Hiring in life sciences? Share your open positions with our professional community. Read more Close

Advertisement

Global Stability Analysis of a Mathematical Model for the "Shock-and-Kill" Strategy in HIV-1/SIV Brain Infection.

Created on 13 Jul 2026

Authors

Yongli Cai, Weiming Wang

Published in

Bulletin of mathematical biology. Volume 88. Issue 8. Jul 13, 2026. Epub Jul 13, 2026.

Abstract

This paper provides a rigorous mathematical resolution of the open global stability problem for a "shock-and-kill" model of HIV-1/SIV infection in brain reservoirs recently formulated by Roda et al. (2021). The model explicitly incorporates the effects of latency-reversing agents and enhanced immune clearance of reactivated cells. We derive an explicit formula for the basic reproduction number R 0 , which serves as the sole threshold parameter governing viral eradication versus persistence and integrates infection pathways from both productive and latent compartments. By combining the next-generation matrix approach with an extended graph-theoretic Lyapunov method for multigraphs with parallel arcs, we rigorously establish that the disease-free equilibrium is globally asymptotically stable when R 0 1 , whereas a unique productive equilibrium exists and is globally asymptotically stable when R 0 > 1 . To resolve the sign-indefinite quadratic perturbations induced by structurally distinct parallel transmission arcs-a fundamental bottleneck of classical graph-theoretic Lyapunov schemes-we develop a refined composite Lyapunov framework equipped with hierarchically calibrated parameters. Systematic asymptotic scaling and multi-parameter tuning eliminate indefinite cyclic quadratic interactions, securing strict negative definiteness of the Lyapunov derivative and overcoming key limitations of conventional graph-based methods. These global stability results provide a definitive mathematical answer to whether therapeutic interventions guarantee viral eradication or lead to persistent brain-reservoir infection. Furthermore, they furnish a rigorous theoretical foundation for the "shock-and-kill" strategy and establish mathematically precise conditions to guide the design of safe, effective interventions for eliminating HIV-1/SIV from CNS reservoirs.

PMID:
42440225
Bibliographic data and abstract were imported from PubMed on 13 Jul 2026.

Read full publication at:
Please sign in to see all details.

Advertisement

Stats

  • Community rating n/a 0 votes
  • Reviewers' rating n/a 0 votes
  • Your rating

1-terrible, 9-excellent. How would you rate this publication? Sign in in to submit your rating.

  • Recommendations n/a n/a positive of 0 vote(s)
  • Views 6
  • Comments 0

Recommended by

  • No recommendations yet.

Post a comment

You need to be signed in to post comments. You can sign in here.

Comments

There are no comments yet.

Advertisement