A computational tool integrating host immunity with antibiotic dynamics to study tuberculosis treatment

A computational tool integrating host immunity with antibiotic dynamics to study tuberculosis treatment

While active tuberculosis (TB) is a treatable disease, many complex factors prevent its global elimination. Part of the difficulty in developing optimal therapies is the large design space of antibiotic doses, regimens and combinations. Computational models that capture the spatial and temporal dyna...

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Bibliographic Details
Published in:Journal of theoretical biology Vol. 367; pp. 166 - 179
Main Authors: Pienaar, Elsje, Cilfone, Nicholas A, Lin, Philana Ling, Dartois, Véronique, Mattila, Joshua T, Butler, J Russell, Flynn, JoAnne L, Kirschner, Denise E, Linderman, Jennifer J
Format: Journal Article
Language:English
Published: England Elsevier 21-02-2015
Subjects:
60 APPLIED LIFE SCIENCES
agent based model
Animals
Anti-Bacterial Agents - pharmacokinetics
Anti-Bacterial Agents - pharmacology
Anti-Bacterial Agents - therapeutic use
antibiotic gradients
Antitubercular Agents - pharmacokinetics
Antitubercular Agents - pharmacology
Antitubercular Agents - therapeutic use
Calibration
Computer Simulation
Disease Models, Animal
Dose-Response Relationship, Drug
granuloma
Granuloma - immunology
Granuloma - pathology
Humans
Immunity - drug effects
Isoniazid - pharmacokinetics
Isoniazid - therapeutic use
MATHEMATICS AND COMPUTING
Mice
Models, Biological
Mycobacterium
Mycobacterium tuberculosis - drug effects
Mycobacterium tuberculosis - growth & development
pharmacodynamics
pharmacokinetics
Primates
Rifampin - pharmacokinetics
Rifampin - therapeutic use
Time Factors
Treatment Outcome
Tuberculosis - drug therapy
Tuberculosis - immunology
Tuberculosis - microbiology
Tuberculosis - pathology
Granuloma
Pharmacodynamics
Agent based model
Pharmacokinetics
Antibiotic gradients
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Summary:While active tuberculosis (TB) is a treatable disease, many complex factors prevent its global elimination. Part of the difficulty in developing optimal therapies is the large design space of antibiotic doses, regimens and combinations. Computational models that capture the spatial and temporal dynamics of antibiotics at the site of infection can aid in reducing the design space of costly and time-consuming animal pre-clinical and human clinical trials. The site of infection in TB is the granuloma, a collection of immune cells and bacteria that form in the lung, and new data suggest that penetration of drugs throughout granulomas is problematic. Here we integrate our computational model of granuloma formation and function with models for plasma pharmacokinetics, lung tissue pharmacokinetics and pharmacodynamics for two first line anti-TB antibiotics. The integrated model is calibrated to animal data. We make four predictions. First, antibiotics are frequently below effective concentrations inside granulomas, leading to bacterial growth between doses and contributing to the long treatment periods required for TB. Second, antibiotic concentration gradients form within granulomas, with lower concentrations toward their centers. Third, during antibiotic treatment, bacterial subpopulations are similar for INH and RIF treatment: mostly intracellular with extracellular bacteria located in areas non-permissive for replication (hypoxic areas), presenting a slowly increasing target population over time. Finally, we find that on an individual granuloma basis, pre-treatment infection severity (including bacterial burden, host cell activation and host cell death) is predictive of treatment outcome.
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SourceType-Scholarly Journals-1
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content type line 23
AC02-05CH11231
USDOE Office of Science (SC)
ISSN:0022-5193
1095-8541
DOI:10.1016/j.jtbi.2014.11.021