Your search keyword '"V F Cassola"' showing total 9 results

1. PATIENT-SPECIFIC ORGAN DOSES FROM PEDIATRIC HEAD CT EXAMINATIONS

Author

V F Cassola, William Jaramillo Garzón, and D F A Aldana

Subjects

Adolescent, Computed tomography, Radiation Dosage, Imaging phantom, 030218 nuclear medicine & medical imaging, Red bone marrow, 03 medical and health sciences, 0302 clinical medicine, Conversion coefficients, Medicine, Humans, Radiology, Nuclear Medicine and imaging, Child, Radiometry, Radiation, Radiological and Ultrasound Technology, medicine.diagnostic_test, business.industry, Phantoms, Imaging, Public Health, Environmental and Occupational Health, Infant, Newborn, Infant, General Medicine, Patient specific, Clinical routine, 030220 oncology & carcinogenesis, Absorbed dose, Child, Preschool, business, Nuclear medicine, Tomography, X-Ray Computed, Head, Monte Carlo Method

Abstract

The aim of this work was to estimate patient’s organ absorbed doses from pediatric helical head computed tomography (CT) examinations using the Size-Specific Dose Estimate (SSDE) methodology and to determine organ dose to SSDE conversion coefficients for clinical routine. Patient-specific organ and tissue absorbed doses from 139 Head CT scans performed in pediatric patients from 0 to 15 years old in a Public Hospital in Tunja, Colombia were estimated. The calculations were made through Monte Carlo simulations, based on patient-specific information, dosimetric CT quantities (CTDIvol, DLP) and age-specific computational human phantoms matched to patients on the basis of gender and size. SSDE showed to be a good quantity for estimate patient-specific organ doses from pediatric head CT examinations when appropriate phantom’s attenuation-based size metrics are chosen to match for any patient size. Strong correlations between absorbed dose and SSDE were found for skin (R2 = 0.99), brain (R2 = 0.98) and eyes (R2 = 0.97), respectively. Besides, a good correlation between SSDE and absorbed dose to the red bone marrow (tissue extended outside the scan coverage) was observed (R2 = 0.94). SSDE-to-organ-dose conversion coefficients obtained in this study provide a practical way to estimate patient-specific organ head CT doses.

Published

2020

2. Development of newborn and 1-year-old reference phantoms based on polygon mesh surfaces

Author

C. A. B. de Oliveira Lira, K Robson Brown, Helen J. Khoury, V F Cassola, J W Vieira, R Kramer, and V J de Melo Lima

Subjects

Male, Models, Anatomic, Pathology, medicine.medical_specialty, Medullary cavity, Surface Properties, Radiation Dosage, computer.software_genre, Skeletal tissue, Imaging, Three-Dimensional, Radiation Protection, Voxel, medicine, Humans, Dosimetry, Computer Simulation, Polygon mesh, Radiometry, Waste Management and Disposal, Phantoms, Imaging, business.industry, Infant, Newborn, Public Health, Environmental and Occupational Health, Infant, General Medicine, Anatomy, Tissue equivalent, Trabecular bone, medicine.anatomical_structure, Female, Cortical bone, business, computer

Abstract

The purpose of this study is the development of paediatric reference phantoms for newborn and 1-year-old infants to be used for the calculation of organ and tissue equivalent doses in radiation protection. The study proposes a method for developing anatomically highly sophisticated paediatric phantoms without using medical images. The newborn and 1-year-old hermaphrodite phantoms presented here were developed using three-dimensional (3D) modelling software applied to anatomical information taken from atlases, textbooks and images provided by the Department of Anatomy of the Federal University of Pernambuco, Brazil. The method uses polygon mesh surfaces to model body contours, the shape of organs as well as their positions and orientations in the human body. Organ and tissue masses agree with corresponding data given by the International Commission on Radiological Protection for newborn and 1-year-old reference children. Bones were segmented into cortical bone, spongiosa, medullary marrow and cartilage to allow for the use of μCT images of trabecular bone for skeletal dosimetry. Anatomical results show 3D images of the phantoms' surfaces, organs and skeletons, as well as tables with organ and tissue masses or skeletal tissue volumes. Dosimetric results present comparisons of organ and tissue absorbed doses or specific absorbed fractions between the newborn and 1-year-old phantoms and corresponding data for other paediatric stylised or voxel phantoms. Most differences were found to be below 10%.

