Demographic Dependence of Vaccine Adoption under Opinion Persuasion

Alessandro Casu; Camilla Quaresmini; Lewis Mitchell; Philip E. Par\'e; Robin Delabays

arxiv: 2512.06385 · v2 · pith:C5YEKVF3new · submitted 2025-12-06 · ⚛️ physics.soc-ph · cs.SY· eess.SY

Demographic Dependence of Vaccine Adoption under Opinion Persuasion

Alessandro Casu , Camilla Quaresmini , Robin Delabays , Lewis Mitchell , Philip E. Par\'e This is my paper

Pith reviewed 2026-05-22 12:59 UTC · model grok-4.3

classification ⚛️ physics.soc-ph cs.SYeess.SY

keywords vaccine adoptionopinion dynamicssigned networksepidemic modelingdemographic heterogeneitypolicy interventionstability analysisSIS-Vo model

0 comments

The pith

Targeted policy messages on signed opinion networks can shift demographic groups toward higher vaccination and a disease-free state.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper builds a model in which vaccine information spreads across a network whose links carry positive or negative opinions, and different demographic groups respond differently to policy messages. It derives the fixed points for a healthy equilibrium with no disease and an endemic equilibrium with ongoing infection, then gives conditions under which the healthy state is locally stable. Numerical simulations show that messages aimed at particular subgroups can move the system from the endemic regime into the healthy one. A reader would care because the framework offers a way to design vaccination campaigns that remain effective even when misinformation reaches some groups more than others.

Core claim

In the SIS-Vo model, vaccine-related information propagates on a signed opinion network while subpopulations respond to policy messages with heterogeneous effects. Fixed-point equations characterize the disease-free and endemic equilibria, and local stability of the disease-free equilibrium is determined by the spectral properties of the contact network combined with opinion-dependent vaccination rates. Simulations demonstrate that suitably chosen interventions, acting through the opinion dynamics, can drive the system into the healthy regime.

What carries the argument

The SIS-Vo model, which couples an SIS epidemic process to opinion propagation on a signed network with demographic-specific policy responses.

If this is right

The disease-free equilibrium is locally stable when the contact network's largest eigenvalue and the opinion-weighted vaccination capacities satisfy a derived threshold inequality.
Policy messages that strengthen positive opinion links within high-risk demographic groups can increase their vaccination capacity enough to stabilize the whole population.
The framework supplies explicit conditions under which misinformation aimed at one subgroup can be counteracted by messages directed at another.
Control-theoretic extensions of the model can identify minimal sets of interventions that guarantee return to the healthy state.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

Real social-media data on opinion signs and vaccination rates could be used to estimate the signed network parameters and test the predicted stability thresholds.
The same modeling approach might apply to other health behaviors such as mask adoption or antibiotic use when opinions are polarized.
If demographic response heterogeneity is smaller than assumed, the required targeting precision for interventions increases.

Load-bearing premise

Vaccine information travels on a signed opinion network and different demographic groups react differently to the same policy messages.

What would settle it

A controlled experiment or field study in which policy messages are delivered to specific demographic subgroups on an observable social network and vaccination uptake is tracked over time; if uptake does not rise in the predicted subgroups or the epidemic does not decline, the stability predictions fail.

Figures

Figures reproduced from arXiv: 2512.06385 by Alessandro Casu, Camilla Quaresmini, Lewis Mitchell, Philip E. Par\'e, Robin Delabays.

**Figure 4.** Figure 4: Opinion oi compared to the infection proportions xi under three intervention strategies u. The blue triangles show the outcome of when the intervention u is aligned with the demographics di . The orange crosses show the outcome when the intervention is anti-aligned with the demographics vectors. The random intervention (black dots) gives an outcome that is closer to the anti-aligned strategy than to the a… view at source ↗

**Figure 3.** Figure 3: Steady state proportions xi versus oi for a large network (n = 200). The theoretical infection proportions (red crosses) are obtained by numerically solving Eq. (10). In the numerical simulation, the infection proportions converge to the blue dots. We observe a very good agreement between the theory and the simulations even though, due to slow convergence, some simulated infection proportions remain too h… view at source ↗

read the original abstract

Inspired by contagion models of social belief formation, we develop an epistemically-informed modeling framework, SIS-Vo, in which vaccine-related information propagates on a signed opinion network. Our model allows for heterogeneous treatment effects of policy messages across subpopulations through demographic-specific responses. We derive fixed-point characterizations of the healthy (disease-free) and endemic equilibria of this model, and obtain conditions for local stability of the healthy state in terms of the contact network and opinion-dependent vaccination capacities. Using numerical simulations, we illustrate how suitably targeted policy interventions, acting through opinion dynamics, can stabilize the epidemic process by moving the system towards the healthy regime. The SIS-Vo framework thus provides a natural basis for control-theoretic analysis of vaccination policies that remain robust even when misinformation targets specific subgroups.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

