Antimicrobial and Anti-Inflammatory Activity of Chitosan–Alginate Nanoparticles: A Targeted Therapy for Cutaneous Pathogens

Friedman, Adam; Phan, Jenny; Schairer, David; Champer, Jackson; Qin, Min; Pirouz, Aslan; Blecher-Paz, Karin; Oren, Ami; Liu, Philip T.; Modlin, Robert L.; Kim, Jenny

doi:10.1038/jid.2012.399

Cited by 252 publications

(137 citation statements)

References 46 publications

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“…Chitosan can also bond to metals, which are critical toxic products involved in the growth of microorganisms (22,26). These characteristics of chitosan lead to its possible use in food, cosmetic, pharmaceutical, and biotechnology industries (22,32,36,37).…”

Section: Discussionmentioning

confidence: 99%

In vivo study of antifungal effects of low-molecular-weight chitosan against Candida albicans

Atai

Amini

et al. 2017

J Oral Sci

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This study investigated the antifungal effects of low-molecular-weight chitosan solution onCandida albicans in denture stomatitis in comparison with nystatin suspension. This randomized, singleblind clinical trial included 40 patients diagnosed with denture stomatitis. Patients were divided into two groups, wherein one was treated with chitosan and the other with nystatin for 2 weeks. Changes in the erythematous area were recorded during and after treatment. A palatal smear was obtained for each patient before and after treatment to determine the number of blastospores and mycelia of C. albicans. The results were compared using the MannWhitney U test, revealing that the chitosan solution significantly decreased the erythematous surface area, burning sensation, time required for clinical improvement, and number of blastospores and mycelia. The antifungal efficacy of chitosan along with its inherent biocompatibility makes it a promising candidate for use as an antifungal mouthwash.

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Section: Discussionmentioning

confidence: 99%

In vivo study of antifungal effects of low-molecular-weight chitosan against Candida albicans

Atai

Amini

et al. 2017

J Oral Sci

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“…It is this polycationic character that confers chitosan's antimicrobial properties, which favors interaction with negatively charged microbial cell walls and cytoplasmic membranes. This electrostatic interaction between protonated chitosan and microbial cell walls results in decreased osmotic stability, membrane disruption and eventual leakage of intracellular elements (26). Since the macroemulsion without AZM showed a negative zeta potential value, it is clear that the formation of protonated chitosan is very low.…”

Section: Discussionmentioning

confidence: 99%

In Vitro Anti-inflammatory and Antimicrobial Activities of Azithromycin After Loaded in Chitosan- and Tween 20-Based Oil-in-Water Macroemulsion for Acne Management

Shunmugaperumal

Kaur

2015

AAPS PharmSciTech

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Abstract. The objectives of the current investigation are (1) to prepare and characterize (particle size, surface charge (potential zeta), surface morphology by transmission electron microscopy, drug content, and drug release) the azithromycin (AZM, 100 mg)-loaded oil-in-water (o/w) macroemulsion, (2) to assess the toxicity of macroemulsion with or without AZM using RBC lysis test in comparison with AZM in phosphate buffer solution of pH 7.4, (3) to compare the in vitro antimicrobial activity (in Escherichia coli using zone inhibition assay) of AZM-loaded macroemulsion with its aqueous solution, and (4) to assess the in vitro anti-inflammatory effect (using egg albumin denaturation bioassay) of the AZM-loaded macroemulsion in comparison with diclofenac sodium in phosphate buffer solution of pH 7.4. The AZM-loaded macroemulsion possessed the dispersed oil droplets with a mean diameter value of 52.40± 1.55 μm. A reversal in the zeta potential value from negative (−2.16±0.75 mV) to positive (+6.52± 0.96 mV) was noticed when AZM was added into the macroemulsion. At a 1:5 dilution ratio, 2.06± 0.03 mg of drug was released from macroemulsion followed by 1.01±0.01 and 0.25±0.08 mg, respectively, for 1:10 and 1:40 dilution ratios. Antimicrobial activity maintenance and significant reduction of RBC lysis property were noticed for AZM after loaded in the macroemulsion. However, an increment in the absorbance values for emulsion-treated samples in comparison to the control samples was noticed in the anti-inflammatory test. This speculates the potential of the AZM-loaded emulsion to manage inflammatory conditions produced at Acne vulgaris.

