Qi Gao scite author profile

The influence of the surface functionalization of silica particles on their colloidal stability in physiological media is studied and correlated with their uptake in cells. The surface of 55 ± 2 nm diameter silica particles is functionalized by amino acids or amino- or poly(ethylene glycol) (PEG)-terminated alkoxysilanes to adjust the zeta potential from highly negative to positive values in ethanol. A transfer of the particles into water, physiological buffers, and cell culture media reduces the absolute value of the zeta potential and changes the colloidal stability. Particles stabilized by L-arginine, L-lysine, and amino silanes with short alkyl chains are only moderately stable in water and partially in PBS or TRIS buffer, but aggregate in cell culture media. Nonfunctionalized, N-(6-aminohexyl)-3-aminopropyltrimethoxy silane (AHAPS), and PEG-functionalized particles are stable in all media under study. The high colloidal stability of positively charged AHAPS-functionalized particles scales with the ionic strength of the media, indicating a mainly electrostatical stabilization. PEG-functionalized particles show, independently from the ionic strength, no or only minor aggregation due to additional steric stabilization. AHAPS stabilized particles are readily taken up by HeLa cells, likely as the positive zeta potential enhances the association with the negatively charged cell membrane. Positively charged particles stabilized by short alkyl chain aminosilanes adsorb on the cell membrane, but are weakly taken up, since aggregation inhibits their transport. Nonfunctionalized particles are barely taken up and PEG-stabilized particles are not taken up at all into HeLa cells, despite their high colloidal stability. The results indicate that a high colloidal stability of nanoparticles combined with an initial charge-driven adsorption on the cell membrane is essential for efficient cellular uptake.

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Skin Penetration and Cellular Uptake of Amorphous Silica Nanoparticles with Variable Size, Surface Functionalization, and Colloidal Stability

Rancan¹,

et al. 2012

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In this study, the skin penetration and cellular uptake of amorphous silica particles with positive and negative surface charge and sizes ranging from 291 ± 9 to 42 ± 3 nm were investigated. Dynamic light scattering measurements and statistical analyses of transmission electron microscopy images were used to estimate the degree of particle aggregation, which was a key aspect to understanding the results of the in vitro cellular uptake experiments. Despite partial particle aggregation occurring after transfer in physiological media, particles were taken up by skin cells in a size-dependent manner. Functionalization of the particle surface with positively charged groups enhanced the in vitro cellular uptake. However, this positive effect was contrasted by the tendency of particles to form aggregates, leading to lower internalization ratios especially by primary skin cells. After topical application of nanoparticles on human skin explants with partially disrupted stratum corneum, only the 42 ± 3 nm particles were found to be associated with epidermal cells and especially dendritic cells, independent of their surface functionalization. Considering the wide use of nanomaterials in industries and the increasing interest for applications in pharmaceutics and cosmetics versus the large number of individuals with local or spread impairment of the skin barrier, e.g., patients with atopic dermatitis and chronic eczema, a careful dissection of nanoparticle-skin surface interactions is of high relevance to assess possible risks and potentials of intended and unintended particle exposure.

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Direct Evidence of Lithium-Induced Atomic Ordering in Amorphous TiO₂ Nanotubes

Gao

Nie

et al. 2014

Chem. Mater.

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In this paper, we report the first direct chemical and imaging evidence of lithium-induced atomic ordering in amorphous TiO 2 nanomaterials and propose new reaction mechanisms that contradict the many works in the published literature on the lithiation behavior of these materials. The lithiation process was conducted in situ inside an atomic resolution transmission electron microscope. Our results indicate that the lithiation started with the valence reduction of Ti 4+ to Ti 3+ leading to a Li x TiO 2 intercalation compound. The continued intercalation of Li ions in TiO 2 nanotubes triggered an amorphous to crystalline phase transformation. The crystals were formed as nano-islands and identified to be Li 2 Ti 2 O 4 with cubic structure (a = 8.375 Å). The tendency for the formation of these crystals was verified with density functional theory (DFT) simulations. The size of the crystalline islands provides a characteristic length scale (∼5 nm) at which the atomic bonding configuration has been changed within a short time period. This phase transformation is associated with local inhomogeneities in Li distribution. On the basis of these observations, a new reaction mechanism is proposed to explain the first cycle lithiation behavior in amorphous TiO 2 nanotubes.

