Ankita Singh, Shayok Chakraborty, Zhe He, Yuanying Pang, Shenghao Zhang, Ronast Subedi, Mia Liza Lustria, Neil Charness, Walter Boot
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While computerized cognitive training programs have demonstrated some promise in addressing cognitive decline, adherence to these interventions can be challenging.</p><p><strong>Objective: </strong>The objective of this study is to improve the accuracy of predicting adherence lapses to ultimately develop tailored adherence support systems to promote engagement with cognitive training among older adults.</p><p><strong>Methods: </strong>Data from 2 previously conducted cognitive training intervention studies were used to forecast adherence levels among older participants. Deep convolutional neural networks were used to leverage their feature learning capabilities and predict adherence patterns based on past behavior. Domain adaptation (DA) was used to address the challenge of limited training data for each participant, by using data from other participants with similar playing patterns. Time series data were converted into image format using Gramian angular fields, to facilitate clustering of participants during DA. To the best of our knowledge, this is the first effort to use DA techniques to predict older adults' daily adherence to cognitive training programs.</p><p><strong>Results: </strong>Our results demonstrated the promise and potential of deep neural networks and DA for predicting adherence lapses. In all 3 studies, using 2 independent datasets, DA consistently produced the best accuracy values.</p><p><strong>Conclusions: </strong>Our findings highlight that deep learning and DA techniques can aid in the development of adherence support systems for computerized cognitive training, as well as for other interventions aimed at improving health, cognition, and well-being. These techniques can improve engagement and maximize the benefits of such interventions, ultimately enhancing the quality of life of individuals at risk for cognitive impairments. 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引用次数: 0
摘要
背景:认知障碍和痴呆症对人口老龄化构成了重大挑战,影响着患者的福祉、生活质量和自主性。随着人口老龄化,这将给医疗保健和经济系统带来巨大压力。虽然计算机化的认知训练计划在解决认知能力下降问题上取得了一定的成效,但坚持使用这些干预措施却具有挑战性:本研究的目的是提高预测坚持率下降的准确性,最终开发出量身定制的坚持率支持系统,以促进老年人参与认知训练:方法: 使用之前进行的两项认知训练干预研究的数据来预测老年参与者的坚持水平。利用深度卷积神经网络的特征学习能力,根据过去的行为预测坚持训练的模式。通过使用具有类似游戏模式的其他参与者的数据,利用领域适应(DA)来解决每位参与者训练数据有限的难题。使用格拉米安角场将时间序列数据转换为图像格式,以便在 DA 期间对参与者进行聚类。据我们所知,这是首次使用DA技术来预测老年人每天坚持认知训练计划的情况:结果:我们的研究结果表明,深度神经网络和DA技术在预测坚持性失效方面具有前景和潜力。在使用 2 个独立数据集进行的所有 3 项研究中,DA 始终能产生最佳准确度值:我们的研究结果强调,深度学习和数据分析技术可以帮助开发用于计算机化认知训练的坚持治疗支持系统,以及其他旨在改善健康、认知和福祉的干预措施。这些技术可以提高参与度,最大限度地发挥这些干预措施的益处,最终提高有认知障碍风险的人的生活质量。这项研究为开发更有效的干预措施提供了信息,通过改善与老龄化相关的状况,使个人和社会受益。
Predicting Adherence to Computer-Based Cognitive Training Programs Among Older Adults: Study of Domain Adaptation and Deep Learning.
Background: Cognitive impairment and dementia pose a significant challenge to the aging population, impacting the well-being, quality of life, and autonomy of affected individuals. As the population ages, this will place enormous strain on health care and economic systems. While computerized cognitive training programs have demonstrated some promise in addressing cognitive decline, adherence to these interventions can be challenging.
Objective: The objective of this study is to improve the accuracy of predicting adherence lapses to ultimately develop tailored adherence support systems to promote engagement with cognitive training among older adults.
Methods: Data from 2 previously conducted cognitive training intervention studies were used to forecast adherence levels among older participants. Deep convolutional neural networks were used to leverage their feature learning capabilities and predict adherence patterns based on past behavior. Domain adaptation (DA) was used to address the challenge of limited training data for each participant, by using data from other participants with similar playing patterns. Time series data were converted into image format using Gramian angular fields, to facilitate clustering of participants during DA. To the best of our knowledge, this is the first effort to use DA techniques to predict older adults' daily adherence to cognitive training programs.
Results: Our results demonstrated the promise and potential of deep neural networks and DA for predicting adherence lapses. In all 3 studies, using 2 independent datasets, DA consistently produced the best accuracy values.
Conclusions: Our findings highlight that deep learning and DA techniques can aid in the development of adherence support systems for computerized cognitive training, as well as for other interventions aimed at improving health, cognition, and well-being. These techniques can improve engagement and maximize the benefits of such interventions, ultimately enhancing the quality of life of individuals at risk for cognitive impairments. This research informs the development of more effective interventions, benefiting individuals and society by improving conditions associated with aging.