Your search keyword '"Zhou, Alexander"' showing total 7 results

1. Butterfly counting and bitruss decomposition on uncertain bipartite graphs

Author

Zhou, Alexander, Wang, Yue, and Chen, Lei

Published

2023

2. Fast-adapting and privacy-preserving federated recommender system

Author

Wang, Qinyong, Yin, Hongzhi, Chen, Tong, Yu, Junliang, Zhou, Alexander, and Zhang, Xiangliang

Published

2022

3. A review of self‐supervised, generative, and few‐shot deep learning methods for data‐limited magnetic resonance imaging segmentation.

Author

Liu, Zelong, Kainth, Komal, Zhou, Alexander, Deyer, Timothy W., Fayad, Zahi A., Greenspan, Hayit, and Mei, Xueyan

Subjects

MAGNETIC resonance imaging, DEEP learning, IMAGE segmentation, SUPERVISED learning, DIAGNOSTIC imaging

Abstract

Magnetic resonance imaging (MRI) is a ubiquitous medical imaging technology with applications in disease diagnostics, intervention, and treatment planning. Accurate MRI segmentation is critical for diagnosing abnormalities, monitoring diseases, and deciding on a course of treatment. With the advent of advanced deep learning frameworks, fully automated and accurate MRI segmentation is advancing. Traditional supervised deep learning techniques have advanced tremendously, reaching clinical‐level accuracy in the field of segmentation. However, these algorithms still require a large amount of annotated data, which is oftentimes unavailable or impractical. One way to circumvent this issue is to utilize algorithms that exploit a limited amount of labeled data. This paper aims to review such state‐of‐the‐art algorithms that use a limited number of annotated samples. We explain the fundamental principles of self‐supervised learning, generative models, few‐shot learning, and semi‐supervised learning and summarize their applications in cardiac, abdomen, and brain MRI segmentation. Throughout this review, we highlight algorithms that can be employed based on the quantity of annotated data available. We also present a comprehensive list of notable publicly available MRI segmentation datasets. To conclude, we discuss possible future directions of the field—including emerging algorithms, such as contrastive language‐image pretraining, and potential combinations across the methods discussed—that can further increase the efficacy of image segmentation with limited labels. [ABSTRACT FROM AUTHOR]

Published

2024

4. The Role of Artificial Intelligence in the Identification and Evaluation of Bone Fractures.

Author

Tieu, Andrew, Kroen, Ezriel, Kadish, Yonaton, Liu, Zelong, Patel, Nikhil, Zhou, Alexander, Yilmaz, Alara, Lee, Stephanie, and Deyer, Timothy

Subjects

ARTIFICIAL intelligence, BONE fractures, DEEP learning, MEDICAL care, COMPUTER-assisted image analysis (Medicine), IMAGE analysis

Abstract

Artificial intelligence (AI), particularly deep learning, has made enormous strides in medical imaging analysis. In the field of musculoskeletal radiology, deep-learning models are actively being developed for the identification and evaluation of bone fractures. These methods provide numerous benefits to radiologists such as increased diagnostic accuracy and efficiency while also achieving standalone performances comparable or superior to clinician readers. Various algorithms are already commercially available for integration into clinical workflows, with the potential to improve healthcare delivery and shape the future practice of radiology. In this systematic review, we explore the performance of current AI methods in the identification and evaluation of fractures, particularly those in the ankle, wrist, hip, and ribs. We also discuss current commercially available products for fracture detection and provide an overview of the current limitations of this technology and future directions of the field. [ABSTRACT FROM AUTHOR]

Published

2024

5. Deep Learning for Automated Measurement of Patellofemoral Anatomic Landmarks.

Author

Liu, Zelong, Zhou, Alexander, Fauveau, Valentin, Lee, Justine, Marcadis, Philip, Fayad, Zahi A., Chan, Jimmy J., Gladstone, James, Mei, Xueyan, and Huang, Mingqian

Subjects

*DEEP learning, *KNEE, *STATISTICAL measurement, *COMPUTED tomography, *BLAND-Altman plot, *TOTAL knee replacement, *STATISTICAL significance

