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Medical Physics, ISSN 0094-2405, 11/2012, Volume 39, Issue 11, pp. 7175 - 7175
...Erratum: “TG-43 U1 based dosimetric characterization of model 67-6520 Cs-137 brachytherapy source” [Med. Phys. 36(10), 4711–4719 (2009)] Ali S. Meigooni... 
Erratum | Therapeutic applications, including brachytherapy | brachytherapy | dosimetry | RADIOLOGY AND NUCLEAR MEDICINE | BRACHYTHERAPY | DOSIMETRY | CESIUM 137
Journal Article
Medical Physics, ISSN 0094-2405, 08/2011, Volume 38, Issue 8, pp. 4785 - 4794
...) brachytherapy using a real-time planning system. Methods: A dosimetric study involving 28 patients was undertaken where measured doses received during treatment were compared to those calculated by the treatment planning system (TPS... 
real-time dosimetry | semiconductor diodes | in vivo dosimetry | brachytherapy | biological organs | Medical image quality | real‐time dosimetry | Medical imaging | Error analysis | dosimetry | biomedical equipment | Medical treatment planning | biomedical ultrasonics | diagnostic radiography | Calibration | Dose‐volume analysis | Radiography | Ultrasonographic imaging | Ultrasonography | Medical image reconstruction | probes | Therapeutic applications, including brachytherapy | Dosimetry/exposure assessment | Cancer | THERMOLUMINESCENCE DOSIMETRY | MOSFET | FEASIBILITY | DIAMOND DETECTOR | IMPLANTS | CANCER | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | HDR BRACHYTHERAPY | Radiotherapy Dosage | Prostatic Neoplasms - radiotherapy | Reproducibility of Results | Uncertainty | Computer Systems - statistics & numerical data | Humans | Brachytherapy - methods | Male | Rectum - radiation effects | Radiometry - statistics & numerical data | Brachytherapy - statistics & numerical data | Prostatic Neoplasms - diagnostic imaging | Radiometry - methods | Phantoms, Imaging | FLUOROSCOPY | PROSTATE | PATIENTS | ERRORS | NEOPLASMS | RECTUM | PERFORMANCE | RADIATION PROTECTION AND DOSIMETRY | RADIATION DOSES | IN VIVO | SEMICONDUCTOR DIODES | PLANNING | PROBES | EQUIPMENT | RADIOLOGY AND NUCLEAR MEDICINE | ULTRASONOGRAPHY | BRACHYTHERAPY | COORDINATES | DOSE RATES | CYLINDRICAL CONFIGURATION | VERIFICATION
Journal Article
Medical Physics, ISSN 0094-2405, 02/2014, Volume 41, Issue 2, pp. 021703 - n/a
Journal Article
Journal Article
Medical Physics, ISSN 0094-2405, 12/2015, Volume 42, Issue 12, pp. 6830 - 6839
Purpose: In current clinical practice, there is no integrated 3D ultrasound (3DUS) guidance system clinically available for breast brachytherapy... 
biomedical MRI | dosimetry | Segmentation | medical robotics | biomedical ultrasonics | skin | Scintigraphy | Robotics | phantoms | Digital computing or data processing equipment or methods, specially adapted for specific applications | Ultrasonographic imaging | Involving electronic [emr] or nuclear [nmr] magnetic resonance, e.g. magnetic resonance imaging | Computed tomography | image segmentation | muscle | Ultrasonography | Catheters; Hollow probes | brachytherapy | catheters | Three dimensional image processing | Computerised tomographs | medical image processing | HDR brachytherapy | 3D ultrasound | Reconstruction | Image scanners | mammography | Diagnosis using ultrasonic, sonic or infrasonic waves | Muscles | image reconstruction | Radiation therapy | Biological material, e.g. blood, urine; Haemocytometers | Dose‐volume analysis | computerised tomography | Magnetic resonance imaging | Image data processing or generation, in general | Medical image reconstruction | cancer | Therapeutic applications, including brachytherapy | breast | PROSTATE | ALGORITHM | CANCER | IRRADIATION | ULTRASOUND | CATHETER RECONSTRUCTION | CONSERVING SURGERY | SEGMENTATION | OPTIMIZATION | DOSE-RATE BRACHYTHERAPY | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | Breast - radiation effects | Radiotherapy Dosage | Brachytherapy - instrumentation | Sepharose | Radiotherapy Planning, Computer-Assisted - methods | Ultrasonography, Mammary - methods | Humans | Brachytherapy - methods | Imaging, Three-Dimensional - methods | Radiotherapy Planning, Computer-Assisted - instrumentation | Tomography, X-Ray Computed | Mammography | Robotics - instrumentation | Feasibility Studies | Magnetic Resonance Imaging | Ultrasonography, Mammary - instrumentation | Breast Neoplasms - radiotherapy | Algorithms | Muscle, Skeletal - radiation effects | Skin - radiation effects | Imaging, Three-Dimensional - instrumentation | Robotics - methods | Breast Neoplasms - diagnostic imaging | Phantoms, Imaging | SURGERY | GRIDS | MAMMARY GLANDS | APPROXIMATIONS | 60 APPLIED LIFE SCIENCES | COMPUTERIZED TOMOGRAPHY | ACCURACY | PLANNING | IMAGE PROCESSING | NMR IMAGING | PHANTOMS | BRACHYTHERAPY | DOSE RATES
Journal Article
Medical Physics, ISSN 0094-2405, 09/2014, Volume 41, Issue 9, pp. 091712 - n/a
Purpose: Brachytherapy is a standard option of care for prostate cancer patients but may be improved by dynamic dose calculation based on localized seed positions... 
