Environmental drivers of tuberculosis transmission in Guangdong, China: Integrating generalized additive models and dynamic simulations
Kong L, Mo Y, Zhu G, Chen L, Wang Z
Mathematical biosciences · 2025-12
Abstract
Tuberculosis (TB) remains a critical global public health challenge, particularly in high-burden regions like Guangdong Province, China. This study develops an integrated framework combining generalized additive models (GAM) and non-autonomous dynamical modeling to elucidate the synergistic effects of environmental and socioeconomic factors on TB transmission dynamics. Utilizing weekly TB case data, air quality index (AQI), absolute humidity (AH), and holiday indicators from Guangdong (2014-2019), GAM quantified nonlinear lagged effects of environmental exposures (AQI, AH) and aperiodic drivers (holidays) on incidence. Results revealed that a 10-unit increase in AQI elevated TB risk by 3.8 % (95 % CI: 1.2-6.5 %), while AH exhibited a negative regulatory effect on transmission. Holiday-related population aggregation amplified case fluctuations by 37 % (p 0 was estimated at 1.9 (95 % CI: 1.2-2.6). Bifurcation analysis confirmed global stability of the disease-free equilibrium when R 0 0 > 1. Sensitivity analysis identified infection rate and relapse probability as dominant drivers of transmission intensity. The model predicted a declining long-term trend (-2.6 % annually) but persistent winter-spring seasonality. This hybrid approach providing a quantitative tool for optimizing intervention strategies. Key recommendations include reducing airborne pollutants, enhancing surveillance, and targeting relapse prevention to mitigate endemic persistence.
MeSH terms
- Humans
- Tuberculosis
- Incidence
- Air Pollution
- Environmental Exposure
- Computer Simulation
- China
- Basic Reproduction Number