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Postnova Analytics to Exhibit Award Winning FFF Technology at SCM-6 and EWPSC Conferences

Postnova Analytics GmbH
4 Feb 2013

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Postnova Analytics kick off the New Year 2013 with a busy schedule of conference attendance, where they will share experiences and demonstrate their award-winning Field-Flow Fractionation (FFF) systems. Featured instrument, the CF2000, is the first commercial Centrifugal FFF system designed for routine use. This groundbreaking instrument was the recent winner of a major European industry award for innovation.

The first chance to meet the team in 2013 will be at the 6th International Symposium on the Separation and Characterization of Natural and Synthetic Macromolecules (SCM-6) to be held in Dresden, Germany, from February 6 to 8, 2013. SCM-6 brings together scientists who share an interest in the separation and characterization of large molecules, and the conference creates a platform for delegates from diverging backgrounds with different perspectives to interact, discuss subjects of mutual interest, and discover new synergies.

Here, Postnova will present three posters – the first ‘Polymer Characterization using Thermal Field-Flow Fractionation’ illustrates the excellent potential of Thermal FFF (TF3) compared to common SEC analysis for different polymers, such as polystyrene, poly(methyl methacrylate), mixed polymer samples and blends thereof. The ability to separate by size and chemical composition within the one method, highlights the predominance of TF3 over standard SEC methodologies. The poster explains the principle of the Thermal FFF technique, with the separation taking place between a cold wall on the bottom of the channel and a hot wall on the top. The extraordinary capabilities of this FFF technique are the opportunity to not only separate by size but also by chemical composition due to thermal diffusion. The results comparing the analysis of a PS and PMMA Standards and its mixtures is undertaken with SEC and FFF, illustrating that only TF3 can achieve a separation. Also common drawbacks of packed columns like shear-degradation, are overcome with FFF technology.

The second of the posters is entitled ‘Characterization of Rubber Polymers by Flow FFF’ and explores the coupling of FFF technology of choice to suitable detector combinations (MALS, RI/UV). This enables the user to easily determine molecular weight and size distributions of macromolecules, which are important properties for polymers. Two synthetic rubber samples were analyzed and compared with a natural rubber sample.

The third poster focuses on ´Latex Nanoparticle Analysis by Flow FFF – DLS coupling´ and this explores the different separation forces applied, e.g. flow, thermal, centrifugal or gravitational. The techniques render variable results, enabling the end-user to choose the most appropriate technique of FFF-family separation to obtain the best performance for their particular application and nanoparticles. The poster shows that the FFF - DLS online coupling is a more precise tool for analysis of mixed latex nanoparticles, as opposed to traditional batch DLS measurements

Also in February, Postnova will be in Kraków, Poland at the European Winter Conference on Plasma Spectrochemistry (EWCPS), being held from 10 to 15 February. The conference focuses on the major topics of analytical plasma spectrochemistry and Postnova Analytics will have on display the modular CF2000, which combines a powerful separation tool based on Field-Flow Fractionation principles, allowing the coupling to a range of different detectors like UV, DLS, MALS or even ICP-MS. The extended higher particle size separation range is between 7 nm to 50 µm, which provide a wide application range for characterization, such as proteins and polymers, from larger particles in one run with high resolution.

Rainer Jünger, Marketing Director of Postnova commented “FFF technology is providing huge benefits to scientists for the separation and characterization of macro species and particles, which are not able to be separated by other chromatography techniques. With the use of centrifugal field as the controlling force for the separation, particles in the laminar flow are separated by dynamic diffusion on the basis of size and density. This novel approach allows discrimination of materials that have the same particle size but different densities, which makes it ideal for nanoparticles but also is applicable in the microparticle size range. Jünger also added that another benefit is “there is no static phase in FFF separation so there is no interference, producing a very gentle separation. This is especially important for biological samples and cells, which might otherwise be damaged by being pressed through a column. Also it has a wide application range – for characterization of challenging biopharmaceutical, food, cosmetics, nanomaterial, but also environmental samples.”

