Your search keyword '"Miyamoto, Yuichiro"' showing total 5 results

1. Development of a deep learning method for improving diagnostic accuracy for uterine sarcoma cases.

Author

Toyohara Y, Sone K, Noda K, Yoshida K, Kurokawa R, Tanishima T, Kato S, Inui S, Nakai Y, Ishida M, Gonoi W, Tanimoto S, Takahashi Y, Inoue F, Kukita A, Kawata Y, Taguchi A, Furusawa A, Miyamoto Y, Tsukazaki T, Tanikawa M, Iriyama T, Mori-Uchino M, Tsuruga T, Oda K, Yasugi T, Takechi K, Abe O, and Osuga Y

Subjects

Female, Humans, Diagnosis, Differential, Sensitivity and Specificity, Deep Learning, Uterine Neoplasms diagnostic imaging, Uterine Neoplasms pathology, Leiomyoma pathology, Sarcoma diagnostic imaging, Sarcoma pathology, Soft Tissue Neoplasms diagnosis, Pelvic Neoplasms

Abstract

Uterine sarcomas have very poor prognoses and are sometimes difficult to distinguish from uterine leiomyomas on preoperative examinations. Herein, we investigated whether deep neural network (DNN) models can improve the accuracy of preoperative MRI-based diagnosis in patients with uterine sarcomas. Fifteen sequences of MRI for patients (uterine sarcoma group: n = 63; uterine leiomyoma: n = 200) were used to train the models. Six radiologists (three specialists, three practitioners) interpreted the same images for validation. The most important individual sequences for diagnosis were axial T2-weighted imaging (T2WI), sagittal T2WI, and diffusion-weighted imaging. These sequences also represented the most accurate combination (accuracy: 91.3%), achieving diagnostic ability comparable to that of specialists (accuracy: 88.3%) and superior to that of practitioners (accuracy: 80.1%). Moreover, radiologists' diagnostic accuracy improved when provided with DNN results (specialists: 89.6%; practitioners: 92.3%). Our DNN models are valuable to improve diagnostic accuracy, especially in filling the gap of clinical skills between interpreters. This method can be a universal model for the use of deep learning in the diagnostic imaging of rare tumors., (© 2022. The Author(s).)

Published

2022

2. Automated system for diagnosing endometrial cancer by adopting deep-learning technology in hysteroscopy.

Author

Takahashi Y, Sone K, Noda K, Yoshida K, Toyohara Y, Kato K, Inoue F, Kukita A, Taguchi A, Nishida H, Miyamoto Y, Tanikawa M, Tsuruga T, Iriyama T, Nagasaka K, Matsumoto Y, Hirota Y, Hiraike-Wada O, Oda K, Maruyama M, Osuga Y, and Fujii T

Subjects

Data Accuracy, Female, Humans, Sensitivity and Specificity, Deep Learning, Early Detection of Cancer methods, Electronic Data Processing methods, Endometrial Hyperplasia diagnosis, Endometrial Neoplasms diagnosis, Hysteroscopy methods, Leiomyoma diagnosis, Polyps diagnosis, Uterine Neoplasms diagnosis

Abstract

Endometrial cancer is a ubiquitous gynecological disease with increasing global incidence. Therefore, despite the lack of an established screening technique to date, early diagnosis of endometrial cancer assumes critical importance. This paper presents an artificial-intelligence-based system to detect the regions affected by endometrial cancer automatically from hysteroscopic images. In this study, 177 patients (60 with normal endometrium, 21 with uterine myoma, 60 with endometrial polyp, 15 with atypical endometrial hyperplasia, and 21 with endometrial cancer) with a history of hysteroscopy were recruited. Machine-learning techniques based on three popular deep neural network models were employed, and a continuity-analysis method was developed to enhance the accuracy of cancer diagnosis. Finally, we investigated if the accuracy could be improved by combining all the trained models. The results reveal that the diagnosis accuracy was approximately 80% (78.91-80.93%) when using the standard method, and it increased to 89% (83.94-89.13%) and exceeded 90% (i.e., 90.29%) when employing the proposed continuity analysis and combining the three neural networks, respectively. The corresponding sensitivity and specificity equaled 91.66% and 89.36%, respectively. These findings demonstrate the proposed method to be sufficient to facilitate timely diagnosis of endometrial cancer in the near future., Competing Interests: Kenbun Sone has a joint research agreement with Predicthy LLC. Katsuhiko Noda and Kaname Yoshida are members of Predicthy LLC. The other authors have no competing interests to disclose. This does not alter our adherence to PLOS ONE policies on sharing data and materials.

