Cationic polythiophenes have been shown to be potent antimicrobial compounds due to their ability to absorb visible light and sensitize the production of reactive oxygen species (ROS) as well as their ability to selectively associate with and damage negatively charged cell envelopes. This study demonstrates the ability of differentially sized imidazolium- and tertiary amine-functionalized poly(3-hexylthiophene) (P3HT) to inactivate Gram-negative Escherichia coli and Gram-positive Bacillus atrophaeus under photolysis and dark conditions. Flow cytometry viability assays are used to quantify cell death. Each compound shows high levels of killing at both 1 and 10 μg mL polymer concentrations for each microbial species after photoactivation as well as high levels of dark inactivation in many cases. Tertiary amine-functionalized P3HT is shown to have different killing patterns, shown by transmission electron microscopy, compared to the imidazolium-functionalized derivatives.
Much
recent effort has been directed toward the development of
novel antimicrobial materials able to defeat new and antibiotic resistant
pathogens. In this report, we study the efficacy of cationic poly(phenylene
ethynylene), polythiophene, and oligo(phenylene ethynylene) electrolytes
against laboratory strains of Pseudomonas aeruginosa, Staphylococcus
aureus and Staphylococcus epidermidis. The
focus of the study is to quantitatively evaluate the speed and extent
of dark and light-activated antimicrobial activity. Using cell plating
with serial dilutions, we determined that planktonic bacteria suspensions
exposed to the antimicrobials (at 10 μg/mL) result in several
log kills at 10 min both in the dark and under UV irradiation (360
nm) for all eight synthetic antimicrobials. However, there are significant
differences in the ease of killing the different pathogens. In most
trials, there is significantly greater killing under light-irradiation,
indicating these materials may be used as versatile disinfectants.
The
threat of antibiotic-resistant bacteria is an ever-increasing
problem in public health. In this report, we examine the photochemical
properties with a proof-of-principle biocidal assay for a novel series
of regio-regular imidazolium derivative poly-(3-hexylthiophene)/sodium
dodecyl sulfate (P3HT-Im/SDS) materials from ultrafast sub-ps dynamics
to μs generation of reactive oxygen species (ROS) and 30 min
biocidal reactivity with Escherichia coli (E. coli). This broad series encompassing
pure P3HT-Im to cationic, neutral, and anionic P3HT-Im/SDS materials
are all interrogated by a variety of techniques to characterize the
physical material structure, electronic structure, and antimicrobial
activity. Our results show that SDS complexation with P3HT-Im results
in aggregate materials with reduced ROS generation and light-induced
anti-microbial activity. However, our characterization reveals that
the presence of non-aggregated or lightly SDS-covered polymer segments
is still capable of ROS generation. Full encapsulation of the P3HT-Im
polymer completely deactivates the light killing pathway. High SDS
concentrations, near and above critical micelle concentration, further
deactivate all anti-microbial activity (light and dark) even though
the P3HT-Im regains its electronic properties to generate ROS.
White-nose syndrome (WNS) is a bat disease caused by the fungal pathogen Pseudogymnoascus destructans, which thrives in cold and very humid environments where bats frequently hibernate. Conidia of Pseudogymnoascus species are often documented on bats prior to the onset of WNS, but characterization of high-risk areas defined by microclimate cave conditions have been lacking. Investigating the occurrence of this fungal genus and appropriate environmental conditions to support P. destructans in southwestern U.S. caves is key to understanding the sites most likely to be impacted by WNS. Microclimate conditions in ten caves at El Malpais (ELMA) National Monument in New Mexico, USA were recorded using i-Button data loggers during the winters of 2011-2014 to assess appropriate environmental conditions (temperature and relative humidity) for P. destructans and other Pseudogymnoascus species. Optimal microclimate conditions for P. destructans and other psychrophilic fungi were found in all the caves with at least 50% of the caves identified as high-risk areas. Pseudogymnoascus species were detected in 70% of the caves using culturing methods and PCR, but no soil samples were positive for P. destructans using realtime PCR in soil and guano samples. Pseudogymnoascus destructans has a recognized range of appropriate temperatures and relative humidity for growth and cave microclimate can help define high-risk areas. This study offers resource managers guidance for establishing priority monitoring areas in their bat caves to determine which bat species are at higher risk. bats, cave microclimate, guano, Pseudogymnoascus destructans, white-nose syndrome
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