Hosan Kim scite author profile

SummaryBacterial spores are surrounded by a morphologically complex, mechanically flexible protein coat, which protects the spore from toxic molecules. The interactions among the over 50 proteins that make up the coat remain poorly understood. We have used cell biological and protein biochemical approaches to identify novel coat proteins in Bacillus subtilis and describe the network of their interactions, in order to understand coat assembly and the molecular basis of its protective functions and mechanical properties. Our analysis characterizes the interactions between 32 coat proteins. This detailed view reveals a complex interaction network. A key feature of the network is the importance of a small subset of proteins that direct the assembly of most of the coat. From an analysis of the network topology, we propose a model in which low-affinity interactions are abundant in the coat and account, to a significant degree, for the coat's mechanical properties as well as structural variation between spores.

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Medical applications of cold atmospheric plasma: state of the science

Izadjoo

Zack

Kim

et al. 2018

J Wound Care

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Cold atmospheric plasmas (CAP) have been used in multiple medical fields and have become a promising medical technology. CAP-generating devices are safe and easy to operate and can now be manufactured at a low cost due to advancements in electronics and microchips. A primary application of CAP is as a broad-spectrum antimicrobial technology. With the high incidence of infections caused by drug-resistant microorganisms, a non-antibiotic based treatment modality such as CAP holds great therapeutic promise, particularly in the wound care field. In addition to its antimicrobial properties, CAP treatment enhances wound healing by increasing cutaneous microcirculation, monocyte stimulation, and keratinocyte proliferation. CAP has been used by dentists for disinfection of teeth, enhancing gingival fibroblast activity, and even teeth whitening. CAP can combat tumour growth by increasing the efficacy of antitumour therapeutic agents, reactivating apoptotic pathways, or down-regulating growth-related gene sites. Most of the health-care related research on CAP has occurred in the past 15 years; the field is relatively young and needs additional research, as well as confirmation of the existing supporting literature. The purpose of this report is to provide the reader with an overview of the therapeutic application of the cold plasma technology.

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Antibacterial Efficacy Testing of a Bioelectric Wound Dressing Against Clinical Wound Pathogens

Kim¹,

Makin²,

Skiba³

et al. 2014

TOMICROJ

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Silver-based wound dressings have been developed for the control of bioburden in wounds. However, the popularity and extensive use of silver-based dressings has been associated with emerging microbial resistances to silver. In this study we examined in vitro antibacterial efficacy of a bioelectric dressing containing silver and zinc against various wound pathogens. Antibiotic-sensitive clinical wound isolates showed a 100% reduction in bacterial growth, except that Enterococcus faecalis isolate was shown to survive with a bacterial log10 reduction rate of less than 102 CFU. We also investigated antibacterial efficacy against the extended spectrum β-lactamase (ESBL) bacteria, multidrug-resistant (MDR) bacteria, and methicillin-resistant Staphylococcus aureus (MRSA). The bioelectric dressing was effective in killing wound pathogens including ESBL, MDR, and MRSA in vitro. Furthermore, based on the primary results against E. faecalis, we carried out extensive studies against several nosocomial Enterococcus species including vancomycin-resistant species. Overall, the vancomycin-sensitive or -resistant Enterococcus species were resistant to this dressing at up to 48 h, except for the vancomycin-resistant Enterococcus raffinosus isolate only showing a 100% bacterial reduction at 48 h, but not at 24 h. The results demonstrated the effective bactericidal activity of a bioelectric dressing against antibiotic-sensitive and MDR strains, but Enterococcus species are bacteriostatic.

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An Overview of the Efficacy of a Next Generation Electroceutical Wound Care Device

Kim¹,

Park

Housler

et al. 2016

Military Medicine

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Novel approaches including nonpharmacological methodologies for prevention and control of microbial pathogens and emerging antibiotic resistance are urgently needed. Procellera is a wound care device consisting of a matrix of alternating silver (Ag) and zinc (Zn) dots held in position on a polyester substrate with a biocompatible binder. This electroceutical medical device is capable of generating a direct current voltage (0.5-0.9 Volts). Wound dressings containing metals such as Ag and/or Zn as active ingredients are being used for control of colonized and infected wounds. Reports on the presence of electric potential field across epithelium and wound current on wounding have shown that wound healing is enhanced in the presence of an external electrical field. However, majority of the electrical devices require an external power source for delivering pulsed or continuous electric power at the wound site. A microelectric potential-generating system without an external power source is an ideal treatment modality for application in both clinical and field settings. The research presented herein describes efficacy evaluation of a wireless bioelectric dressing against both planktonic and biofilm forms of wound pathogens including multidrug resistant organisms.

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A Novel Peptide-Based Antimicrobial Wound Treatment is Effective Against Biofilms of Multi-Drug Resistant Wound Pathogens

Bayramov

Patel

et al. 2018

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Wound infections are a common complication of combat-related injuries that significantly increase morbidity and mortality. Multi-drug resistant (MDR) organisms and their associated biofilms play a significant role in the pathogenicity and chronicity of wound infections. A critical barrier to progress in the treatment of traumatic wounds is the need for broad spectrum antimicrobials that are effective against biofilms and compatible with topical delivery. In this study, we present the in vitro efficacy of two de novo designed cationic, antimicrobial peptides and related topical formulations against single species and polymicrobial biofilms of MDR bacteria. Minimum biofilm eradication concentrations for peptides ranged from 0.7 μM for Staphylococcus aureus to 13.2 μM for Pseudomonas aeruginosa. Varying pH did not adversely impact peptide activity, however, in the presence of albumin, minimum biofilm eradication concentrations generally increased. When formulated into gels or dressings, both peptides eradicated mono- and polymicrobial biofilms of MDR pathogens. The biocompatibility index (BI) was found to be greater than one for both ASP-1 and ASP-2, with a slightly greater (more favorable) BI for ASP-2. The BIs for both peptides were greater than BIs previously reported for commonly used topical antimicrobial agents. The antimicrobial peptides and related formulations presented provide a promising platform for treatment of wound biofilms to improve outcomes for those injured in combat.

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Hosan Kim

The Bacillus subtilis spore coat protein interaction network

Medical applications of cold atmospheric plasma: state of the science

Antibacterial Efficacy Testing of a Bioelectric Wound Dressing Against Clinical Wound Pathogens

An Overview of the Efficacy of a Next Generation Electroceutical Wound Care Device

A Novel Peptide-Based Antimicrobial Wound Treatment is Effective Against Biofilms of Multi-Drug Resistant Wound Pathogens

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