Transmission dynamics of community-and hospital-acquired infections: insights from mathematical modelling

Authors

  • Peace P. Desben
    Department of Mathematics, University of Jos, Jos, Nigeria
  • Emmanuel N. Dashe
    Department of Mathematics, University of Jos, Jos, Nigeria
  • Joel N. Ndam
    Department of Mathematics, University of Jos, Jos, Nigeria

Keywords:

Community transmission, local and global stability, bifurcation analysis, hospital-acquired infection

Abstract

Hospital-associated infections (HAIs) remain a critical public health challenge, particularly in resource-limited settings where surveillance and infection control are inadequate. This study develops and analyzes a modified S E I R mathematical model, denoted by S EcIcEhIhR, to capture the transmission dynamics of infectious diseases across hospital and community settings. The model incorporates both community and hospital transmission of infections, which have not been addressed jointly in previous studies. Using the next-generation matrix approach, the basic reproduction number (R0) was determined. Local and global stability analyses revealed that the disease-free equilibrium is stable when R0 < 1, but unstable otherwise. Sensitivity analysis identified the recruitment rate, community contact rate, and hospital infection rate as the most influential parameters, with community transmission exerting a stronger impact on the overall dynamics than hospital transmission. Numerical simulations further confirmed the dominant role of community transmission over hospital infections. Bifurcation analysis confirmed the possibility of backward bifurcation, indicating the possible coexistence of endemic and disease-free equilibrium states, even when R0 < 1. These findings highlight the complex interplay between hospital and community transmission and indicate that effective control strategies must prioritize reducing community contact rates while strengthening hospital infection-prevention measures. The model provides insights for policymakers and healthcare managers designing evidence-based interventions to mitigate HAIs and community outbreaks, particularly in countries facing systemic healthcare challenges.

Dimensions

[1] Centers for disease control and prevention, ``2023 National and State Healthcare-Associated Infections Progress Report'', 2024. Available online: https://arpsp.cdc.gov/profile/national-progress-2023/united-states.

[2] G. Hutton, C. Chase, R. Kennedy-Walker & H. Hamilton, ``Financial and economic costs of healthcare-associated infections in Africa'', Journal of Hospital Infection 150 (2024) 1. https://doi.org/10.1016/j.jhin.2024.04.015.

[3] U. Igwe, O.J. Okolie, S.U. Ismail & E. Adukwu, “Effectiveness of infection prevention and control interventions in health care facilities in Africa: A systematic review”, American Journal of Infection Control 52 (2024) 1135. https://doi.org/10.1016/j.ajic.2024.06.004.

[4] C.D. Onwuliri, I.U. Ezebialu, A. Adebisi, G.U. Eleje, B. Akinola, C.U. Ezebialu, K. Abdullahi, B. Okoro, C. Okoroafor, O. John, M. Gadanya, F. Alomba, E. Okechukwu, H. Swomen & T.J. Okwor., ``Systematic review and meta-analysis of the prevalence and types of healthcare-associated infections in Nigeria'', BMC Infectious Diseases 25 (2025) 836. https://doi.org/10.1186/s12879-025-11246-1.

[5] A. Odoom, P. B. Tetteh-Quarcoo & E. S. Donkor, ``Prevalence of hospital-acquired infections in low- and middle-income countries: systematic review and meta-analysis'', Asia-Pacific Journal of Public Health 37 (2025) 448. https://doi.org/10.1177/10105395251338002.

[6] U. Abubakar, O. Amir & J. Rodriguez-Ba~{n}o, ``Healthcare-associated infections in Africa: a systematic review and meta-analysis of point prevalence studies'', Journal of Pharmaceutical Policy and Practice 15 (2022) 99. https://doi.org/10.1186/s40545-022-00500-5.

[7] L. Milazzo, J. L. Brown, A. Eberst, G. Phillips & J. W. Crawford, ``Modelling of healthcare-associated infections: a study on the dynamics of pathogen transmission by using an individual-based approach'', Computer Methods and Programs in Biomedicine 104 (2011) 260. https://doi.org/10.1016/j.cmpb.2011.02.002.

[8] A. A. Alimi & A. A. Ayoade, ``Mathematical modelling of the effect of vaccination on the dynamics of infectious diseases'', Nepal Journal of Mathematical Sciences 4 (2023) 1. https://doi.org/10.3126/njmathsci.v4i1.53151.

[9] R. Assab, N. Nekkab, P. Crepey, P. Astagneau, D. Guillemot, L. Opatowski & L. Temime, ``Mathematical models of infection transmission in healthcare settings: recent advances from the use of network structured data'', Current Opinion in Infectious Diseases 30 (2017) 410. https://doi.org/10.1097/QCO.0000000000000390.