Published

2013

3. Mathematical modelling of scanner-specific bowtie filters for Monte Carlo CT dosimetry

Author

V F Cassola, Marcos Ely Almeida Andrade, M W C de Araújo, Helen J. Khoury, David J. Brenner, and R Kramer

Subjects

Scanner, Tomography Scanners, X-Ray Computed, Computer science, Image quality, Monte Carlo method, Radiation Dosage, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Optics, Cylinder, Dosimetry, Humans, Radiology, Nuclear Medicine and imaging, Radiological and Ultrasound Technology, business.industry, Phantoms, Imaging, Filter factor, Filter (signal processing), Models, Theoretical, Mockup, 030220 oncology & carcinogenesis, Tomography, business, Nuclear medicine, Tomography, X-Ray Computed, Monte Carlo Method, Beam (structure), Algorithms, Filtration

Abstract

The purpose of bowtie filters in CT scanners is to homogenize the x-ray intensity measured by the detectors in order to improve the image quality and at the same time to reduce the dose to the patient because of the preferential filtering near the periphery of the fan beam. For CT dosimetry, especially for Monte Carlo calculations of organ and tissue absorbed doses to patients, it is important to take the effect of bowtie filters into account. However, material composition and dimensions of these filters are proprietary. Consequently, a method for bowtie filter simulation independent of access to proprietary data and/or to a specific scanner would be of interest to many researchers involved in CT dosimetry. This study presents such a method based on the weighted computer tomography dose index, CTDIw, defined in two cylindrical PMMA phantoms of 16 cm and 32 cm diameter. With an EGSnrc-based Monte Carlo (MC) code, ratios CTDIw/CTDI100,a were calculated for a specific CT scanner using PMMA bowtie filter models based on sigmoid Boltzmann functions combined with a scanner filter factor (SFF) which is modified during calculations until the calculated MC CTDIw/CTDI100,a matches ratios CTDIw/CTDI100,a, determined by measurements or found in publications for that specific scanner. Once the scanner-specific value for an SFF has been found, the bowtie filter algorithm can be used in any MC code to perform CT dosimetry for that specific scanner. The bowtie filter model proposed here was validated for CTDIw/CTDI100,a considering 11 different CT scanners and for CTDI100,c, CTDI100,p and their ratio considering 4 different CT scanners. Additionally, comparisons were made for lateral dose profiles free in air and using computational anthropomorphic phantoms. CTDIw/CTDI100,a determined with this new method agreed on average within 0.89% (max. 3.4%) and 1.64% (max. 4.5%) with corresponding data published by CTDosimetry (www.impactscan.org) for the CTDI HEAD and BODY phantoms, respectively. Comparison with results calculated using proprietary data for the PHILIPS Brilliance 64 scanner showed agreement on average within 2.5% (max. 5.8%) and with data measured for that scanner within 2.1% (max. 3.7%). Ratios of CTDI100,c/CTDI100, p for this study and corresponding data published by CTDosimetry (www.impactscan.org) agree on average within about 11% (max. 28.6%). Lateral dose profiles calculated with the proposed bowtie filter and with proprietary data agreed within 2% (max. 5.9%), and both calculated data agreed within 5.4% (max. 11.2%) with measured results. Application of the proposed bowtie filter and of the exactly modelled filter to human phantom Monte Carlo calculations show agreement on the average within less than 5% (max. 7.9%) for organ and tissue absorbed doses.

Published

2017

4. Skeletal dosimetry based on µCT images of trabecular bone: update and comparisons

Author

Helen J. Khoury, K Robson Brown, J W Vieira, R Kramer, C. A. B. de Oliveira Lira, and V F Cassola

Subjects

Adult, Materials science, Radiological and Ultrasound Technology, Medullary cavity, Phantoms, Imaging, business.industry, Soft tissue, X-Ray Microtomography, Radiation, Bone and Bones, Imaging phantom, medicine.anatomical_structure, Absorbed dose, medicine, Humans, Dosimetry, Female, Radiology, Nuclear Medicine and imaging, Cortical bone, Tomography, Radiometry, Nuclear medicine, business

