64 research outputs found

    Fabrication of photothermally active poly(vinyl alcohol) films with gold nanostars for antibacterial applications.

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    The unique photothermal properties of non-spherical gold nanoparticles under near-infrared (NIR) irradiation find broad application in nanotechnology and nanomedicine. The combination of their plasmonic features with widely used biocompatible poly(vinyl alcohol) (PVA) films can lead to novel hybrid polymeric materials with tunable photothermal properties and a wide range of applications. In this study, thin PVA films containing highly photothermally efficient gold nanostars (GNSs) were fabricated and their properties were studied. The resulting films displayed good mechanical properties and a pronounced photothermal effect under NIR irradiation. The local photothermal effect triggered by NIR irradiation of the PVA-GNS films is highly efficient at killing bacteria, therefore providing an opportunity to develop new types of protective antibacterial films and coatings

    In Vivo Bioengineering of Fluorescent Conductive Protein-Dye Microfibers

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    Engineering protein-based biomaterials is extremely challenging in bioelectronics, medicine, and materials science, as mechanical, electrical, and optical properties need to be merged to biocompatibility and resistance to biodegradation. An effective strategy is the engineering of physiological processes in situ, by addition of new properties to endogenous components. Here we show that a green fluorescent semiconducting thiophene dye, DTTO, promotes, in vivo, the biogenesis of fluorescent conductive protein microfibers via metabolic pathways. By challenging the simple freshwater polyp Hydra vulgaris with DTTO, we demonstrate the stable incorporation of the dye into supramolecular protein-dye co-assembled microfibers without signs of toxicity. An integrated multilevel analysis including morphological, optical, spectroscopical, and electrical characterization shows electrical conductivity of biofibers, opening the door to new opportunities for augmenting electronic functionalities within living tissue, which may be exploited for the regulation of cell and animal physiology, or in pathological contexts to enhance bioelectrical signaling

    Chapter 9: Silica-based Nanovectors: From Mother Nature to Biomedical Applications (Book chapter)

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    Diatomite is a natural porous silica material of sedimentary origin, formed by remains of diatom skeletons called “frustules.” The abundance in many areas of the world and the peculiar physico-chemical properties made diatomite an intriguing material for several applications ranging from food production to pharmaceutics. However, diatomite is a material still rarely used in biomedical applications. In this chapter, the properties of diatom frustules reduced to nanoparticles, with an average diameter less than 350 nm, as potential drug vectors are described. Their biocompatibility, cellular uptake, and capability to transport molecules inside cancer cells are discussed. Preliminary studies of in vivo toxicity are also presented.Peer reviewe

    Hymyc1 Downregulation Promotes Stem Cell Proliferation in Hydra vulgaris

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    Hydra is a unique model for studying the mechanisms underlying stem cell biology. The activity of the three stem cell lineages structuring its body constantly replenishes mature cells lost due to normal tissue turnover. By a poorly understood mechanism, stem cells are maintained through self-renewal while concomitantly producing differentiated progeny. In vertebrates, one of many genes that participate in regulating stem cell homeostasis is the protooncogene c-myc, which has been recently identified also in Hydra, and found expressed in the interstitial stem cell lineage. In the present paper, by developing a novel strategy of RNA interference-mediated gene silencing (RNAi) based on an enhanced uptake of small interfering RNAi (siRNA), we provide molecular and biological evidence for an unexpected function of the Hydra myc gene (Hymyc1) in the homeostasis of the interstitial stem cell lineage. We found that Hymyc1 inhibition impairs the balance between stem cell self renewal/differentiation, as shown by the accumulation of stem cell intermediate and terminal differentiation products in genetically interfered animals. The identical phenotype induced by the 10058-F4 inhibitor, a disruptor of c-Myc/Max dimerization, demonstrates the specificity of the RNAi approach. We show the kinetic and the reversible feature of Hymyc1 RNAi, together with the effects displayed on regenerating animals. Our results show the involvement of Hymyc1 in the control of interstitial stem cell dynamics, provide new clues to decipher the molecular control of the cell and tissue plasticity in Hydra, and also provide further insights into the complex myc network in higher organisms. The ability of Hydra cells to uptake double stranded RNA and to trigger a RNAi response lays the foundations of a comprehensive analysis of the RNAi response in Hydra allowing us to track back in the evolution and the origin of this process

