MRI-Derived 3-D-Printed Breast Phantom for Microwave Breast Imaging Validation

Burfeindt, Matthew J.; Colgan, Timothy J.; Mays, R. Owen; Shea, Jacob D.; Behdad, Nader; Veen, B.D. Van; Hagness, Susan C.

doi:10.1109/lawp.2012.2236293

Cited by 156 publications

(86 citation statements)

References 18 publications

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“…However plastic is to rigid to match the mechanical properties and heterogeneity can only be achieved in combination with other TMMs. The plastic model was characterized over the frequency range of 500 MHz to 3.50 GHz and displayed a effective conductivity and a dielectric constant lower than the values recorded by Lazebnik et al [3], [16].…”

Section: -D Printedmentioning

confidence: 73%

“…In 2012, Burfeindt et al [16] used MRI-derived data to build a phantom that featured several cavities, representing glandular structures among adipose tissue. Those excavations were filled with a mixture of deionized water and Triton X100 surfactant to gain an appropriate dielectric contrast between the fatty tissue-mimicking plastic and fibroid-glandular tissue [16]. Since MRI images from a real patient were the basis of the computer model, the resulting breast phantom was anatomical very accurate, especially in perspective of the inner structures.…”

Section: -D Printedmentioning

confidence: 99%

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Experimental phantom for contrast enhanced microwave breast cancer detection based on 3D-printing technology

Moll

Wörtge

Byrne³

et al. 2016

2016 10th European Conference on Antennas and Propagation (EuCAP)

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Section: -D Printedmentioning

confidence: 73%

Section: -D Printedmentioning

confidence: 99%

Experimental phantom for contrast enhanced microwave breast cancer detection based on 3D-printing technology

Moll

Wörtge

Byrne³

et al. 2016

2016 10th European Conference on Antennas and Propagation (EuCAP)

View full text Add to dashboard Cite

“…3D printer generated thorax phantom based on CT images, with a tumor for radiation dosimetry. It was also developed with plastic and filled with tissue substitute materials [46].…”

Section: Discussionmentioning

confidence: 99%

“…Therefore it is only possible to build anatomical phantoms for structural images, non-functional, which does not reveal physiological activities on the tissue or organ [46][47][48]. With the limited choices of available plastics to use on 3D printers, it could be employed Hounsfield Units to select the closest material as an equivalent tissue one [47].…”

Section: Discussionmentioning

confidence: 99%

Anthropomorphic Phantoms - Potential for More Studies and Training in Radiology

Ramos¹,

Thomas²,

Berdeguez³

et al. 2017

IJRRT

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Anthropomorphic phantoms are used for the assessment of image quality and to simulate a medical procedure. They can be likewise developed for training and teaching for all modalities of imaging. Phantoms built from tissue-equivalent materials provide a physical representation of the anatomy of the human body and attenuation characteristics, allowing researchers to calculate absorbed organ doses, improving treatments effectiveness and protecting healthy tissues. Nowadays, physical phantoms have been used as a comparison to computational models for validation of Monte Carlo codes, which are computational phantoms. The more complex the tissue is structured, the more difficult it gets to design the phantom. With the development of 3D printers, new phantoms can be built from medical imaging. However, current 3D printers do not use a wide variety of materials, so it is not possible yet to create phantoms for functional imaging. Studies must be performed to optimize current imaging techniques and elevate their accuracy, which would provide visual, practical, hands-on training of the medical staff, with real-world simulations, ideally patient-specific. This technological advance should be made with physical and computational phantoms in parallel since validation has a high value to the reliability of this scientific method. When it comes to radiation protection of patients and staff, new anthropomorphic phantoms could also provide data for new dosimetry and radiation protection studies, serving as a foundation for the progress of radiological safety throughout the world.

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“…The model, a realistic MRI-derived numerical phantom from the University of WisconsinMadison UWCEM Numerical Breast Phantom Repository [31,32], has been converted to an FEM model shown in Fig. 9.…”

Section: A Practical Example Of a Forward Solution For Biomedical Micmentioning

confidence: 99%

The Time-Harmonic Discontinuous Galerkin Method as a Robust Forward Solver for Microwave Imaging Applications

Jeffrey¹,

Geddert²,

Brown³

et al. 2015

PIER

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Abstract-Novel microwave imaging systems require flexible forward solvers capable of incorporating arbitrary boundary conditions and inhomogeneous background constitutive parameters. In this work we focus on the implementation of a time-harmonic Discontinuous Galerkin Method (DGM) forward solver with a number of features that aim to benefit tomographic microwave imaging algorithms: locally varying high-order polynomial field expansions, locally varying high-order representations of the complex constitutive parameters, and exact radiating boundary conditions. The DGM formulated directly from Maxwell's curl equations facilitates including both electric and magnetic contrast functions, the latter being important when considering quantitative imaging with magnetic contrast agents. To improve forward solver performance we formulate the DGM for time-harmonic electric and magnetic vector wave equations driven by both electric and magnetic sources. Sufficient implementation details are provided to permit existing DGM codes based on nodal expansions of Maxwell's curl equations to be converted to the wave equation formulations. Results are shown to validate the DGM forward solver framework for transverse magnetic problems that might typically be found in tomographic imaging systems, illustrating how high-order expansions of the constitutive parameters can be used to improve forward solver performance.

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MRI-Derived 3-D-Printed Breast Phantom for Microwave Breast Imaging Validation

Cited by 156 publications

References 18 publications

Experimental phantom for contrast enhanced microwave breast cancer detection based on 3D-printing technology

Experimental phantom for contrast enhanced microwave breast cancer detection based on 3D-printing technology

Anthropomorphic Phantoms - Potential for More Studies and Training in Radiology

The Time-Harmonic Discontinuous Galerkin Method as a Robust Forward Solver for Microwave Imaging Applications

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