Tissue-specific direct microtransfer of nanomaterials into Drosophila embryos as a versatile in vivo test bed for nanomaterial toxicity assessment

Vega-Alvarez, Sasha; Herrera, Adriana; Rinaldi, Carlos; Carrero-Martínez, Franklin

doi:10.2147/ijn.s56459

Cited by 14 publications

(5 citation statements)

References 76 publications

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“…Repeated experiments on possible toxic/genotoxic effects have shown that variables including core size, morphology, surface charge, and coating type are apparently key factors in modifying such effects(Arami, Khandhar, Liggitt, & Krishnan, 2015). There have been only two studies to investigate the toxicity of iron oxide NPs on small fruit flies (Drosophila)(Chen et al, 2015;Vega-Alvarez, Herrera, Rinaldi, & Carrero-Martínez, 2014) Vega-Alvarez, Herrera, Rinaldi, and Carrero-Martínez (2014). attempted to show their toxicity by introducing NPs directly into the embryonic cells through microinjection at doses of 2.5 and 5 ng, which caused a dramatic rise in cell mortality, thus concluding that FeO NPs could prove highly fatal during the initial phase of embryonic development.Similarly, Chen et al (2015) reported that relatively high doses (300-600 μg/g) of magnetite NPs impaired the survival and ability to produce live offspring (fecundity) in young females.…”

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confidence: 99%

A review on nanotoxicity and nanogenotoxicity of different shapes of nanomaterials

Demir

2020

J of Applied Toxicology

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Nanomaterials (NMs) generally display fascinating physical and chemical properties that are not always present in bulk materials; therefore, any modification to their size, shape, or coating tends to cause significant changes in their chemical/physical and biological characteristics. The dramatic increase in efforts to use NMs renders the risk assessment of their toxicity highly crucial due to the possible health perils of this relatively uncharted territory. The different sizes and shapes of the nanoparticles are known to have an impact on organisms and an important place in clinical applications. The shape of nanoparticles, namely, whether they are rods, wires, or spheres, is a particularly critical parameter to affect cell uptake and site-specific drug delivery, representing a significant factor in determining the potency and magnitude of the effect. This review, therefore, intends to offer a picture of research into the toxicity of different shapes (nanorods, nanowires, and nanospheres) of NMs to in vitro and in vivo models, presenting an in-depth analysis of health risks associated with exposure to such nanostructures and benefits achieved by using certain model organisms in genotoxicity testing. Nanotoxicity experiments use various models and tests, such as cell cultures, cores, shells, and coating materials. This review article also attempts to raise awareness about practical applications of NMs in different shapes in biology, to evaluate their potential genotoxicity, and to suggest approaches to explain underlying mechanisms of their toxicity and genotoxicity depending on nanoparticle shape.

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confidence: 99%

A review on nanotoxicity and nanogenotoxicity of different shapes of nanomaterials

Demir

2020

J of Applied Toxicology

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“…On the other hand, the chicken embryo model has an advantage that the direct effect of NPs on the embryonic development can be evaluated by removing the indirect effect mediated by maternal factors easily, as reported for the results of developmental toxicity of TiO 2 -NP [185] and carbon NPs [186–188]. In addition, the use of Drosophila, which has a short life span and 77% of the human disease genes [189], has just started in terms of developing cost-effective high-throughput screening methods for assessment of the developmental toxicity of NPs [190]. These animal models may provide rapid hazard assessment techniques to facilitate regulation and ensure safer NPs reach the market thereby protection future generations.…”

Section: Main Textmentioning

confidence: 99%

Particle toxicology and health - where are we?

Riediker¹,

et al. 2019

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Background Particles and fibres affect human health as a function of their properties such as chemical composition, size and shape but also depending on complex interactions in an organism that occur at various levels between particle uptake and target organ responses. While particulate pollution is one of the leading contributors to the global burden of disease, particles are also increasingly used for medical purposes. Over the past decades we have gained considerable experience in how particle properties and particle-bio interactions are linked to human health. This insight is useful for improved risk management in the case of unwanted health effects but also for developing novel medical therapies. The concepts that help us better understand particles’ and fibres’ risks include the fate of particles in the body; exposure, dosimetry and dose-metrics and the 5 Bs: bioavailability, biopersistence, bioprocessing, biomodification and bioclearance of (nano)particles. This includes the role of the biomolecule corona, immunity and systemic responses, non-specific effects in the lungs and other body parts, particle effects and the developing body, and the link from the natural environment to human health. The importance of these different concepts for the human health risk depends not only on the properties of the particles and fibres, but is also strongly influenced by production, use and disposal scenarios. Conclusions Lessons learned from the past can prove helpful for the future of the field, notably for understanding novel particles and fibres and for defining appropriate risk management and governance approaches.

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“…Magnetite (Fe3O4) nanoparticles, which is another form of iron oxide, was found to be highly toxic displaying 30% of viability reduction at low concentration. (Vega-Alvarez et al 2014) found that iron oxide nanoparticles synthesized by co-precipitation coated with 3-Aminopropyltriethoxysilane and iron oxide nanoparticles synthesized by thermal decomposition showed the highest mortality level in Drosophila embryos among eight different types of nanoparticles tested. The obtained data showed that iron oxide nanoparticles may act as a larvicidal agent against mosquito larvae.…”

Section: Discussionmentioning

confidence: 97%

“…Recent application of nanoparticles as insecticidal agents resulted in high mortality levels in larvae of Spodoptera littoralis (Elek et al 2010), Sitophilusoryzae (Depnath et al 2010, Anopheles subpictus and Culex quinquefasciatus (Santhoshkumar et al 2010). A limited number of studies investigated the toxicological and biological effects of different forms of iron oxide nanoparticles on Drosophila melanogaster (Alvarez et al 2014& Chen et al 2014.…”

Section: Introductionmentioning

confidence: 99%

Toxicological Effects of Hematite Nanoparticles on the Common House Mosquito, Culex pipiens L. (Diptera: Culicidae)

Bakr,

Guneidy,

Attia

et al. 2016

Egyptian Academic Journal of Biological Sciences. A, Entomology

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The obtained work aimed to evaluate the efficiency of hematite nanoparticles as larvicidal agents against Cx. pipiens larvae. Hematite nanoparticles were synthesized by a simple hypothermal method. The obtained nanoparticles average size was below 50 nm. TEM images determined the size and morphology of nanoparticles. Serial concentrations were applied on mosquito larvae. It was found that LC50 of hematite nanoparticles after 48 hours of treatment was 5.6997 ppm. The obtained results added a new weapon to control mosquitoes. It is suggested to investigate the joint action of nanoparticles with other insecticides to which insects had developed resistance.

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Tissue-specific direct microtransfer of nanomaterials into Drosophila embryos as a versatile in vivo test bed for nanomaterial toxicity assessment

Cited by 14 publications

References 76 publications

A review on nanotoxicity and nanogenotoxicity of different shapes of nanomaterials

A review on nanotoxicity and nanogenotoxicity of different shapes of nanomaterials

Particle toxicology and health - where are we?

Toxicological Effects of Hematite Nanoparticles on the Common House Mosquito, Culex pipiens L. (Diptera: Culicidae)

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