Extra standard XNano microfluidic cartridge
SKU: INX-302
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INX-302 XNano – dodatkowy kartridż Dodatkowy standardowy kartridż microfluidiczny XNano
INX-302 XNano – dodatkowy kartridż Dodatkowy standardowy kartridż microfluidiczny XNano
Insplorion offers access to a large number of application notes describing the applications of nanoplasmonic detection systems in various research fields. Below, we present a selection of application notes covering various types of plasmon resonance research. To view all available application notes, please visit the website. Insplorion.
Presentation of the NanoPlasmonic Sensing technique and an overview of applications.
Presentation of the application of NanoPlasmonic Sensing in lipid research.
Summary of 3 publications using NPS for protein adsorption studies.
Study of the thermodynamics of hydrogen layer on SiO2 before deposition of Pd nanoparticles on the Pd nanoparticle surface using the indirect nanoplasmonic detection (INPS) technique.
Study of storage stability and hydrogen transport kinetics using INPS.
Using INPS to monitor local temperature changes on nanoparticle catalysts.
Using INPS technique on Pt/SiO2 catalysts to monitor catalyst sintering and damage in real time.
Using LSPR to study the kinetic and quantitative properties of molecular permeation in solar cells (DSSC).
NPS technology was used to measure the effect of confinement on the glass transition temperature (Tg) in thin polymer films and polymer composites.
Use of NPS for quantitative study of lipid vesicle adsorption kinetics.
Monitoring lipid membranes on Insplorion sensors with different substrates.
Acquisition of quantitative data on light-induced trans-cis and cis-trans processes as a function of irradiation intensity.
Using NPS technology to monitor the adsorption of CO2 molecules on polymer.
Application of NPS in monitoring first-order transitions from nematic to isotropic phase in liquid crystal layers
Insplorion XNano II was used to analyze spectral changes during the capture of virus-like particles on a gold sensor with nanoholes.
Using NPS to monitor gas adsorption on a surface-anchored metal-organic framework (SURMOF).
This note presents how nanostructured plasmonic substrates can provide a way to obtain a sensor with specific detection properties.
Using indirect nanoplasmonic sensing (INPS) to study the adsorption of dye molecules on flat, thin (12–70 nm) and dense (i.e. non-porous) TiO2 layers.
Study of catalytic processes on a 3D matrix with catalyst nanoparticles.
Lipid adsorption study in a combined NPS and QCD-D study.
The use of NPS and sensors mimicking dielectric nanoparticles for in situ monitoring of biocrown formation.
Study of the dynamics of enzymatic hydrolysis of polyester films using NPS and QCM-D.
Combination of NPS and QCM-D techniques for studying the dynamics between lipid bilayers.
NPS was used to evaluate the effect of layer thickness on the thermal stability of semi-crystalline, liquid crystal and glass-organic semiconductor layers.
Using LSPR to distinguish between mono- and multi-stranded DNA structures by analyzing hybridization processes.
Using LSPR to measure changes in the phase transition temperature of liposms.
Using LSPR to track molecules as they adsorb into a hydrogel.
Monitoring iron ion binding in magnetosome proteins and their mutations.
Using a combination of NPS and QCM-D to build an antibody biosensor in water.
Using Insplorion optical sensors to track the progress of internal precipitation processes in sodium batteries.
Presentation of the capabilities of sensors with active epoxy groups for protein immobilization in the Insplorion S2 system.
Using Insplorion optical sensors to track the progress of internal precipitation processes in lithium batteries.
