A wide variety of the latest experimental and theoretical approaches are included with both practical and fundamental objectives in mind. Key references are included for the reader's convenience for locating the most recent and useful work on each topic. Readers are encouraged to contact the authors or consult the references for additional information.This is the best ready reference available today. It is a perfect source book or supplemental text on the subject.

Published
2022

218. Surface imaging of HD 199178 (V1794 Cygni)

Author

Hackman, T., Jetsu, L., and Tuominen, I.

Subjects
Astrophysics
Abstract

We present surface temperature maps for the FK Comae-type star HD 199178 (V1794 Cygni) calculated from high resolution spectra obtained in 1994 and 1995. The spot pattern evolves, but all maps reveal a large cool spot remaining nearly at the same high latitude. The main spot is 1200 -- 1600 K cooler than the mean surface temperature. The observed slightly flat bottomed absorption lines would usually be interpreted as evidence for a large cool polar spot. We argue that antisolar surface differential rotation offers a better explanation for the box like shape of the line profiles. However, we do not find conclusive evidence for antisolar differential rotation and note that there are still other possible explanations for the slightly flat bottomed line profiles., Comment: 10 pages, 5 figures, Astron. Astrophys., in press

Published
2001
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220. Evaluation of technical performance of optical surface imaging system using conventional and novel stereotactic radiosurgery algorithms

Author

Haruna Yokoyama, Kimiya Noto, Shogo Kurokawa, Shigeyuki Takamatsu, Akihiro Takemura, Hironori Kojima, and Shinichi Ueda

Subjects
medicine.medical_treatment, Image registration, Radiosurgery, Standard deviation, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, registration, Approximation error, medicine, Radiation Oncology Physics, Humans, stereotactic radiosurgery (SRS), Radiology, Nuclear Medicine and imaging, Instrumentation, Sweden, Physics, Reproducibility, optical surface imaging system, Radiation, Phantoms, Imaging, surface‐guided radiation therapy (SGRT), Reproducibility of Results, Isocenter, Rigid body, positioning, 030220 oncology & carcinogenesis, Algorithm, Algorithms
Abstract

The Catalyst HD (C‐RAD Positioning AB, Uppsala, Sweden) optical surface imaging (OSI) system is able to manage interfractional patient positioning, intrafractional motion monitoring, and non‐contact respiratory gating without x‐ray exposure for radiation therapy. In recent years, a novel high‐precision surface registration algorithm for stereotactic radiosurgery (SRS algorithm) has been released. This study aimed to evaluate the technical performance of the OSI system using rigid phantoms, by comparing the conventional and SRS algorithms. To determine the system’s technical performance, isocenter displacements were calculated by surface image registration via the OSI system using head, thorax, and pelvis rigid phantoms. The reproducibility of positioning was evaluated by the mean value calculated by repeating the registration 10 times, without moving each phantom. The accuracy of positioning was evaluated by the mean value of the residual error, where the 10 offset values given to each phantom were subtracted from the isocenter displacement values. The stability of motion monitoring was evaluated by measuring isocenter drift during 20 min and averaging it over 10 measurements. For the head phantom, all tests were compared with the mask types and algorithms. As a result, for all sites and both algorithms, the reproducibility, accuracy, and stability for translation and rotation were

Published
2020
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221. Facial aesthetic fat graft retention rates after filtration, centrifugation, or sedimentation processing techniques measured using three-dimensional surface imaging devices

Author

Guan-Hui-Er Wang, Jian-Fang Zhao, Hong-Yu Xue, Dong Li, and Qiang Shi

Subjects
Medicine
Abstract

Abstract. Objective:. How to increase the long-term retention rate of autologous fat grafting has been widely discussed. This study aimed to evaluate long-term fat graft retention rates for the most widely used fat processing methods in the area of facial esthetic surgery, including centrifugation, filtration, and sedimentation, using three-dimensional (3D) imaging. Data Sources:. PubMed, Embase, Wiley/Cochrane Library, and Web of Science databases were comprehensively searched from inception to July 2018 according to the guidelines of the American Society of Plastic Surgeons Fat Graft Task Force Assessment Methodology. Study Selection:. Articles were screened using predetermined inclusion and exclusion criteria. Data collected included patient characteristics, follow-up devices, fat grafting techniques, and clinical outcomes. Patient cohorts were pooled, and fat graft retention rates were calculated. Complications were summarized according to different clinical characteristics. Results:. Of 77 articles, 10 clinical studies met the inclusion criteria and reported quantified measurement outcomes with 3D imaging which provide precise volumetric data with approximately 2% standard deviation compared to real volumes. Data of 515 patients were included. Fat grafting retention varied from 21% to 82%. We found filtration and centrifugation techniques could result in better retention outcomes. However, retention varied within each processing technique, with no significant difference among the 3 techniques. Twenty-two complications were reported among 515 patients, including donor-site hematoma (1 case), mild post-operative erythema (2 cases), mild volumetric asymmetries (2 cases), chronic edema (2 cases), overcorrection (2 cases), skin irregularity (6 cases), and headache or dysesthesia (7 cases). Conclusions:. Filtration and centrifugation techniques may result in better fat grafting retention outcomes than gravity sedimentation; however, more accurate statistical evidence is needed. Controversies continue to exist with respect to the performance of the different fat-processing techniques in fat graft retention.

