Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability

The Escherichia coli(E. coli) isGram negative bacteria, that normally live in the digestive tracts of humans and animals, can cause bloody diarrhea, severe anemia or kidney falureand other illnesses which can lead to death.Systemic therapy with antibiotic cause bacteria resistant. So,an alternative...

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Main Authors:	Suryani Dyah Astuti, R. Arif Wibowo, Abdurachman, NIDN. 0011096602, Kuwat Triyana
Format:	Article PeerReviewed
Language:	Indonesian English English
Published:	EBSCO Industrias 2017
Subjects:	R5-920 Medicine (General)
Online Access:	http://repository.unair.ac.id/84534/6/Antimicrobial%20Photodynamic.pdf http://repository.unair.ac.id/84534/7/Antimicrobial%20Photodynamic%20Effects%20of%20Polychromatic%20Light%20Activated%20by%20Magnetic%20Fields%20to%20Bacterial%20Viability_compressed.pdf http://repository.unair.ac.id/84534/8/Karil%20Antimicrobial%20_compressed.pdf http://repository.unair.ac.id/84534/ http://www.ektodermaldisplazi.com/journal.htm
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Institution:	Universitas Airlangga
Language:	Indonesian English English

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spelling	id-langga.845342019-07-23T00:39:16Z http://repository.unair.ac.id/84534/ Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability Suryani Dyah Astuti R. Arif Wibowo Abdurachman, NIDN. 0011096602 Kuwat Triyana R5-920 Medicine (General) The Escherichia coli(E. coli) isGram negative bacteria, that normally live in the digestive tracts of humans and animals, can cause bloody diarrhea, severe anemia or kidney falureand other illnesses which can lead to death.Systemic therapy with antibiotic cause bacteria resistant. So,an alternative method is needed, one of them is Photodynamic therapy (PDT).This research aims to investigate antimicrobial photodynamic effects of the light emitting diode (LED) activated by magnetic fields 1.8 mT irradiation to bacteria viability. To determine the antimicrobial effect of treatments, three measurements of bacterial colony growth (in %) were carried out. Three measurements groups as follow: Groups I to measurements the effects of LED irradiation by varying wavelength (469nm, 541 nm and 626 nm); Groups II to measurements effects of magnetic fields 1.8 mT to antimicrobial efficacy; Groups III to determine the effects and efficacy of LED 541 nm and magnetic fields irradiation with varying LED intensity (0.62, 2.50, 6.27, and 8.21) mW/cm2 and time irradiation (20, 30, 40, 50) minutes, respectively. The suspension was planted on sterile media and incubated at a temperature of 37oC for 24 hours. After incubation, the number of colony-forming units per milliliter (CFU/ml) was determined. The results were analyzed by analysis of variance (ANOVA) and the Tukey test. A P value ≤0.05 was considered to indicate a statistically significant difference. The LED treatment group 469 nm, 541 nm and 626 nm resulted in statistically significant decrease of CFU (p<0.05) compared to each other. The LED 541 nm treatment group with magnetic fields resulted significantly differ with treatment group without magnetic fields. The LED 541 nm treatment with magnetic fields 1.8 mT at various light intensity and time irradiation resulted significantly differ each other (p<0.05). LED irradiation with intensity 6.27 mW/cm 2 and time irradiation 50 minutes (energy dose 18.81 J/cm 2) resulted highest decreases the number of bacteria E.coli 80%. LED irradiation combined by magnetic fields can improve the efficacy of antimicrobial photodynamic effects. EBSCO Industrias 2017 Article PeerReviewed text id http://repository.unair.ac.id/84534/6/Antimicrobial%20Photodynamic.pdf text en http://repository.unair.ac.id/84534/7/Antimicrobial%20Photodynamic%20Effects%20of%20Polychromatic%20Light%20Activated%20by%20Magnetic%20Fields%20to%20Bacterial%20Viability_compressed.pdf text en http://repository.unair.ac.id/84534/8/Karil%20Antimicrobial%20_compressed.pdf Suryani Dyah Astuti and R. Arif Wibowo and Abdurachman, NIDN. 0011096602 and Kuwat Triyana (2017) Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability. Journal of International Dental and Medical Research, 10 (1). pp. 111-117. ISSN 1309-100x http://www.ektodermaldisplazi.com/journal.htm
