Antibacterial clay against gram-negative antibiotic resistant bacteria

[Display omitted] •Ferroan saponite acts as antibacterial antibiotic resistant bacteria.•The antibacterial action is time-dependent.•The antibacterial action is against gram-negative antibiotic resistant bacteria.•Growth inhibition relies on membrane lipopolysaccharides-clay surface interactions.•La...

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Bibliographic Details
Published in:Journal of hazardous materials 2018-01, Vol.342, p.625-632
Main Authors: Zarate-Reyes, Luis, Lopez-Pacheco, Cynthia, Nieto-Camacho, Antonio, Palacios, Eduardo, Gómez-Vidales, Virginia, Kaufhold, Stephan, Ufer, Kristian, García Zepeda, Eduardo, Cervini-Silva, Javiera
Format: Article
Language:English
Subjects:
Human pathogens
Low-cost remediation
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Summary:[Display omitted] •Ferroan saponite acts as antibacterial antibiotic resistant bacteria.•The antibacterial action is time-dependent.•The antibacterial action is against gram-negative antibiotic resistant bacteria.•Growth inhibition relies on membrane lipopolysaccharides-clay surface interactions.•Labile or bioavailable Fe contribute not to the bacteriostatic activity of the clay. Antibiotic resistant bacteria persist throughout the world because they have evolved the ability to express various defense mechanisms to cope with antibiotics and the immune system; thus, low-cost strategies for the treatment of these bacteria are needed, such as the usage of environmental minerals. This paper reports the antimicrobial properties of a clay collected from Brunnenberg, Germany, that is composed of ferroan saponite with admixtures of quartz, feldspar and calcite as well as exposed or hidden (layered at inner regions) nano Fe(0). Based on the growth curves (log phase) of six antibiotic resistant bacteria (4 gram-negative and 2 gram-positive), we concluded that the clay acted as a bacteriostat; however, the clay was only active against the gram-negative bacteria (except for resilient Klebsiella pneumonia). The bacteriostatic mode of action was evidenced by the initial lack of Colony Forming Units on agar plates with growth registered afterward, certainly after 24h, and can be explained because interactions between membrane lipopolysaccharides and the siloxane surfaces of the clay. Labile or bioavailable Fe in the clay (extracted by EDTA or DFO-B) induced the quantitative production of HO as well as oxidative stress, which, nevertheless, did not account for by its bacteriostatic activity.
ISSN:0304-3894
1873-3336
DOI:10.1016/j.jhazmat.2017.08.078