Editorial: Emerging strategies in combatting and managing bacterial biofilms
Date
2023-08
Journal Title
Journal ISSN
Volume Title
Type
Article
Publisher
Frontiers Media S.A.
Series Info
Front. Cell. Infect. Microbiol.;13:1264346
Scientific Journal Rankings
Abstract
Numerous microbes use biofilm formation as a mean of survival. Biofilms are
multicellular communities in which microorganisms are encased in a protective matrix
that enables them to endure challenging environments and resist traditional therapies. The
widespread existence of biofilm-forming bacteria in various settings, including healthcare
facilities, is made possible by their capacity to colonize a variety of biotic and abiotic
surfaces. They pose a serious threat to human health because they can develop increasing
resistance to traditional antibiotics and spread morbidity through both device- and non-
device (tissue)-associated infections, as reviewed by Zhao et al. This microbial phenotype
consequently became a significant concern in several fields, including public health
and medicine.
Biofilms are involved in the pathogenicity of infectious diseases as well as the
establishment of healthy microbiomes. Many bacterial species within the gut
microbiome grow as biofilms, and disease outcome is greatly impacted by the location
of the biofilms within the gastrointestinal tract (Miller et al., 2021). Hammouda et al.
reported that hormonal drugs affect biofilm formation by selected gut microbiota such as
Bifidobacterium longum, Limosilactobacillus reuteri, Bacteroides fragilis, and Escherichia
coli, representing the four main phyla in the gut. Despite increasing the adhesion of L.
reuteri to Caco-2/HT-29 cell line coculture, progesterone inhibited the biofilm
development of the Gram-positive bacteria. In contrast, it increased the ability of Gram-
negative bacteria to form biofilms and increased the adherence of B. fragilis to the cell lines
coculture. Both estradiol and thyroxine displayed antibiofilm activity against L. reuteri. In
the meantime, thyroxine boosted the capacity of E. coli to develop a biofilm.
The implication of biofilm-related multi-drug resistance (MDR) in hospital-acquired
infections is a significant issue with increased rates of patient mortality and morbidity as
well as economic burden, including high healthcare expenses and extended hospital stays
(Assefa and Amare, 2022). Hu et al. reported the ability of the emerging opportunistic
nosocomial pathogen Elizabethkingia anophelis to form biofilms. MDR phenotype was also
exhibited by all isolates. The authors concluded that biofilm development and antibiotic
Description
Keywords
biofilm, microbiome, hospital-acquired infection (HAI), implanted medical devices, multidrug resistance (MDR), biofilm associated infections, catheters