利用数据驱动的深度学习方法的进步进行混合流行病建模

IF 3 3区 医学 Q2 INFECTIOUS DISEASES
Shi Chen , Daniel Janies , Rajib Paul , Jean-Claude Thill
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引用次数: 0

摘要

疫情动态的数学模型对于了解其基本机制、量化重要参数以及做出有助于做出更明智决策的预测至关重要。目前主要有三种模型:包括 SEIR 型范例在内的机理模型、替代性数据驱动(DD)方法以及将机理模型与 DD 方法相结合的混合模型。在本文中,我们总结了自 2021 年初以来,我们在 COVID-19 场景建模中心(SMH)为知情决策支持所做的超过 12 轮的工作。我们强调了深度学习技术在流行病建模中的重要性,即通过灵活的 DD 框架,对机理范式进行实质性补充,以评估各种未来流行病情景。我们首先采用传统的曲线拟合方法,根据 SEIR 类型的基本机制对累积 COVID-19 进行建模。住院和死亡分别被模拟为病例和住院的二项过程。我们进一步制定了两种基于多变量长短期记忆(LSTM)的深度学习模型,以应对更多传统 DD 模型所面临的挑战。第一种 LSTM 在结构上类似于曲线拟合方法,假定住院和死亡是病例的二项过程。LSTM 不使用预定义的指数曲线,而是依靠基础数据来确定最合适的函数,并且能够捕捉长期和短期的流行病行为。然后,我们放宽了病例、住院和死亡之间依赖输入的假设。我们还开发了另一种将所有输入时间序列作为并行信号处理的 LSTM,即独立多变量 LSTM。独立多变量 LSTM 可纳入传统病例流行病监测以外的各种数据源。在大数据时代,DD 框架可以利用以前被忽视的异构监测数据源(如综合征、环境、基因组、血清学、信息监测和流动性数据)释放其潜力。DD 方法,尤其是 LSTM,补充并整合了机理建模范式,为当今复杂的社会流行病学系统建模提供了一种可行的替代方法,并进一步提高了我们探索不同情景的能力,从而在卫生紧急情况下做出更明智的决策。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Leveraging advances in data-driven deep learning methods for hybrid epidemic modeling

Mathematical modeling of epidemic dynamics is crucial to understand its underlying mechanisms, quantify important parameters, and make predictions that facilitate more informed decision-making. There are three major types of models: mechanistic models including the SEIR-type paradigm, alternative data-driven (DD) approaches, and hybrid models that combine mechanistic models with DD approaches. In this paper, we summarize our work in the COVID-19 Scenario Modeling Hub (SMH) for more than 12 rounds since early 2021 for informed decision support. We emphasize the importance of deep learning techniques for epidemic modeling via a flexible DD framework that substantially complements the mechanistic paradigm to evaluate various future epidemic scenarios. We start with a traditional curve-fitting approach to model cumulative COVID-19 based on the underlying SEIR-type mechanisms. Hospitalizations and deaths are modeled as binomial processes of cases and hospitalization, respectively. We further formulate two types of deep learning models based on multivariate long short term memory (LSTM) to address the challenges of more traditional DD models. The first LSTM is structurally similar to the curve fitting approach and assumes that hospitalizations and deaths are binomial processes of cases. Instead of using a predefined exponential curve, LSTM relies on the underlying data to identify the most appropriate functions, and is capable of capturing both long-term and short-term epidemic behaviors. We then relax the assumption of dependent inputs among cases, hospitalizations, and death. Another type of LSTM that handles all input time series as parallel signals, the independent multivariate LSTM, is developed. Independent multivariate LSTM can incorporate a wide range of data sources beyond traditional case-based epidemiological surveillance. The DD framework unleashes its potential in big data era with previously neglected heterogeneous surveillance data sources, such as syndromic, environment, genomic, serologic, infoveillance, and mobility data. DD approaches, especially LSTM, complement and integrate with the mechanistic modeling paradigm, provide a feasible alternative approach to model today’s complex socio-epidemiological systems, and further leverage our ability to explore different scenarios for more informed decision-making during health emergencies.

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来源期刊
Epidemics
Epidemics INFECTIOUS DISEASES-
CiteScore
6.00
自引率
7.90%
发文量
92
审稿时长
140 days
期刊介绍: Epidemics publishes papers on infectious disease dynamics in the broadest sense. Its scope covers both within-host dynamics of infectious agents and dynamics at the population level, particularly the interaction between the two. Areas of emphasis include: spread, transmission, persistence, implications and population dynamics of infectious diseases; population and public health as well as policy aspects of control and prevention; dynamics at the individual level; interaction with the environment, ecology and evolution of infectious diseases, as well as population genetics of infectious agents.
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