A predictive model of iron oxide nanoparticles flocculation tuning Z-potential in aqueous environment for biological application

Baldassarre, Francesca; Cacciola, Matteo; Ciccarella, Giuseppe

doi:10.1007/s11051-015-3163-6

Cited by 32 publications

(18 citation statements)

References 85 publications

(96 reference statements)

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“…6 ). We have previously reported on the unusual structure of 1m , 6 a where all metallic distances are shorter than 2.80 Å, which is twice the van der Waals radius (only four structures have been reported in the CSD database version 5.36 with similar characteristics 25 , 26 ). However, 2m adopts the most common disposition of the Cu 2 I 2 units in these stair-step chain structures, showing alternation of long (>2.80 Å) and short (<2.80 Å) distances between Cu and Cu atoms.…”

Section: Resultsmentioning

confidence: 99%

Smart composite films of nanometric thickness based on copper–iodine coordination polymers. Toward sensors

et al. 2018

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Section: Resultsmentioning

confidence: 99%

Smart composite films of nanometric thickness based on copper–iodine coordination polymers. Toward sensors

et al. 2018

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“…Since DLS can also provide indications on the aggregation tendency of a sol, it can be combined with ζ-potential measurements for a more complete characterization. 219 Branda et al employed DLS and ζ-potential studies (which in fact can be carried out in the same device with modern instruments) to analyse the influence of the exposure to growth media on the size and surface charge of silica-based Stöber NPs. These techniques appeared to be valuable tools to investigate the fate of NPs in biological environments.…”

Section: X-ray-based Techniquesmentioning

confidence: 99%

Characterization techniques for nanoparticles: comparison and complementarity upon studying nanoparticle properties

2018

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Nanostructures have attracted huge interest as a rapidly growing class of materials for many applications. Several techniques have been used to characterize the size, crystal structure, elemental composition and a variety of other physical properties of nanoparticles. In several cases, there are physical properties that can be evaluated by more than one technique. Different strengths and limitations of each technique complicate the choice of the most suitable method, while often a combinatorial characterization approach is needed. In addition, given that the significance of nanoparticles in basic research and applications is constantly increasing, it is necessary that researchers from separate fields overcome the challenges in the reproducible and reliable characterization of nanomaterials, after their synthesis and further process (e.g. annealing) stages. The principal objective of this review is to summarize the present knowledge on the use, advances, advantages and weaknesses of a large number of experimental techniques that are available for the characterization of nanoparticles. Different characterization techniques are classified according to the concept/group of the technique used, the information they can provide, or the materials that they are destined for. We describe the main characteristics of the techniques and their operation principles and we give various examples of their use, presenting them in a comparative mode, when possible, in relation to the property studied in each case.

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“…Magnetic iron oxide nanoparticles (IONPs) have attracted extensive interest, due to their superparamagnetic physicochemical properties, in the biomedical (i.e., brain‐targeted drug or gene delivery, magnetic resonance imaging, contrast agents, tissue repair agent, cancer treatment, etc. ), industrial and environmental fields (i.e., audio speakers, position sensing, catalysis and magnetic storage, water purification) (Baldassarre et al , ; Hood, ; Wu et al , ). Up to now, human and ecosystem exposure to IONPs is progressively increasing and the untoward effects of IONPs on human health are still unclear; therefore, understanding the health impact of IONPs has become a priority for ensuring health protection.…”

Section: Introductionmentioning

confidence: 99%

Cytotoxicity and proliferative capacity impairment induced on human brain cell cultures after short- and long-term exposure to magnetite nanoparticles

Coccini¹,

Caloni

Ramírez-Cando

et al. 2016

J. Appl. Toxicol.

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Since magnetic iron oxide nanoparticles (IONP) as magnetite (Fe O NPs) have potential applications in life sciences, industrial fields and biomedical care, the risks for occupational, general population and patients rises correspondingly. Excessive IONP accumulation in central nervous system (CNS) cells can lead to a disruption of normal iron metabolism/homeostasis, which is a characteristic hallmark resembling that of several neurodegenerative disorders. Fe O NPs- versus Fe O bulk-induced toxic effects have been assessed in two human CNS cells namely astrocytes (D384) and neurons (SH-SY5Y) after short-term exposure (4-24-48 h) to 1-100 μg ml , and long-term exposure to lower concentrations. Short-term Fe O NPs induced significant concentration- and time-dependent alterations of mitochondrial function in D384 (25-75% cell viability decrease): effects started at 25 μg ml after 4 h, and 1 μg ml after 48 h. SH-SY5Y were less susceptible: cytotoxicity occurred after 48 h only with 35-45% mortality (10-100 μg ml ). Accordingly, a more marked intracellular iron accumulation was observed in astrocytes than neurons. Membrane integrity was unaltered in both CNS cell types. Lowering Fe O NP concentrations (0.05-10 μg ml ) and prolonging the exposure time (up to 10 days), D384 toxicity was again observed (colony number decrease at ≥0.05 μg ml , morphology alterations and colony size reduction at ≥0.5 μg ml ). Effects on SH-SY5Y appeared at the highest concentration only. Fe O bulk was always remarkably toxic toward both cells. In summary, human cultured astrocytes were susceptible to both Fe O NP and bulk forms following short-term and extended exposure to low concentrations, while neurons were more resistant to NPs. Cellular iron overload may trigger adverse responses by releasing iron ions (particularly in astrocytes) thus compromising the normal functions of CNS. Copyright © 2016 John Wiley & Sons, Ltd.

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A predictive model of iron oxide nanoparticles flocculation tuning Z-potential in aqueous environment for biological application

Cited by 32 publications

References 85 publications

Smart composite films of nanometric thickness based on copper–iodine coordination polymers. Toward sensors

Smart composite films of nanometric thickness based on copper–iodine coordination polymers. Toward sensors

Characterization techniques for nanoparticles: comparison and complementarity upon studying nanoparticle properties

Cytotoxicity and proliferative capacity impairment induced on human brain cell cultures after short- and long-term exposure to magnetite nanoparticles

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