Combating <i>Pseudomonas aeruginosa</i> Biofilms by a Chitosan-PEG-Peptide Conjugate via Changes in Assembled Structure

Ju, Xiaoyan; Chen, Jun; Zhou, Mengxue; Zhu, Meng; Li, Zhuang; Gao, Sijia; Ou, Jinzhao; Xu, Dandan; Wu, Man; Jiang, Shidong; Hu, Yi; Tian, Ye; Niu, Zhongwei

doi:10.1021/acsami.0c02034

Cited by 43 publications

(55 citation statements)

References 35 publications

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“…Experiments with stealth, poly(ethylene glycol) coated liposomes and polystyrene nanoparticles (see Figure 3), unable to adsorb to biofilm components, demonstrated that liposomes with diameters above 100-130 nm were unable to diffuse through channels in Burkholderia multivorans and P. aeruginosa biofilms (see Figure 3) (Forier et al 2014). A similar minimal width of 100 nm was reported in order to avoid adsorption of antimicrobials to channel walls upon diffusion-controlled penetration of an antimicrobial in an infectious biofilm (Ju et al 2020). However, intra-colony channels with much larger diameters of around 10 mm have also been described in E. coli, using giant objective lens microscopy with a high numerical aperture at low magnification ("mesoscopy") (Rooney et al 2020) and even wider channels (18-99 mm) have been described in P. aeruginosa (Lei et al 2020).…”

Section: Structure Of Water-filled Regions In Biofilms: Channels and Poresmentioning

confidence: 72%

Water in bacterial biofilms: pores and channels, storage and transport functions

Quan

Hou

Zhang

et al. 2021

Critical Reviews in Microbiology

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Section: Structure Of Water-filled Regions In Biofilms: Channels and Poresmentioning

confidence: 72%

Water in bacterial biofilms: pores and channels, storage and transport functions

Quan

Hou

Zhang

et al. 2021

Critical Reviews in Microbiology

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“…ANS fluorescence and PI fluorescence measurements of the hydrogel-treated groups show obvious enhancements compared with the control group (Figure S24, Supporting Information), indicating that bacteria died and their membranes turned over after treatment. [58] On the basis of these observations, we inferred that the antibacterial activity of the FLN-based hydrogel, like that of other amyloid fibrils, is based on a membrane-disrupting mechanism (Figure 7h). Interestingly, the FLN nanofibrils could capture the planktonic microorganisms and achieved bead-like bacterial agglomeration (MRSA and P. aeruginosa), as recorded by AFM (Figure 7g), which is likely a consequence of the organized β-sheet structure of the nanofibrils and the positive charge of the Lys exposed on the surface of the nanofibrils (Figure 3).…”

Section: Antibacterial Mechanism Of the Fln-based Hydrogelmentioning

confidence: 86%

“…Notably, bacteria do not easily develop resistance to such a physical-damage-based antibacterial mechanism. [58] A diabetic ulcer, as a typical chronic wound, is prone to wound nonclosure and persistent microbial infection, eventually resulting in a 41% possibility of amputation. Diabetic ulcers thus pose a large challenge to medicine and represent a financial burden to society.…”

Section: Antibacterial Mechanism Of the Fln-based Hydrogelmentioning

confidence: 99%

Bioinspired Intrinsic Versatile Hydrogel Fabricated by Amyloidal Toxin Simulant‐Based Nanofibrous Assemblies for Accelerated Diabetic Wound Healing

Xuan

Jiang

Dong

et al. 2021

Adv Funct Materials

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Persistent microbial infection and decreased neovascularization are common issues associated with diabetic wound treatment. Hydrogel dressings that offer intrinsic antibacterial and angiogenesis-inducing may substantially avoid the use of antibiotics or angiogenic agents. Herein, a versatile hydrogel is fabricated using an amyloid-derived toxin simulant (Fmoc-LFKFFK-NH 2 , FLN) as building blocks, inspired by the defense strategy of Staphylococcus aureus (S. aureus). The simulant assemblies of the hydrogel function as both matrix components and functional elements for diabetic wound treatment. The hydrogel undergoes quick assembly from random monomers to nanofibrils with abundant b-sheet driven by multiple non-covalent interactions. The developed hydrogel demonstrates excellent biocompatibility and accelerates angiogenesis via hypoxia-inducible factor 1α (HIF-1α) and vascular endothelial growth factor A (VEGFA) signaling as a consequence of its amyloidal structure. The simulant-based nanofibrils endow the hydrogel with broad-spectrum antibacterial activity dominated by a membrane-disruption mechanism. In addition, the hydrogel exhibits excellent performance compared with the commercial hydrogel Prontosan in accelerating wound healing of diabetic mice infected with methicillinresistant S. aureus (MRSA). This study highlights the fabrication of a single component and versatile hydrogel platform, thereby avoiding the drugrelated side effects and complicated preparations and demonstrating its profound potential as a clinical dressing for the manage ment of microbeinfected diabetic wounds.

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“…However, recent evidence revealed that chitosan penetrates the cell membrane of P. aeruginosa, releasing the cell contents and aggregating the residue cytoplasmic material into a mass. It was presumed that the cytoplasmic material was agglomerated by flocculation of chitosan after entering the cell [50], an effect that would overcome the resistance mechanisms mentioned above. Finally, so far, this finding could mean highly deacetylated chitosan is a potential antimicrobial agent to use against CST-resistant MDR strains.…”

Section: Antimicrobial Activitymentioning

confidence: 99%

Antimicrobial Contribution of Chitosan Surface-Modified Nanoliposomes Combined with Colistin against Sensitive and Colistin-Resistant Clinical Pseudomonas aeruginosa

et al. 2020

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Colistin is a re-emergent antibiotic peptide used as a last resort in clinical practice to overcome multi-drug resistant (MDR) Gram-negative bacterial infections. Unfortunately, the dissemination of colistin-resistant strains has increased in recent years and is considered a public health problem worldwide. Strategies to reduce resistance to antibiotics such as nanotechnology have been applied successfully. In this work, colistin was characterized physicochemically by surface tension measurements. Subsequently, nanoliposomes coated with highly deacetylated chitosan were prepared with and without colistin. The nanoliposomes were characterized using dynamic light scattering and zeta potential measurements. Both physicochemical parameters fluctuated relatively to the addition of colistin and/or polymer. The antimicrobial activity of formulations increased by four-fold against clinical isolates of susceptible Pseudomona aeruginosa but did not have antimicrobial activity against multidrug-resistant (MDR) bacteria. Interestingly, the free coated nanoliposomes exhibited the same antibacterial activity in both sensitive and MDR strains. Finally, the interaction of colistin with phospholipids was characterized using molecular dynamics (MD) simulations and determined that colistin is weakly associated with micelles constituted by zwitterionic phospholipids.

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Combating Pseudomonas aeruginosa Biofilms by a Chitosan-PEG-Peptide Conjugate via Changes in Assembled Structure

Cited by 43 publications

References 35 publications

Water in bacterial biofilms: pores and channels, storage and transport functions

Water in bacterial biofilms: pores and channels, storage and transport functions

Bioinspired Intrinsic Versatile Hydrogel Fabricated by Amyloidal Toxin Simulant‐Based Nanofibrous Assemblies for Accelerated Diabetic Wound Healing

Antimicrobial Contribution of Chitosan Surface-Modified Nanoliposomes Combined with Colistin against Sensitive and Colistin-Resistant Clinical Pseudomonas aeruginosa

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