Segmentation | dosimetry | Pipelines | biomedical ultrasonics | Scintigraphy | Digital computing or data processing equipment or methods, specially adapted for specific applications | seed reconstruction | Ultrasound therapy | Computed tomography | image segmentation | Ultrasonography | brachytherapy | medical image processing | dynamic dose calculation | Reconstruction | Diagnosis using ultrasonic, sonic or infrasonic waves | prostate brachytherapy | Medical image segmentation | ultrasonic therapy | diagnostic radiography | Fluoroscopy | image reconstruction | Radiation therapy | Radiography | registration of fluoroscopy and ultrasound | Image data processing or generation, in general | Medical image reconstruction | Therapeutic applications, including brachytherapy | ultrasonic imaging | mobile C‐arm | Dosimetry/exposure assessment | mobile C-arm | RECONSTRUCTION | AMERICAN-BRACHYTHERAPY | IMPLANTS | SEEDS | C-ARM | TRACKING | SEGMENTATION | TRUS | REGISTRATION | DOSIMETRY | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | Prostatic Neoplasms - radiotherapy | Fiducial Markers | Radiotherapy Planning, Computer-Assisted - methods | Humans | Brachytherapy - methods | Radiotherapy Planning, Computer-Assisted - instrumentation | Fluoroscopy - instrumentation | Fluoroscopy - methods | Male | Time | Image Processing, Computer-Assisted - methods | Ultrasonography - instrumentation | Algorithms | Radiotherapy, Image-Guided - methods | Prostate - diagnostic imaging | Prostatic Neoplasms - diagnostic imaging | Radiometry - methods | Radiotherapy, Image-Guided - instrumentation | Phantoms, Imaging | Radiometry - instrumentation | Ultrasonography - methods | FLUOROSCOPY | PROSTATE | NEOPLASMS | APPROXIMATIONS | RADIOLOGY AND NUCLEAR MEDICINE | PHANTOMS | RADIATION DOSES | ALGORITHMS | COMPARATIVE EVALUATIONS | BRACHYTHERAPY | PLANNING | RADIATION SOURCE IMPLANTS | Radiation Therapy Physics
Journal Article
Medical Physics, ISSN 0094-2405, 02/2013, Volume 40, Issue 2, pp. 021716 - n/a
... (trakSTAR, Ascension Technology, VT). The performance of the system, including the accuracy and noise level with various tracking parameters and conditions, were investigated. Methods: A direct current (dc) EM transmitter (midrange model... 
Error analysis | Direct current power transmission | bioelectric potentials | Ferromagnetic materials | Biophysical mechanisms of interaction | phantoms | Digital computing or data processing equipment or methods, specially adapted for specific applications | Ultrasonography | Catheters; Hollow probes | Dosimetry | brachytherapy | catheters | medical image processing | Tracking devices | Reconstruction | Position sensitive detectors | Medical imaging | Probability theory, stochastic processes, and statistics | biomagnetism | image reconstruction | Radiation therapy | Calibration | electromagnetic fields | Image data processing or generation, in general | cancer | Therapeutic applications, including brachytherapy | statistical analysis | SYSTEM | SURGERY | IMPLANT | MOTION | NEEDLES | TRACKERS | CANCER | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | BIRDS | KINEMATICS | FLOCK | Radiotherapy Dosage | Electromagnetic Phenomena | Prostatic Neoplasms - radiotherapy | Brachytherapy - instrumentation | Time Factors | Humans | Male | Radiotherapy Setup Errors | Radiation Dosage | Catheters | PROSTATE | CALIBRATION | SAMPLING | ELECTROMAGNETIC FIELDS | ERRORS | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | ACCURACY | RADIOLOGY AND NUCLEAR MEDICINE | DIRECT CURRENT | INTERFERENCE | BRACHYTHERAPY | DOSE RATES | DOSIMETRY
Journal Article
Medical Physics, ISSN 0094-2405, 10/2011, Volume 38, Issue 10, pp. 5539 - 5550
Purpose: High energy photon beams are used in calibrating dosimeters for use in brachytherapy since absorbed dose to water can be determined accurately and with traceability to primary standards in such beams... 
