Measurement of the linear attenuation coefficient of breast tissues using polienergetic x-ray for energies from 12 to 50 keV and a silicon dispersive detector

In this work we obtained experimental linear attenuation coefficients, at mammography energy range (12–50 keV), for 57 breast tissue samples, previously classified as adipose tissue (17), glandular tissue (9) or invasive ductal carcinoma (IDC, grades 1 (3), 2 (12) or 3 (16)). The density of those sa...

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Bibliographic Details
Published in:Radiation physics and chemistry (Oxford, England : 1993) England : 1993), 2020-02, Vol.167, p.108226, Article 108226
Main Authors: Soares, L.D.H., Gobo, M.S.S., Poletti, M.E.
Format: Article
Language:English
Subjects:
Adipose tissue
Attenuation coefficients
Breast tissue
Chemical composition
Collimation
Collimators
Density
Linear attenuation coefficient
Polienergetic x-ray
Samples
Silicon
Statistical analysis
Statistical methods
Timber industry
Tungsten
X ray tubes
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Summary:In this work we obtained experimental linear attenuation coefficients, at mammography energy range (12–50 keV), for 57 breast tissue samples, previously classified as adipose tissue (17), glandular tissue (9) or invasive ductal carcinoma (IDC, grades 1 (3), 2 (12) or 3 (16)). The density of those samples was measured using the Archimedes Principle. A polienergetic narrow beam was obtained using a tungsten anode x-ray tube, collimators (before and after the sample) and silicon drift detector. The linear attenuation coefficient of known composition materials was obtained to validate the experimental setup, showing differences up to 3%, lower than the uncertainties of the measurements (4%). The density of the samples was compared with previous published data. Our results show that the density of IDC tissue increases for higher grades. The variability of the linear attenuation coefficient was also studied, for different regions of the same sample (4%) and for each sample group (18–25%). The elemental composition of the tissues is the main responsible for the group variability. Analyzing the mean results for the different groups, the adipose tissue presents the lowest linear attenuation coefficient, then the glandular tissue, the IDC 1, IDC 2 and IDC 3 being the largest. A statistical analysis was performed on the linear attenuation coefficient of the tissue groups. Adipose tissue group was statistically different from the other groups of tissues, for all the energy interval. There was no statistical difference of the glandular tissue group from any of the IDC groups, for all the energy interval, due to the variability in density and elemental composition. The group of IDC grade 2 was not statistically different from the IDC grade 3 group, however there is a tendency that the linear attenuation coefficient of IDC grade 3 is slightly higher than the IDC grade 2 one. •Linear attenuation coefficients (μ) of breast tissues were experimentally obtained.•The adopted methodological procedure allowed minimizing uncertainties.•The variability within a tissue group depends mainly on its elemental composition.•Different Grades of Invasive Ductal Carcinomas (IDC) were studied.•The μ from IDCs of Grade 3 is higher than those from other IDC grades.
ISSN:0969-806X
1879-0895
DOI:10.1016/j.radphyschem.2019.03.030