SIS-Vo model adds demographic layers to signed opinion-epidemic coupling with local stability conditions, but simulations leave open whether interventions reach the healthy state from endemic conditions.

read the letter

The main takeaway is that this paper builds an SIS-Vo framework that incorporates signed opinion networks and demographic differences into a model of vaccine adoption and epidemic spread. It derives fixed points and local stability conditions for the healthy equilibrium based on the network structure and opinion-dependent vaccination capacities. What the paper does well is lay out the mathematical structure clearly and use simulations to explore how policy interventions targeting opinions can influence the system toward lower infection levels. The low circularity from deriving stability from the equations themselves is a plus. The soft spot is the gap between local stability and the ability of interventions to move the system from an endemic state to the healthy one. Local analysis shows the healthy state can be stable under certain conditions, but to support the claim that targeted interventions stabilize the process by moving it there, the simulations need to start from endemic regimes and show convergence after the intervention. If they only illustrate local behavior or don't address potential multiple equilibria or basin sizes, that part of the argument is not as strong. The assumptions about how information spreads on signed networks and heterogeneous demographic responses are reasonable starting points but could be probed more. This kind of work is for researchers in mathematical epidemiology and opinion dynamics who are interested in integrating social factors into disease models. It has enough new construction and analysis to warrant a serious referee, even if revisions on the global dynamics would be needed. I would recommend putting it through peer review.

Referee Report

2 major / 2 minor

Summary. The manuscript introduces the SIS-Vo framework that couples SIS epidemic dynamics with opinion propagation on signed networks, allowing for demographic heterogeneity in responses to policy messages. It derives fixed-point characterizations of the healthy (disease-free) and endemic equilibria, obtains local stability conditions for the healthy state in terms of the contact network and opinion-dependent vaccination capacities, and presents numerical simulations to illustrate that suitably targeted policy interventions acting through opinion dynamics can move the system toward the healthy regime.

Significance. If the central claims hold, the SIS-Vo framework supplies a basis for control-theoretic analysis of vaccination policies that remain robust when misinformation targets specific subgroups. The paper is credited for its fixed-point derivations, local stability analysis, and numerical illustrations of opinion-mediated policy effects.

major comments (2)

[§5 (Numerical Simulations)] The abstract and §5 claim that targeted interventions can stabilize the epidemic by moving the system from an endemic regime to the healthy one. However, only local stability of the healthy equilibrium is derived; the simulations do not analyze basin boundaries, multiple equilibria, or trajectories starting from endemic initial conditions under intervention, leaving the global reachability claim unsupported.
[§4 (Stability Analysis)] The heterogeneous treatment effects across subpopulations are introduced via demographic-specific response parameters, yet the stability conditions in §4 appear to treat these as fixed rather than dynamically responsive to the signed opinion network updates; this weakens the link between opinion dynamics and the claimed policy robustness.

minor comments (2)

[§2] Notation for the signed opinion network adjacency matrix is introduced without an explicit definition of the sign convention in the model equations.
[Figure 2] Figure 2 caption does not specify the initial conditions or parameter values used for the intervention scenarios.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for their constructive comments, which have helped us improve the clarity and scope of our manuscript. We address each major comment in detail below.

read point-by-point responses

Referee: [§5 (Numerical Simulations)] The abstract and §5 claim that targeted interventions can stabilize the epidemic by moving the system from an endemic regime to the healthy one. However, only local stability of the healthy equilibrium is derived; the simulations do not analyze basin boundaries, multiple equilibria, or trajectories starting from endemic initial conditions under intervention, leaving the global reachability claim unsupported.

Authors: We agree that our current simulations primarily illustrate the effect of interventions under specific initial conditions and do not provide a comprehensive global stability analysis. To address this, we will expand §5 with additional numerical experiments that include trajectories starting from endemic equilibria and apply interventions to demonstrate convergence to the healthy state. We will also add a discussion noting that while local stability is proven, global reachability is supported numerically in the revised simulations but a full basin analysis remains for future work. revision: yes
Referee: [§4 (Stability Analysis)] The heterogeneous treatment effects across subpopulations are introduced via demographic-specific response parameters, yet the stability conditions in §4 appear to treat these as fixed rather than dynamically responsive to the signed opinion network updates; this weakens the link between opinion dynamics and the claimed policy robustness.

