Surface charge modulation of rifampicin-loaded PLA nanoparticles to improve antibiotic delivery in Staphylococcus aureus biofilms

Costa, David da; Exbrayat-Héritier, Chloé; Rambaud, Basile; Mégy, Simon; Terreux, Raphaël; Verrier, Bernard; Primard, Charlotte

doi:10.1186/s12951-020-00760-w

Cited by 54 publications

(46 citation statements)

References 39 publications

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“…PLA-NP were provided by the company Adjuvatis (Lyon, France), using a surfactantfree solvent diffusion method (also called the nanoprecipitation technique) previously described [29]. Briefly, PLA polymer was dissolved in acetone and this solution was added dropwise to an aqueous solution made of ethanol and carbonate buffer under stirring.…”

Section: Pla-np Synthesismentioning

confidence: 99%

LipoParticles: Lipid-Coated PLA Nanoparticles Enhanced In Vitro mRNA Transfection Compared to Liposomes

et al. 2021

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The approval of two mRNA vaccines as urgent prophylactic treatments against Covid-19 made them a realistic alternative to conventional vaccination methods. However, naked mRNA is rapidly degraded by the body and cannot effectively penetrate cells. Vectors capable of addressing these issues while allowing endosomal escape are therefore needed. To date, the most widely used vectors for this purpose have been lipid-based vectors. Thus, we have designed an innovative vector called LipoParticles (LP) consisting of poly(lactic) acid (PLA) nanoparticles coated with a 15/85 mol/mol DSPC/DOTAP lipid membrane. An in vitro investigation was carried out to examine whether the incorporation of a solid core offered added value compared to liposomes alone. To that end, a formulation strategy that we have named particulate layer-by-layer (pLbL) was used. This method permitted the adsorption of nucleic acids on the surface of LP (mainly by means of electrostatic interactions through the addition of LAH4-L1 peptide), allowing both cellular penetration and endosomal escape. After a thorough characterization of size, size distribution, and surface charge— and a complexation assessment of each vector—their transfection capacity and cytotoxicity (on antigenic presenting cells, namely DC2.4, and epithelial HeLa cells) were compared. LP have been shown to be significantly better transfecting agents than liposomes through pLbL formulation on both HeLa and DC 2.4 cells. These data illustrate the added value of a solid particulate core inside a lipid membrane, which is expected to rigidify the final assemblies and makes them less prone to early loss of mRNA. In addition, this assembly promoted not only efficient delivery of mRNA, but also of plasmid DNA, making it a versatile nucleic acid carrier that could be used for various vaccine applications. Finally, if the addition of the LAH4-L1 peptide systematically leads to toxicity of the pLbL formulation on DC 2.4 cells, the optimization of the nucleic acid/LAH4-L1 peptide mass ratio becomes an interesting strategy—essentially reducing the peptide intake to limit its cytotoxicity while maintaining a relevant transfection efficiency.

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Section: Pla-np Synthesismentioning

confidence: 99%

LipoParticles: Lipid-Coated PLA Nanoparticles Enhanced In Vitro mRNA Transfection Compared to Liposomes

et al. 2021

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“…Moreover, Da Costa et al investigated the potential of rifampicin-containing PLA nanoparticles functionalized with poly-L-lysine. This cationic peptide could reverse the negative nanoparticle surface charge to positive, against planktonic bacteria and biofilm growth [134]. By contrast, Vrouvaki et al developed PLA nanoparticles encapsulating the Pistacia lentiscus L. var.…”

Section: Antibacterial Nanoparticlesmentioning

confidence: 99%

Polymeric Nanoparticles for Antimicrobial Therapies: An up-to-date Overview

et al. 2021

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Despite the many advancements in the pharmaceutical and medical fields and the development of numerous antimicrobial drugs aimed to suppress and destroy pathogenic microorganisms, infectious diseases still represent a major health threat affecting millions of lives daily. In addition to the limitations of antimicrobial drugs associated with low transportation rate, water solubility, oral bioavailability and stability, inefficient drug targeting, considerable toxicity, and limited patient compliance, the major cause for their inefficiency is the antimicrobial resistance of microorganisms. In this context, the risk of a pre-antibiotic era is a real possibility. For this reason, the research focus has shifted toward the discovery and development of novel and alternative antimicrobial agents that could overcome the challenges associated with conventional drugs. Nanotechnology is a possible alternative, as there is significant evidence of the broad-spectrum antimicrobial activity of nanomaterials and nanoparticles in particular. Moreover, owing to their considerable advantages regarding their efficient cargo dissolving, entrapment, encapsulation, or surface attachment, the possibility of forming antimicrobial groups for specific targeting and destruction, biocompatibility and biodegradability, low toxicity, and synergistic therapy, polymeric nanoparticles have received considerable attention as potential antimicrobial drug delivery agents. In this context, the aim of this paper is to provide an up-to-date overview of the most recent studies investigating polymeric nanoparticles designed for antimicrobial therapies, describing both their targeting strategies and their effects.

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“…The effective drug concentration reached within the biofilm is very crucial [17]. The impaired diffusion of antimicrobial agents in the biofilm mode of growth is another cause of antimicrobial therapy failure.…”

Section: Application Of Nps In Drug Delivery Systemsmentioning

confidence: 99%

“…NPs improve the effectiveness of the photosensitizer because they can pass through the bacteria cell walls [16]. Additionally, nanotechnology in the case of drug delivery vehicles can improve drug availability into the target tissue to deliver the maximum therapeutic effect [17]. Herein, this review investigated the antimicrobial actions of NPs against oral infectious disease with a focus on oral bacterial biofilms.…”

Section: Introductionmentioning

confidence: 99%

Nanostructures as Targeted Therapeutics for Combating Oral Bacterial Diseases

et al. 2021

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Pathogenic oral biofilms are now recognized as a key virulence factor in many microorganisms that cause the heavy burden of oral infectious diseases. Recently, new investigations in the nanotechnology field have propelled the development of novel biomaterials and approaches to control bacterial biofilms, either independently or in combination with other substances such as drugs, bioactive molecules, and photosensitizers used in antimicrobial photodynamic therapy (aPDT) to target different cells. Moreover, nanoparticles (NPs) showed some interesting capacity to reverse microbial dysbiosis, which is a major problem in oral biofilm formation. This review provides a perspective on oral bacterial biofilms targeted with NP-mediated treatment approaches. The first section aims to investigate the effect of NPs targeting oral bacterial biofilms. The second part of this review focuses on the application of NPs in aPDT and drug delivery systems.

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Surface charge modulation of rifampicin-loaded PLA nanoparticles to improve antibiotic delivery in Staphylococcus aureus biofilms

Cited by 54 publications

References 39 publications

LipoParticles: Lipid-Coated PLA Nanoparticles Enhanced In Vitro mRNA Transfection Compared to Liposomes

LipoParticles: Lipid-Coated PLA Nanoparticles Enhanced In Vitro mRNA Transfection Compared to Liposomes

Polymeric Nanoparticles for Antimicrobial Therapies: An up-to-date Overview

Nanostructures as Targeted Therapeutics for Combating Oral Bacterial Diseases

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