Published
2019
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223. Reliability and comparison of 3-dimensional surface imaging of the face using a hand-held and whole body surface scanner

Author

Xu, Ya

Subjects
FOS: Medical and Health Sciences, 3-Dimensional, Surface Imaging, Hand-held Scanner, Whole-body Scanner
Abstract

Objective: 3-Dimensional surface (3DSI) imaging has been shown to be a useful tool for plastic surgeons in the preoperative, intraoperative and postoperative setting. And to the knowledge of the authors no data about the reproducibility and accuracy of 3-Dimensional surface imaging of the face using a whole-body scanner is available. Thus, the objective of this investigation was to assess the reproducibility of facial scans acquired using a whole-body imaging device and to compare the precision of distance measurements in the face using a hand-held surface imaging device and a whole-body surface imaging device. Furthermore, the reproducibility of the whole body scanner was investigated. Material and Methods: This investigation enrolled a total of 22 healthy volunteers with a mean age of 29.36 years. Two consecutive 3-D images of the volunteers were obtained utilizing a whole-body imaging device(WB360) and a hand-hold imaging device(Vectra H2). For the whole-body imaging predefined distances in the face were performed in each scan and compared. Furthermore, surface deviation between two consecutively captured scans was assessed. Results: For the reliability of whole-body scan, the distance with the smallest statistical significance was found to be at the nose with p = 0.998, while the biggest statistical significance was found in the midface with p = 0.658. The area with the biggest surface deviation between the superimposed scans was the neck with a RMS of 1.62 ± 1.71 mm and the area with the smallest surface deviation was the forehead with a RMS of 0.17 ± 0.05 mm. For the comparison of the both scanners our results revealed that the measured difference between the length and the standard reference did not differ statistically significant between the two investigated devices in all investigated areas of the face (p > 0.266), however the measured difference of the width and the width of the standard reference differed statistically significant in all areas of the face across the investigated devices (p < 0.032). Conclusion: The whole – body-imaging device investigated in this study can be utilized to capture the face and provides enough accuracy to compare scans. Even though not directly investigated, it can be hypothesized that the error caused by repositioning the patient between a baseline and a follow – up scan will not be too big to consider measurements performed with the whole – body-imaging device as impractical. Both, measurements obtained from scans acquired using the hand held imaging device and the whole – body-imaging device differed significantly from the standard reference. Users should be aware of deviations when obtaining 3DSI using the presented imaging devices but should not refrain from using them, as the absolute differences might be too small to play a role in both, clinical and research, setting.

Published
2022
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225. Sea Surface Imaging Simulation for 3D Interferometric Imaging Radar Altimeter

Author

Yongxin Liu, Zhaoxia Wang, Chenqing Fan, and Jie Zhang

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Geophysics. Cosmic physics, 0211 other engineering and technologies, quasi-mirror scattering, 02 engineering and technology, interferometric imaging radar altimeter (InIRA), 01 natural sciences, Signal, law.invention, Superposition principle, symbols.namesake, law, Radar imaging, Computers in Earth Sciences, TC1501-1800, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, QC801-809, Delaunay triangulation, sea surface imaging simulation, Elevation, Ocean engineering, Radar altimeter, Surface wave, symbols, Elevation inversion, Doppler effect, Geology
Abstract

The interferometric imaging radar altimeter (InIRA) is a new generation radar altimeter, which can provide two-dimensional images of the sea surface topography at high resolution along a wide swath. This article proposes a method for the simulation of sea surface images measured by InIRA. First, the Pierson-Moskowitz wave spectrum and two-scale model are used to simulate the sea surface from which elevation data is to be acquired. This simulated sea surface is then divided into small triangular facets using Delaunay triangulation. Second, the backscattering cross sections of these small facets are calculated via application of quasi-mirror scattering theory, and the backscattering coefficient of the simulated region derived via coherent superposition. Third, system parameters are set, consistent with the basic principle of InIRA. Assuming that the signal transmitted is a linear frequency modulation pulse signal, the simulation images are then derived using the range Doppler and back projection algorithms. By inverting the interferometric phase diagram, elevation estimates can be derived, and compared with original simulated sea levels. This demonstrated accuracy within the centimeter range, verifying the correctness and feasibility of the proposed method.

