Nanoparticle approaches against bacterial infections

Gao, Weiwei; Thamphiwatana, Soracha; Angsantikul, Pavimol; Zhang, Liangfang

doi:10.1002/wnan.1282

Cited by 260 publications

(172 citation statements)

References 168 publications

(256 reference statements)

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“…Passive targeting is based on particle size and the ability of PNPs to form pores, which disrupt the structure of the pathogen membrane [23,36,37]. Recent studies indicate that conjugation of lectin-specific ligands on the PNP surface showed enhanced binding affinity to the carbohydrate receptors on the Helicobacter pylori membrane [38].…”

Section: Mechanism Of Actionmentioning

confidence: 99%

“…In another study Jain et al used concanavalin-A (Con-A) decorated elastin as a clarithromycin delivery system for H. pylori eradication [39]. In active targeting other homing molecules including specific antibodies and aptamer bacteriophage proteins have been used for nanoparticle surface functionalization resulting in targeted delivery platforms effective against different types of bacterial infections [37,40,41]. Targeting molecules can also be used for sensitive and specific identification strategies for detection of pathogens such as Staphylococcus aureus, Mycobacterium tuberculosis and Escherichia coli via aptamer recognition and fluorescently tagged silica nanoparticles [42][43][44].…”

Section: Mechanism Of Actionmentioning

confidence: 99%

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Polymeric nanoparticles – a novel solution for delivery of antimicrobial agents

Michalak¹,

Głuszek²,

Piktel³

et al. 2016

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The increased prevalence of antibiotic-resistant pathogens requires additional efforts to develop new antimicrobial agents and alternative methods to prevent and treat infections. In response to this challenge, a variety of nanotechnology-based tools are currently being designed and thoroughly investigated. To date, a considerable number of studies have reported increased activity of antibiotic-conjugated polymeric nanoparticles against bacteria and fungi associated with various infections, including those caused by drug-resistant pathogens. Importantly, high biocompatibility of these structures coupled with enhanced biological activity and improved pharmacokinetic properties supports the potential of these nanosystems as new tools to treat infections. In this review, we summarize the synthesis of polymer-based nanoparticles and describe their mechanism of action. We also highlight the recent advances in the application of antibiotic-conjugated polymeric nanoparticles as novel antimicrobial agents. StreszczenieStale narastająca lekooporność drobnoustrojów wymusza konieczność rozwoju alternatywnych metod profilaktyki i terapii zakażeń, a także uzasadnia prace nad nowymi lekami o aktywności przeciwdrobnoustrojowej. Realizacja tego celu jest moż-liwa dzięki zastosowaniu osiągnięć z zakresu nanotechnologii. Zwiększająca się liczba doniesień literaturowych potwierdza znaczną aktywność przeciwdrobnoustrojową nanocząstek polimerowych skoniugowanych z klasycznymi antybiotykami, co może zostać wykorzystane w terapii infekcji o charakterze bakteryjnym i grzybiczym, również tych wywoływanych przez patogeny lekooporne. Wysoka biokompatybilność nanocząstek polimerowych, a także możliwość zwiększania aktywności przeciwdrobnoustrojowej i poprawy parametrów farmakokinetycznych stosowanych obecnie chemioterapeutyków, wskazuje na możliwość zastosowania nanostruktur w nowoczesnej terapii chorób infekcyjnych. W niniejszej pracy podsumowano metody syntezy nanosystemów opartych na nanocząstkach polimerowych, a także opisano mechanizm ich działania. Przedstawione zostały również najnowsze osiągnięcia w syntezie nanocząstek skoniugowanych z antybiotykami, pozwalające na ich zastosowanie w terapii infekcji o charakterze bakteryjnym i grzybiczym.

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Section: Mechanism Of Actionmentioning

confidence: 99%

Section: Mechanism Of Actionmentioning

confidence: 99%

Polymeric nanoparticles – a novel solution for delivery of antimicrobial agents

Michalak¹,

Głuszek²,

Piktel³

et al. 2016

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“…Thus, liposomes are promising delivery systems mainly because of their biocompatibility, biodegradability and low toxicity in the human body (Benech et al 2002;Saddi et al 2008;Shehata et al 2008;Akbarzadeh et al 2013;Gao et al 2014). Any compound, irrespective of its solubility, can be entrapped inside a liposome, resulting in a slow degradation during transport to the target, minimal side-effects and greater stability (Ghalandarlaki et al 2014).…”

Section: Liposomal Systems As Carriers For Bioactive Compoundsmentioning

confidence: 99%

Liposomal systems as carriers for bioactive compounds

et al. 2015

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Since the revolutionary discovery that phospholipids can form closed bilayered structures in aqueous systems, the study of liposomes has become a very interesting area of research. The versatility and amazing biocompatibility of liposomes has resulted in their wide-spread use in many scientific fields, and many of their applications, especially in medicine, have yielded breakthroughs in recent decades. Specifically, their easy preparation and various structural aspects have given rise to broadly usable methodologies to internalize different compounds, with either lipophilic or hydrophilic properties. The study of compounds with potential biotechnological application(s) is generally related to evaluation and risk assessment of the possible cytotoxic or therapeutic effects of the compound under study. In most cases, undesirable sideeffects are associated with an interaction of the liposome with the cell membrane and/or its absorption and subsequent interaction with a cellular biomolecule. Liposomal carrier systems have an unprecedented potential for delivering bioactive substances to specific molecular targets due to their biocompatibility, biodegradability and low toxicity. Liposomes are therefore considered to be an invaluable asset in applied biotechnology studies due to their potential for interaction with both hydrophilic and lipophilic compounds.

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“…In particular novel approaches that can replace or enhance current antimicrobials are highly desired. [3][4][5] Polymeric materials have often been postulated as alternatives in these areas, either as delivery vehicles for antimicrobials, 6,7 or as novel antimicrobial polymers, [8][9][10][11] and materials that can interfere with microbial adhesion. [12][13][14][15] Polymeric materials are especially attractive in these applications because of their multivalency, ease of manufacturing and the potential to precisely control polymer length and composition.…”

Section: Introductionmentioning

confidence: 99%

Engineering Microbial Physiology with Synthetic Polymers: Cationic Polymers Induce Biofilm Formation inVibrio choleraeand Downregulate the Expression of Virulence Genes

Pérez-Soto

Moule

Crisan

et al. 2016

Preprint

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Here we report the first application of non-bactericidal synthetic polymers to modulate the physiology of a bacterial pathogen. Poly(N-[3- is associated with the reduction to the number of free bacteria, but also the downregulation of toxin production. Finally we demonstrate that these polymers can reduce colonisation of zebrafish larvae upon ingestion of water contaminated with V. cholerae. Overall, our results suggest that the physiology of this pathogen can be modulated without the need to genetically manipulate the microorganism and that this modulation is an off-target effect that results from the intrinsic ability of the pathogen to sense and adapt to its environment. We believe these findings pave the way towards a better understanding of the interactions between pathogenic bacteria and polymeric materials and will underpin the development of novel antimicrobial polymers.

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Nanoparticle approaches against bacterial infections

Cited by 260 publications

References 168 publications

Polymeric nanoparticles – a novel solution for delivery of antimicrobial agents

Polymeric nanoparticles – a novel solution for delivery of antimicrobial agents

Liposomal systems as carriers for bioactive compounds

Engineering Microbial Physiology with Synthetic Polymers: Cationic Polymers Induce Biofilm Formation inVibrio choleraeand Downregulate the Expression of Virulence Genes

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