Published

2021

3. Application of artificial intelligence in gynecologic malignancies: A review.

Author

Sone, Kenbun, Toyohara, Yusuke, Taguchi, Ayumi, Miyamoto, Yuichiro, Tanikawa, Michihiro, Uchino‐Mori, Mayuyo, Iriyama, Takayuki, Tsuruga, Tetsushi, and Osuga, Yutaka

Subjects

DEEP learning, PAPILLOMAVIRUSES, COLPOSCOPY, ARTIFICIAL intelligence, MACHINE learning, MAGNETIC resonance imaging, PAP test, HYSTEROSCOPY, ARTIFICIAL neural networks, FEMALE reproductive organ tumors, ALGORITHMS

Abstract

With the development of machine learning and deep learning models, artificial intelligence is now being applied to the field of medicine. In oncology, the use of artificial intelligence for the diagnostic evaluation of medical images such as radiographic images, omics analysis using genome data, and clinical information has been increasing in recent years. There have been increasing numbers of reports on the use of artificial intelligence in the field of gynecologic malignancies, and we introduce and review these studies. For cervical and endometrial cancers, the evaluation of medical images, such as colposcopy, hysteroscopy, and magnetic resonance images, using artificial intelligence is frequently reported. In ovarian cancer, many reports combine the assessment of medical images with the multi‐omics analysis of clinical and genomic data using artificial intelligence. However, few study results can be implemented in clinical practice, and further research is needed in the future. [ABSTRACT FROM AUTHOR]

Published

2021

4. Application of deep learning to the classification of images from colposcopy.

Author

Sato, Masakazu, Horie, Koji, Hara, Aki, Miyamoto, Yuichiro, Kurihara, Kazuko, Tomio, KENsuke, and Yokota, Harushige

Subjects

TUMOR classification, CARCINOMA in situ, COLPOSCOPY, DEEP learning, MEDICAL technology, CONIZATION, DIAGNOSIS

Abstract

The objective of the present study was to investigate whether deep learning could be applied successfully to the classification of images from colposcopy. For this purpose, a total of 158 patients who underwent conization were enrolled, and medical records and data from the gynecological oncology database were retrospectively reviewed. Deep learning was performed with the Keras neural network and TensorFlow libraries. Using preoperative images from colposcopy as the input data and deep learning technology, the patients were classified into three groups [severe dysplasia, carcinoma in situ (CIS) and invasive cancer (IC)]. A total of 485 images were obtained for the analysis, of which 142 images were of severe dysplasia (2.9 images/patient), 257 were of CIS (3.3 images/patient), and 86 were of IC (4.1 images/patient). Of these, 233 images were captured with a green filter, and the remaining 252 were captured without a green filter. Following the application of L2 regularization, L1 regularization, dropout and data augmentation, the accuracy of the validation dataset was ~50%. Although the present study is preliminary, the results indicated that deep learning may be applied to classify colposcopy images. [ABSTRACT FROM AUTHOR]

Published

2018

5. Evolution of a surgical system using deep learning in minimally invasive surgery (Review).

Author

Sone, Kenbun, Tanimoto, Saki, Toyohara, Yusuke, Taguchi, Ayumi, Miyamoto, Yuichiro, Mori, Mayuyo, Iriyama, Takayuki, Wada-Hiraike, Osamu, and Osuga, Yutaka

Subjects

MINIMALLY invasive procedures, DEEP learning, SURGICAL robots, COGNITIVE processing speed, AUTONOMOUS robots, SUTURING

Abstract

Recently, artificial intelligence (AI) has been applied in various fields due to the development of new learning methods, such as deep learning, and the marked progress in computational processing speed. AI is also being applied in the medical field for medical image recognition and omics analysis of genomes and other data. Recently, AI applications for videos of minimally invasive surgeries have also advanced, and studies on such applications are increasing. In the present review, studies that focused on the following topics were selected: i) Organ and anatomy identification, ii) instrument identification, iii) procedure and surgical phase recognition, iv) surgery-time prediction, v) identification of an appropriate incision line, and vi) surgical education. The development of autonomous surgical robots is also progressing, with the Smart Tissue Autonomous Robot (STAR) and RAVEN systems being the most reported developments. STAR, in particular, is currently being used in laparoscopic imaging to recognize the surgical site from laparoscopic images and is in the process of establishing an automated suturing system, albeit in animal experiments. The present review examined the possibility of fully autonomous surgical robots in the future. [ABSTRACT FROM AUTHOR]

Published

2023