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Start Over Author "Marotta, Roberto" Publisher american chemical society
13 results on '"Marotta, Roberto"'

6. "Tandem" Nanomedicine Approach against Osteoclastogenesis: Polysulfide Micelles Synergically Scavenge ROS and Release Rapamycin.

Author

El Mohtadi F, d'Arcy R, Burke J, Rios De La Rosa JM, Gennari A, Marotta R, Francini N, Donno R, and Tirelli N

Subjects
Animals, Anti-Inflammatory Agents, Non-Steroidal chemistry, Anti-Inflammatory Agents, Non-Steroidal pharmacology, Antioxidants chemistry, Antioxidants pharmacology, Drug Carriers pharmacokinetics, Drug Liberation, Mice, Osteoclasts drug effects, Osteogenesis physiology, Oxidation-Reduction, RAW 264.7 Cells, Reactive Oxygen Species metabolism, Sulfides chemistry, Sulfides pharmacology, Drug Carriers chemistry, Micelles, Nanomedicine methods, Osteogenesis drug effects, Sirolimus pharmacokinetics
Abstract

We show the first example of a synergic approach of oxidant (ROS) scavenging carrier and ROS-responsive drug release in the context of a potential therapy against osteoporosis, aiming to inhibit the differentiation of inflammatory cells into osteoclasts. In our "tandem" approach, a branched amphiphilic, PEGylated polysulfide (PPSES-PEG) was preferred over a linear analogue, because of improved homogeneity in the aggregates (spherical micelles vs mixture of wormlike and spherical), increased stability, and higher drug loading (up to ∼22 wt % of antiosteoclastic rapamycin). These effects are ascribed to the branching inhibiting crystallization in the polysulfide blocks. The ROS-scavenging micelles alone were already able to reduce osteoclastogenesis in a RAW 264.7 model, but the "drug" combination (the polymer itself + rapamycin released only under oxidation) completely abrogated the process. An important take-home message is that the synergic performance depended very strongly on the oxidant:oxidizable group molar ratio, a parameter to carefully tune in the perspective of targeting specific diseases.

Published
2020
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7. Enhanced Intraliposomal Metallic Nanoparticle Payload Capacity Using Microfluidic-Assisted Self-Assembly.

Author

Al-Ahmady ZS, Donno R, Gennari A, Prestat E, Marotta R, Mironov A, Newman L, Lawrence MJ, Tirelli N, Ashford M, and Kostarelos K

Subjects
Gold chemistry, Lab-On-A-Chip Devices, Liposomes chemistry, Metal Nanoparticles chemistry, Microfluidic Analytical Techniques
Abstract

Hybrids composed of liposomes (L) and metallic nanoparticles (NPs) hold great potential for imaging and drug delivery purposes. However, the efficient incorporation of metallic NPs into liposomes using conventional methodologies has so far proved to be challenging. In this study, we report the fabrication of hybrids of liposomes and hydrophobic gold NPs of size 2-4 nm (Au) using a microfluidic-assisted self-assembly process. The incorporation of increasing amounts of AuNPs into liposomes was examined using microfluidics and compared to L-AuNP hybrids prepared by the reverse-phase evaporation method. Our microfluidics strategy produced L-AuNP hybrids with a homogeneous size distribution, a smaller polydispersity index, and a threefold increase in loading efficiency when compared to those hybrids prepared using the reverse-phase method of production. Quantification of the loading efficiency was determined by ultraviolet spectroscopy, inductively coupled plasma mass spectroscopy, and centrifugal field flow fractionation, and qualitative validation was confirmed by transmission electron microscopy. The higher loading of gold NPs into the liposomes achieved using microfluidics produced a slightly thicker and more rigid bilayer as determined with small-angle neutron scattering. These observations were confirmed using fluorescent anisotropy and atomic force microscopy. Structural characterization of the liposomal-NP hybrids with cryo-electron microscopy revealed the coexistence of membrane-embedded and interdigitated NP-rich domains, suggesting AuNP incorporation through hydrophobic interactions. The microfluidic technique that we describe in this study allows for the automated production of monodisperse liposomal-NP hybrids with high loading capacity, highlighting the utility of microfluidics to improve the payload of metallic NPs within liposomes, thereby enhancing their application for imaging and drug delivery.

