Antibacterial mechanism of ultrasound against Escherichia coli: Alterations in membrane microstructures and properties

This study was aimed at providing new insights on the response of bacterial cell membranes to ultrasound exposure. Escherichia coli (E. coli) O157:H7 cells were exposed to different ultrasound treatments (power intensities of 64, 191, 372, and 573 W/cm², frequency of 20 kHz, pulsed mode of 2 sec: 2 sec) and the dynamic changes in cell viability within 27 min were assessed. With an increase in ultrasonic intensity and prolonged duration, a 0.76–3.52 log CFU/mL reduction in E. coli populations was attained. The alterations in the sensitivity of ultrasound-treated cells to antimicrobial compounds were evaluated by exposure to thyme essential oil nanoemulsion (TEON). The treatment reduced the E. coli population by 2.16–7.10 log CFU/mL, indicating the effects of ultrasonic field on facilitating the antibacterial efficacy of TEON. Ultrasonic-treated E. coli cells also displayed remarkable morphological and ultrastructural damages with destroyed membrane integrity and misshaped cell structures, which was observed by electron microscopy analysis. Significant increase in outer and inner membrane permeability, along with the cytoplasmic leakage and membrane depolarization were assessed utilizing spectrophotometry. For the first time, significant reduction in the membrane fluidity in response to ultrasound exposure were investigated. Additional efforts in exploring the effect of ultrasonic field on some bacterial membrane compositions were performed with infrared spectroscopy. In this study, multiple lines of evidence effectively served to elucidate the alterations on cellular membrane structure and property during exposure to sonication that could extend our understanding of the antimicrobial molecular mechanisms of ultrasound.     

Synthesis,in-silico antiviral screening and in-vitro antibacterial screening of a novel chalcone derivatives

A new series of novel chalcones was synthesized and subjected to screening of theoretical molecular and biological properties. For evaluating the theoretical molecular properties of these molecules Molinspiration and Osiris software were used. It was concluded from data that the majority of molecules exhibited theoretical molecular and biological properties similar to that of standard drugs. Role of Hemagglutinin is vital during the attack of virus on cells so Hemagglutinin inhibitors may act as potent antiviral agents. Considering this fact in-silico studies were performed using the SwissDock screening engine on Hemagglutinin target PDB code 1HGH. Hemagglutinin inhibition potential in terms of binding affinity was expressed as ΔG values ranging from −8.71 kcal/mol to −7.39 kcal/mol. Compound IIIm showed maximum binding affinity with ΔG value −8.71 kcal/mol followed by compound IIIj ΔG value −8.31 kcal/mol. It's prudent from ΔG values that compounds may act as potent antiviral agents. Compounds were also screened for in-vitro antibacterial activity against five pathogenic strains. Most of the compounds exhibited low to moderate activity against strains under study. Compound IIIn demonstrated good activity against four pathogenic strains with highest zone of inhibition of 16 mm against K. pneumoniae and S. typhi.     

Polypept(o)ide-based bactericides: weapons against antibiotic-resistant bacterial infections

Emerging antibiotic resistance in bacterial pathogens has necessitated the development of alternative ‘outside of the box’ antimicrobial therapeutics. Polypept(o)ide-based bactericides with chemical structures mimicking antimicrobial host defense peptides have emerged as promising candidates for treating antibiotic-resistant and recurring infections. This review summarizes the recent advances in membrane-active polypept(o)ide-based bactericides in the treatment of antibiotic-resistant bacterial infections associated with the physical disruption of bacterial cell walls/cell membranes. Among these polypept(o)ide-based bactericides, nonantibiotic treatment strategies are employed to combat lethal bacterial strains resulting from acquired antibiotic resistance and biofilm formation, featuring the capacity to evade acquired antibiotic resistance-related mechanisms and to alleviate the emergence of drug resistance. Emphasis will focus on the typical polypept(o)ides with diverse molecular conformations (e.g., linear, brush-like, and star-shaped) and various chemical structures of monomers (e.g., α-amino acid, β-amino acid, and N-substituted glycine) that are central to the performance of antimicrobial polypept(o)ides. Finally, a brief discussion of the key challenges and prospects of polypept(o)ide-based bactericides is presented.     

Recent studies on advance spectroscopic techniques for the identification of microorganisms: A review

The continuous development of resistance to antibiotic drugs by microorganisms causes high mortality and morbidity. Pathogens with distinct features and biochemical abilities make them destructive to human health. Therefore, early identification of the pathogen is of substantial importance for quick ailments and healthcare outcomes. Several phenotype methods are used for the identification and resistance determination but most of the conventional procedures are time-consuming, costly, and give qualitative results. Recently, great focus has been made on the utilization of advanced techniques for microbial identification. This review is focused on the research studies performed in the last five years for the identification of microorganisms particularly, bacteria using advanced spectroscopic techniques including mass spectrometry (MS), infrared (IR) spectroscopy, Raman spectroscopy (RS), and nuclear magnetic resonance (NMR) spectroscopy. Among all the techniques, MS techniques, particularly MALDI-TOF/MS have been widely utilized for microbial identification. A total of 44 bacteria i.e., 6 Staphylococcus spp., 3 Enterococcus spp., 6 Bacillus spp., 4 Streptococcus spp., 6 Salmonella spp., and one from each genus including Escherichia, Acinetobacter, Pseudomonas, Proteus, Clostridioides, Candida, Brucella, Burkholderia, Francisella, Yersinia, Moraxella, Vibrio, Shigella, Serratia, Citrobacter, and Haemophilus (spp.) were discussed in the review for their identification using the above-mentioned techniques. Among all the identified microorganisms, 21% of studies have been conducted for the identification of E. coli, 14% for S. aureus followed by 37% for other microorganisms.