institution	Universitas Airlangga
building	Universitas Airlangga Library
country	Indonesia
collection	UNAIR Repository
language	Indonesian English English
topic	R5-920 Medicine (General)
spellingShingle	R5-920 Medicine (General) Suryani Dyah Astuti R. Arif Wibowo Abdurachman, NIDN. 0011096602 Kuwat Triyana Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability
description	The Escherichia coli(E. coli) isGram negative bacteria, that normally live in the digestive tracts of humans and animals, can cause bloody diarrhea, severe anemia or kidney falureand other illnesses which can lead to death.Systemic therapy with antibiotic cause bacteria resistant. So,an alternative method is needed, one of them is Photodynamic therapy (PDT).This research aims to investigate antimicrobial photodynamic effects of the light emitting diode (LED) activated by magnetic fields 1.8 mT irradiation to bacteria viability. To determine the antimicrobial effect of treatments, three measurements of bacterial colony growth (in %) were carried out. Three measurements groups as follow: Groups I to measurements the effects of LED irradiation by varying wavelength (469nm, 541 nm and 626 nm); Groups II to measurements effects of magnetic fields 1.8 mT to antimicrobial efficacy; Groups III to determine the effects and efficacy of LED 541 nm and magnetic fields irradiation with varying LED intensity (0.62, 2.50, 6.27, and 8.21) mW/cm2 and time irradiation (20, 30, 40, 50) minutes, respectively. The suspension was planted on sterile media and incubated at a temperature of 37oC for 24 hours. After incubation, the number of colony-forming units per milliliter (CFU/ml) was determined. The results were analyzed by analysis of variance (ANOVA) and the Tukey test. A P value ≤0.05 was considered to indicate a statistically significant difference. The LED treatment group 469 nm, 541 nm and 626 nm resulted in statistically significant decrease of CFU (p<0.05) compared to each other. The LED 541 nm treatment group with magnetic fields resulted significantly differ with treatment group without magnetic fields. The LED 541 nm treatment with magnetic fields 1.8 mT at various light intensity and time irradiation resulted significantly differ each other (p<0.05). LED irradiation with intensity 6.27 mW/cm 2 and time irradiation 50 minutes (energy dose 18.81 J/cm 2) resulted highest decreases the number of bacteria E.coli 80%. LED irradiation combined by magnetic fields can improve the efficacy of antimicrobial photodynamic effects.
format	Article PeerReviewed
author	Suryani Dyah Astuti R. Arif Wibowo Abdurachman, NIDN. 0011096602 Kuwat Triyana
author_facet	Suryani Dyah Astuti R. Arif Wibowo Abdurachman, NIDN. 0011096602 Kuwat Triyana
author_sort	Suryani Dyah Astuti
title	Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability
title_short	Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability
title_full	Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability
title_fullStr	Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability
title_full_unstemmed	Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability
title_sort	antimicrobial photodynamic effects of polychromatic light activated by magnetic fields to bacterial viability
publisher	EBSCO Industrias
publishDate	2017
url	http://repository.unair.ac.id/84534/6/Antimicrobial%20Photodynamic.pdf http://repository.unair.ac.id/84534/7/Antimicrobial%20Photodynamic%20Effects%20of%20Polychromatic%20Light%20Activated%20by%20Magnetic%20Fields%20to%20Bacterial%20Viability_compressed.pdf http://repository.unair.ac.id/84534/8/Karil%20Antimicrobial%20_compressed.pdf http://repository.unair.ac.id/84534/ http://www.ektodermaldisplazi.com/journal.htm
_version_	1681151911423639552

Antimicrobial Photodynamic Effects of Polychromatic Light Activated by Magnetic Fields to Bacterial Viability

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