A generative, predictive model for menstrual cycle lengths that accounts for potential self-tracking artifacts in mobile health data

TL;DR

This paper introduces a hierarchical generative model for menstrual cycle length prediction that explicitly accounts for self-tracking artifacts, improving accuracy and interpretability in mobile health data analysis.

Contribution

It presents a novel hierarchical, generative modeling approach that explicitly models self-tracking artifacts, outperforming existing methods in menstrual cycle length prediction.

Findings

State-of-the-art prediction accuracy achieved

Model effectively disentangles menstrual patterns from artifacts

Provides interpretable insights into cycle length dynamics

Abstract

Mobile health (mHealth) apps such as menstrual trackers provide a rich source of self-tracked health observations that can be leveraged for health-relevant research. However, such data streams have questionable reliability since they hinge on user adherence to the app. Therefore, it is crucial for researchers to separate true behavior from self-tracking artifacts. By taking a machine learning approach to modeling self-tracked cycle lengths, we can both make more informed predictions and learn the underlying structure of the observed data. In this work, we propose and evaluate a hierarchical, generative model for predicting next cycle length based on previously-tracked cycle lengths that accounts explicitly for the possibility of users skipping tracking their period. Our model offers several advantages: 1) accounting explicitly for self-tracking artifacts yields better prediction accuracy as likelihood of skipping increases; 2) because it is a generative model, predictions can be updated online as a given cycle evolves, and we can gain interpretable insight into how these predictions change over time; and 3) its hierarchical nature enables modeling of an individual's cycle length history while incorporating population-level information. Our experiments using mHealth cycle length data encompassing over 186,000 menstruators with over 2 million natural menstrual cycles show that our method yields state-of-the-art performance against neural network-based and summary statistic-based baselines, while providing insights on disentangling menstrual patterns from self-tracking artifacts. This work can benefit users, mHealth app developers, and researchers in better understanding cycle patterns and user adherence.