Published
2019
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8. Sputtering-Enabled Intracellular X-ray Photoelectron Spectroscopy: A Versatile Method To Analyze the Biological Fate of Metal Nanoparticles.

Author

Turco A, Moglianetti M, Corvaglia S, Rella S, Catelani T, Marotta R, Malitesta C, and Pompa PP

Subjects
HeLa Cells, Humans, Oxidation-Reduction, Particle Size, Photoelectron Spectroscopy, Platinum metabolism, Silver metabolism, Surface Properties, Tumor Cells, Cultured, Metal Nanoparticles analysis, Platinum analysis, Silver analysis
Abstract

The investigation of the toxicological profile and biomedical potential of nanoparticles (NPs) requires a deep understanding of their intracellular fate. Various techniques are usually employed to characterize NPs upon cellular internalization, including high-resolution optical and electron microscopies. Here, we show a versatile method, named sputtering-enabled intracellular X-ray photoelectron spectroscopy, proving that it is able to provide valuable information about the behavior of metallic NPs in culture media as well as within cells, directly measuring their internalization, stability/degradation, and oxidation state, without any preparative steps. The technique can also provide nanoscale vertical resolution along with semiquantitative information about the cellular internalization of the metallic species. The proposed approach is easy-to-use and can become a standard technique in nanotoxicology/nanomedicine and in the rational design of metallic NPs. Two model cases were investigated: silver nanoparticles (AgNPs) and platinum nanoparticles (PtNPs) with the same size and coating. We observed that, after 48 h incubation, intracellular AgNPs were almost completely dissolved, forming nanoclusters as well as AgO, AgS, and AgCl complexes. On the other hand, PtNPs were resistant to the harsh endolysosomal environment, and only some surface oxidation was detected after 48 h.

Published
2018
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9. Internalization of Carbon Nano-onions by Hippocampal Cells Preserves Neuronal Circuit Function and Recognition Memory.

Author

Trusel M, Baldrighi M, Marotta R, Gatto F, Pesce M, Frasconi M, Catelani T, Papaleo F, Pompa PP, Tonini R, and Giordani S

Subjects
Animals, Carbon, Mice, Nanomedicine, Nanostructures, Onions, Hippocampus
Abstract

One area where nanomedicine may offer superior performances and efficacy compared to current strategies is in the diagnosis and treatment of central nervous system (CNS) diseases. However, the application of nanomaterials in such complex arenas is still in its infancy and an optimal vector for the therapy of CNS diseases has not been identified. Graphitic carbon nano-onions (CNOs) represent a class of carbon nanomaterials that shows promising potential for biomedical purposes. To probe the possible applications of graphitic CNOs as a platform for therapeutic and diagnostic interventions on CNS diseases, fluorescently labeled CNOs were stereotaxically injected in vivo in mice hippocampus. Their diffusion within brain tissues and their cellular localization were analyzed ex vivo by confocal microscopy, electron microscopy, and correlative light-electron microscopy techniques. The subsequent fluorescent staining of hippocampal cells populations indicates they efficiently internalize the nanomaterial. Furthermore, the inflammatory potential of the CNOs injection was found comparable to sterile vehicle infusion, and it did not result in manifest neurophysiological and behavioral alterations of hippocampal-mediated functions. These results clearly demonstrate that CNOs can interface effectively with several cell types, which encourages further their development as possible brain disease-targeted diagnostics or therapeutics nanocarriers.

Published
2018
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10. Selective Targeting of Neurons with Inorganic Nanoparticles: Revealing the Crucial Role of Nanoparticle Surface Charge.

