Your search keyword '"Mika Yamamuro"' showing total 14 results

1. The effect of breast density on the missed lesion rate in screening digital mammography determined using an adjustable-density breast phantom tailored to Japanese women.

Author

Mika Yamamuro, Yoshiyuki Asai, Naomi Hashimoto, Nao Yasuda, Yoshiaki Ozaki, Kazunari Ishii, and Yongbum Lee

Subjects

Medicine, Science

Abstract

ObjectiveDespite the high risk of missing lesions in mammography, the missed lesion rate is yet to be clinically established. Further, no breast phantoms with adjustable breast density currently exist. We developed a novel, adjustable-density breast phantom with a composition identical to that of actual breasts, and determined the quantitative relationship between breast density and the missed lesion rate in mammography.MethodsAn original breast phantom consisting of adipose- and fibroglandular-equivalent materials was developed, and a receiver operating characteristic (ROC) study was performed. Breast density, which is the fraction by weight of fibroglandular to total tissue, was adjusted to 25%, 50%, and 75% by arbitrarily mixing the two materials. Microcalcification, mass lesions, and spiculated lesions, each with unique characteristics, were inserted into the phantom. For the above-mentioned fibroglandular densities, 50 positive and 50 negative images for each lesion type were used as case samples for the ROC study. Five certified radiological technologists participated in lesion detection.ResultsThe mass-lesion detection rate, according to the area under the curve, decreased by 18.0% (p = 0.0001, 95% Confidence intervals [CI] = 0.1258 to 0.1822) and 37.8% (p = 0.0003, 95% CI = 0.2453 to 0.4031) for breast densities of 50% and 75%, respectively, compared to that for a 25% breast density. A similar tendency was observed with microcalcification; however, spiculated lesions did not follow this tendency.ConclusionsWe quantified the missed lesion rate in different densities of breast tissue using a novel breast phantom, which is imperative for advancing individualized screening mammography.

Published

2021

2. Development and validation of the surmising model for volumetric breast density using X-ray exposure conditions in digital mammography.

Author

Mika Yamamuro, Yoshiyuki Asai, Takahiro Yamada, Yuichi Kimura, Kazunari Ishii, and Yohan Kondo

Published

2025

3. How to select training data to segment mammary gland region using a deep-learning approach for reliable individualized screening mammography.

Author

Mika Yamamuro, Yoshiyuki Asai, Naomi Hashimoto, Nao Yasuda, Takahiro Yamada, Mitsutaka Nemoto, Yuichi Kimura, Hisashi Handa, Hisashi Yoshida, Koji Abe, Masahiro Tada, Hitoshi Habe, Takashi Nagaoka, Yoshiaki Ozaki, Seiun Nin, Kazunari Ishii, and Yongbum Lee

Published

2021

4. Prediction of glandularity and breast radiation dose from mammography results in Japanese women.

Author

Mika Yamamuro, Yoshiyuki Asai, Koji Yamada, Yoshiaki Ozaki, Masao Matsumoto, and Takamichi Murakami

Published

2019

5. Accurate Quantification of Glandularity and Its Applications with Regard to Breast Radiation Doses and Missed Lesion Rates During Individualized Screening Mammography.

Author

Mika Yamamuro, Kanako Yamada, Yoshiyuki Asai, Koji Yamada, Yoshiaki Ozaki, Masao Matsumoto, and Takamichi Murakami

Published

2016

6. Robustness of a U-net model for different image processing types in segmentation of the mammary gland region

Author

Mika Yamamuro, Yoshiyuki Asai, Naomi Hashimoto, Nao Yasuda, Hiroto Kimura, Takahiro Yamada, Mitsutaka Nemoto, Yuichi Kimura, Hisashi Handa, Hisashi Yoshida, Koji Abe, Masahiro Tada, Hitoshi Habe, Takashi Nagaoka, Seiun Nin, Kazunari Ishii, and Yongbum Lee

Published

2022

7. Utility of U-Net for the objective segmentation of the fibroglandular tissue region on clinical digital mammograms

Author

Mika Yamamuro, Yoshiyuki Asai, Naomi Hashimoto, Nao Yasuda, Hiorto Kimura, Takahiro Yamada, Mitsutaka Nemoto, Yuichi Kimura, Hisashi Handa, Hisashi Yoshida, Koji Abe, Masahiro Tada, Hitoshi Habe, Takashi Nagaoka, Seiun Nin, Kazunari Ishii, and Yohan Kondo

Subjects

Adipose Tissue, Image Processing, Computer-Assisted, Breast, General Nursing, Breast Density, Mammography