Published
2021
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227. Using a Smartphone 3-Dimensional Surface Imaging Technique to Manufacture Custom 3-Dimensional-Printed Eyeglasses

Author

Alejandra G. de Alba Campomanes, Elana Meer, Matthew Clarke, and Frank L. Brodie

Subjects
Craniofacial Abnormalities, Ophthalmology, Eyeglasses, Imaging, Three-Dimensional, Vision Disorders, Humans, Smartphone, Child, Amblyopia
Abstract

ImportanceFinding a suitable fit in glasses for pediatric patients with congenital and acquired craniofacial abnormalities is difficult; consequently, these children are at high risk of vision loss secondary to refractive amblyopia as they often have poor adherence to daily glasses wearing. Custom 3-dimensional (3D)–printed glasses may have an improved design and fit, but access is limited by the availability of computed tomography and magnetic resonance imaging (MRI).ObjectiveTo describe a method for using a commercially available smartphone 3D surface imaging (3DSI) technique to capture facial anatomy as a basis for custom glasses design.Design, Setting, and ParticipantsThis quality improvement study analyzes data from a case series in a primary academic center with multiple referral centers throughout the United States. The evaluation included reported fit descriptions from patients with poor glasses adherence due to craniofacial abnormalities.Main Outcomes and MeasuresKey anatomic parameters for glasses fit (face width, distance from ear bridge to nasal bridge, distance from center of pupil to center of nasal bridge, distance from lateral to medial canthus, ear vertical offset, and nasal bridge width) were compared between scans. A 3DSI scan was considered successful if these key parameters could be determined and the difference in measurements was less than 5% between MRI and 3DSI. A second outcome measure included the fit of glasses designed by the 3DSI method as reported by the patient, parent, or guardian.ResultsMeasurements of key parameters for glasses fit were similar across MRI and 3DSI scans with a mean (SD) difference of 1.47 (0.79) mm between parameters (range, 0.3-4.60 mm). Among 20 patients aged 1 to 17 years with craniofacial abnormalities, all achieved a successful fit (reporting daily glasses adherence without irritation) as judged by the patient, parent, or guardian. A mean of 1.7 revisions were made from initial prototype to final frame production using 3DSI technology.Conclusions and RelevanceThis study demonstrated that smartphone-enabled 3DSI coupled with widely available 3D printing technology can produce custom frames with a successful fit for patients with craniofacial anomalies. This accessible and well-tolerated imaging process may have implications for adherence with glasses wearing among patients at risk of vision loss due to amblyopia.

Published
2023

228. Surface Imaging by Microlensing - Exploring Depth in Stellar Atmospheres

Author

Sasselov, Dimitar D.

Subjects
Astrophysics
Abstract

Gravitational microlensing is a new technique for studying the surfaces of distant stars. A point mass lens, usually a low-mass star from the disk, will typically resolve the surface of a red giant in the Galactic bulge, as well as amplify its brightness by a factor of 10 or more. Such events are now detected in real time and can be followed up with precision photometry and spectroscopy. The motivation for stellar imaging via microlensing lies in its unique ability to provide center-to-limb variation of spectral diagnostic lines. Such variation maps into a variation with depth in the stellar atmosphere - a unique and very valuable constraint for modeling the structure of red giants' atmospheres. We illustrate the technique on a recent successful observational campaign and discuss the implications for current stellar models., Comment: 8 pages, 3 figures, LaTex, invited talk 10th Cambridge Workshop on "Cool Stars, Stellar Systems, and the Sun", eds. R.Donahue & J.Bookbinder

