SUPPRESSION OF VIABILITY OF STAPHYLOCOCCI CELLS BY 1270 NM LASER BEAM
- Authors: Fialkina SV1, Alekseev Y.V1, Konovalova GN1, Lukovkin AV1, Bondarenko VM1
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Affiliations:
- Issue: Vol 89, No 5 (2012)
- Pages: 70-73
- Section: Articles
- Submitted: 13.06.2023
- Published: 15.10.2012
- URL: https://microbiol.crie.ru/jour/article/view/14210
- ID: 14210
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Full Text
Abstract
Aim. Study the effect of 1270 nm wavelength laser exposure on the viability of Staphylocoсcus aureus and
S. epidermidis cells in vitro. Materials and methods. Reference strain S. aureus 209P and clinical isolate
S. epidermidis 26/193 that form bacterial biofilm were used in the study. Ica gene presence in S. epidermidis
26/193 that controls biofilm formation was confirmed in the study by PCR with a primer that generates a
specific 814 n.p. amplicon. Experimental device by «ew surgical technologies, Ltd.»was used as a source
of emission. The device has a continuous emission mode of laser semiconductor diodes with 1270 nm wavelength.
Maximum regulated power of the emission is up to 3 W. Emission power in the studies performed was
150 mW. The time of exposition was 5, 10, 15 and 30 minutes. The amount of viable cells in the experiment
and control was determined by calculating CFU/ml. Evaluation of bacterial biofilm formation was performed
by the method described in OToole G.A. et al. (2000). Results. A decrease of the number of viable forms of
S. aureus 209P by a mean of 52±.0% and 76±.0%, and of S. epidermidis 26/193 by a mean of 48±% and
64±% for 15 and 30 min exposition, respectively, and a significant suppression of biofilm formation by
staphylococci was shown. Conclusion. Exposure to 1270 nm laser renders a moderate bactericidal effect on
staphylococci cells and significantly suppresses their bacterial biofilm formation.
S. epidermidis cells in vitro. Materials and methods. Reference strain S. aureus 209P and clinical isolate
S. epidermidis 26/193 that form bacterial biofilm were used in the study. Ica gene presence in S. epidermidis
26/193 that controls biofilm formation was confirmed in the study by PCR with a primer that generates a
specific 814 n.p. amplicon. Experimental device by «ew surgical technologies, Ltd.»was used as a source
of emission. The device has a continuous emission mode of laser semiconductor diodes with 1270 nm wavelength.
Maximum regulated power of the emission is up to 3 W. Emission power in the studies performed was
150 mW. The time of exposition was 5, 10, 15 and 30 minutes. The amount of viable cells in the experiment
and control was determined by calculating CFU/ml. Evaluation of bacterial biofilm formation was performed
by the method described in OToole G.A. et al. (2000). Results. A decrease of the number of viable forms of
S. aureus 209P by a mean of 52±.0% and 76±.0%, and of S. epidermidis 26/193 by a mean of 48±% and
64±% for 15 and 30 min exposition, respectively, and a significant suppression of biofilm formation by
staphylococci was shown. Conclusion. Exposure to 1270 nm laser renders a moderate bactericidal effect on
staphylococci cells and significantly suppresses their bacterial biofilm formation.
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