OOIR: Observatory of International Research

Papers

(The H4-Index of Journal of Mathematical Biology is 19. The table below lists those papers that are above that threshold based on CrossRef citation counts [max. 250 papers]. The publications cover those that have been published in the past four years, i.e., from 2021-03-01 to 2025-03-01.)

Article	Citations
Dynamical analysis of a stochastic maize streak virus epidemic model with logarithmic Ornstein–Uhlenbeck process	49
Site-bond percolation model of epidemic spreading with vaccination in complex networks	46
Gain and loss of function mutations in biological chemical reaction networks: a mathematical model with application to colorectal cancer cells	46
A branching model for intergenerational telomere length dynamics	35
SIRC epidemic model with cross-immunity and multiple time delays	33
The role of A$$\beta $$ and Tau proteins in Alzheimer’s disease: a mathematical model on graphs	31
Perturbation theory for evolution of cooperation on networks	29
Relative prevalence-based dispersal in an epidemic patch model	27
Three-stage modeling of HIV infection and implications for antiretroviral therapy	26
An estimator for the recombination rate from a continuously observed diffusion of haplotype frequencies	26
The expected loss of feature diversity (versus phylogenetic diversity) following rapid extinction at the present	24
A Markovian arrival stream approach to stochastic gene expression in cells	24
Homeostatic regulation of renewing tissue cell populations via crowding control: stability, robustness and quasi-dedifferentiation	21
Adaptation in a heterogeneous environment II: to be three or not to be	20
A comparison of mutation and amplification-driven resistance mechanisms and their impacts on tumor recurrence	20
Rich dynamics of a bidirectionally linked immuno-epidemiological model for cholera	19
Dynamics of consumer-resource reaction-diffusion models: single and multiple consumer species	19
Nonlinear diffusion in multi-patch logistic model	19
Characterization of differential susceptibility and differential infectivity epidemic models	19