Published
1998

230. The Colour and Stereo Surface Imaging System (CaSSIS) for the ExoMars Trace Gas Orbiter

Author

Thomas, N., Cremonese, G., Ziethe, R., Gerber, M., Brändli, M., Bruno, G., Erismann, M., Gambicorti, L., Gerber, T., Ghose, K., Gruber, M., Gubler, P., Mischler, H., Jost, J., Piazza, D., Pommerol, A., Rieder, M., Roloff, V., Servonet, A., Trottmann, W., Uthaicharoenpong, T., Zimmermann, C., Vernani, D., Johnson, M., Pelò, E., Weigel, T., Viertl, J., De Roux, N., Lochmatter, P., Sutter, G., Casciello, A., Hausner, T., Ficai Veltroni, I., Da Deppo, V., Orleanski, P., Nowosielski, W., Zawistowski, T., Szalai, S., Sodor, B., Tulyakov, S., Troznai, G., Banaskiewicz, M., Bridges, J. C., Byrne, S., Debei, S., El-Maarry, M. R., Hauber, E., Hansen, C. J., Ivanov, A., Keszthelyi, L., Kirk, R., Kuzmin, R., Mangold, N., Marinangeli, L., Markiewicz, W. J., Massironi, M., McEwen, A. S., Okubo, C., Tornabene, L. L., Wajer, P., and Wray, J. J.

Published
2017
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233. Advances and potential of optical surface imaging in radiotherapy.

Author

Li G

Subjects
Female, Humans, Radiotherapy Planning, Computer-Assisted methods, Radiotherapy Setup Errors, Brachytherapy methods, Breast Neoplasms pathology, Radiotherapy, Image-Guided methods
Abstract

This article reviews the recent advancements and future potential of optical surface imaging (OSI) in clinical applications as a four-dimensional (4D) imaging modality for surface-guided radiotherapy (SGRT), including OSI systems, clinical SGRT applications, and OSI-based clinical research. The OSI is a non-ionizing radiation imaging modality, offering real-time 3D surface imaging with a large field of view (FOV), suitable for in-room interactive patient setup, and real-time motion monitoring at any couch rotation during radiotherapy. So far, most clinical SGRT applications have focused on treating superficial breast cancer or deep-seated brain cancer in rigid anatomy, because the skin surface can serve as tumor surrogates in these two clinical scenarios, and the procedures for breast treatments in free-breathing (FB) or at deep-inspiration breath-hold (DIBH), and for cranial stereotactic radiosurgery (SRS) and radiotherapy (SRT) are well developed. When using the skin surface as a body-position surrogate, SGRT promises to replace the traditional tattoo/laser-based setup. However, this requires new SGRT procedures for all anatomical sites and new workflows from treatment simulation to delivery. SGRT studies in other anatomical sites have shown slightly higher accuracy and better performance than a tattoo/laser-based setup. In addition, radiographical image-guided radiotherapy (IGRT) is still necessary, especially for stereotactic body radiotherapy (SBRT). To go beyond the external body surface and infer an internal tumor motion, recent studies have shown the clinical potential of OSI-based spirometry to measure dynamic tidal volume as a tumor motion surrogate, and Cherenkov surface imaging to guide and assess treatment delivery. As OSI provides complete datasets of body position, deformation, and motion, it offers an opportunity to replace fiducial-based optical tracking systems. After all, SGRT has great potential for further clinical applications. In this review, OSI technology, applications, and potential are discussed since its first introduction to radiotherapy in 2005, including technical characterization, different commercial systems, and major clinical applications, including conventional SGRT on top of tattoo/laser-based alignment and new SGRT techniques attempting to replace tattoo/laser-based setup. The clinical research for OSI-based tumor tracking is reviewed, including OSI-based spirometry and OSI-guided tumor tracking models. Ongoing clinical research has created more SGRT opportunities for clinical applications beyond the current scope., (© 2022 Institute of Physics and Engineering in Medicine.)

Published
2022
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234. Analysis of a surface imaging system using a six degree-of-freedom couch.

Author

Zhao X, Covington EL, and Popple RA

Subjects
Humans, Motion, Particle Accelerators, Phantoms, Imaging, Radiotherapy Planning, Computer-Assisted methods, Radiosurgery methods
Abstract