Author

Dante S, Petrelli A, Petrini EM, Marotta R, Maccione A, Alabastri A, Quarta A, De Donato F, Ravasenga T, Sathya A, Cingolani R, Proietti Zaccaria R, Berdondini L, Barberis A, and Pellegrino T

Subjects
Action Potentials, Animals, Cell Membrane metabolism, Cells, Cultured, Hydrogen-Ion Concentration, Nanoparticles chemistry, Nanoparticles ultrastructure, Neurons cytology, Particle Size, Rats, Surface Properties, Synapses metabolism, Nanoparticles metabolism, Neurons metabolism, Static Electricity
Abstract

Nanoparticles (NPs) are increasingly used in biomedical applications, but the factors that influence their interactions with living cells need to be elucidated. Here, we reveal the role of NP surface charge in determining their neuronal interactions and electrical responses. We discovered that negatively charged NPs administered at low concentration (10 nM) interact with the neuronal membrane and at the synaptic cleft, whereas positively and neutrally charged NPs never localize on neurons. This effect is shape and material independent. The presence of negatively charged NPs on neuronal cell membranes influences the excitability of neurons by causing an increase in the amplitude and frequency of spontaneous postsynaptic currents at the single cell level and an increase of both the spiking activity and synchronous firing at neural network level. The negatively charged NPs exclusively bind to excitable neuronal cells, and never to nonexcitable glial cells. This specific interaction was also confirmed by manipulating the electrophysiological activity of neuronal cells. Indeed, the interaction of negatively charged NPs with neurons is either promoted or hindered by pharmacological suppression or enhancement of the neuronal activity with tetrodotoxin or bicuculline, respectively. We further support our main experimental conclusions by using numerical simulations. This study demonstrates that negatively charged NPs modulate the excitability of neurons, revealing the potential use of NPs for controlling neuron activity.

Published
2017
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11. Functionalization of strongly interacting magnetic nanocubes with (thermo)responsive coating and their application in hyperthermia and heat-triggered drug delivery.

Author

Kakwere H, Leal MP, Materia ME, Curcio A, Guardia P, Niculaes D, Marotta R, Falqui A, and Pellegrino T

Subjects
Antimetabolites, Antineoplastic administration & dosage, Antimetabolites, Antineoplastic chemistry, Cell Survival drug effects, Coated Materials, Biocompatible chemical synthesis, Combined Modality Therapy methods, Delayed-Action Preparations administration & dosage, Diffusion, Doxorubicin chemistry, HeLa Cells, Hot Temperature, Humans, Magnetite Nanoparticles ultrastructure, Materials Testing, Neoplasms, Experimental pathology, Particle Size, Polymers chemistry, Delayed-Action Preparations chemistry, Doxorubicin administration & dosage, Hyperthermia, Induced methods, Magnetite Nanoparticles chemistry, Magnetite Nanoparticles therapeutic use, Neoplasms, Experimental therapy
Abstract

Herein, we prepare nanohybrids by incorporating iron oxide nanocubes (cubic-IONPs) within a thermoresponsive polymer shell that can act as drug carriers for doxorubicin(doxo). The cubic-shaped nanoparticles employed are at the interface between superparamagnetic and ferromagnetic behavior and have an exceptionally high specific absorption rate (SAR), but their functionalization is extremely challenging compared to bare superparamagnetic iron oxide nanoparticles as they strongly interact with each other. By conducting the polymer grafting reaction using reversible addition-fragmentation chain transfer (RAFT) polymerization in a viscous solvent medium, we have here developed a facile approach to decorate the nanocubes with stimuli-responsive polymers. When the thermoresponsive shell is composed of poly(N-isopropylacrylamide-co-polyethylene glycolmethyl ether acrylate), nanohybrids have a phase transition temperature, the lower critical solution temperature (LCST), above 37 °C in physiological conditions. Doxo loaded nanohybrids exhibited a negligible drug release below 37 °C but showed a consistent release of their cargo on demand by exploiting the capability of the nanocubes to generate heat under an alternating magnetic field (AMF). Moreover, the drug free nanocarrier does not exhibit cytotoxicity even when administered at high concentration of nanocubes (1g/L of iron) and internalized at high extent (260 pg of iron per cell). We have also implemented the synthesis protocol to decorate the surface of nanocubes with poly(vinylpyridine) polymer and thus prepare pH-responsive shell coated nanocubes.