Authors: The stability conditions are derived for the coupled system at the joint equilibrium of the epidemic and opinion dynamics. The demographic response parameters are determined by the steady-state opinions on the signed network, which are solved as part of the fixed-point equations. The linearization accounts for the opinion updates through the Jacobian of the full system. We will revise the presentation in §4 to explicitly connect the opinion-dependent vaccination capacities to the network updates and clarify that the parameters are not fixed but equilibrium values responsive to the opinion propagation. revision: yes

Circularity Check

0 steps flagged

No circularity: equilibria and stability derived directly from model equations

full rationale

The paper constructs the SIS-Vo model from first principles combining SIS epidemic dynamics with signed opinion networks and demographic heterogeneity. Fixed-point characterizations of the healthy and endemic equilibria, plus local stability conditions in terms of the contact network and opinion-dependent vaccination capacities, are obtained by direct algebraic manipulation of the governing equations. Numerical simulations then illustrate the effect of policy interventions on opinion dynamics. No step reduces by construction to a fitted input, self-citation, or renamed ansatz; the derivation chain remains independent of the target claims and is self-contained against the model's stated assumptions.

Axiom & Free-Parameter Ledger

1 free parameters · 2 axioms · 1 invented entities

The central claims rest on modeling assumptions about network structure and opinion propagation that are introduced without independent empirical grounding in the abstract.

free parameters (1)

opinion-dependent vaccination capacities
Appears in the stability conditions and is treated as a model input that varies by opinion state.

axioms (2)

domain assumption Vaccine-related information propagates on a signed opinion network
Core modeling choice stated in the abstract as the basis for the SIS-Vo framework.
domain assumption Subpopulations exhibit heterogeneous treatment effects to policy messages
Required for the demographic-specific response feature of the model.

invented entities (1)

SIS-Vo framework no independent evidence
purpose: To couple epidemic spread with opinion dynamics on signed networks while incorporating demographic heterogeneity
New modeling construct introduced by the authors.

pith-pipeline@v0.9.0 · 5669 in / 1386 out tokens · 73008 ms · 2026-05-22T12:59:10.142617+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

20 extracted references · 20 canonical work pages

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and Selvaganesan, N

Bhowmick, S. and Selvaganesan, N. (2024). Social network-based epidemic spread with opinion-dependent vaccination. IEEE Control Systems Letters, 8, 1829--1834

work page 2024

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Eom, D., Molder, A.L., Tosteson, H.A., Howell, E.L., DeSalazar, M., Kirschner, E., Goodwin, S.S., and Scheufele, D.A. (2025). Race and gender biases persist in public perceptions of scientists’ credibility. Scientific Reports, 15(1), 11021

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Fricker, M. (2007). Epistemic Injustice: Power and the Ethics of Knowing. Oxford University Press

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Gauchat, G. (2012). Politicization of science in the public sphere: A study of public trust in the United States , 1974 to 2010. American Sociological Review, 77(2), 167--187

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Hardwig, J. (1985). Epistemic dependence. The Journal of Philosophy, 82(7), 335--349

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Horn, R.A. and Johnson, C.R. (2012). Matrix Analysis. Cambridge University Press, Cambridge, 2nd ed edition

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Kahan, D.M., Jenkins-Smith, H., and Braman, D. (2011). Cultural cognition of scientific consensus. Journal of Risk Research, 14(2), 147--174

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Leung, C.H., Gibbs, M.E., and Paré, P.E. (2022). The impact of vaccine hesitancy on epidemic spreading. In Proc. American Control Conference (ACC), 3656--3661

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Leung, H.C.H., Li, Z., She, B., and Paré, P.E. (2023). Leveraging opinions and vaccination to eradicate networked epidemics. In Proc. European Control Conference (ECC), 1--6

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Longino, H.E. (1990). Science as Social Knowledge: Values and Objectivity in Scientific Inquiry. Princeton University Press

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Mitchell, L. and Ross, J.V. (2016). A data-driven model for influenza transmission incorporating media effects. Royal Society Open Science, 3(10), 160481

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Newman, M.E.J. (2010). Networks: An Introduction. Oxford University Press

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She, B., Liu, J., Sundaram, S., and Paré, P.E. (2022). On a networked SIS epidemic model with cooperative and antagonistic opinion dynamics. IEEE Transactions on Control of Network Systems, 9(3), 1154--1165

work page 2022

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Sieghart, M.A. (2022). The Authority Gap: Why Women Are Still Taken Less Seriously Than Men, and What We Can Do About It. WW Norton & Company

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