Abstract

This study investigates the equivalence or compatibility between U-Net and visual segmentations of fibroglandular tissue regions by mammography experts for calculating the breast density and mean glandular dose (MGD). A total of 703 mediolateral oblique-view mammograms were used for segmentation. Two region types were set as the ground truth (determined visually): (1) one type included only the region where fibroglandular tissue was identifiable (called the ‘dense region’); (2) the other type included the region where the fibroglandular tissue may have existed in the past, provided that apparent adipose-only parts, such as the retromammary space, are excluded (the ‘diffuse region’). U-Net was trained to segment the fibroglandular tissue region with an adaptive moment estimation optimiser, five-fold cross-validated with 400 training and 100 validation mammograms, and tested with 203 mammograms. The breast density and MGD were calculated using the van Engeland and Dance formulas, respectively, and compared between U-Net and the ground truth with the Dice similarity coefficient and Bland–Altman analysis. Dice similarity coefficients between U-Net and the ground truth were 0.895 and 0.939 for the dense and diffuse regions, respectively. In the Bland–Altman analysis, no proportional or fixed errors were discovered in either the dense or diffuse region for breast density, whereas a slight proportional error was discovered in both regions for the MGD (the slopes of the regression lines were −0.0299 and −0.0443 for the dense and diffuse regions, respectively). Consequently, the U-Net and ground truth were deemed equivalent (interchangeable) for breast density and compatible (interchangeable following four simple arithmetic operations) for MGD. U-Net-based segmentation of the fibroglandular tissue region was satisfactory for both regions, providing reliable segmentation for breast density and MGD calculations. U-Net will be useful in developing a reliable individualised screening-mammography programme, instead of relying on the visual judgement of mammography experts.

Published

2022

8. The effect of breast density on the missed lesion rate in screening digital mammography determined using an adjustable-density breast phantom tailored to Japanese women

Author

Yongbum Lee, Kazunari Ishii, Naomi Hashimoto, Yoshiyuki Asai, Mika Yamamuro, Yoshiaki Ozaki, and Nao Yasuda

Subjects

Epidemiology, Physiology, Diagnostic Radiology, Japan, Breast Tumors, Medicine and Health Sciences, Medicine, Breast, skin and connective tissue diseases, Early Detection of Cancer, Breast Density, Multidisciplinary, medicine.diagnostic_test, Phantoms, Imaging, Radiology and Imaging, Cancer Risk Factors, Bone Imaging, Oncology, Physiological Parameters, Female, Microcalcification, medicine.symptom, Anatomy, Cancer Screening, Research Article, Mammography, Digital mammography, Imaging Techniques, Science, Breast Neoplasms, Research and Analysis Methods, Imaging phantom, Lesion, Breast cancer, Signs and Symptoms, Diagnostic Medicine, Breast Cancer, Cancer Detection and Diagnosis, Humans, Receiver operating characteristic, business.industry, Body Weight, Reproductive System, Cancers and Neoplasms, Biology and Life Sciences, medicine.disease, Confidence interval, X-Ray Radiography, Medical Risk Factors, Lesions, Clinical Medicine, business, Nuclear medicine, Breast Tissue

Abstract

ObjectiveDespite the high risk of missing lesions in mammography, the missed lesion rate is yet to be clinically established. Further, no breast phantoms with adjustable breast density currently exist. We developed a novel, adjustable-density breast phantom with a composition identical to that of actual breasts, and determined the quantitative relationship between breast density and the missed lesion rate in mammography.MethodsAn original breast phantom consisting of adipose- and fibroglandular-equivalent materials was developed, and a receiver operating characteristic (ROC) study was performed. Breast density, which is the fraction by weight of fibroglandular to total tissue, was adjusted to 25%, 50%, and 75% by arbitrarily mixing the two materials. Microcalcification, mass lesions, and spiculated lesions, each with unique characteristics, were inserted into the phantom. For the above-mentioned fibroglandular densities, 50 positive and 50 negative images for each lesion type were used as case samples for the ROC study. Five certified radiological technologists participated in lesion detection.ResultsThe mass-lesion detection rate, according to the area under the curve, decreased by 18.0% (p= 0.0001, 95% Confidence intervals [CI] = 0.1258 to 0.1822) and 37.8% (p= 0.0003, 95% CI = 0.2453 to 0.4031) for breast densities of 50% and 75%, respectively, compared to that for a 25% breast density. A similar tendency was observed with microcalcification; however, spiculated lesions did not follow this tendency.ConclusionsWe quantified the missed lesion rate in different densities of breast tissue using a novel breast phantom, which is imperative for advancing individualized screening mammography.

