Search results for "DNA hairpin"

showing 4 items of 4 documents

On the Effect of Downscaling in Inkjet Printed Life-Inspired Compartments

2019

The fabrication of size-scalable liquid compartments is a topic of fundamental importance in synthetic biology, aiming to mimic the structures and the functions of cellular compartments. Here, inkjet printing is demonstrated as a customizable approach to fabricate aqueous compartments at different size regimes (from nanoliter to femtoliter scale) revealing the crucial role of size in governing the emerging of new properties. At first, inkjet printing is shown to produce homogenous aqueous compartments stabilized by oil-confinement with mild surfactants down to the hundreds of picoliter scale [1]. Raster Image Correlation Spectroscopy allows to monitor few intermolecular events by the involv…

DNA hairpinsFluorescence LifetimeInkjet PrintingMolecular crowdingSettore CHIM/02 - Chimica Fisica
researchProduct

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
researchProduct

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
researchProduct

DNA Sensors for the Detection of Biomolecules and Biochemical Conditions

2017

chemistry.chemical_classificationChemistryBiomoleculeBiomedical SciencesNanobiotechnologyNanotechnologyBiochemistryNanomaterials and NanostructuresAnalytical ChemistryBiosensors DNA hairpin Raman FRETchemistry.chemical_compoundFörster resonance energy transferBiochemistryNanobiotechnologyDna hairpinBiosensorDNANanobiotechnology Biotechnology Biochemistry Biochemistry Biomedical Sciences Nanomaterials and Nanostructures Analytical ChemistryBiotechnology
researchProduct