Abstract

Two skeletal dosimetry methods using µCT images of human bone have recently been developed: the paired-image radiation transport (PIRT) model introduced by researchers at the University of Florida (UF) in the US and the systematic–periodic cluster (SPC) method developed by researchers at the Federal University of Pernambuco in Brazil. Both methods use µCT images of trabecular bone (TB) to model spongiosa regions of human bones containing marrow cavities segmented into soft tissue volumes of active marrow (AM), trabecular inactive marrow and the bone endosteum (BE), which is a 50 µm thick layer of marrow on all TB surfaces and on cortical bone surfaces next to TB as well as inside the medullary cavities. With respect to the radiation absorbed dose, the AM and the BE are sensitive soft tissues for the induction of leukaemia and bone cancer, respectively. The two methods differ mainly with respect to the number of bone sites and the size of the µCT images used in Monte Carlo calculations and they apply different methods to simulate exposure from radiation sources located outside the skeleton. The PIRT method calculates dosimetric quantities in isolated human bones while the SPC method uses human bones embedded in the body of a phantom which contains all relevant organs and soft tissues. Consequently, the SPC method calculates absorbed dose to the AM and to the BE from particles emitted by radionuclides concentrated in organs or from radiation sources located outside the human body in one calculation step. In order to allow for similar calculations of AM and BE absorbed doses using the PIRT method, the so-called dose response functions (DRFs) have been developed based on absorbed fractions (AFs) of energy for electrons isotropically emitted in skeletal tissues. The DRFs can be used to transform the photon fluence in homogeneous spongiosa regions into absorbed dose to AM and BE. This paper will compare AM and BE AFs of energy from electrons emitted in skeletal tissues calculated with the SPC and the PIRT method and AM and BE absorbed doses and AFs calculated with PIRT-based DRFs and with the SPC method. The results calculated with the two skeletal dosimetry methods agree well if one takes the differences between the two models properly into account. Additionally, the SPC method will be updated with larger µCT images of TB.

Published

2012

5. Electron absorbed fractions of energy andS-values in an adult human skeleton based on µCT images of trabecular bone

Author

Richard B. Richardson, C. A. B. de Oliveira Lira, R Kramer, J W Vieira, V F Cassola, K Robson Brown, and Helen J. Khoury

Subjects

Adult, Materials science, Electrons, Radiation Dosage, Bone and Bones, Ionizing radiation, Bone Marrow, medicine, Humans, Dosimetry, Radiology, Nuclear Medicine and imaging, Endosteum, Radiological and Ultrasound Technology, Isotope, Phantoms, Imaging, business.industry, Soft tissue, Human skeleton, medicine.anatomical_structure, Mockup, Absorbed dose, Tomography, X-Ray Computed, Nuclear medicine, business, Algorithms, Biomedical engineering

Abstract

When the human body is exposed to ionizing radiation, among the soft tissues at risk are the active marrow (AM) and the bone endosteum (BE) located in tiny, irregular cavities of trabecular bone. Determination of absorbed fractions (AFs) of energy or absorbed dose in the AM and the BE represent one of the major challenges of dosimetry. Recently, at the Department of Nuclear Energy at the Federal University of Pernambuco, a skeletal dosimetry method based on µCT images of trabecular bone introduced into the spongiosa voxels of human phantoms has been developed and applied mainly to external exposure to photons. This study uses the same method to calculate AFs of energy and S-values (absorbed dose per unit activity) for electron-emitting radionuclides known to concentrate in skeletal tissues. The modelling of the skeletal tissue regions follows ICRP110, which defines the BE as a 50 µm thick sub-region of marrow next to the bone surfaces. The paper presents mono-energetic AFs for the AM and the BE for eight different skeletal regions for electron source energies between 1 keV and 10 MeV. The S-values are given for the beta emitters (14)C, (59)Fe, (131)I, (89)Sr, (32)P and (90)Y. Comparisons with results from other investigations showed good agreement provided that differences between methodologies and trabecular bone volume fractions were properly taken into account. Additionally, a comparison was made between specific AFs of energy in the BE calculated for the actual 50 µm endosteum and the previously recommended 10 µm endosteum. The increase in endosteum thickness leads to a decrease of the endosteum absorbed dose by up to 3.7 fold when bone is the source region, while absorbed dose increases by ∼20% when the beta emitters are in marrow.