Published

2021

9. Deep learning-based segmentation of mammary gland region in digital mammograms of scattered mammary glands and fatty breasts

Author

Yoshiyuki Asai, Yougbum Lee, Tatsuo Konishi, Mika Yamamuro, Yoshiaki Ozaki, Kenta Sakaguchi, Koji Yamada, Naomi Hashimoto, Kazunari Ishii, and Nao Yasuda

Subjects

medicine.anatomical_structure, Sørensen–Dice coefficient, medicine.diagnostic_test, Mammary gland, medicine, Mammography, Segmentation, Anatomy, Image segmentation, Biology

Abstract

This study is aimed to automatically segment mammary gland region into scattered mammary glands and fatty breasts using deep learning method. Total 433 mediolateral oblique-view mammograms of Japanese women were collected and confirmed for scattered mammary glands or fatty breasts; using BI-RADS’s classification. First, manually contoured mammary gland regions were determined for all mammograms as ground truths by three certified radiological technologists. Second, the U-net model was employed to segment the mammary gland region automatically. This model is a type of convolutional neural network (CNN) mainly aimed at medical image segmentation. The segmentation accuracies were assessed based on five criteria, Dice coefficients, breast densities, mean gray values, centroids, and sizes of mammary gland region. The Dice coefficient was 0.915. The mean size of mammary gland regions obtained by the Unet was 8.7% larger than that of the ground truths. The mean centroid coordinates of mammary gland regions by the U-net were shifted 1.6 and 5.4 mm on average in mediolateral and craniocaudal directions, respectively from ground truths. The mean gray value of mammary gland regions obtained by the U-net was only 0.4% higher compared with ground truths. The resultant difference was 0.4% on average in breast densities between ground truths and the segmented mammary gland regions. We found significant similarity in the ground truths and the data generated by deep learning on all the parameters, thereby attesting the efficacy of this method for segmenting the mammary gland regions of not only the dense breasts but also the scattered mammary gland- and fatty- breasts.

Published

2020

10. Effectiveness of high-luminance display monitors in digital mammography

Author

Yongbum Lee, Kazunari Ishii, Naomi Hashimoto, Nao Yasuda, Yoshiyuki Asai, Mika Yamamuro, Koji Yamada, and Yoshiaki Ozaki

Subjects

Physics, Liquid-crystal display, Digital mammography, Receiver operating characteristic, medicine.diagnostic_test, Luminance, Imaging phantom, law.invention, Display size, law, medicine, Mammography, Microcalcification, medicine.symptom, Biomedical engineering

Abstract

Receiver operating characteristic (ROC) examination was performed to investigate the effectiveness of high-luminance monitors in digital X-ray mammography. For this purpose, an original breast phantom consisting of adipose and fibroglandular equivalent tissues with an identical X-ray absorption characteristic over the entire mammographic photon energy range was developed. Furthermore, the phantom’s fibroglandular density and distribution could be changed arbitrarily. Three types of lesions, microcalcification, mass, and spiculated, were inserted into the breast phantom, and the ROC examination was performed by five radiological technologists certified in screening mammography, to obtain the area under the curve. A liquid crystal display (LCD) monitor with 5 megapixels in a 21-inch display size calibrated to a grayscale standard display function curve was used for the observation. The monitor was set to 600, 900, and 1200 cd/m2 in maximum luminance. The experimental details were fibroglandular density of 25%, respective 50 positive and negative images, and free observation time and distance. As a result, the dependence on monitor luminance differed according to the lesion type. The detectability of microcalcification increased with the increase in the luminance of the monitor. Spiculated lesions were similar for all luminance changes. The detectability of mass lesions was significantly higher at 900 cd/m2 than at 600 cd/m2 . There was no significant difference between those at 900 cd/m2 and 1200 cd/m2 . In conclusion, the maximum luminance of the diagnostic LCD monitor for mammography should be at least 900 cd/m2 to guarantee stable detectability.

Published

2020

11. Prediction of glandularity and breast radiation dose from mammography results in Japanese women

Author

Masao Matsumoto, Takamichi Murakami, Yoshiyuki Asai, Yoshiaki Ozaki, Koji Yamada, and Mika Yamamuro

Subjects

0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Body weight, Radiation Dosage, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, Japan, medicine, Mammography, Humans, Breast, medicine.diagnostic_test, business.industry, Radiation dose, Reproducibility of Results, Dose-Response Relationship, Radiation, Human physiology, Breast radiation, medicine.disease, 020601 biomedical engineering, Computer Science Applications, Regression Analysis, Female, Stepwise multiple regression analysis, Nuclear medicine, business, Body mass index

