Polymeric Nanoparticles with Neglectable Protein Corona (original) (raw)
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Quantitative comparison of the protein corona of nanoparticles with different matrices
International Journal of Pharmaceutics: X
Nanoparticles (NPs) are paving the way for improved treatments for difficult to treat diseases diseases; however, much is unknown about their fate in the body. One important factor is the interaction between NPs and blood proteins leading to the formation known as the "protein corona" (PC). The PC, consisting of the Hard (HC) and Soft Corona (SC), varies greatly based on the NP composition, size, and surface properties. This highlights the need for specific studies to differentiate the PC formation for each individual NP system. This work focused on comparing the HC and SC of three NPs with different matrix compositions: a) polymeric NPs based on poly(lacticco-glycolic) acid (PLGA), b) hybrid NPs consisting of PLGA and Cholesterol, and c) lipidic NPs made only of Cholesterol. NPs were formulated and characterized for their physico-chemical characteristics and composition, and then were incubated in human plasma. In-depth purification, identification, and statistical analysis were then performed to identify the HC and SC components. Finally, similar investigations demonstrated whether the presence of a targeting ligand on the NP surface would affect the PC makeup. These results highlighted the different PC fingerprints of these NPs, which will be critical to better understand the biological influences of the PC and improve future NP designs.
How protein coronas determine the fate of engineered nanoparticles in biological environment
Arhiv za higijenu rada i toksikologiju, 2017
Nanomedicine is a booming medical field that utilises nanoparticles (NPs) for the development of medicines, medical devices, and diagnostic tools. The behaviour of NPs in vivo may be quite complex due to their interactions with biological molecules. These interactions in biological fluids result in NPs being enveloped by dynamic protein coronas, which serve as an interface between NPs and their environment (blood, cell, tissue). How will the corona interact with this environment will depend on the biological, chemical, and physical properties of NPs, the properties of the proteins that make the corona, as well as the biological environment. This review summarises the main characteristics of protein corona and describes its dynamic nature. It also presents the most common analytical methods to study the corona, including examples of protein corona composition for the most common NPs used in biomedicine. This knowledge is necessary to design NPs that will create a corona with a desire...
Bioconjugate Chemistry, 2018
Significant progress in the characterization of protein corona has been made. However, insights on how the corona affects the aggregation of nanoparticles (NPs) and consequent biological identity are still lacking. Here, we examined how the corona formed from four major serum proteins: immunoglobulin G (IgG), fibrinogen (FBG), apolipoprotein A1 (ApoA1), and human serum albumin (HSA) over a range of concentrations affect the aggregation of gold NPs (AuNPs). We found that at physiological pH of 7.4, all four proteins aggregated the AuNPs at low concentrations but conferred colloidal stability at high concentrations due to the complete "corona coat" around individual AuNP. Due to their immune-related functions, IgG and FBG aggregated the AuNPs to a greater extent compared to HSA and ApoA1 which were mostly involved in transport of small molecules. We then introduced the AuNP-corona formed from each protein into an acidic solution at pH 6.2 with high ionic concentration for up to 24 h as a model of the tumor microenvironment to examine for changes in their aggregation. We observed that protein corona formation sterically stabilized the AuNP-corona for all four proteins, resulting in a smaller increase in aggregation and size compared to citrate-capped AuNPs. This was especially true for corona formed at high protein:AuNP ratios. Our study therefore showed that the formation of a complete "corona coat" around NPs at sufficiently high protein:NP ratio was required for colloidal stability of designed NP systems in both physiological and cancer microenvironment to maintain efficiency and efficacy in cancer drug delivery.
Protein Corona-Enabled Systemic Delivery and Targeting of Nanoparticles
The AAPS Journal, 2020
Upon systemic administration, nanoparticles encounter serum proteins in the biological system resulting in the formation of "protein corona" on the surface. Increased understanding of the relationship between nanoparticles' "chemical identity" and "biological identity" can contribute to improved clinical translation. Recent studies of protein corona composition on nanoparticles, including from our group, suggest that a strategic choice of materials can influence the types of protein adsorbed from plasma and lead to improved delivery efficiency. This mini-review reflects on the fundamental knowledge of nanoparticle protein corona and highlights the recent applications of protein corona on nanoparticles' systemic circulation, cell, and tissue-specific delivery. Important considerations on the safety and efficacy aspects pertaining to the exploration of nanoparticle protein corona's targeting effect are also summarized. Finally, the future perspectives of protein corona research are discussed.
