Search results for "Inkjet printing"

showing 10 items of 28 documents

Advanced Drug Screening platforms by Inkjet printing

2011

In this work, we show a low-cost, speed, microarray-based drug screening platform that employs inkjet printing drug dispensing on an enzymatic-rich surface. Mixtures of a model substrate (Dglucose)/ inhibitor (D-glucal) couple have been inkjet printed on a target enzymatic monolayer (glucose oxidase) linked to a functionalized silicon oxide solid surface [1]. It has been possible to fabricate microarrays with quality factors as high as those of conventional pin printing spotting. By a simple horseradish-based colorimetric enzymatic assay, the detection of biological activity at the single spot has been proved. The figure shows a scheme of the platform: molecular inks of the enzymatic substr…

Drug screening biochip inkjet printingSettore CHIM/02 - Chimica Fisica
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Autonomous molecularly crowded confinement in inkjet printed femtoliter-scale aqueous compartments

2019

Natural evolution has chosen the localization of biomolecular processes into crowded sub-cellular femtoliter (fL) scale compartments for organizing complex biological processes. [1] Many synthetic biology platforms with life-like activities have been able to mimic these systems under different compartment sizes regimes. [2] However, the fabrication of crowded compartments down to sub-cellular scales is challenging, mainly because of high surface-volume ratio of these systems, finally compromising the stability of the encapsulated biomolecules. In this regard, we here bridge this gap by showing the possibility to produce femtoliter-scale aqueous droplets using a novel inkjet printing approac…

Molecular confinementDNA hairpinCYP2E1Inkjet PrintingSettore CHIM/02 - Chimica Fisica
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On the Relationship between Jetted Inks and Printed Biopatterns:Molecular-Thin Functional Microarrays of Glucose Oxidase

2009

Arrays of circular spots of glucose oxidase have been obtained on functionalized silicon oxide by piezoelectric inkjet printing and the enzymatic activity toward glucose recognition has been monitored. The addition of glycerol to the molecular ink allows to obtain high spot definition and resolution (tens of micrometers wide; one molecule tall), but in spite of its well-known structural stabilizing properties, in dynamic conditions it may lead to increased protein stresses. The jetting voltage and pulse length have been found to be critical factors for both activity retention and pattern definition. High voltages and pulse lengths results in stress effects along with the loss of activity, w…

GlycerolSiliconSurface PropertiesProtein Array Analysischemistry.chemical_elementNanotechnologyASPERGILLUS-NIGERMicrometreSIO2 SURFACESGlucose Oxidase inkjet printingGlucose OxidaseStructure-Activity RelationshipElectrochemistryGeneral Materials ScienceGlucose oxidaseSilicon oxideSpectroscopybiologyInkwellPulse (signal processing)ChemistryPulse durationSurfaces and InterfacesCondensed Matter PhysicsPiezoelectricityChemical engineeringIMMOBILIZATIONbiology.proteinMicroscopy Electron ScanningInkHIGH HYDROSTATIC-PRESSURE
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Metodologie da stampa a getto d'inchiostro per la fabbricazione di substrati SERS

2019

Uno degli argomenti di maggiore interesse della Surface-enhanced Raman spectroscopy (SERS) è il controllo del posizionamento su superficie degli “hot spots” – le zone interstiziali fra aggregati di particelle metalliche che producono un aumento locale del segnale Raman. I substrati SERS consistono tipicamente in una matrice di hot-spots ad alta densità sui quali volumi macroscopici (>1 µL) di molecole di analita sono disperse. Questo approccio porta ad una alta invasività ed una distribuzione non uniforme dell’analita a causa dei flussi capillari. In questo lavoro, viene sviluppata una nuova piattaforma SERS realizzata da stampa a getto d’inchiostro2 in cui una miscela di un analita SERS…

Inkjet printing Sers Raman AlizarinSettore CHIM/01 - Chimica Analitica
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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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Luminometric sub-nanoliter droplet-to-droplet array (LUMDA) and its application to drug screening by phase I metabolism enzymes.

2012

Here we show the fabrication of the Luminometric Sub-nanoliter Droplet-to-droplet Array (LUMDA chip) by inkjet printing. The chip is easy to be implemented and allows for a multiplexed multi-step biochemical assay in sub-nanoliter liquid spots. This concept is here applied to the integral membrane enzyme CYP3A4, i.e. the most relevant enzymatic target for phase I drug metabolism, and to some structurally-related inhibitors.

chemistry.chemical_classificationChromatographytechnology industry and agricultureBiomedical EngineeringAssayBioprintingDrug Evaluation PreclinicalBioengineeringGeneral ChemistryMicroarray AnalysisBiochemistryMembraneEnzymechemistryLuminescent MeasurementsCytochrome P-450 CYP3ANanotechnologyBiochipBiosensorInkjet printingDrug metabolismLab on a chip
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Towards bioarrays of cellular-like compartments for monitoring few molecular binding events

2016

The aim of this work is to artificially reproduce scalable cellular-like compartments on a chip, thus realizing specialized small volume systems to study the behaviour of interacting biomolecules by few binding events. In particular, we show an unprecedented solution-based protein-binding assay based on arrays of oil-confined water droplets containing protein targets, labelled ligands and other compounds.

Water-in-oil droplets inkjet printing Raster Image Correlation SpectroscopySettore CHIM/01 - Chimica Analitica
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Inkjet Printing Quasi-Miscible Droplets for Pseudo-Planar Organic Heterojunctions

2021

bisolvent inksInkjet PrintingPlanar heterojunction
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Aqueous Processed Biopolymer Interfaces for Single-Cell Microarrays

2020

Single-cell microarrays are emerging tools to unravel intrinsic diversity within complex cell populations, opening up new approaches for the in-depth understanding of highly relevant diseases. However, most of the current methods for their fabrication are based on cumbersome patterning approaches, employing organic solvents and/or expensive materials. Here, we demonstrate an unprecedented green-chemistry strategy to produce single-cell capture biochips onto glass surfaces by all-aqueous inkjet printing. At first, a chitosan film is easily inkjet printed and immobilized onto hydroxyl-rich glass surfaces by electrostatic immobilization. In turn, poly(ethylene glycol) diglycidyl ether is graft…

Diglycidyl etherMaterials scienceFabrication0206 medical engineeringBiomedical EngineeringBiointerfaceNanotechnology02 engineering and technologyengineering.materialArticleBiomaterialsChitosanchemistry.chemical_compoundBiopolymersbiopolymerbiointerfaceHumansBiochipMicroscale chemistrySettore CHIM/02 - Chimica Fisicainkjet printingsingle-cellMicroarray Analysis021001 nanoscience & nanotechnology020601 biomedical engineeringSettore FIS/07 - Fisica Applicata(Beni Culturali Ambientali Biol.e Medicin)Inkjet printing biopolymer single-cell microarray biointerfacechemistryengineeringGlassBiopolymer0210 nano-technologymicroarrayEthylene glycol
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High-throughput screening at the picoliter scale by combining Dip Pen Lithography with Inkjet printing

Drug screening is a complex, expensive and time consuming field consisting of diseasebased target identification in conjunction with high-throughput screening of chemical and natural product libraries. Conventional drug screening technology is usually time and reagent consuming (micro-, nanoliter scale) and is based on complex liquid handling robotics. In this work, we show a low-cost and miniaturized drug screening methodology based on direct bio-printing methodologies like Inkjet Printing and Dip Pen Lithography. We show the possibility to precisely deliver femtoliter scale droplets of protein targets by Dip Pen Lithography by finely tuning deposition parameters. This allows obtaining mic…

Inkjet printing drug screening drug screening
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