Applications

For the first time, glyphosate determination and that of its primary metabolite AMPA in drinking water using IC with pulsed amperometric detection (flexIPAD) in the low µg/L range are shown. Compared to HPLC analysis with a mass-selective detector, it is a very cost-effective method for determining the glyphosate and AMPA content in water and foodstuffs. With a detection limit at approx. 1 µg/L, compliance with limit values for glyphosate can be monitored in the USA, Canada, and Australia, among others.

More strict regulations paired with more complex products have increased testing complexity in the paint and coating industry. Therefore, producers ask for more powerful, safe and sustainable analytical methods. Testing by Vis-NIR spectroscopy is a sustainable and costefficient alternative to many wet chemical methods. This white paper describes how Vis-NIR spectroscopy improves testing procedures for various analyses during the formulation and production of paint and coatings in an economic and ecological way.Key words: testing, sustainable, VOC, paint, coating, binders, resins, additives, pigments, solvents

Many refiners look at discounted opportunity crudes as a means to improve their margin spread. The varieties of these cheap crude oils on the market are growing in number, but they have hidden risks for the purchaser caused by factors such as high naphthenic acid and sulfur content. Sulfur compounds and naphthenic acids are among the substances that contribute to the corrosive nature of crude oils and petroleum products. This is why the risk of corrosion is increased when processing crude oils with high naphthenic acid and sulfur content. The refiner must balance the cost benefit versus the risk and the cost of corrosion control when processing these crudes. A reliable acid number determination is a crucial part of corrosion control. Guest authors Bert Thakkar, Bryce McGarvey, and Colette McGarvey of Imperial Oil and Larry Tucker and Lori Carey of Metrohm USA were involved in the development of the new ASTM Method D8045 for acid number determination. Here, they report on the method and how it came to be.

Brad Meadows is Vice President and Lab Director at the US company BSK Labs, which runs a number of environmental laboratories and service centers. Brad is an analytical chemist and has been working in the management of analysis laboratories for 15 years. He shared his experiences with Metrohm ion chromatography with us in the form of some concrete facts and figures.

The pharmaceutical industry is very likely more comprehensively regulated that any other branch of industry. It therefore requires analytic methods that meet the requirements of regulations while at the same time being practical. This applies in particular for large sample quantities, such as are encountered with incoming goods inspections, for example. It is here that particularly rapid and simple analysis methods are called for which make routine analyses simpler and more efficient. This White Paper describes some of the most important regulations in the pharmaceutical analysis and shows how Vis-NIR spectroscopy can solve analytic problems in the pharmaceutical industry in accordance with regulations.

This Metrohm White Paper shows the requirements demanded of the pharmaceutical industry by the FDA with respect to software products. Implementation examples of the regulations formulated by the FDA in 21 CFR Part 11 are presented using Vision Air Pharma Software.Key words: electronic signatures, audit trails, user management, documentation

Ion chromatography is a flexible technique with a large selection of intended uses in the pharmaceutical industry. – A few development trends and the latest advances are displayed here.

This White Paper compares the two most commonly used technologies in near-infrared spectroscopy: Predispersive monochromator technology and Fourier transformation technology. In addition to measurement speeds and captured spectral ranges, the noise levels and the signal-noise ratios associated with them are also contrasted with one another.

Heavy metals such as arsenic and mercury find their way into the ground water in many regions of the world, either through natural processes or as the result of human activities. Limit values are exceeded many times over, particularly for arsenic in drinking water, in many areas. This calls for a rigorous monitoring of water quality. The present whitepaper focuses on field determinations of arsenic, mercury, and copper – directly at the sampling site.

In this work, time resolved Raman spectroelectrochemistry measurements with screen printed electrodes are shown. The instrument used combines in a totally integrated box: a 785 nm laser source, a high resolution Raman spectrometer and a bipotentiostat/galvanostat. Experiments are controlled with an excellent spectroelectrochemical software which allows real time data collection and useful data treatment.