Purpose: To validate surface imaging (SI)-reported offsets using a six degree-of-freedom couch and an anthropomorphic phantom for commissioning and routine quality assurance of an SI system used for stereotactic radiosurgery (SRS)., Methods: An anthropomorphic phantom with a radiopaque ball bearing (BB) placed either anterior, midline, or posterior, was tracked with SI with a typical SRS region of interest. Couch motion in all six degrees of freedom was programmed and delivered on a linac. SI system logs were synchronized with linac trajectory logs. Ten random couch positions were selected at couch 0°, 45°, 90°, 270°, 315° with megavolt (MV) images taken to account for couch walkout. The SI residual error (ε), the difference between SI reported offset and MV or trajectory log position, was calculated. Residual errors were measured with and without one SI pod blocked., Results: The median [range] of magnitude of translational ε was 0.13 [0.07, 0.21], 0.16 [0.11, 0.26], 0.61 [0.50, 0.68], 0.49 [0.42, 0.55], 0.55 [0.38, 0.72] mm for couch rotations of 0°, 45°, 90°, 270°, 315°, respectively, for the midline BB and no pod blocked. The range of all translational ε from all couch angles (with and without pod block) at different BB positions is [0.05, 0.96] mm. The absolute range of difference when changing BB position when no pod is blocked in median translational ε is [0.01, 0.40] mm with the maximum at BB posterior. The absolute range of difference when not changing BB positions with and without pod block in median translational ε is [0.01, 0.37] mm with the maximum at BB posterior and couch 315°., Conclusion: SI system and linac trajectory log analysis can be used to assess SI system performance with automated couch motion to validate SI accuracy., (© 2022 The Authors. Journal of Applied Clinical Medical Physics published by Wiley Periodicals, LLC on behalf of The American Association of Physicists in Medicine.)

Published
2022
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235. Accuracy and Efficiency of Patient Setup Using Surface Imaging versus Skin Tattoos for Accelerated Partial Breast Irradiation.

Author

Mueller B, Song Y, Chia-Ko W, Hsu HY, Zhai X, Tamas P, Powell S, Cahlon O, McCormick B, Khan A, Gillespie E, Cervino L, Zhao B, Hong L, and Braunstein LZ

Abstract

Purpose: Skin tattoos represent the standard approach for surface alignment and setup of breast cancer radiation therapy, yet permanent skin markings contribute to adverse cosmesis and patient dissatisfaction. With the advent of contemporary surface-imaging technology, we evaluated setup accuracy and timing between "tattoo-less" and traditional tattoo-based setup techniques., Methods and Materials: Patients receiving accelerated partial breast irradiation (APBI) underwent traditional tattoo-based setup (TTB), alternating daily with a tattoo-less setup via surface imaging using AlignRT (ART). Following initial setup, position was verified via daily kV imaging, with matching on surgical clips representing ground truth. Translational shifts (TS) and rotational shifts (RS) were ascertained, as were setup time and total in-room time. Statistical analyses used the Wilcoxon signed rank test and Pitman-Morgan variance test., Results: A total of 43 patients receiving APBI and 356 treatment fractions were analyzed (174 TTB fractions and 182 using ART). For tattoo-less setup via ART, the median absolute TS were 0.31 cm in the vertical (range, 0.08-0.82), 0.23 cm in the lateral (0.05-0.86), and 0.26 cm in the longitudinal (0.02-0.72) axes. For TTB setup, the corresponding median TS were 0.34 cm (0.05-1.98), 0.31 cm (0.09-1.84), and 0.34 cm (0.08-1.25), respectively. The median magnitude shifts were 0.59 (0.30-1.31) for ART and 0.80 (0.27-2.13) for TTB. ART was not statistically distinguishable from TTB in terms of TS, except in the longitudinal direction ( P  = .154, .059, and .021, respectively), and was superior to TTB for magnitude shift ( P < .001). The variance of each TS variable was significantly narrower for ART compared with TTB ( P ≤ .001 vertical, P  = .001 lateral, P  = .005 longitudinal). The median absolute RS for ART was 0.64° rotation (range, 0.00-1.90), 0.65° roll (0.05-2.90), and 0.30° pitch (0.00-1.50). The corresponding median RS for TTB were 0.80° (0.00-2.50), 0.64° (0.00-3.00), and 0.46° (0.00-2.90), respectively. ART setup was not statistically different from TTB in terms of RS ( P  = .868, .236, and .079, respectively). ART showed lower variance than TTB in terms of pitch ( P  = .009). The median total in-room time was shorter for ART than TTB (15.42 vs 17.25 minutes; P  = .008), as was the median setup time (11.12 vs 13.00 minutes; P  = .001). Moreover, ART had a narrower distribution of setup time with fewer lengthy outliers versus TTB., Conclusions: These findings suggest that a tattoo-less setup approach with AlignRT may be sufficiently accurate and expeditious to supplant surface tattoos for patients receiving APBI. Further analyses with larger cohorts will determine whether tattoo-based approaches can be replaced by noninvasive surface imaging., (© 2023 The Author(s).)

