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ADMarker: A Multi-Modal Federated Learning System for Detecting Digital Biomarkers of Alzheimer's Disease


核心概念
ADMarker is the first end-to-end system that integrates multi-modal sensors and new federated learning algorithms to accurately detect a comprehensive set of multidimensional digital biomarkers of Alzheimer's disease in a privacy-preserving manner.
要約

The paper presents ADMarker, a novel multi-modal federated learning system for monitoring digital biomarkers of Alzheimer's disease (AD). Key highlights:

  1. ADMarker features a comprehensive set of 22 digital biomarkers related to basic activities of daily living, instrumental activities, and social interactions, which are strongly associated with different stages of AD.

  2. ADMarker incorporates a compact multi-modality hardware system with depth camera, mmWave radar, and microphone to capture these digital biomarkers in a privacy-preserving manner.

  3. ADMarker introduces a novel three-stage federated learning architecture that can accurately detect the digital biomarkers without sharing raw sensor data. The approach includes model pre-training, unsupervised multi-modal federated learning, and weakly supervised multi-modal federated learning.

  4. The system was deployed in a 4-week clinical trial with 91 elderly participants, including 31 with AD and 30 with mild cognitive impairment (MCI). ADMarker can detect the digital biomarkers with up to 93.8% accuracy and identify early AD with 88.9% accuracy.

  5. ADMarker offers a new platform that allows clinicians to monitor the progression of AD manifestations and study the complex correlation between multidimensional interpretable digital biomarkers, demographic factors, and AD diagnosis.

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統計
"ADMarker can detect a comprehensive set of daily activities in natural home environments with up to 93.8% detection accuracy." "Leveraging the detected digital biomarkers, ADMarker can identify early AD with an average of 88.9% accuracy."
引用
"ADMarker is the first end-to-end system that integrates multi-modal sensors and new federated learning algorithms for detecting multidimensional AD digital biomarkers in a privacy-preserving manner." "The results show that ADMarker can accurately detect a comprehensive set of digital biomarkers and identify early AD with high accuracy."

抽出されたキーインサイト

by Xiaomin Ouya... 場所 arxiv.org 03-29-2024

https://arxiv.org/pdf/2310.15301.pdf
ADMarker

深掘り質問

How can the digital biomarkers detected by ADMarker be further utilized to develop personalized intervention plans for Alzheimer's patients?

The digital biomarkers detected by ADMarker can be leveraged to develop personalized intervention plans for Alzheimer's patients in several ways. Firstly, by analyzing the duration and frequency of activities captured by the sensors, patterns and trends can be identified that indicate the progression of the disease. For example, changes in daily activities like eating, grooming, or social interactions can provide insights into cognitive decline. These biomarkers can then be used to tailor interventions that target specific areas of impairment. Secondly, the data collected by ADMarker can be used to create individualized care plans based on the unique needs and behaviors of each patient. By understanding the daily routines and challenges faced by the patient, caregivers and healthcare providers can develop strategies to support and enhance their quality of life. For instance, if the data shows a decline in certain activities, interventions can be designed to improve those specific skills or provide assistance in those areas. Furthermore, the digital biomarkers can be utilized to monitor the effectiveness of interventions over time. By tracking changes in behavior and activity patterns, healthcare professionals can assess the impact of interventions and make adjustments as needed. This continuous monitoring allows for a personalized and adaptive approach to care that is tailored to the individual needs of each patient.

What are the potential limitations of the federated learning approach used in ADMarker, and how can they be addressed to improve the system's robustness and scalability?

While federated learning offers many advantages for privacy-preserving and distributed model training, there are potential limitations that can impact the robustness and scalability of the system. One limitation is the challenge of dealing with non-i.i.d. data distributions across nodes, which can lead to biased models and reduced accuracy. To address this, techniques like data augmentation and model aggregation can be employed to mitigate the effects of non-i.i.d. data and ensure that the models are more generalizable. Another limitation is the potential for communication delays and bandwidth constraints, especially in real-world settings where network conditions may vary. To improve system robustness and scalability, adaptive communication strategies can be implemented to dynamically adjust the communication frequency and bandwidth based on the network conditions. This can help optimize the data transfer process and reduce latency in model updates. Additionally, the limited labeled data available for training in a federated learning setting can pose a challenge for model performance. To overcome this limitation, techniques like semi-supervised learning and active learning can be integrated into the system to make the most of the available labeled data and leverage unlabeled data effectively. By incorporating these strategies, the system can improve its robustness and scalability while maintaining privacy and data security.

Given the diverse manifestations of Alzheimer's disease, how can the integration of multi-dimensional digital biomarkers in ADMarker be extended to better understand the underlying pathogenesis and progression of the disease?

The integration of multi-dimensional digital biomarkers in ADMarker can be extended to better understand the underlying pathogenesis and progression of Alzheimer's disease by capturing a comprehensive set of behavioral and lifestyle indicators that reflect the diverse manifestations of the disease. By incorporating a wide range of activities and interactions monitored by the sensors, ADMarker can provide a holistic view of the patient's daily life and cognitive function. To further enhance the understanding of the disease progression, the digital biomarkers can be analyzed in conjunction with other clinical data, such as cognitive assessments, genetic information, and medical history. By correlating the multi-dimensional digital biomarkers with these additional data sources, patterns and trends that indicate the pathogenesis and progression of Alzheimer's disease can be identified. Moreover, machine learning algorithms can be applied to the integrated data to uncover hidden patterns and relationships that may not be apparent through traditional analysis methods. By leveraging advanced analytics and AI techniques, ADMarker can provide insights into the complex interplay between behavioral biomarkers, demographic factors, and disease diagnosis, leading to a deeper understanding of Alzheimer's disease pathogenesis and progression. Overall, the extension of multi-dimensional digital biomarkers in ADMarker offers a comprehensive and personalized approach to studying Alzheimer's disease, shedding light on the underlying mechanisms and facilitating early detection and intervention strategies.
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