Published

2011

6. FASH and MASH: female and male adult human phantoms based on polygon mesh surfaces: I. Development of the anatomy

Author

Helen J. Khoury, V F Cassola, R Kramer, and V J de Melo Lima

Subjects

Adult, Male, Models, Anatomic, Sex Characteristics, Radiological and Ultrasound Technology, Phantoms, Imaging, Computer science, Equivalent dose, Anatomy, computer.software_genre, Models, Biological, Atlases as Topic, Voxel, Cadaver, Humans, Computer Simulation, Female, Radiology, Nuclear Medicine and imaging, Polygon mesh, Anatomy, Artistic, computer, Software

Abstract

Among computational models, voxel phantoms based on computer tomographic (CT), nuclear magnetic resonance (NMR) or colour photographic images of patients, volunteers or cadavers have become popular in recent years. Although being true to nature representations of scanned individuals, voxel phantoms have limitations, especially when walled organs have to be segmented or when volumes of organs or body tissues, like adipose, have to be changed. Additionally, the scanning of patients or volunteers is usually made in supine position, which causes a shift of internal organs towards the ribcage, a compression of the lungs and a reduction of the sagittal diameter especially in the abdominal region compared to the regular anatomy of a person in the upright position, which in turn can influence organ and tissue absorbed or equivalent dose estimates. This study applies tools developed recently in the areas of computer graphics and animated films to the creation and modelling of 3D human organs, tissues, skeletons and bodies based on polygon mesh surfaces. Female and male adult human phantoms, called FASH (Female Adult meSH) and MASH (Male Adult meSH), have been designed using software, such as MakeHuman, Blender, Binvox and ImageJ, based on anatomical atlases, observing at the same time organ masses recommended by the International Commission on Radiological Protection for the male and female reference adult in report no 89. 113 organs, bones and tissues have been modelled in the FASH and the MASH phantoms representing locations for adults in standing posture. Most organ and tissue masses of the voxelized versions agree with corresponding data from ICRP89 within a margin of 2.6%. Comparison with the mesh-based male RPI_AM and female RPI_AF phantoms shows differences with respect to the material used, to the software and concepts applied, and to the anatomies created.

Published

2009

7. FASH and MASH: female and male adult human phantoms based on polygon mesh surfaces: II. Dosimetric calculations

Author

V F Cassola, Helen J. Khoury, R Kramer, V J de Melo Lima, K Robson Brown, and J W Vieira

Subjects

Adult, Male, Models, Anatomic, Supine position, Posture, Electrons, Radiation Dosage, computer.software_genre, Models, Biological, Imaging phantom, Atlases as Topic, Voxel, Cadaver, Modelling methods, Supine Position, Humans, Medicine, Computer Simulation, Radiology, Nuclear Medicine and imaging, Polygon mesh, Anatomy, Artistic, Photons, Sex Characteristics, Radiological and Ultrasound Technology, Phantoms, Imaging, business.industry, Radiotherapy Planning, Computer-Assisted, Soft tissue, Anatomy, Tissue equivalent, Female, Nuclear medicine, business, Monte Carlo Method, computer, Software

Abstract

Female and male adult human phantoms, called FASH (Female Adult meSH) and MASH (Male Adult meSH), have been developed in the first part of this study using 3D animation software and anatomical atlases to replace the image-based FAX06 and the MAX06 voxel phantoms. 3D modelling methods allow for phantom development independent from medical images of patients, volunteers or cadavers. The second part of this study investigates the dosimetric implications for organ and tissue equivalent doses due to the anatomical differences between the new and the old phantoms. These differences are mainly caused by the supine position of human bodies during scanning in order to acquire digital images for voxel phantom development. Compared to an upright standing person, in image-based voxel phantoms organs are often coronally shifted towards the head and sometimes the sagittal diameter of the trunk is reduced by a gravitational change of the fat distribution. In addition, volumes of adipose and muscle tissue shielding internal organs are sometimes too small, because adaptation of organ volumes to ICRP-based organ masses often occurs at the expense of general soft tissues, such as adipose, muscle or unspecified soft tissue. These effects have dosimetric consequences, especially for partial body exposure, such as in x-ray diagnosis, but also for whole body external exposure and for internal exposure. Using the EGSnrc Monte Carlo code, internal and external exposure to photons and electrons has been simulated with both pairs of phantoms. The results show differences between organ and tissue equivalent doses for the upright standing FASH/MASH and the image-based supine FAX06/MAX06 phantoms of up to 80% for external exposure and up to 100% for internal exposure. Similar differences were found for external exposure between FASH/MASH and REGINA/REX, the reference voxel phantoms of the International Commission on Radiological Protection. Comparison of effective doses for external photon exposure showed good agreement between FASH/MASH and REGINA/REX, but large differences between FASH/MASH and the mesh-based RPI_AM and the RPI_AF phantoms, developed at the Rensselaer Polytechnic Institute (RPI).

