The purpose of this study is to compare the imaging performance of an investigational breast computed tomography (CT) scanner, built at UC Davis, with that of an FDA-Approved breast tomosynthesis scanner (capable of producing standard 2-D mammography and 3-D tomosynthesis images), built by Hologic, Incorporated, in a group of patients with suspected breast cancer.
The primary aim of this study is the comparison of Beta values of several different CT and Tomosynthesis views (Beta of CT Sagittal View, Beta of CT Coronal View, Beta of CT Axial View, Beta of Tomosynthesis Craniocaudal View, Beta of Tomosynthesis Medial Lateral Oblique View). Lower Beta values correspond to better image quality (less noise, increased cancer detection).
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
DIAGNOSTIC
Masking
NONE
Enrollment
23
The breast is positioned and compressed the same way it is in a conventional mammogram using a compression paddle device. The subject will be instructed to hold their breath and not move during the 7- second 3-D tomosynthesis acquisition. The affected breast is positioned with MLO compression. The radiation dose levels for each scan are equivalent to mammography
CT scanning will be performed before and after I.V. iodine contrast injection. The subject will lie prone on a large table (which is covered by a foam pad), and she will place the breast to be scanned in a small hole in that tabletop. The hole is surrounded by a soft neoprene "hammock," which will allow the subject's entire upper torso to slump into the scan plane of the device. After positioning of the affected breast by a female mammography technologist, the subject will be instructed to hold their breath for 16 seconds and the pre-contrast scan will commence. There will be no breast compression. Other than the sound of the relatively noisy x-ray system in the room, the subject will not feel or sense any aspect of this scan.
UC Davis Medical Center
Sacramento, California, United States
Beta of CT Coronal View
frequency range corresponding to noise power spectrum (NPS) where beta = NPS(f) = af\^-B. beta is calculated as noise corresponding to frequency. The values of the exponent, beta, range from 1.5 to 3.5 Lower Beta values correspond to better image quality (less noise, increased cancer detection).
Time frame: Day 1
Beta of CT Sagittal View
frequency range corresponding to noise power spectrum (NPS) where beta = NPS(f) = af\^-B. beta is calculated as noise corresponding to frequency. The values of the exponent, beta, range from 1.5 to 3.5 Lower Beta values correspond to better image quality (less noise, increased cancer detection).
Time frame: Day 1
Beta of CT Axial View
frequency range corresponding to noise power spectrum (NPS) where beta = NPS(f) = af\^-B. beta is calculated as noise corresponding to frequency. The values of the exponent, beta, range from 1.5 to 3.5 Lower Beta values correspond to better image quality (less noise, increased cancer detection).
Time frame: Day 1
Beta of Tomosynthesis Craniocaudal View
frequency range corresponding to noise power spectrum (NPS) where beta = NPS(f) = af\^-B. beta is calculated as noise corresponding to frequency. The values of the exponent, beta, range from 1.5 to 3.5 Lower Beta values correspond to better image quality (less noise, increased cancer detection).
Time frame: Day 1
Beta of Tomosynthesis Medial Lateral Oblique View
frequency range corresponding to noise power spectrum (NPS) where beta = NPS(f) = af\^-B. beta is calculated as noise corresponding to frequency. The values of the exponent, beta, range from 1.5 to 3.5 Lower Beta values correspond to better image quality (less noise, increased cancer detection).
Time frame: Day 1
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