Related papers: Approximate Bayesian Computation for an Explicit-Duration Hidden Markov Model of COVID-19 Hospital Trajectories

Approximate Bayesian Computation for an Explicit-Duration Hidden Markov Model of COVID-19 Hospital Trajectories

URL: http://arxiv.org/abs/2105.00773v1
Date: Wed, 28 Apr 2021 15:32:42 GMT
Title: Approximate Bayesian Computation for an Explicit-Duration Hidden Markov Model of COVID-19 Hospital Trajectories
Authors: Gian Marco Visani, Alexandra Hope Lee, Cuong Nguyen, David M. Kent, John B. Wong, Joshua T. Cohen, and Michael C. Hughes
Abstract summary: We address the problem of modeling constrained hospital resources in the midst of the COVID-19 pandemic. For broad applicability, we focus on the common yet challenging scenario where patient-level data for a region of interest are not available. We propose an aggregate count explicit-duration hidden Markov model, nicknamed the ACED-HMM, with an interpretable, compact parameterization.
Score: 55.786207368853084
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We address the problem of modeling constrained hospital resources in the midst of the COVID-19 pandemic in order to inform decision-makers of future demand and assess the societal value of possible interventions. For broad applicability, we focus on the common yet challenging scenario where patient-level data for a region of interest are not available. Instead, given daily admissions counts, we model aggregated counts of observed resource use, such as the number of patients in the general ward, in the intensive care unit, or on a ventilator. In order to explain how individual patient trajectories produce these counts, we propose an aggregate count explicit-duration hidden Markov model, nicknamed the ACED-HMM, with an interpretable, compact parameterization. We develop an Approximate Bayesian Computation approach that draws samples from the posterior distribution over the model's transition and duration parameters given aggregate counts from a specific location, thus adapting the model to a region or individual hospital site of interest. Samples from this posterior can then be used to produce future forecasts of any counts of interest. Using data from the United States and the United Kingdom, we show our mechanistic approach provides competitive probabilistic forecasts for the future even as the dynamics of the pandemic shift. Furthermore, we show how our model provides insight about recovery probabilities or length of stay distributions, and we suggest its potential to answer challenging what-if questions about the societal value of possible interventions.

Related papers

Deep State-Space Generative Model For Correlated Time-to-Event Predictions [54.3637600983898]
We propose a deep latent state-space generative model to capture the interactions among different types of correlated clinical events. Our method also uncovers meaningful insights about the latent correlations among mortality and different types of organ failures.
arXiv Detail & Related papers (2024-07-28T02:42:36Z)
Addressing Data Heterogeneity in Federated Learning of Cox Proportional Hazards Models [8.798959872821962]
This paper outlines an approach in the domain of federated survival analysis, specifically the Cox Proportional Hazards (CoxPH) model. We present an FL approach that employs feature-based clustering to enhance model accuracy across synthetic datasets and real-world applications.
arXiv Detail & Related papers (2024-07-20T18:34:20Z)
MedDiffusion: Boosting Health Risk Prediction via Diffusion-based Data Augmentation [58.93221876843639]
This paper introduces a novel, end-to-end diffusion-based risk prediction model, named MedDiffusion. It enhances risk prediction performance by creating synthetic patient data during training to enlarge sample space. It discerns hidden relationships between patient visits using a step-wise attention mechanism, enabling the model to automatically retain the most vital information for generating high-quality data.
arXiv Detail & Related papers (2023-10-04T01:36:30Z)
Forecasting COVID-19 Counts At A Single Hospital: A Hierarchical Bayesian Approach [59.318136981032]
We consider the problem of forecasting the daily number of hospitalized COVID-19 patients at a single hospital site. We develop several candidate hierarchical Bayesian models which directly capture the count nature of data. We demonstrate our approach on public datasets for 8 hospitals in Massachusetts, U.S.A. and 10 hospitals in the United Kingdom.
arXiv Detail & Related papers (2021-04-14T11:58:54Z)
Temporal Cascade and Structural Modelling of EHRs for Granular Readmission Prediction [10.943928059802174]
We propose a novel model, MEDCAS, to model temporal cascade relationships. MEDCAS integrates point processes in modelling visit types and time gaps into an attention-based sequence-to-sequence learning model. Experiments on three real-world EHR datasets have been performed and the results demonstrate ttexttMEDCAS outperforms state-of-the-art models in both tasks.
arXiv Detail & Related papers (2021-02-04T13:02:04Z)
Combining Graph Neural Networks and Spatio-temporal Disease Models to Predict COVID-19 Cases in Germany [0.0]
Several experts have called for the necessity to account for human mobility to explain the spread of COVID-19. Most statistical or epidemiological models cannot directly incorporate unstructured data sources, including data that may encode human mobility. We propose a trade-off between both research directions and present a novel learning approach that combines the advantages of statistical regression and machine learning models.
arXiv Detail & Related papers (2021-01-03T16:39:00Z)
DeepCOVIDNet: An Interpretable Deep Learning Model for Predictive Surveillance of COVID-19 Using Heterogeneous Features and their Interactions [2.30238915794052]
We propose a deep learning model to forecast the range of increase in COVID-19 infected cases in future days. Using data collected from various sources, we estimate the range of increase in infected cases seven days into the future for all U.S. counties.
arXiv Detail & Related papers (2020-07-31T23:37:38Z)
Temporal Phenotyping using Deep Predictive Clustering of Disease Progression [97.88605060346455]
We develop a deep learning approach for clustering time-series data, where each cluster comprises patients who share similar future outcomes of interest. Experiments on two real-world datasets show that our model achieves superior clustering performance over state-of-the-art benchmarks.
arXiv Detail & Related papers (2020-06-15T20:48:43Z)
Estimating Counterfactual Treatment Outcomes over Time Through Adversarially Balanced Representations [114.16762407465427]
We introduce the Counterfactual Recurrent Network (CRN) to estimate treatment effects over time. CRN uses domain adversarial training to build balancing representations of the patient history. We show how our model achieves lower error in estimating counterfactuals and in choosing the correct treatment and timing of treatment.
arXiv Detail & Related papers (2020-02-10T20:47:36Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.