Published
2015
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12. Hybrid assemblies of fluorescent nanocrystals and membrane proteins in liposomes.

Author

De Leo V, Catucci L, Falqui A, Marotta R, Striccoli M, Agostiano A, Comparelli R, and Milano F

Subjects
Cadmium Compounds chemistry, Fluorescent Dyes, Hydrophobic and Hydrophilic Interactions, Micelles, Nanoparticles ultrastructure, Rhodobacter sphaeroides chemistry, Selenium Compounds chemistry, Sulfides chemistry, Zinc Compounds chemistry, Bacterial Proteins chemistry, Liposomes chemistry, Nanoparticles chemistry, Photosynthetic Reaction Center Complex Proteins chemistry
Abstract

Because of the growing potential of nanoparticles in biological and medical applications, tuning and directing their properties toward a high compatibility with the aqueous biological milieu is of remarkable relevance. Moreover, the capability to combine nanocrystals (NCs) with biomolecules, such as proteins, offers great opportunities to design hybrid systems for both nanobiotechnology and biomedical technology. Here we report on the application of the micelle-to-vesicle transition (MVT) method for incorporation of hydrophobic, red-emitting CdSe@ZnS NCs into the bilayer of liposomes. This method enabled the construction of a novel hybrid proteo-NC-liposome containing, as model membrane protein, the photosynthetic reaction center (RC) of Rhodobacter sphaeroides. Electron microscopy confirmed the insertion of NCs within the lipid bilayer without significantly altering the structure of the unilamellar vesicles. The resulting aqueous NC-liposome suspensions showed low turbidity and kept unaltered the wavelengths of absorbance and emission peaks of the native NCs. A relative NC fluorescence quantum yield up to 8% was preserved after their incorporation in liposomes. Interestingly, in proteo-NC-liposomes, RC is not denatured by Cd-based NCs, retaining its structural and functional integrity as shown by absorption spectra and flash-induced charge recombination kinetics. The outlined strategy can be extended in principle to any suitably sized hydrophobic NC with similar surface chemistry and to any integral protein complex. Furthermore, the proposed approach could be used in nanomedicine for the realization of theranostic systems and provides new, interesting perspectives for understanding the interactions between integral membrane proteins and nanoparticles, i.e., in nanotoxicology studies.

Published
2014
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13. Multifunctional nanobeads based on quantum dots and magnetic nanoparticles: synthesis and cancer cell targeting and sorting.

Author

Di Corato R, Bigall NC, Ragusa A, Dorfs D, Genovese A, Marotta R, Manna L, and Pellegrino T

Subjects
Biological Transport, Ethylamines chemistry, Fluorescent Dyes chemistry, Folic Acid chemistry, Humans, KB Cells, Microscopy, Confocal, Spectrometry, Fluorescence, Surface Properties, Cell Separation methods, Magnetics, Neoplasms metabolism, Neoplasms pathology, Quantum Dots
Abstract

Trifunctional polymer nanobeads are prepared by destabilization of a mixture of magnetic nanoparticles, quantum dots, and an amphiphilic polymer, followed by functionalization of the bead surface with folic acid molecules. The distribution of the nanoparticles within the nanobeads can be tuned using either acetonitrile or water as destabilizing solvent. The luminescence of the resulting beads can be tuned by varying the ratio of quantum dots per magnetic nanoparticles. The application of an external magnetic field (such as a small static magnet of 0.3 T) to the magnetic-fluorescent nanobeads allows the quantitative accumulation of the beads within a few hours depending on the total size of the beads. Furthermore, specific targeting of cancer cells overexpressing folate receptors is achieved thanks to the folic acid decorating the surface of the as-synthesized nanobeads. Folate receptor mediated cellular uptake of the folic acid-functionalized nanobeads is proven via both confocal imaging and transmission electron microscopy characterization. Cell sorting experiments performed with trifunctional nanobeads show quantitative recovering of targeted cells even when they are present at low percentage (up to 1%).

Published
2011
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