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“…38 Chitosan-alginate NPs did not have a toxic effect on human monocytes but there was mild toxicity to skin keratinocytes at higher concentration of NPs. 29 Moreover, chitosan and PLGA NPs loaded with chlorexidine dihydrochloride in vitro toxicity evaluation on human gingival fi broblasts was between 20 % and 60 % in all experimental conditions. 9 Poly-γ-glutamic acid/glycol chitosan NPs incorporating p-phenylenediamine (PDA) showed lower cytotoxicity against HaCaT human skin keratinocyte cells than PDA alone.…”

Section: Chitosan Modified Poly(lactic-co-glycolic) Acid Nanoparticlementioning

confidence: 92%

“…9 Chitosan by itself is known to strongly adhere to negatively charged surfaces due to its high charge density at pH< 6.5. 29 The advantages of modifying the surface of PLGA NPs with a mucoadhesive polymer, such as chitosan, may potentially include the inversion of zeta potential, the ability to promote cellular adhesion and retention of the delivery system at the target site. 30 In order to fabricate polymeric NPs for future dental applications, we have tested the positive charged chitosan coated PLGA NPs (PLGAChi NPs) on oral cavity cells.…”

Section: Chitosan Modified Poly(lactic-co-glycolic) Acid Nanoparticlementioning

confidence: 99%

Chitosan Modified Poly(lactic-Co-Glycolic) Acid Nanoparticles Interaction With Normal, Precancerous Keratinocytes and Dental Pulp Cells

Vîrlan¹,

Calenic²,

Cimpan³

et al. 2017

EDUJ

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Introduction: Nanoparticles (NPs) can carry molecules to different body tissues. Due to their controlled delivery properties, chitosan covered poly-lacto-co-glycolic NPs (PLGAChi NPs) could be used to deliver drugs to oral tissues for the treatment of dental diseases or in anticancer therapy. The aim of this study was to determine the uptake and cytotoxicity of PLGAChi NPs on different types of cells found in the oral cavity. Methodology: Normal oral keratinocytes (NOKs), precancerous keratinocytes (POE9i) and dental pulp cells (DPCs) were exposed for 12h and 24h to 20 g/mL and 200 g/mL PLGAChi NPs covalently tagged with fl uorescein. 3D organotypic tissues of oral mucosa were grown in vitro and exposed to 200g/mL PLGAChi NPs for 24h. Results: Both normal and premalignant oral mucosa cells (NOKs and POE9i) displayed uptake of PLGAChiNPs in a time and concentration-dependent manner, both in 2D and 3D models. A higher and more rapid uptake of PLGAChi NPs by precancerous cell line POE9i was observed when compared to NOKs. Interestingly, DPCs did not display internalized PLGAChi NPs, even at the highest concentration of 200 g/mL. Conclusion: Chitosan-coated PLGAChi NPs proved to be able to cross the cellular membrane of oral keratinocytes, in 2D as well as in 3D cultures. The polymeric NPs used in the present study seem not to be suitable for applications that require NPs uptake by DPCs, as no evidence of uptake in these cells was found in this study. The fi nding that PLGAChi NPs showed signifi cant internalization by human keratinocytes indicate that they could be used for drug delivery purposes to oral mucosa. Keywords: chitosan, PLGAChi, nanoparticles, oral keratinocytes, dental pulp. ABSTRACT

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Antimicrobial and Anti-Inflammatory Activity of Chitosan–Alginate Nanoparticles: A Targeted Therapy for Cutaneous Pathogens

Cited by 252 publications

References 46 publications

<i>In vivo</i> study of antifungal effects of low-molecular-weight chitosan against <i>Candida albicans </i>

<i>In vivo</i> study of antifungal effects of low-molecular-weight chitosan against <i>Candida albicans </i>

In Vitro Anti-inflammatory and Antimicrobial Activities of Azithromycin After Loaded in Chitosan- and Tween 20-Based Oil-in-Water Macroemulsion for Acne Management

Chitosan Modified Poly(lactic-Co-Glycolic) Acid Nanoparticles Interaction With Normal, Precancerous Keratinocytes and Dental Pulp Cells

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