A chain-binomial model for intra-household spread of Mycobacterium tuberculosis in a low socio-economic setting in Pakistan

S. AKHTAR; T. E. CARPENTER; S. K. RATHI

doi:10.1017/S0950268806006364

Abstract

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A simulation study using Greenwood's chain-binomial model was carried out to elucidate the spread and control of Mycobacterium tuberculosis among the household contacts of infectious pulmonary tuberculosis (TB) patients. Based on the observed data, the maximum-likelihood estimates (±S.E.) of chain-binomial probabilities of intra-household M. tuberculosis transmission from an index case in 3-person and 4-person households were 0·313±0·008 and 0·325±0·009 respectively. The χ2 goodness-of-fit test of observed and simulated mean expected frequencies of cases revealed good fit for 3-person (P=0·979) and 4-person (P=0·546) households. With the assumption of varying risk of M. tuberculosis transmission across the households under β-distribution, goodness-of-fit tests of observed and mean simulated expected frequencies revealed the inadequacy of Greenwood's chain-binomial model both for 3-person (P=0·0185) and 4-person (P<0·001) households. Simulated M. tuberculosis control strategy comprising efficient diagnosis, segregation and prompt antibiotic therapy of index pulmonary TB patients showed a substantial reduction of new cases among the household contacts in both household sizes. In conclusion, segregation coupled with prompt antibiotic therapy of the index case, chemoprophylaxis of M. tuberculosis-exposed household contacts, and the assessment of household environmental risks to devise and implement an educational programme may help reduce the TB burden in this and similar settings.

Crossref Citations

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Hussain, Rabia Talat, Najeeha Shahid, Firdaus and Dawood, Ghaffar 2007. Longitudinal Tracking of Cytokines after Acute Exposure to Tuberculosis: Association of Distinct Cytokine Patterns with Protection and Disease Development. Clinical and Vaccine Immunology, Vol. 14, Issue. 12, p. 1578.

Ansari, Ambreen Talat, Najeeha Jamil, Bushra Hasan, Zahra Razzaki, Tashmeem Dawood, Ghaffar Hussain, Rabia and Ratner, Adam J. 2009. Cytokine Gene Polymorphisms across Tuberculosis Clinical Spectrum in Pakistani Patients. PLoS ONE, Vol. 4, Issue. 3, p. e4778.

Brooks-Pollock, E. Becerra, M. C. Goldstein, E. Cohen, T. and Murray, M. B. 2011. Epidemiologic Inference From the Distribution of Tuberculosis Cases in Households in Lima, Peru. Journal of Infectious Diseases, Vol. 203, Issue. 11, p. 1582.

Meenakshi, P. Ramya, S. Shruthi, T. Lavanya, J. Mohammed, H. H. Mohammed, S. A. Vijayalakshmi, V. and Sumanlatha, G. 2013. Association of IL‐1β +3954 C/T and IL‐10‐1082 G/A Cytokine Gene Polymorphisms with Susceptibility to Tuberculosis. Scandinavian Journal of Immunology, Vol. 78, Issue. 1, p. 92.

Hsu, Chen-Yang Yen, Amy Ming-Fang Chen, Li-Sheng and Chen, Hsiu-Hsi 2014. Surveillance of influenza from household to community in Taiwan. Transactions of The Royal Society of Tropical Medicine and Hygiene, Vol. 108, Issue. 4, p. 213.

Thada, Shruthi Ponnana, Meenakshi Sivangala, Ramya Joshi, Lavanya Alasandagutti, Madhavilatha Ansari, Mohd Soheb Sadat Schumann, Ralf R. Valluri, Vijayalakshmi and Gaddam, Sumanlatha 2016. Polymorphisms of IFN-γ (+874A/T) and IL-12 (+1188A/C) in tuberculosis patients and their household contacts in Hyderabad, India. Human Immunology, Vol. 77, Issue. 7, p. 559.

Khan, Ali H. 2017. Tuberculosis control in Sindh, Pakistan: Critical analysis of its implementation. Journal of Infection and Public Health, Vol. 10, Issue. 1, p. 1.

Hussain, Sana Hasnain, Jamshed Hussain, Zareen Badshah, Masroor Siddique, Hafeez Fiske, Christina and Pettit, April 2018. Type of Treatment Supporters in Successful Completion of Tuberculosis Treatment: A Retrospective Cohort Study in Pakistan. The Open Infectious Diseases Journal, Vol. 10, Issue. 1, p. 37.

Abel, Laurent Fellay, Jacques Haas, David W Schurr, Erwin Srikrishna, Geetha Urbanowski, Michael Chaturvedi, Nimisha Srinivasan, Sudha Johnson, Daniel H and Bishai, William R 2018. Genetics of human susceptibility to active and latent tuberculosis: present knowledge and future perspectives. The Lancet Infectious Diseases, Vol. 18, Issue. 3, p. e64.

Laghari, Madeeha Sulaiman, Syed Azhar Syed Khan, Amer Hayat and Memon, Naheed 2018. Epidemiology of tuberculosis and treatment outcomes among children in Pakistan: a 5 year retrospective study. PeerJ, Vol. 6, Issue. , p. e5253.

Crawford, Forrest W. Marx, Florian M. Zelner, Jon and Cohen, Ted 2020. Transmission Modeling with Regression Adjustment for Analyzing Household-based Studies of Infectious Disease. Epidemiology, Vol. 31, Issue. 2, p. 238.

Loginov, K. and Pertsev, N. 2021. Direct Statistical Modeling of Spread of Epidemic Based On a Stage-Dependent Stochastic Model. Mathematical Biology and Bioinformatics, Vol. 16, Issue. 2, p. 169.

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A chain-binomial model for intra-household spread of Mycobacterium tuberculosis in a low socio-economic setting in Pakistan

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