Cationic nanoparticles induce caspase 3-, 7- and 9-mediated cytotoxicity in a human astrocytoma cell line

Bexiga, Mariana G.; Varela, Juan A.; Wang, Fengjuan; Fenaroli, Federico; Salvati, Anna; Lynch, Iseult; Simpson, Jeremy C.; Dawson, Kenneth A.

doi:10.3109/17435390.2010.539713

Cited by 129 publications

(169 citation statements)

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“…[4][5][6][7][8] Although several nanoparticles accumulate in cells with no acute toxicity, 3,9 some nanomaterials have been found to impact cells and this has generated nanosafety concerns. [10][11][12][13] Cytotoxic responses have been associated to nanoparticles such as metal oxide ones and fullerenes, [14][15][16][17][18] where the effect can be connected mainly to the release of toxic ions due to particle solubility, 19 oxidative stress, 17,20,21 and cationic damage. 20 Recent studies have shown that alterations of the native structure of the proteins that adsorb on the nanoparticles' surface in the context of biological fluids can trigger signaling cascades and activate inflammatory responses.…”

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confidence: 99%

Low Dose of Amino-Modified Nanoparticles Induces Cell Cycle Arrest

et al. 2013

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The interaction of nanoscaled materials with biological systems is currently the focus of a fast-growing area of investigation. Though many nanoparticles interact with cells without acute toxic responses, amino-modified polystyrene nanoparticles are known to induce cell death. We have found that by lowering their dose, cell death remains low for several days while, interestingly, cell cycle progression is arrested. In this scenario, nanoparticle uptake, which we have recently shown to be affected by cell cycle progression, develops differently over time due to the absence of cell division. This suggests that the same nanoparticles can trigger different pathways depending on exposure conditions and the dose accumulated.

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Low Dose of Amino-Modified Nanoparticles Induces Cell Cycle Arrest

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“…30 This is in contrast to amine-modified PS NPs which have been shown to be toxic to in vitro CNS cell lines due to cell membrane rupture and caspase activation. 11 The 100 nm PS COOH NPs were then used for uptake, localisation and paracrine signalling studies. NP characterisation (size and zeta potential, in Supp Fig 1 and 2 respectively) indicated that in cell culture medium supplemented with 2 % bovine serum, stable dispersions were obtained and that the average size increased, while (absolute) zeta potential decreased, as a consequence of protein adsorption, protein corona formation 33 and likely partial agglomeration.…”

Section: Resultsmentioning

confidence: 99%

“…Understanding the effect of NP exposure to biological entities under the criteria of cellular transportation and long-term toxicity is therefore of paramount importance. [11][12][13][14][15][16] There has been an explosion in the number of studies of NP transport to the brain, most of which focussed on the potential of nanomaterials to cross biological barriers and/or biodistribute to the brain, and on the impacts of nanomaterials on the delicate tissues and cells of the CNS once across. [17][18][19][20][21] However, two as yet neglected areas of research are the investigation of the potential impact of NPs on the cells of the barrier themselves as a result of NP accumulation in the barrier, and the potential for signalling or other impacts to the brain without actual crossing of the NPs into the CNS (so-called indirect effects).…”

Section: Introductionmentioning

confidence: 99%

Paracrine signalling of inflammatory cytokines from an in vitro blood brain barrier model upon exposure to polymeric nanoparticles