Published
2023
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238. The Chromaticity of Microlensing (Surface Imaging of Stars)

Author

Sasselov, Dimitar D.

Subjects
Astrophysics
Abstract

Gravitational microlensing is not achromatic when the star being microlensed is resolved by the lens. We show how narrow-band photometry and moderate- to high-resolution spectroscopy can be used to reconstruct the stellar surface intensity distribution of a microlensed star. Such microlens imaging can provide a unique opportunity to study the surfaces of normal red giants where Doppler imaging is not applicable due to slow rotation.}, Comment: 5 pages, 2 figures, LaTex, invited talk 12th IAP Colloquium on "The Astrophysical Returns of Microlensing Surveys", eds. R.Ferlet and J.P.Maillard

Published
1997

239. True Atomic-Resolution Surface Imaging and Manipulation under Ambient Conditions via Conductive Atomic Force Microscopy.

Author

Sumaiya SA, Liu J, and Baykara MZ

Abstract

A great number of chemical and mechanical phenomena, ranging from catalysis to friction, are dictated by the atomic-scale structure and properties of material surfaces. Yet, the principal tools utilized to characterize surfaces at the atomic level rely on strict environmental conditions such as ultrahigh vacuum and low temperature. Results obtained under such well-controlled, pristine conditions bear little relevance to the great majority of processes and applications that often occur under ambient conditions. Here, we report true atomic-resolution surface imaging via conductive atomic force microscopy (C-AFM) under ambient conditions, performed at high scanning speeds. Our approach delivers atomic-resolution maps on a variety of material surfaces that comprise defects including single atomic vacancies. We hypothesize that atomic resolution can be enabled by either a confined, electrically conductive pathway or an individual, atomically sharp asperity at the tip-sample contact. Using our method, we report the capability of in situ charge state manipulation of defects on MoS 2 and the observation of an exotic electronic effect: room-temperature charge ordering in a thin transition metal carbide (TMC) crystal (i.e., an MXene), α-Mo 2 C. Our findings demonstrate that C-AFM can be utilized as a powerful tool for atomic-resolution imaging and manipulation of surface structure and electronics under ambient conditions, with wide-ranging applicability.

Published
2022
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246. Change detection and monitoring of active Martian surface phenomena with the Colour and Stereo Surface Imaging System (CaSSIS) onboard the ExoMars Trace Gas Orbiter (TGO)

Author

Rangarajan, Vidhya Ganesh, primary, Tornabene, Livio L., additional, Osinski, Gordon R., additional, Conway, Susan J., additional, Seelos, Frank P., additional, Silvestro, Simone, additional, Salese, Francesco, additional, Pajola, Maurizio, additional, Lucchetti, Alice, additional, Munaretto, Giovanni, additional, Bickel, Valentin T., additional, Thomas, Nicolas, additional, and Cremonese, Gabriele, additional

Published
2023
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250. Technical note: Surface imaging for real-time patient positioning in external radiation therapy.

Author

Nazir S, Bert J, Fayad H, and Visvikis D

Subjects
Cone-Beam Computed Tomography, Humans, Patient Positioning, Radiotherapy Setup Errors, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Image-Guided
Abstract

Purpose: In the last few years, there has been a growing interest in surface imaging for patient positioning in external radiation therapy. The aim of this study is to evaluate the accuracy of daily patient positioning using the Azure Kinect surface imaging., Methods: A total of 50 fractions in 10 patients including lung, pelvic, and head and neck tumors were analyzed in real time. A rigid registration algorithm, based on the iterative closest point (ICP) approach, is employed to estimate the patient position in 6 degrees of freedom (DOF). This position is compared to the reference values obtained by the radiograph imaging. The mean setup error and its standard deviation were calculated for all measured fractions., Results: The positioning error showed 1.1 ± 1.1 mm in lateral, 1.8 ± 2.1 mm in longitudinal, and 0.8 ± 1.1 mm in vertical, and 0.3°± 0.4° in yaw, 0.2°± 0.2° in pitch, and 0.2°± 0.2° in roll directions. The larger setup error occurred in pelvic regions., Conclusion: We have evaluated in a radiotherapy set-up considering different patient anatomical locations, a depth measurement based surface imaging solution for patient positioning considering the 6 DOF couch motion. We showed that the proposed solution allows an accurate patient positioning without the need for patient markings or the use of additional radiation dose., (© 2021 American Association of Physicists in Medicine.)

Published
2021
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