Synthetic Survival Control: Extending Synthetic Controls for "When-If" Decision
- URL: http://arxiv.org/abs/2511.14133v1
- Date: Tue, 18 Nov 2025 04:36:20 GMT
- Title: Synthetic Survival Control: Extending Synthetic Controls for "When-If" Decision
- Authors: Jessy Xinyi Han, Devavrat Shah,
- Abstract summary: Estimating causal effects on time-to-event outcomes from observational data is challenging due to censoring, limited sample sizes, and non-random treatment assignment.<n>We propose Synthetic Survival Control (SSC) to estimate counterfactual hazard trajectories in a panel data setting.
- Score: 14.313335826236722
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Estimating causal effects on time-to-event outcomes from observational data is particularly challenging due to censoring, limited sample sizes, and non-random treatment assignment. The need for answering such "when-if" questions--how the timing of an event would change under a specified intervention--commonly arises in real-world settings with heterogeneous treatment adoption and confounding. To address these challenges, we propose Synthetic Survival Control (SSC) to estimate counterfactual hazard trajectories in a panel data setting where multiple units experience potentially different treatments over multiple periods. In such a setting, SSC estimates the counterfactual hazard trajectory for a unit of interest as a weighted combination of the observed trajectories from other units. To provide formal justification, we introduce a panel framework with a low-rank structure for causal survival analysis. Indeed, such a structure naturally arises under classical parametric survival models. Within this framework, for the causal estimand of interest, we establish identification and finite sample guarantees for SSC. We validate our approach using a multi-country clinical dataset of cancer treatment outcomes, where the staggered introduction of new therapies creates a quasi-experimental setting. Empirically, we find that access to novel treatments is associated with improved survival, as reflected by lower post-intervention hazard trajectories relative to their synthetic counterparts. Given the broad relevance of survival analysis across medicine, economics, and public policy, our framework offers a general and interpretable tool for counterfactual survival inference using observational data.
Related papers
- Toward Valid Generative Clinical Trial Data with Survival Endpoints [4.7846041866823965]
Existing generative approaches, largely GAN-based, are data-hungry, unstable, and rely on strong assumptions such as independent censoring.<n>We introduce a variational autoencoder (VAE) that jointly generates mixed-type co variables and survival outcomes within a unified latent variable framework, without assuming independent censoring.<n>Our method outperforms GAN baselines on fidelity, utility, and privacy metrics, while revealing systematic miscalibration of type I error and power.
arXiv Detail & Related papers (2025-11-20T17:03:38Z) - Predictive Causal Inference via Spatio-Temporal Modeling and Penalized Empirical Likelihood [0.0]
This study introduces an integrated framework for predictive causal inference designed to overcome limitations in conventional single model approaches.<n> Specifically, we combine a Hidden Markov Model for spatial health state estimation with a Multi Task and Multi Graph Convolutional Network (MTGCN) for capturing temporal outcome trajectories.<n>To demonstrate its utility, we focus on clinical domains such as cancer, dementia, Parkinson disease, where treatment effects are challenging to observe directly.
arXiv Detail & Related papers (2025-07-11T03:11:15Z) - GST-UNet: A Neural Framework for Spatiotemporal Causal Inference with Time-Varying Confounding [46.46135774964818]
Estimating causal effects from data is essential in public health, environmental science, and policy evaluation.<n>We introduce GST-UNet, a neural framework that combines a U-Net-basedtemporal encoder with regression-based iterative G-mputation.<n>We validate its effectiveness in synthetic experiments and in a real-world analysis of wildfire smoke exposure and respiratory hospitalizations during California Camp Fire.
arXiv Detail & Related papers (2025-02-07T19:56:01Z) - 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) - Continuous-Time Modeling of Counterfactual Outcomes Using Neural
Controlled Differential Equations [84.42837346400151]
Estimating counterfactual outcomes over time has the potential to unlock personalized healthcare.
Existing causal inference approaches consider regular, discrete-time intervals between observations and treatment decisions.
We propose a controllable simulation environment based on a model of tumor growth for a range of scenarios.
arXiv Detail & Related papers (2022-06-16T17:15:15Z) - SurvITE: Learning Heterogeneous Treatment Effects from Time-to-Event
Data [83.50281440043241]
We study the problem of inferring heterogeneous treatment effects from time-to-event data.
We propose a novel deep learning method for treatment-specific hazard estimation based on balancing representations.
arXiv Detail & Related papers (2021-10-26T20:13:17Z) - A Deep Variational Approach to Clustering Survival Data [5.871238645229228]
We introduce a novel probabilistic approach to cluster survival data in a variational deep clustering setting.
Our proposed method employs a deep generative model to uncover the underlying distribution of both the explanatory variables and the potentially censored survival times.
arXiv Detail & Related papers (2021-06-10T14:10:25Z) - MIA-Prognosis: A Deep Learning Framework to Predict Therapy Response [58.0291320452122]
This paper aims at a unified deep learning approach to predict patient prognosis and therapy response.
We formalize the prognosis modeling as a multi-modal asynchronous time series classification task.
Our predictive model could further stratify low-risk and high-risk patients in terms of long-term survival.
arXiv Detail & Related papers (2020-10-08T15:30:17Z) - Enabling Counterfactual Survival Analysis with Balanced Representations [64.17342727357618]
Survival data are frequently encountered across diverse medical applications, i.e., drug development, risk profiling, and clinical trials.
We propose a theoretically grounded unified framework for counterfactual inference applicable to survival outcomes.
arXiv Detail & Related papers (2020-06-14T01:15:00Z) - Generalization Bounds and Representation Learning for Estimation of
Potential Outcomes and Causal Effects [61.03579766573421]
We study estimation of individual-level causal effects, such as a single patient's response to alternative medication.
We devise representation learning algorithms that minimize our bound, by regularizing the representation's induced treatment group distance.
We extend these algorithms to simultaneously learn a weighted representation to further reduce treatment group distances.
arXiv Detail & Related papers (2020-01-21T10:16:33Z)
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.