Abstract

Glandularity has a marked impact on the incidence of breast cancer and the missed lesion rate of mammography. The aim of this study was to develop a novel model for predicting glandularity and patient radiation dose using physical factors that are easily determined prior to mammography. Data regarding glandularity and mean glandular dose were obtained from 331 mammograms. A stepwise multiple regression analysis model was developed to predict glandularity using age, compressed breast thickness and body mass index (BMI), while a model to predict mean glandular dose was created using quantified glandularity, age, compressed breast thickness, height and body weight. The most significant factor for predicting glandularity was age, the influence of which was 1.8 times that of BMI. The most significant factor for predicting mean glandular dose was compressed breast thickness, the influence of which was 1.4 times that of glandularity, 3.5 times that of age and 6.1 times that of height. Both models were statistically significant (both p 0.0001). Easily determined physical factors were able to explain 42.8% of the total variance in glandularity and 62.4% of the variance in mean glandular dose. Graphical abstract Validation results of the above prediction model made using physical factors in Japanese women. The plotted points of actual vs. prediction glandularity shown in a are distributed in the vicinity of the diagonal line, and the residual plot for predicted glandularity shows an almost random distribution as shown in b. These distributions indicate the appropriateness of the prediction model.

Published

2017

12. Exposure dose reduction for the high energy spectrum in the photon counting mammography: simulation study based on Japanese breast glandularity and thickness

Author

Naoko Niwa, Misaki Yamazaki, Yoshie Kodera, Mika Yamamuro, Koji Yamada, Kanako Yamada, and Yoshiyuki Asai

Subjects

Physics, medicine.medical_specialty, Photon, Digital mammography, medicine.diagnostic_test, business.industry, Physics::Medical Physics, Detector, Noise (electronics), Flat panel detector, Photon counting, Optics, Contrast-to-noise ratio, medicine, Mammography, Medical physics, business

Abstract

Recently, digital mammography with a photon counting silicon detector has been developed. With the aim of reducing the exposure dose, we have proposed a new mammography system that uses a cadmium telluride series photon counting detector. In addition, we also propose to use a high energy X-ray spectrum with a tungsten anode. The purpose of this study was assessed that the effectiveness of the high X-ray energy spectrum in terms of image quality using a Monte Carlo simulation. The proposed photon counting system with the high energy X-ray is compared to a conventional flat panel detector system with a Mo/Rh spectrum. The contrast-to-noise ratio (CNR) is calculated from simulation images with the use of breast phantoms. The breast model phantoms differed by glandularity and thickness, which were determined from Japanese clinical mammograms. We found that the CNR values were higher in the proposed system than in the conventional system. The number of photons incident on the detector was larger in the proposed system, so that the noise values was lower in comparison with the conventional system. Therefore, the high energy spectrum yielded the same CNR as using the conventional spectrum while allowing a considerable dose reduction to the breast.

Published

2015

13. Dual site occupancy of hydrogen in Sm2Fe17

Author

Atsushi Komatsu, K Kinoshita, Mika Yamamuro, Hirohisa Uchida, and Toshiro Kuji

Subjects

Hydrogen, Standard molar entropy, Mechanical Engineering, Alloy, Metals and Alloys, chemistry.chemical_element, engineering.material, Atmospheric temperature range, Dual site, Crystallography, Lattice constant, chemistry, Octahedron, Mechanics of Materials, Lattice (order), Materials Chemistry, engineering, Nuclear chemistry

Abstract

The hydrogen absorption properties of the Sm2Fe17 alloy were investigated by measurements of pressure–composition isotherms over the temperature range 423–623 K. The hydrogen atoms occupy not only the octahedral 9e sites but also the tetrahedral 18g sites in the rhombohedral Sm2Fe17 lattice. It is believed that the full occupation of the 9e sites, corresponding to the hydrogen composition H/Sm2Fe17=3.0, is followed by a partial occupation of the 18g sites. In the present work, however, the partial molar entropy of hydrogen suggests that the 18g sites start to be occupied even at low hydrogen concentrations. This behavior is followed by drastic changes in the partial thermodynamic properties of hydrogen starting around H/Sm2Fe17=2.0, implying that a large amount of hydrogen can start to enter the 18g sites before the 9e sites are completely occupied. This thermodynamic behavior was confirmed by discontinuous changes in the lattice constants and the saturation magnetization of Sm2Fe17 alloy with hydrogen composition.

Published

2002

14. Effect of KOH pretreatment for LaNi2.5Co2.5 on electrochemical hydrogen absorption rate and cyclic capacity

Author

Kohichiroh Yamashita, Masanobu Goto, Mika Yamamuro, and Hirohisa Uchida

Subjects

Chemistry, parasitic diseases, Inorganic chemistry, Pellet, Sample preparation, Hydrogen absorption, Electrochemistry

Abstract

Previously, we reported the improvement of the initial activation rate of LaNi2.5Co2.5 by KOH pretreatment for electrochemical reaction. Hydrogen absorption rate is very sensitive to the sample preparation. In this study, we prepared the pellet form and powder of the LaNi2.5Co2.5 pretreated with KOH. In each form, we examined the effects of the pretreatment on cyclic capacity and hydrogen absorption rate.

Published

1999