[10] A. Omame & M. Abbas, ``The stability analysis of a co-circulation model for COVID-19, dengue, and zika with nonlinear incidence rates and vaccination strategies'', Healthcare Analytics 3 (2023) 100151. https://doi.org/10.1016/j.health.2023.100151.

[11] M. O. Adewole, A. A. Onifade, A. F. Abdullah, F. Fasali & M. I. Ismail, ``Modeling the dynamics of COVID-19 in Nigeria'', International Journal of Applied and Computational Mathematics 7 (2021) 67. https://doi.org/10.1007/s40819-021-01014-5.

[12] O. Adedire & J. N. Ndam, ``Mathematical model for the spread of COVID-19 in Plateau State, Nigeria'', Journal of the Egyptian Mathematical Society 30 (2022) 10. https://doi.org/10.1186/s42787-022-00144-z.

[13] V. O. Akinsola, M. O. Adeyemi, A. O. Eesuola, O. I. Adebayo, E. K. Oladipo & F. A. Ayodeji, ``Analysis of transmission dynamics of COVID-19 in Nigeria: mathematical modelling'', Adeleke University Journal of Science 1 (2022) 360. Available online: https://aujs.adelekeuniversity.edu.ng/index.php/aujs/article/view/56.

[14] E. A. Iboi, O. Sharomi, C. N. Ngonghala & A. B. Gumel, ``Mathematical modelling and analysis of COVID-19 in Nigeria'', Mathematical Biosciences and Engineering 17 (2020) 7192. https://doi.org/10.3934/mbe.2020369.

[15] J. N. Ndam, ``Modelling the impacts of lockdown and isolation on the eradication of COVID-19'', Biomath 9 (2020) 2009107. Available online: https://doi.org/10.11145/j.biomath.2020.09.107.

[16] J. Wang, G. Wang, Y. Wang & Y. Wang, ``Development and evaluation of a model for predicting the risk of healthcare-associated infections in patients admitted to intensive care units'', Frontiers in Public Health 12 (2024) 1444176. https://doi.org/10.3389/fpubh.2024.1444176.

[17] H. Tahir, L. E. L'{o}pez-Cort'{e}s, A. Kola, D. Yahav, A. Karch, H. Xia, J. Horn, K. Sakowski, M. J. Piotrowska, L. Leibovici, R. T. Mikolajczyk & M. E. Kretzschmar, ``Relevance of intra-hospital patient movements for the spread of healthcare-associated infections within hospitals: a mathematical modelling study'', PLoS Computational Biology 17 (2021) e1008600. https://doi.org/10.1371/journal.pcbi.1008600.

[18] I. Zada, M. N. Jan, N. Ali, D. Alrowail, K. S. Nisar & G. Zaman, ``Mathematical analysis of hepatitis B epidemic model with optimal control'', Advances in Difference Equations 2021 (2021) 451. https://doi.org/10.1186/s13662-021-03607-2.

[19] Statista, ``Total life expectancy at birth in Nigeria from 1960 to 2023'', Statista Research Department, 2026. Available online: https://www.statista.com/statistics/382222/life-expectancy-at-birth-in-nigeria/. access date: April 12, 2026.

[20] T. T. Ashezua, L. C. Aondona & A. U. Amaonyeiro, ``Modelling the transmission dynamics of COVID-19 incorporating public enlightenment campaign'', Journal of Applied Sciences and Environmental Management 26 (2022) 1721. Available online: https://doi.org/10.4314/jasem.v26i10.17.

[21] O. Diekmann, J. A. P. Heesterbeek & J. A. J. Metz, ``On the definition and the computation of the basic reproduction ratio (R_0) in models for infectious diseases in heterogeneous populations'', Journal of Mathematical Biology 28 (1990) 365. https://doi.org/10.1007/BF00178324.

[22] C. Castillo-Chavez & B. Song, ``Dynamical models of tuberculosis and their applications'', Mathematical Biosciences and Engineering 1 (2004) 361. https://doi.org/10.3934/mbe.2004.1.361.

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Published

2026-05-29

How to Cite

Transmission dynamics of community-and hospital-acquired infections: insights from mathematical modelling. (2026). African Scientific Reports, 5(2), 448. https://doi.org/10.46481/asr.2026.5.2.448

Issue

Volume 5, Issue 2, August 2026

Section

SPECIAL ISSUE IN HONOUR OF PROF. OLABODE MATTHIAS BAMIGBOLA
Copyright & Licensing

Copyright (c) 2026 Peace P. Desben, Emmanuel N. Dashe, Joel N. Ndam

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

How to Cite

Transmission dynamics of community-and hospital-acquired infections: insights from mathematical modelling. (2026). African Scientific Reports, 5(2), 448. https://doi.org/10.46481/asr.2026.5.2.448

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