Published

2009

8. Development of 5- and 10-year-old pediatric phantoms based on polygon mesh surfaces

Author

V J de Melo, Lima, V F, Cassola, R, Kramer, C A B de Oliveira, Lira, H J, Khoury, and J W, Vieira

Subjects

Male, Models, Anatomic, Imaging, Three-Dimensional, Radiation Protection, Phantoms, Imaging, Surface Properties, Child, Preschool, Humans, Computer Simulation, Female, X-Ray Microtomography, Child, Radiometry

Abstract

The purpose of this study is the development of reference pediatric phantoms for 5- and 10-year-old children to be used for the calculation of organ and tissue equivalent doses in radiation protection.The study proposes a method for developing anatomically highly sophisticated pediatric phantoms without using medical images. The 5- and 10-year-old male and female phantoms presented here were developed using 3D modeling software applied to anatomical information taken from atlases and textbooks. The method uses polygon mesh surfaces to model body contours, the shape of organs as well as their positions, and orientations in the human body. Organ and tissue masses comply with the corresponding data given by the International Commission on Radiological Protection (ICRP) for the 5- and 10-year-old reference children. Bones were segmented into cortical bone, spongiosa, medullary marrow, and cartilage to allow for the use of micro computer tomographic (microCT) images of trabecular bone for skeletal dosimetry.The four phantoms, a male and a female for each age, and their organs are presented in 3D images and their organ and tissue masses in tables which show the compliance of the ICRP reference values. Dosimetric data, calculated for the reference pediatric phantoms by Monte Carlo methods were compared with corresponding data from adult mesh phantoms and pediatric stylized phantoms. The comparisons show reasonable agreement if the anatomical differences between the phantoms are properly taken into account.Pediatric phantoms were developed without using medical images of patients or volunteers for the first time. The models are reference phantoms, suitable for regulatory dosimetry, however, the 3D modeling method can also be applied to medical images to develop patient-specific phantoms.

Published

2011

9. Posture-specific phantoms representing female and male adults in Monte Carlo-based simulations for radiological protection

Author

C A O Brayner, R Kramer, V F Cassola, and Helen J. Khoury

Subjects

Adult, Male, Supine position, Radiography, Monte Carlo method, Posture, Radiation Dosage, Subcutaneous fat, Effective dose (radiation), Radiation Protection, Medicine, Humans, Radiology, Nuclear Medicine and imaging, Left lung, Radiological and Ultrasound Technology, business.industry, Phantoms, Imaging, X-Rays, medicine.anatomical_structure, Organ Specificity, Radiological weapon, Abdomen, Female, business, Nuclear medicine, Monte Carlo Method, Whole-Body Irradiation

Abstract

Does the posture of a patient have an effect on the organ and tissue absorbed doses caused by x-ray examinations? This study aims to find the answer to this question, based on Monte Carlo (MC) simulations of commonly performed x-ray examinations using adult phantoms modelled to represent humans in standing as well as in the supine posture. The recently published FASH (female adult mesh) and MASH (male adult mesh) phantoms have the standing posture. In a first step, both phantoms were updated with respect to their anatomy: glandular tissue was separated from adipose tissue in the breasts, visceral fat was separated from subcutaneous fat, cartilage was segmented in ears, nose and around the thyroid, and the mass of the right lung is now 15% greater than the left lung. The updated versions are called FASH2_sta and MASH2_sta (sta = standing). Taking into account the gravitational effects on organ position and fat distribution, supine versions of the FASH2 and the MASH2 phantoms have been developed in this study and called FASH2_sup and MASH2_sup. MC simulations of external whole-body exposure to monoenergetic photons and partial-body exposure to x-rays have been made with the standing and supine FASH2 and MASH2 phantoms. For external whole-body exposure for AP and PA projection with photon energies above 30 keV, the effective dose did not change by more than 5% when the posture changed from standing to supine or vice versa. Apart from that, the supine posture is quite rare in occupational radiation protection from whole-body exposure. However, in the x-ray diagnosis supine posture is frequently used for patients submitted to examinations. Changes of organ absorbed doses up to 60% were found for simulations of chest and abdomen radiographs if the posture changed from standing to supine or vice versa. A further increase of differences between posture-specific organ and tissue absorbed doses with increasing whole-body mass is to be expected.

Published

2010