The Impact of Chemotherapy for Drug-Resistant Respiratory Tuberculosis on the Composition of Fecal Microbiota in Children
https://doi.org/10.58838/2075-1230-2026-104-1-8-18
Abstract
The objective: to study the species and quantitative composition of fecal microbiota in children undergoing chemotherapy for drug-resistant respiratory tuberculosis.
Subjects and Methods. The study included 17 children from 2 to 12 years old with respiratory tuberculosis who received treatment for drug-resistant respiratory tuberculosis from 2022 to 2024 at Central Tuberculosis Research Institute. Fecal microbiota was tested by real-time PCR using the ENTEROFLOR® Children reagent kit at the following time points: before the start of chemotherapy, after 2 and 4 months of chemotherapy.
Results. The most pronounced disturbances in the intestinal microbiocenosis among representatives of normobiota were noted after 2 months of chemotherapy; by 4 months, those parameters did not deteriorate either in quantitative terms or frequency of deviations from reference values: for representatives of the phylum Actinomycetota (Actinobacteria) – in Bifidobacterium spp. and Coriobacteriia, for representatives of the phylum Bacteroidota (Bacteroidetes) – in Butyricimonas spp., Parabacteroides spp., Prevotella spp. Changes in the composition of normobiota were associated with the elevated proportion of opportunistic microbiota by 2 months and persistence of these values by 4 months of chemotherapy. Representatives of pathogenic microbiota, which were not present before chemotherapy, appeared by 2 months of chemotherapy with the following frequency: Streptococcus agalactiae – in 35.3% of cases, Clostridioides difficile, with the toxigenic genes cdtA and cdtB – in 58.9%, and increasing to 71.5% by 4 months of chemotherapy.
Conclusion. Treatment with chemotherapy regimens for drug-resistant tuberculosis has a statistically significant negative impact on intestinal microbiota in children: the proportion of normobiota decreases, the proportion of opportunistic microbiota increases, and pathogenic microbiota develops.
Keywords
About the Authors
N. V. YukhimenkoRussian Federation
Natalya V. Yukhimenko, Doctor of Medical Sciences, Leading Researcher of Children and Adolescents Department
2 Yauzskaya Alleya, Moscow, 107564
Phone: +7 (499) 785-30-23
S. S. Sterlikova
Russian Federation
Svetlana S. Sterlikova, Physician of Junior Children Department
2 Yauzskaya Alleya, Moscow, 107564
Phone: +7 (499) 785-30-23
M. F. Gubkina
Russian Federation
Marina F. Gubkina, Doctor of Medical Sciences, Head Researcher of Children and Adolescents Department, Professor of Phthisiology Department
2 Yauzskaya Alleya, Moscow, 107564
Phone: +7 (499) 785-30-23
S. I. Kayukova
Russian Federation
Sveltana I. Kayukova, Doctor of Medical Sciences, Leading Researcher of Immunology Department, Professor of Phthisiology Department
2 Yauzskaya Alleya, Moscow, 107564
Phone: +7 (499) 785-30-23
A. E. Donnikov
Russian Federation
Andrey E. Donnikov, Candidate of Medical Sciences, Head of Laboratory of Molecular Genetic Methods, Associate Professor of Department of Clinical Laboratory Diagnostics, Medical Microbiology and Pathological Anatomy
4 Akademika Oparina St., Moscow, 117997
Phone: +7 (495) 531-44-44
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Review
For citations:
Yukhimenko N.V., Sterlikova S.S., Gubkina M.F., Kayukova S.I., Donnikov A.E. The Impact of Chemotherapy for Drug-Resistant Respiratory Tuberculosis on the Composition of Fecal Microbiota in Children. Tuberculosis and Lung Diseases. 2026;104(1):8-16. (In Russ.) https://doi.org/10.58838/2075-1230-2026-104-1-8-18
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