Coralie Thirifays scite author profile

Until now, the results of nanotoxicology research have shown that the interactions between nanoparticles (NPs) and cells are remarkably complex. In order to get a deep understanding of the NP-cell interactions, scientists have focused on the physicochemical effects. However, there are still considerable debates about the regulation of nanomaterials and the reported results are usually in contradictions. Here, we are going to introduce the potential key reasons for these conflicts. In this case, modification of conventional in vitro toxicity assays, is one of the crucial ignored matter in nanotoxicological sciences. More specifically, the conventional methods neglect important factors such as the sedimentation of NPs and absorption of proteins and other essential biomolecules onto the surface of NPs. Another ignored matter in nanotoxicological sciences is the effect of cell “vision” (i.e., cell type). In order to show the effects of these ignored subjects, we probed the effect of superparamagnetic iron oxide NPs (SPIONs), with various surface chemistries, on various cell lines. We found thatthe modification of conventional toxicity assays and the consideration of the “cell vision” concept are crucial matters to obtain reliable, and reproducible nanotoxicology data. These new concepts offer a suitable way to obtain a deep understanding on the cell-NP interactions. In addition, by consideration of these ignored factors, the conflict of future toxicological reports would be significantly decreased.

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Significance of cell “observer” and protein source in nanobiosciences

Laurent

Burtéa

Thirifays

et al. 2013

Journal of Colloid and Interface Science

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Hard corona composition and cellular toxicities of the graphene sheets

Mao

Chen

Laurent

et al. 2013

Colloids and Surfaces B: Biointerfaces

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Corona protein composition and cytotoxicity evaluation of ultra-small zeolites synthesized from template free precursor suspensions

Laurent¹,

Ng²,

Thirifays³

et al. 2013

Toxicol. Res.

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The toxicity of two types of ultra-small zeolites (8-18 nm) with LTL-and EMT-type structures is reported.Both the LTL-and EMT-type zeolites belong to the same group of molecular sieves; they have large pores (7.1-7.5 Å) and low silica content (Si/Al = 1.2-2.3). The zeolites are prepared by an environmentally friendly synthetic approach from precursor suspensions without using any organic template. Cellular interactions with the two types of zeolite nanocrystals are evaluated by cell viability, reactive oxygen species and cell life cycle assays. It is found that various concentrations of zeolites have negligible effects on the cell life cycle. Moreover, the LTL-and EMT-types zeolites did not cause extensive oxidative stress on the cells. Although it is seen that the zeolites extensively entered in the cells, there is no sign of toxicity for all employed concentrations of ultra-small EMT and LTL zeolites. Additionally, no abnormality in DNA replication while exposed to the zeolites is observed. Very importantly, the zeolite corona shows a high affinity for fibrinogen, moderate affinity for apoA-II and complement factor 3, and trace affinity for albumin, which is the most abundant protein of human plasma. Thus the zeolite nanoparticles can be considered as very promising material for purification of fibrinogen and lipoproteins. Since fibrinogen is considered as acute phase protein and found to be the most associated biomolecule in the composition of corona at the surface of zeolites, we propose that these nanoparticles can be potentially pro-inflammatory for in vivo applications. † Electronic supplementary information (ESI) available. See

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Paramagnetic Liposomes: Inner versus Outer Membrane Relaxivity of DPPC Liposomes Incorporating Lipophilic Gadolinium Complexes

et al. 2008

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Proton relaxometric properties of unilamellar DPPC liposomes embedding an amphiphilic paramagnetic chelate (Gd-DTPA-BC(14)A) in both layers of the phospholipid membrane or only in the external one are compared. The results show that the membrane's water permeability is able to quench the effect of the paramagnetic complexes located in the internal layer of DPPC liposomes, leading thus to an apparent lower global relaxivity.

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