Surface chemistry and serum type both determine the nanoparticle-protein corona
Journal of Proteomics, 2015
The protein corona that forms around nanoparticles in vivo is a critical factor that affects their physiological response. The potential to manipulate nanoparticle characteristics such that either proteins advantageous for delivery are recruited and/or detrimental proteins are avoided offers exciting possibilities for improving drug delivery. In this work, we used nanoliquid chromatography tandem mass spectrometry to characterize the corona of five lipid formulations after incubation in mouse and human plasma with the hope of providing data that may contribute to a better understanding of the role played by both the nanoparticle properties and the physiological environment in recruiting specific proteins to the corona. Notably, we showed that minor changes in the lipid composition might critically affect the protein corona composition demonstrating that the surface chemistry and arrangement of lipid functional groups are key players that regulate the liposome-protein interactions. Notably, we provided evidence that the protein corona that forms around liposomes is strongly affected by the physiological environment, i.e., the serum type. These results are likely to suggest that the translation of novel pharmaceutical formulations from animal models to the clinic must be evaluated on a case-by-case basis.
Nanomedicine: Nanotechnology, Biology and Medicine, 2012
Nanoparticles (NPs) for medical applications are often introduced into the body via intravenous injections, leading to the formation of a protein corona on their surface due to the interaction with blood plasma proteins. Depending on its composition and time evolution, the corona will modify the biological behavior of the particle. For successful delivery and targeting, it is therefore important to assess on a quantitative basis how and to what extent the presence of the corona perturbs the specific interaction of a designed NP with its cellular target. We present a theoretical systems-level analysis, in which peptides have been covalently coupled to the surface of nanoparticles, describing the delivery success rate in varying conditions, with regard to protein composition of the surrounding fluid. Dynamic modeling and parameter sensitivity analysis proved to be useful and computationally affordable tools to aid in the design of NPs with increased success rate probability in a biological context.
Recent advances in the analysis of nanoparticle-protein coronas
Nanomedicine, 2020
In spite of radical advances in nanobiotechnology, the clinical translation of nanoparticle (NP)-based agents is still a major challenge due to various physiological factors that influence their interactions with biological systems. Recent decade witnessed meticulous investigation on protein corona (PC) that is the first surrounds NPs once administered into the body. Formation of PC around NP surface exhibits resilient effects on their circulation, distribution, therapeutic activity, toxicity and other factors. Although enormous literature is available on the role of PC in altering pharmacokinetics and pharmacodynamics of NPs, understanding on its analytical characterization methods still remains shallow. Therefore, the current review summarizes the impact of PC on biological fate of NPs and stressing on analytical methods employed for studying the NP-PC.
Nanoscale Research Letters, 2015
Protein corona has became a prevalent subject in the field of nanomedicine owing to its diverse role in determining the efficiency, efficacy, and the ultimate biological fate of the nanomaterials used as a tool to treat and diagnose various diseases. For instance, protein corona formation on the surface of nanoparticles can modify its physicochemical properties and interfere with its intended functionalities in the biological microenvironments. As such, much emphasis should be placed in understanding these complex phenomena that occur at the bio-nano interface. The main aim of this review is to present different factors that are influencing protein-nanoparticle interaction such as physicochemical properties of nanoparticle (i.e., size and size distribution, shape, composition, surface chemistry, and coatings) and the effect of biological microenvironments. Apart from that, the effect of ignored factors at the bio-nano interface such as temperature, plasma concentration, plasma gradient effect, administration route, and cell observer were also addressed.
Modification of the protein corona–nanoparticle complex by physiological factors
Materials Science and Engineering: C, 2016
Nanoparticle (NP) effects in a biological system are driven through the formation and structure of the protein corona-NP complex, which is dynamic by nature and dependent upon factors from both the local environment and NP physicochemical parameters. To date, considerable data has been gathered regarding the structure and behavior of the protein corona in blood, plasma, and traditional cell culture medium. However, there exists a knowledge gap pertaining to the protein corona in additional biological fluids and following incubation in a dynamic environment. Using 13 nm gold NPs (AuNPs), functionalized with either polyethylene glycol or tannic acid, we demonstrated that both particle characteristics and the associated protein corona were altered when exposed to artificial physiological fluids and under dynamic flow. Furthermore, the magnitude of observed behavioral shifts were dependent upon AuNP surface chemistry. Lastly, we revealed that exposure to interstitial fluid produced protein corona modifications, reshaping of the nano-cellular interface, modified AuNP dosimetry, and induction of previously unseen cytotoxicity. This study highlights the need to elucidate both NP and protein corona behavior in biologically representative environments in an effort to increase accurate interpretation of data and transfer of this knowledge to efficacy, behavior, and safety of nano-based applications.