Abstract

Background: Patellofemoral anatomy has not been well characterized. Applying deep learning to automatically measure knee anatomy can provide a better understanding of anatomy, which can be a key factor in improving outcomes. Methods: 483 total patients with knee CT imaging (April 2017–May 2022) from 6 centers were selected from a cohort scheduled for knee arthroplasty and a cohort with healthy knee anatomy. A total of 7 patellofemoral landmarks were annotated on 14,652 images and approved by a senior musculoskeletal radiologist. A two-stage deep learning model was trained to predict landmark coordinates using a modified ResNet50 architecture initialized with self-supervised learning pretrained weights on RadImageNet. Landmark predictions were evaluated with mean absolute error, and derived patellofemoral measurements were analyzed with Bland–Altman plots. Statistical significance of measurements was assessed by paired t-tests. Results: Mean absolute error between predicted and ground truth landmark coordinates was 0.20/0.26 cm in the healthy/arthroplasty cohort. Four knee parameters were calculated, including transepicondylar axis length, transepicondylar-posterior femur axis angle, trochlear medial asymmetry, and sulcus angle. There were no statistically significant parameter differences (p > 0.05) between predicted and ground truth measurements in both cohorts, except for the healthy cohort sulcus angle. Conclusion: Our model accurately identifies key trochlear landmarks with ~0.20–0.26 cm accuracy and produces human-comparable measurements on both healthy and pathological knees. This work represents the first deep learning regression model for automated patellofemoral annotation trained on both physiologic and pathologic CT imaging at this scale. This novel model can enhance our ability to analyze the anatomy of the patellofemoral compartment at scale. [ABSTRACT FROM AUTHOR]

Published

2023

6. ReFRS: Resource-efficient Federated Recommender System for Dynamic and Diversified User Preferences.

Author

IMRAN, MUBASHIR, HONGZHI YIN, TONG CHEN, QUOC VIET HUNG NGUYEN, ZHOU, ALEXANDER, and KAI ZHENG

Abstract

Owing to its nature of scalability and privacy by design, federated learning (FL) has received increasing interest in decentralized deep learning. FL has also facilitated recent research on upscaling and privatizing personalized recommendation services, using on-device data to learn recommender models locally. These models are then aggregated globally to obtain a more performant model while maintaining data privacy. Typically, federated recommender systems (FRSs) do not take into account the lack of resources and data availability at the end-devices. In addition, they assume that the interaction data between users and items is i.i.d. and stationary across end-devices (i.e., users), and that all local recommender models can be directly averaged without considering the user’s behavioral diversity. However, in real scenarios, recommendations have to be made on end-devices with sparse interaction data and limited resources. Furthermore, users’ preferences are heterogeneous and they frequently visit new items. This makes their personal preferences highly skewed, and the straightforwardly aggregated model is thus ill-posed for such non-i.i.d. data. In this article, we propose Resource Efficient Federated Recommender System (ReFRS) to enable decentralized recommendation with dynamic and diversified user preferences. On the device side, ReFRS consists of a lightweight self-supervised local model built upon the variational autoencoder for learning a user’s temporal preference from a sequence of interacted items. On the server side, ReFRS utilizes a scalable semantic sampler to adaptively perform model aggregation within each identified cluster of similar users. The clustering module operates in an asynchronous and dynamic manner to support efficient global model update and cope with shifting user interests. As a result, ReFRS achieves superior performance in terms of both accuracy and scalability, as demonstrated by comparative experiments on real datasets. [ABSTRACT FROM AUTHOR]

Published

2023

7. Long-standing themes and new developments in offsite construction: the case of UK housing.

Author

Zhang, Ruoheng, Zhou, Alexander S J, Tahmasebi, Saeed, and Whyte, Jennifer

Subjects

*HOUSING, *CONSTRUCTION, *RESEARCH & development, *BUSINESS models

Abstract

This paper reviews the evolution of offsite construction methods in UK housing over the past 15 years and puts this in an international context. Long-standing themes include targets for construction productivity, challenges of labour shortages and skills, desire to learn across sectors and a need to develop new business models. Newer developments include research and development funding through the UK government's 'transforming construction' initiative, higher pre-manufactured value and increased digitisation. The paper concludes with recommendations for practice, policy and research. [ABSTRACT FROM AUTHOR]

Published

2019