    Bridging the fields of nanoscience and toxicology: nanoparticle impact on biological models

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    In the emerging area of nanotechnology a key issue is related to the potential impacts of the novel nanomaterials on the environment and human health so that this technology can be used with minimal risk. Specifically designed to combine on a single structure multipurpose tags and properties, nanomaterials need a comprehensive characterization of both chemicophysical properties and toxicological evaluation, which is a challenging endeavor: the in vitro toxicity assays that are employed for nanotoxicity assessments do not accurately predict in vivo response. To overcome these limitations and gain a deeper understanding of nanoparticle-cell interactions, we have employed cnidarian models, in particular the freshwater polyp Hydra vulgaris, not opposed to more complex and evoluted systems, but to add valuable information, at an intermediate level between prokaryotes and vertebrates, on both cytoxicity and on pollution affecting the environment. By testing CdSe/CdS core shell nanocrystals in vivo, at whole animal level, we investigated the impact of their properties on uptake, accumulation, biodistribution, elicitation of behavioural responses. Spanning from animal to cell biology, we provide an analysis on metal based and semiconductor NC, discussing the crucial role played by the synthesis route and chemical surface on the toxicity for living organisms

    In Vivo Toxicity Assessment of Hybrid Diatomite Nanovectors Using Hydra vulgaris as a Model System

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    Drug nanocarriers based on nanostructured materials are very promising for precision and personalized medicine applications. Diatomite porous biosilica has been recently proposed as a novel and effective material in formulations of drug systems for oral and systemic delivery. In this paper, the cytotoxicity of hybrid diatomite silica functionalized nanovectors is assessed in vivo in a living model organism, the cnidarian freshwater polyp Hydra vulgaris. Hydra specimens are exposed to modified diatomite nanoparticles by prolonged incubation within their medium. Uptake and toxicological effects on Hydra are examined from viability and genetic points of view. High concentrations, up to 3.5 g L−1 for 72 h, of diatomite modified nanoparticles do not affect Hydra morphology nor do growth rate and the genetic analysis confirm the biosafety of this material, opening the way to new applications in nanomedicine

    THE 2-OXOPYRROLIDINACETAMIDE PIRACETAM REDUCES INFARCT BRAIN VOLUME INDUCED BY PERMANENT MIDDLE CEREBRAL ARTERY OCCLUSION IN MALE RATS

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    Photoreactivity of Thiophene-Based Core@Shell Nanoparticles: The Effect of Photoinduced Charge Separation on In Vivo ROS Production

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    Here, we show that in thiophene-based core@shell nanoparticles, namely, P3HT@PTDO NPs, the nanosegregation of the materials results in a peculiar photoreactivity, which, together with their soft and biocompatible nature, makes them interesting bioplatforms. By combining macroscopic and microscopic Kelvin probe measurements, we show that the surface of core@shell NPs becomes rich in negative charges under light illumination-due to the promotion of photogenerated electrons from the inner P3HT core to the outer oxidized PTDO shell-making them more reactive to the environment (air dopants, water, substrate, etc.). Fluorometric and electron paramagnetic resonance (EPR) techniques revealed the formation of transient reactive oxygen species (ROS) upon illumination of aqueous suspensions of NPs, indicating their photoredox reactivity. Detailed analysis permitted to reveal a type I mechanism in ROS generation, ruling out the formation of potentially biodamaging singlet oxygen species. Finally, the biocompatibility of these systems was tested in cells and Hydra polyps. Core@shell NPs exhibit perfect viability and allow the modulation of ROS generation depending on the shell's oxygenation degree, both in vitro and in vivo, in agreement with EPR measurements
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