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UHPLC and HPLCHigh performance liquid chromatography (HPLC) and ultra high performance liquid chromatography (UHPLC), also known as UPLC, are analytical techniques used to separate, identify and quantitate components of complex mixtures including biological samples such as proteins and lipids as well as chemical mixtures of pesticides, drugs and oils. Both techniques are liquid chromatographic methods but differ by operating pressures (HPLC < 6000 psi < UHPLC ). Components of HPLC and UHPLC systems include columns, detectors, pumps, autosamplers and column heaters. Explore a range of UHPLC and HPLC columns for your specific sample needs including reverse phase, normal phase, ion exchange, HILIC, ion exclusion and size exclusion columns. For more specialized HPLC, explore FPLC, countercurrent LC and simulated moving bed systems. Find the best UHPLC and HPLC equipment in our peer reviewed product directory: compare products, check customer reviews and receive pricing direct from manufacturers.Sample PreparationSample preparation can improve the quality and speed of separation techniques. Products to assist sample preparation include filtration equipment, evaporators, membranes and sieves.UV-Visible SpectroscopyUltraviolet-visible (UV-Vis) spectrophotometers are used to measure the interaction of UV and visible light with a sample, including transmission, reflectance & absorbance. The two major instrument classes are single-beam or double-beam spectrophotometers. More specialized equipment includes colorimeters, spectroradiometers and refractometers. Portable and microvolume spectrophotometers are also available. For the modular spectroscopy lab, explore a range of light sources for combination with a spectrograph/spectrometer and optics. Find the best UV-Vis spectroscopy products in our peer-reviewed product directory: compare products, check customer reviews and receive pricing direct from manufacturers.Preparative ChromatographyPreparative chromatography equipment is used for purification purposes, separating and collecting compounds eluted from a mixture which can then be subsequently used for further purposes. This can be done in large quantities or small. Preparative chromatography systems are usually low to medium pressure liquid chromatographs that are semi-automated. Explore a range of preparative columns and fraction collectors. Find the best preparative chromatography equipment in our peer-reviewed product directory: compare products, check customer reviews and receive pricing direct from manufacturers.CentrifugesCentrifuges are used to separate particulates suspended in a liquid via the application of a centrifugal force including cells, macromolecules, nanoparticles and precipitates. Centrifuges come in three sizes: microcentrifuges, benchtop and floor-standing centrifuges, depending on the volume and number of samples that require separation. When choosing a centrifuge, consider its maximum separation power indicated by its relative centrifugal force (RCF) value. Low force centrifuges reach a maximum RCF of 8,000 g, high-force centrifuges can reach maximum RCF values of 80,000 g. For extremely high forces, consider ultracentrifuges (up to 800,000 g). Refrigerated and vacuum centrifuges also known as concentrators are available for more specialized applications. A range of volumes are available for centrifuge tubes and microfuge tubes, depending on sample sizes. Find the best centrifuges in our peer-reviewed product directory: compare products, check customer reviews and receive pricing direct from manufacturers.Particle CharacterizationParticle characterization instruments are used to determine particle size distribution, shape, surface area, zeta potential, density and porosity of particles and materials. Multiple tecchniques are available for determining particle size, shape and count including dynamic light scattering (DLS), laser diffraction, electrozone (Coulter technique), imaging particle analysis and single particle optical sensing. Determine the density of your material with a gas pycnometer or examine its surface area and porosity with gas adsorption analyzers and mercury porosimeters. Find the best particle characterization instruments in our peer-reviewed product directory: compare products, check customer reviews and receive pricing direct from manufacturers.Field Flow FractionationPolymersPolymers are large molecules made up of many repeat units. Natural polymers such as DNA and proteins are essential to life, whereas synthetic polymers such as polystyrene and polyethylene are used widely due to their functionality. Typical techniques for analysis include GPC, SEC, DSC, FT-IR and NMR.Polymeric MaterialsPolymeric materials are widely used in industries ranging from biomedical devices to packaging and electronics. Research into these materials focuses on their properties, including strength, flexibility, and degradation. Advances in polymer science have enabled the development of more sustainable and high-performance materials. Explore the best polymeric material products in our peer-reviewed product directory; compare products, check reviews, and get pricing directly from manufacturers.Molecular Weight AnalysisMolecular weight analysis determines the size and structure of biomolecules, essential in protein characterization, polymer studies, and drug development. Techniques like mass spectrometry ensure precise results. Compare solutions for molecular weight analysis in our peer-reviewed product directory.NanoparticlesNanoparticles are between 1-100nm in size. Nanoparticles can be used for a wide variety of applications including biomedical, catalysis and electronics.CosmeticsBiopharmaceuticalsBiopharmaceuticals are proteins and other compounds (such as nucleic acids) produced by living organisms that have uses as therapeutics or for in vivo diagnostics. The most well known example of a biopharmaceutical product, and the first to be approved for therapeutic use, was recombinant human insulin.Dynamic Light ScatteringDynamic light scattering is used to measure the size distribution of particles in suspension by analyzing the way light scatters off them. It is commonly used in materials science, nanotechnology, and protein characterization. Browse our peer-reviewed product directory to find the best dynamic light scattering systems, compare products, check reviews, and get pricing directly from manufacturers.Refractive Index

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Postnova Analytics to Exhibit Award Winning FFF Technology at SCM-6 and EWPSC Conferences