0000000000405879

AUTHOR

F Cavaleri

showing 7 related works from this author

Monitoring few molecular binding events in scalable confined aqueous compartments by raster image correlation spectroscopy (CADRICS)

2016

The assembly of scalable liquid compartments for binding assays in array formats constitutes a topic of fundamental importance in life sciences. This challenge can be addressed by mimicking the structure of cellular compartments with biological native conditions. Here, inkjet printing is employed to develop up to hundreds of picoliter aqueous droplet arrays stabilized by oil-confinement with mild surfactants (Tween-20). The aqueous environments constitute specialized compartments in which biomolecules may exploit their function and a wide range of molecular interactions can be quantitatively investigated. Raster Image Correlation Spectroscopy (RICS) is employed to monitor in each compartmen…

0301 basic medicineStreptavidinBiomedical EngineeringMolecular bindingBiotinBioengineeringNanotechnology02 engineering and technologydroplets microarrays inkjet printing Raster Image Correlation Spectroscopy water-in-oil emulsion StreptvidinBiochemistry03 medical and health scienceschemistry.chemical_compoundCompartment (pharmacokinetics)Cellular compartmentchemistry.chemical_classificationAqueous solutionSpectrum AnalysisBiomoleculeWaterGeneral Chemistrycomputer.file_formatMicroarray Analysis021001 nanoscience & nanotechnology030104 developmental biologychemistryPrintingInkStreptavidinRaster graphics0210 nano-technologycomputerTwo-dimensional nuclear magnetic resonance spectroscopyLab on a Chip
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Imbibition of Femtoliter-Scale DNA-Rich Aqueous Droplets into Porous Nylon Substrates by Molecular Printing

2019

This work presents the first reported imbibition mechanism of femtoliter (fL)-scale droplets produced by microchannel cantilever spotting (μCS) of DNA molecular inks into porous substrates (hydrophilic nylon). Differently from macroscopic or picoliter droplets, the downscaling to the fL-size leads to an imbibition process controlled by the subtle interplay of evaporation, spreading, viscosity, and capillarity, with gravitational forces being quasi-negligible. In particular, the minimization of droplet evaporation, surface tension, and viscosity allows for a reproducible droplet imbibition process. The dwell time on the nylon surface permits further tuning of the droplet lateral size, in acc…

Materials scienceDiffusionSettore CHIM/05 - Scienza e Tecnologia dei Materiali PolimericiEvaporation02 engineering and technology010402 general chemistry01 natural sciencesSurface tensionMolecular ImprintingViscosityElectrochemistrySurface TensionGeneral Materials Sciencedroplets imbibition molecular printing nylon substrates biosensors microarraysPorositySpectroscopyMicrochannelFemtoliterNucleic Acid HybridizationWaterSurfaces and InterfacesDNA021001 nanoscience & nanotechnologyCondensed Matter Physics0104 chemical sciencesNylonsChemical engineeringSettore CHIM/03 - Chimica Generale E InorganicaImbibition0210 nano-technologyHydrophobic and Hydrophilic InteractionsPorosity
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Printing Life-Inspired Subcellular Scale Compartments with Autonomous Molecularly Crowded Confinement.

2019

A simple, rapid, and highly controlled platform to prepare life-inspired subcellular scale compartments by inkjet printing has been developed. These compartments consist of fL-scale aqueous droplets (few µm in diameter) incorporating biologically relevant molecular entities with programmed composition and concentration. These droplets are ink-jetted in nL mineral oil drop arrays allowing for lab-on-chip studies by fluorescence microscopy and fluorescence life time imaging. Once formed, fL-droplets are stable for several hours, thus giving the possibility of readily analyze molecular reactions and their kinetics and to verify molecular behavior and intermolecular interactions. Here, this pla…

Surface PropertiesDNA hairpinBiomedical EngineeringGeneral Biochemistry Genetics and Molecular BiologyFluorescenceBiomaterialsSettore CHIM/01molecular crowdingbiomolecular confinementlife-like compartmentFluorescence microscopeInkjet printinginkjet printingBiochemistry Genetics and Molecular Biology (all)ChemistryDrop (liquid)Intermolecular forceLife timeDNABiomaterialFluorescencebiomolecular confinement; DNA hairpins; inkjet printing; life-like compartments; molecular crowdingDNA hairpinslife-like compartmentsPrinting Three-DimensionalBiophysicsMolecular probeAdvanced biosystems
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Sub-Cellular Scale Compartments: Printing Life-Inspired Subcellular Scale Compartments with Autonomous Molecularly Crowded Confinement (Adv. Biosys. …

2019

BiomaterialsScale (ratio)Biomedical EngineeringEnvironmental scienceNanotechnologyGeneral Biochemistry Genetics and Molecular BiologyInkjet printingAdvanced Biosystems
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DNA-based biosensor on flexible nylon substrate by dip-pen lithography for topoisomerase detection

2019

Dip-pen lithography (DPL) technique has been employed to develop a new flexible biosensor realized on nylon with the aim to detect the activity of human topoisomerase. The sensor is constituted by an ordered array of a DNA substrate on flexible nylon supports that can be exploited as a drug screening platform for anticancer molecules. Here, we demonstrate a rapid protocol that permits to immobilize minute quantities of DNA oligonucleotides by DPL on nylon surfaces. Theoretical and experimental aspects have been investigated to successfully print DNA oligonucleotides by DPL on such a porous and irregular substrate.

Materials scienceFlexible deviceNanotechnologymacromolecular substances02 engineering and technologySubstrate (printing)01 natural sciencesIndustrial and Manufacturing Engineeringchemistry.chemical_compoundA-DNALithographyTopoisomerasebiologyOligonucleotideTopoisomerase010401 analytical chemistrytechnology industry and agriculture021001 nanoscience & nanotechnology0104 chemical sciencesSettore BIO/18 - GeneticachemistryMolecular printingbiology.protein0210 nano-technologyBiosensorDNABiosensor
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Oil-in-Water fL Droplets by Interfacial Spontaneous Fragmentation and Their Electrical Characterization

2019

Inkjet printing is here employed for the first time as a method to produce femtoliter-scale oil droplets dispersed in water. In particular, picoliter-scale fluorinated oil (FC40) droplets are printed in the presence of perfluoro-1-octanol surfactant at a velocity higher than 5 m/s. Femtoliter-scale oil droplets in water are spontaneously formed through a fragmentation process at the water/air interface using minute amounts of nonionic surfactant (down to 0.003% v/v of Tween 80). This fragmentation occurs by a Plateau-Rayleigh mechanism at a moderately high Weber number (10(1)). A microfluidic chip with integrated microelectrodes allows droplets characterization in terms of number and diamet…

Materials scienceFabricationSettore ING-IND/34Femtoliter02 engineering and technologySurfaces and Interfaces010402 general chemistry021001 nanoscience & nanotechnologyCondensed Matter PhysicsInkjet printing Plateau–Rayleigh instability electrical impedance lab-on-chip01 natural sciences0104 chemical sciencesMicroelectrodeChemical engineeringFragmentation (mass spectrometry)Pulmonary surfactantOil dropletEmulsionElectrochemistryWeber numberGeneral Materials Science0210 nano-technologySpectroscopy
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INCORPORATION OF METAL-PORPHYRIN DERIVATIVES IN TITANIA NANOSTRUCTURED 3D NETWORKS: THIN FILM PROPERTIES AND APPLICATIONS

2014

Nanostructured thin films Functional nanoparticles Derivatized Titania Electron Transfer
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