Raghnaill

Bramini

Dong

et al. 2014

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Nanoparticle properties, such as small size relative to large highly modifiable surface area, offer great promise for neuro-therapeutics and nanodiagnostics. A fundamental understanding and control of how nanoparticles interact with the blood-brain barrier (BBB) could enable major developments in nanomedical treatment of previously intractable neurological disorders, and help ensure that nanoparticles not intended to reach the brain do not cause adverse effects. Nanosafety is of utmost importance to this field. However, a distinct lack of knowledge exists regarding nanoparticle accumulation within the BBB and the biological effects this may induce on neighbouring cells of the Central Nervous System (CNS), particularly in the long-term. This study focussed on the exposure of an in vitro BBB model to model carboxylated polystyrene nanoparticles (PS COOH NPs), as these nanoparticles are well characterised for in vitro experimentation and have been reported as non-toxic in many biological settings. TEM imaging showed accumulation but not degradation of 100 nm PS COOH NPs within the lysosomes of the in vitro BBB over time. Cytokine secretion analysis from the in vitro BBB post 24 h 100 nm PS COOH NP exposure showed a low level of proinflammatory RANTES protein secretion compared to control. In contrast, 24 h exposure of the in vitro BBB endothelium to 100 nm PS COOH NPs in the presence of underlying astrocytes caused a significant increase in pro-survival signalling. In conclusion, the tantalising possibilities of nanomedicine must be balanced by cautious studies into the possible long-term toxicity caused by accumulation of known 'toxic' and 'non-toxic' nanoparticles, as general toxicity assays may be disguising significant signalling regulation during long-term accumulation.

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“…This, in turn, results in damage to the mitochondria and activation of caspases 3 and 7, with consequent cleavage of PARP-1, ultimately resulting in the apoptotic death of the cells [112]. Ongoing work has shown that the kinetics of the lysosome membrane damage can be correlated with the digestion of the nanoparticle protein corona in the lysosomes which allows the underlying amine groups on the nanoparticles to be re-exposed [113].…”

Section: The Signalling Concept: Interaction Of Nanoparticles With Mamentioning

confidence: 96%

“…A detailed investigation of the mechanism of toxicity induced by 50 nm amine-modified polystyrene nanoparticles following uptake by 1321N1 brain astrocytoma cells found that the nanoparticles are localized in lysosomes, whereupon the lysosomal membrane becomes destabilized, likely because of the nanoparticle's positive charge, leading to release into the cytoplasm of both nanoparticles and proteolytic enzymes such as cathepsins [112]. This, in turn, results in damage to the mitochondria and activation of caspases 3 and 7, with consequent cleavage of PARP-1, ultimately resulting in the apoptotic death of the cells [112].…”

Section: The Signalling Concept: Interaction Of Nanoparticles With Mamentioning

confidence: 99%

The bio-nano-interface in predicting nanoparticle fate and behaviour in living organisms: towards grouping and categorising nanomaterials and ensuring nanosafety by design

et al. 2013

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Abstract:In biological media, nanoparticles acquire a coating of biomolecules (proteins, lipids, polysaccharides) from their surroundings, which reduces their surface energy and confers a biological identity to the particles. This adsorbed layer is the interface between the nanomaterial and living systems and therefore plays a significant role in determining the fate and behaviour of the nanoparticles. This review summarises the state of the art in terms of understanding the bio-nano interface and provides direction for potential future research and recommendations for future priorities and strategies to support the safe implementation of nanotechnologies. The central premise is that nanomaterials must be studied as biological entities under the appropriate exposure conditions and that this should be implemented in study design and reporting for nanosafety assessment. The implications of the bio-nano interface for nanomaterials fate and behaviour are described in light of four interlinked perspectives: the Coating concept; the Translocation concept; the Signalling concept, and the Kinetics concept. A key conclusion is that nanoparticles cannot be viewed as non-interacting species, but rather must be thought of, and studied as, biological entities, where their interaction with the environment is mediated by the proteins and other biomolecules that adsorb to them, and the key parameter to characterise then becomes the nature, composition and evolution of the bionano interface.

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Cationic nanoparticles induce caspase 3-, 7- and 9-mediated cytotoxicity in a human astrocytoma cell line

Cited by 129 publications

References 32 publications

Low Dose of Amino-Modified Nanoparticles Induces Cell Cycle Arrest

Low Dose of Amino-Modified Nanoparticles Induces Cell Cycle Arrest

Paracrine signalling of inflammatory cytokines from an in vitro blood brain barrier model upon exposure to polymeric nanoparticles

The bio-nano-interface in predicting nanoparticle fate and behaviour in living organisms: towards grouping and categorising nanomaterials and ensuring nanosafety by design

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