Analisis Model Stokastik Birth-Death pada Populasi Bakteri Esherichia coli dengan Kematian di Bawah Tekanan Antibiotik

Farhan Anshari; Puspa Arinda Ginting; Anggi Pasha Aritonang; Elizabeth Hutasoit; Oliver Juan Gery Manihuruk; Sudianto Manullang; Alvi Sahrin Nasution

doi:10.31004/innovative.v5i3.19442

Analisis Model Stokastik Birth-Death pada Populasi Bakteri Esherichia coli dengan Kematian di Bawah Tekanan Antibiotik

Authors

Farhan Anshari Universitas Negeri Medan
Puspa Arinda Ginting Universitas Negeri Medan
Anggi Pasha Aritonang Universitas Negeri Medan
Elizabeth Hutasoit Universitas Negeri Medan
Oliver Juan Gery Manihuruk Universitas Negeri Medan
Sudianto Manullang Universitas Negeri Medan
Alvi Sahrin Nasution Universitas Negeri Medan

DOI:

https://doi.org/10.31004/innovative.v5i3.19442

Keywords:

Birth-Death, Escherichia coli, Minimum Inhibitory Concentration (MIC), Populasi Bakteri

Abstract

Penelitian membahas model stokastik dinamika populasi bakteri Escherichia coli pada kondisi tekanan antibiotik, khususnya pada konsentrasi Minimum Inhibitory Concentration (MIC), menggunakan proses birth-death linier sebagai kerangka dasar. Dinamika sistem dianalisis melalui master equation untuk memperoleh distribusi probabilitas waktu-ke-waktu, distribusi stasioner, serta waktu rata-rata kepunahan (Mean Time to Extinction) dan probabilitas first-passage time. Pendekatan stokastik mengintegrasikan model berbasis widget pada tingkat sel individu, di mana setiap sel direpresentasikan sebagai unit molekuler minimum. Ketika jumlah widget mencapai ambang batas, sistem mengalami kematian atau pembelahan, masing-masing dengan distribusi binomial simetris. Analisis dilakukan secara teoritis melalui simulasi Monte Carlo berbasis Python. Hasil menunjukkan bahwa meskipun rata-rata populasi tampak stasioner pada kondisi, sistem mengalami fluktuasi stokastik signifikan yang memicu aktivitas mikroskopik intens. Varians populasi meningkat terhadap waktu, menandakan instabilitas tersembunyi. Simulasi menunjukkan bahwa waktu rata-rata kepunahan meningkat subeksponensial terhadap ukuran populasi awal.

References

Chib, S., Portier, N., & Singer, B. (2018). Stochastic fluctuations at the MIC: Modeling the hidden dynamics of cell death and division. Journal of Antimicrobial Chemotherapy, 73(5), 1271–1278.

Di Crescenzo, A., & Paraggio, P. (2019). Logistic growth described by birth-death and diffusion processes. Mathematics, 7(6), 489. https://doi.org/10.3390/math7060489

Jamieson, N., Charalambous, C., Schultz, D. M., & Hall, I. (2025). A within-host birth–death and time–dose–response model for Legionnaires’ disease. medRxiv. https://doi.org/10.1101/2025.01.31.25321481

Jones, E. W., Derrick, J., Nisbet, R. M., Ludington, W. B., & Sivak, D. A. (2023). First-passage-time statistics of growing microbial populations carry an imprint of initial conditions. Scientific Reports, 13, 21340. https://doi.org/10.1038/s41598-023-48726-w

Koyama, K., Aspridou, Z., Abe, H., Koutsoumanis, K., & Koseki, S. (2025). Reconsidering stochasticity in modeling of bacterial population growth and inactivation with technical and biological variability. Journal of Food Protection, 88, 100482. https://doi.org/10.1016/j.jfp.2025.100482

Marrec, L., & Bank, C. (2023). Solving the stochastic dynamics of population growth. Ecology and Evolution, 13(8), e10295. https://doi.org/10.1002/ece3.10295

Martínez-López, N., Vilas, C., & García, M. R. (2024). A birth–death model to understand bacterial antimicrobial heteroresistance from time-kill curves. Mathematical Biosciences, 376, 109278. https://doi.org/10.1016/j.mbs.2024.109278

Mansour, M. (2023). Stochastic models of antibiotic resistance and mutational rescue. Journal of Theoretical Biology, 568, 111506.

Novozhilov, A. S., Karev, G. P., & Koonin, E. V. (2006). Biological applications of the theory of birth-and-death processes. Briefings in Bioinformatics, 7(1), 70–85.

Pramuditya, S. A., Marwati, R., & Puspita, E. (2020). Model Stokastik Pertumbuhan Populasi (Pure Birth Process). Jurnal Euclid, 4(1), pp. 604–688.

Teimouri, H., & Kolomeisky, A. B. (2019). Stochastic modeling of population extinction. The Journal of Chemical Physics, 150(6), 064113.

Wang, Y., Liu, T., & Zhang, L. (2022). Escherichia coli as a model organism in synthetic biology and systems biology. Synthetic and Systems Biotechnology, 7(1), 64–72. https://doi.org/10.1016/j.synbio.2021.12.005

Xia, H., Cheng, X., & Xu, Y. (2023). Stochastic persistence and heterogeneity in E. coli under antibiotic stress. mSystems, 8(2), e01234-22. https://doi.org/10.1128/msystems.01234-22

Downloads

Published

2025-06-30

How to Cite

Anshari, F., Ginting, P. A., Aritonang, A. P., Hutasoit, E., Manihuruk, O. J. G., Manullang, S., & Nasution, A. S. (2025). Analisis Model Stokastik Birth-Death pada Populasi Bakteri Esherichia coli dengan Kematian di Bawah Tekanan Antibiotik. Innovative: Journal Of Social Science Research, 5(3), 8386–8398. https://doi.org/10.31004/innovative.v5i3.19442