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Lysosomal Dysfunction Caused by Cellular Accumulation of Silica Nanoparticles

Schütz

López-Hernández

Gao

et al. 2016

Journal of Biological Chemistry

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Nanoparticles (NPs) are widely used as components of drugs or cosmetics and hold great promise for biomedicine, yet their effects on cell physiology remain poorly understood. Here we demonstrate that clathrin-independent dynamin 2-mediated caveolar uptake of surface-functionalized silica nanoparticles (SiNPs) impairs cell viability due to lysosomal dysfunction. We show that internalized SiNPs accumulate in lysosomes resulting in inhibition of autophagy-mediated protein turnover and impaired degradation of internalized epidermal growth factor, whereas endosomal recycling proceeds unperturbed. This phenotype is caused by perturbed delivery of cargo via autophagosomes and late endosomes to SiNP-filled cathepsin B/L-containing lysosomes rather than elevated lysosomal pH or altered mTOR activity. Given the importance of autophagy and lysosomal protein degradation for cellular proteostasis and clearance of aggregated proteins, these results raise the question of beneficial use of NPs in biomedicine and beyond. Nanoparticles (NPs)2 are widely used as components of drugs or cosmetics and hold great promise as tools in biomedicine to improve the detection and treatment of diseases (1). For example, nanoparticle technology has enabled improvements in cancer treatment, ranging from improved efficacy of drug delivery (2) to enhanced immunogenicity of cancer vaccines (3). Moreover, NPs are used as biosensors and biomarkers (4, 5) or for DNA/drug delivery (6). Hence, it is necessary to understand the mechanisms of interaction of NPs with living cells and tissues to assess the biological consequences associated with their application in biomedicine (7). At present, the risks associated with the biomedical application of NPs at the cellular and organismic levels remain incompletely understood (1). Among the phenotypic changes reported to be associated with the biomedical application of NPs are cellular stress responses (i.e. redox imbalance, oxidative stress), DNA damage, and altered gene expression (8,9). Which of these phenotypes can be considered a direct consequence of cellular NP association or uptake and the underlying molecular mechanisms have remained in many cases unknown.Upon cellular application, NPs initially interact with the plasma membrane, often followed by their internalization into the cell interior (10 -12) via clathrin-dependent as well as clathrin-independent endocytosis routes (i.e. via caveolae), which may require the membrane-severing GTPase dynamin (13,14). Due to the questionable specificity of many commonly used pharmacological tools toward these pathways (15) the precise mechanisms of cellular uptake of NPs often have remained elusive. After cell entry NPs are delivered to the endolysosomal system (16), where they may accumulate. Lysosomes play essential roles in cell physiology ranging from the degradation of malfunctional or aggregated proteins (e.g. via autophagy) or lipids to nutrient signaling and cellular growth control (17). For example, internalized growth factors such as EGF are sorted to la...

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Association between extreme temperatures and emergency room visits related to mental disorders: A multi-region time-series study in New York, USA

Yoo

Eum

Roberts

et al. 2021

Science of The Total Environment

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Qi Gao

Surface Functionalization of Silica Nanoparticles Supports Colloidal Stability in Physiological Media and Facilitates Internalization in Cells

Skin Penetration and Cellular Uptake of Amorphous Silica Nanoparticles with Variable Size, Surface Functionalization, and Colloidal Stability

Direct Evidence of Lithium-Induced Atomic Ordering in Amorphous TiO₂ Nanotubes

Lysosomal Dysfunction Caused by Cellular Accumulation of Silica Nanoparticles

Association between extreme temperatures and emergency room visits related to mental disorders: A multi-region time-series study in New York, USA

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Qi Gao

Surface Functionalization of Silica Nanoparticles Supports Colloidal Stability in Physiological Media and Facilitates Internalization in Cells

Skin Penetration and Cellular Uptake of Amorphous Silica Nanoparticles with Variable Size, Surface Functionalization, and Colloidal Stability

Direct Evidence of Lithium-Induced Atomic Ordering in Amorphous TiO2 Nanotubes

Lysosomal Dysfunction Caused by Cellular Accumulation of Silica Nanoparticles

Association between extreme temperatures and emergency room visits related to mental disorders: A multi-region time-series study in New York, USA

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Resources

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Direct Evidence of Lithium-Induced Atomic Ordering in Amorphous TiO₂ Nanotubes