Understanding the Influence of a Bifunctional Polyethylene Glycol Derivative in Protein Corona Formation around Iron Oxide Nanoparticles

Ruiz, Amalia; Alpízar, Adán; Beola, Lilianne; Rubio, Carmen; Gavilán, Helena; Marciello, Marzia; Rodríguez-Ramiro, Ildefonso; Ciordia, Sergio; Morris, C J; Morales, M.P.

doi:10.3390/ma12142218

Cited by 24 publications

(17 citation statements)

References 72 publications

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“…Undoubtedly, in order to rationally design nanoparticles for medical applications, it is necessary to understand the mechanism of formation of the protein corona and its composition. Ruiz et al [ 31 ] investigated, by means of proteomic analysis, the formation and composition of the protein corona around magnetic nanoparticles coated in two ways: in the first case using dimercaptosuccinic acid (DMSA), and in the other – by means of a diamine (PEG)-derived molecule (2000 Da) which is widely used for providing a long circulation time [ 32 , 33 ]. Semiquantitative analysis of the protein corona composition of the above-mentioned nanoparticles is shown in Fig.…”

Section: Intravenously Injected Mnpsmentioning

confidence: 99%

Pharmacokinetics of magnetic iron oxide nanoparticles for medical applications

Nowak-Jary

Machnicka

2022

J Nanobiotechnol

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Magnetic iron oxide nanoparticles (MNPs) have been under intense investigation for at least the last five decades as they show enormous potential for many biomedical applications, such as biomolecule separation, MRI imaging and hyperthermia. Moreover, a large area of research on these nanostructures is concerned with their use as carriers of drugs, nucleic acids, peptides and other biologically active compounds, often leading to the development of targeted therapies. The uniqueness of MNPs is due to their nanometric size and unique magnetic properties. In addition, iron ions, which, along with oxygen, are a part of the MNPs, belong to the trace elements in the body. Therefore, after digesting MNPs in lysosomes, iron ions are incorporated into the natural circulation of this element in the body, which reduces the risk of excessive storage of nanoparticles. Still, one of the key issues for the therapeutic applications of magnetic nanoparticles is their pharmacokinetics which is reflected in the circulation time of MNPs in the bloodstream. These characteristics depend on many factors, such as the size and charge of MNPs, the nature of the polymers and any molecules attached to their surface, and other. Since the pharmacokinetics depends on the resultant of the physicochemical properties of nanoparticles, research should be carried out individually for all the nanostructures designed. Almost every year there are new reports on the results of studies on the pharmacokinetics of specific magnetic nanoparticles, thus it is very important to follow the achievements on this matter. This paper reviews the latest findings in this field. The mechanism of action of the mononuclear phagocytic system and the half-lives of a wide range of nanostructures are presented. Moreover, factors affecting clearance such as hydrodynamic and core size, core morphology and coatings molecules, surface charge and technical aspects have been described. Graphical Abstract

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Section: Intravenously Injected Mnpsmentioning

confidence: 99%

Pharmacokinetics of magnetic iron oxide nanoparticles for medical applications

Nowak-Jary

Machnicka

2022

J Nanobiotechnol

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“…Indeed, in vivo the nanoparticles are in contact with biological fluids and, immediately after injection, they interact with the plasma proteins (opsonins) which results in the adsorption of these proteins on their surface. This process, named opsonization, will take place at different rates depending on the nanoparticle features, particularly its coating nature [161,162]. Toxicology results obtained in vivo in diverse animal models (e.g.…”

Section: Do Magnetic Nanoparticles Affect Cellular Functions?mentioning

confidence: 99%

Magnetic nanoparticles in regenerative medicine: what of their fate and impact in stem cells?

Walle

Perez

Abou‐Hassan

et al. 2020

Materials Today Nano

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With advancing developments over the use of magnetic nanoparticles in biomedical engineering, and more specifically cell-based therapies, the question of their fate and impact once internalized within (stem) cells remains crucial. After highlighting the regenerative medicine applications based on magnetic nanoparticles, this review documents their potential cytotoxicity and, more importantly, underscores their valuable features for stem cell differentiation. It then focuses on the transformations magnetic nanoparticles might experience in cells, mainly consisting in their progressive degradation, and assesses the practical pitfalls related to this degradation. First, it may result in a loss of long-term theranostic potential, and second, it necessitates an adaptation of the cell metabolism to the released iron. Overall, this review demonstrates that magnetic nanoparticles present undeniable interest for stem cell-based biomedical applications; however, each nanoparticle/cell system must be carefully considered for a safe medical use. It also clearly evidences that the biodegradation of the nanoparticles and the cell response to the released iron must be systematically assessed.

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“…Despite nearly identical magnetite core size, hydrodynamic size, and zeta potential of the MNPs in the stock solution, the hydrodynamic size of PEG-SO-MNPs in culture medium was almost three times that of BSA-SO-MNPs (281 nm vs 98 nm, respectively) due to absorption of serum proteins on the particle surface [ 40 ]. Although PEGylation decreases the protein absorption on the particle surface, it does not completely prevent it [ 41 ]. BSA is a component of serum proteins and commonly involved in PC formation.…”

Section: Discussionmentioning

confidence: 99%

Differences in surface chemistry of iron oxide nanoparticles result in different routes of internalization

Svitkova¹,

Závišová²,

Némethová³

et al. 2021

Beilstein J. Nanotechnol.

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The efficient entry of nanotechnology-based pharmaceuticals into target cells is highly desired to reach high therapeutic efficiency while minimizing the side effects. Despite intensive research, the impact of the surface coating on the mechanism of nanoparticle uptake is not sufficiently understood yet. Herein, we present a mechanistic study of cellular internalization pathways of two magnetic iron oxide nanoparticles (MNPs) differing in surface chemistry into A549 cells. The MNP uptake was investigated in the presence of different inhibitors of endocytosis and monitored by spectroscopic and imaging techniques. The results revealed that the route of MNP entry into cells strongly depends on the surface chemistry of the MNPs. While serum bovine albumin-coated MNPs entered the cells via clathrin-mediated endocytosis (CME), caveolin-mediated endocytosis (CavME) or lipid rafts were preferentially involved in the internalization of polyethylene glycol-coated MNPs. Our data indicate that surface engineering can contribute to an enhanced delivery efficiency of nanoparticles.

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Understanding the Influence of a Bifunctional Polyethylene Glycol Derivative in Protein Corona Formation around Iron Oxide Nanoparticles

Cited by 24 publications

References 72 publications

Pharmacokinetics of magnetic iron oxide nanoparticles for medical applications

Pharmacokinetics of magnetic iron oxide nanoparticles for medical applications

Magnetic nanoparticles in regenerative medicine: what of their fate and impact in stem cells?

Differences in surface chemistry of iron oxide nanoparticles result in different routes of internalization

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