efficiency | LiF:Mg | dosimetry | detector response | x-ray energy spectra | brachytherapy | Ti TLD | x‐ray energy spectra | Annealing | Error analysis | Applications | X‐ray imaging | titanium | magnesium | lithium compounds | Photons | X‐ray detectors | Calibration | Monte Carlo methods | thermoluminescent dosimeters | Monte Carlo simulations | Particle beam detectors | Therapeutic applications, including brachytherapy | Dosimetry/exposure assessment | LIF-MG,TI | LIF-MG | X-RAYS | UPDATE | MONTE-CARLO SIMULATIONS | SPECTRA | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | Reproducibility of Results | Humans | Brachytherapy - methods | Titanium - chemistry | Thermoluminescent Dosimetry - methods | Ions | Air | Models, Statistical | Cobalt Radioisotopes - analysis | Fluorides - chemistry | Magnesium - chemistry | Lithium Compounds - chemistry | X-Rays | Thermoluminescent Dosimetry - instrumentation | Linear Energy Transfer | Radiometry - methods | Monte Carlo Method | INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY | X RADIATION | MONTE CARLO METHOD | COBALT 60 | LITHIUM FLUORIDES | ENERGY SPECTRA | RADIATION DOSES | ENERGY ABSORPTION | KEV RANGE | THERMOLUMINESCENT DOSIMETRY | READOUT SYSTEMS | CESIUM 137 | THERMOLUMINESCENT DOSEMETERS | COMPUTERIZED SIMULATION | MAGNESIUM ADDITIONS | PHOTON BEAMS | RADIOLOGY AND NUCLEAR MEDICINE | LET | BRACHYTHERAPY | TITANIUM ADDITIONS | IONIZATION CHAMBERS
Journal Article
Medical Physics, ISSN 0094-2405, 10/2010, Volume 37, Issue 10, pp. 5188 - 5198
Purpose: The objective of this work is to assess the sensitivity of Monte Carlo (MC) dose calculations to uncertainties in human tissue composition for a range of low photon energy brachytherapy sources... 
seed implants | dose calculation | brachytherapy | Monte Carlo | tissue composition | Biomedical modeling | biological tissues | Mammography | Photons | Tissues | water | Monte Carlo methods | Computed tomography | Anisotropy | Dosimetry | Therapeutic applications, including brachytherapy | Phase space methods | Cancer | QUALITY ASSURANCE | CALCULATION ENGINE | BREAST | RADIATION-THERAPY | PD-103 SEED IMPLANT | INTERSEED ATTENUATION | PERMANENT PROSTATE IMPLANTS | ELECTRON-DENSITY CALIBRATION | CT NUMBERS | DOSIMETRY | RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING | Breast - radiation effects | Radiotherapy Dosage | Prostatic Neoplasms - radiotherapy | Biophysical Phenomena | Radioisotopes - therapeutic use | Humans | Prostate - radiation effects | Radiotherapy Planning, Computer-Assisted - statistics & numerical data | Cesium Radioisotopes - therapeutic use | Male | Tomography, X-Ray Computed | Adipose Tissue - radiation effects | Breast Neoplasms - radiotherapy | Iodine Radioisotopes - therapeutic use | Algorithms | Brachytherapy - statistics & numerical data | Palladium - therapeutic use | Female | Monte Carlo Method | PATIENTS | SPECTRAL HARDENING | PHOTONS | SENSITIVITY | STANDARDS | ANIMAL TISSUES | RADIATION DOSES | IMPLANTS | 60 APPLIED LIFE SCIENCES | IODINE 125 | CAT SCANNING | PALLADIUM 103 | PLANNING | RADIATION DOSE DISTRIBUTIONS | CESIUM 131 | POINT SOURCES | RADIOLOGY AND NUCLEAR MEDICINE | WATER | PROSTATE | MAMMARY GLANDS | MONTE CARLO METHOD | BIOMEDICAL RADIOGRAPHY | ALGORITHMS | SIMULATION | PHOTOELECTRIC EFFECT | BRACHYTHERAPY
Journal Article
52.