Synthetic breast phantoms from patient based eigenbreasts

Sturgeon, Gregory M.; Park, Subok; Segars, W. Paul; Lo, Joseph Y.

doi:10.1002/mp.12579

Cited by 11 publications

(9 citation statements)

References 37 publications

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“…In a study at Duke University, 41,55 a population of 224 breast phantoms was produced based on in vivo BCT data for imaging research acquired at University of California Davis. There is a difference in the number of produced phantoms because in the work of Erickson they used 184 unilateral (left or right) breast data from 184 different subjects, and 40 BCT volumes from 20 subjects.…”

Section: Discussionmentioning

confidence: 99%

Dataset of patient‐derived digital breast phantoms for in silico studies in breast computed tomography, digital breast tomosynthesis, and digital mammography

et al. 2021

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Purpose: To present a dataset of computational digital breast phantoms derived from high-resolution three-dimensional (3D) clinical breast images for the use in virtual clinical trials in two-dimensional (2D) and 3D x-ray breast imaging. Acquisition and validation methods: Uncompressed computational breast phantoms for investigations in dedicated breast CT (BCT) were derived from 150 clinical 3D breast images acquired via a BCT scanner at UC Davis (California, USA). Each image voxel was classified in one out of the four main materials presented in the field of view: fibroglandular tissue, adipose tissue, skin tissue, and air. For the image classification, a semi-automatic software was developed. The semi-automatic classification was compared via manual glandular classification performed by two researchers. A total of 60 compressed computational phantoms for virtual clinical trials in digital mammography (DM) and digital breast tomosynthesis (DBT) were obtained from the corresponding uncompressed phantoms via a software algorithm simulating the compression and the elastic deformation of the breast, using the tissue's elastic coefficient. This process was evaluated in terms of glandular fraction modification introduced by the compression procedure. The generated cohort of 150 uncompressed computational breast phantoms presented a mean value of the glandular fraction by mass of 12.3%; the average diameter of the breast evaluated at the center of mass was 105 mm. Despite the slight differences between the two manual segmentations, the resulting glandular tissue segmentation did not consistently differ from that obtained via the semi-automatic classification. The difference between the glandular fraction by mass before and after the compression was 2.1% on average. The 60 compressed phantoms presented an average glandular fraction by mass of 12.1% and an average compressed thickness of 61 mm. Data format and access: The generated digital breast phantoms are stored in DICOM files. Image voxels can present one out of four values representing the different classified materials: 0 for the air, 1 for the adipose tissue, 2 for the glandular tissue, and 3 for the skin tissue. The generated computational phantoms datasets were stored in the Zenodo public repository for research purposes (http://

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Section: Discussionmentioning

confidence: 99%

Dataset of patient‐derived digital breast phantoms for in silico studies in breast computed tomography, digital breast tomosynthesis, and digital mammography

et al. 2021

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“…Recent efforts have established that computational methods can model many of the characteristics of breast anatomy and pathology 10,11 as well as the physics of imaging. 12,13 In addition, image interpretation algorithms have been shown to track the performance of human readers for specific visual tasks.…”

Section: Introductionmentioning

confidence: 99%

“…In the last decade, powerful, efficient, and open-source radiation imaging system simulation tools have become freely available, allowing for a greater understanding of design choices. Recent efforts have established that computational methods can model many of the characteristics of breast anatomy and pathology as well as the physics of imaging . In addition, image interpretation algorithms have been shown to track the performance of human readers for specific visual tasks .…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Digital Breast Tomosynthesis as Replacement of Full-Field Digital Mammography Using an In Silico Imaging Trial

et al. 2018

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Key Points Question Can in silico imaging trials play a role in the evaluation of new medical imaging systems? Findings This diagnostic study used computer-simulated imaging of 2986 synthetic image–based virtual patients to compare digital mammography and digital breast tomosynthesis and found an improved lesion detection performance favoring tomosynthesis for all breast sizes and lesion types. The increased performance for tomosynthesis was consistent with results from a comparative trial using human patients and radiologists. Meaning The study’s findings suggest that in silico imaging trials and imaging system computer simulation tools can in some cases be considered viable sources of evidence for the regulatory evaluation of imaging devices.

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“…Segmentation of CT images allows for accurate representation of large scale breast anatomy, but CT image resolution does not currently allow for segmentation of fine structures such as ligaments that are visible in higher resolution mammographic and DBT systems. The size of the virtual population is also limited to the number of CT data sets available, though some efforts have been made to solve this problem with eigenfunction analysis [194]. Procedural generation on the other hand allows for a virtual patient population of arbitrary size at an arbitrary voxel resolution, but current phantoms generated in this manner have limitations in terms of realism.…”

Section: Applications Of Realistic Computational Human Phantoms In Bimentioning

confidence: 99%

Advances in Computational Human Phantoms and Their Applications in Biomedical Engineering—A Topical Review

Kainz

Neufeld

Bolch

et al. 2019

IEEE Trans. Radiat. Plasma Med. Sci.

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Over the past decades, significant improvements have been made in the field of computational human phantoms (CHPs) and their applications in biomedical engineering. Their sophistication has dramatically increased. The very first CHPs were composed of simple geometric volumes, e.g., cylinders and spheres, while current CHPs have a high resolution, cover a substantial range of the patient population, have high anatomical accuracy, are poseable, morphable, and are augmented with various details to perform functionalized computations. Advances in imaging techniques and semi-automated segmentation tools allow fast and personalized development of CHPs. These advances open the door to quickly develop personalized CHPs, inherently including the disease of the patient. Because many of these CHPs are increasingly providing data for regulatory submissions of various medical devices, the validity, anatomical accuracy, and availability to cover the entire patient population is of utmost importance. The article is organized into two main sections: the first section reviews the different modeling techniques used to create CHPs, whereas the second section discusses various applications of CHPs in biomedical engineering. Each topic gives an overview, a brief history, recent developments, and an outlook into the future.

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Synthetic breast phantoms from patient based eigenbreasts

Cited by 11 publications

References 37 publications

Dataset of patient‐derived digital breast phantoms for in silico studies in breast computed tomography, digital breast tomosynthesis, and digital mammography

Dataset of patient‐derived digital breast phantoms for in silico studies in breast computed tomography, digital breast tomosynthesis, and digital mammography

Evaluation of Digital Breast Tomosynthesis as Replacement of Full-Field Digital Mammography Using an In Silico Imaging Trial

Advances in Computational Human Phantoms and Their Applications in Biomedical Engineering—A Topical Review

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