Malaria threatens more than 40% of the world’s population and kills up to 1.2 million people worldwide each year. Many of these deaths happen in Sub-Saharan Africa in children under the age of five and pregnant woman. The estimates for clinical infection is somewhere between 300 to 500 million people each year, worldwide.
Quality assurance is essential in industrial workflows and the Dortmund-based SGS Institut...
In May 2014, a private company in China, WinSun, printed 10 full-size houses using 3-D printers...
Measuring oil content in wastes is nothing new to the petrochemical industry. Whether it’s produced water from onshore or offshore sites, effluents from refineriers or drill cuttings and drilling mud, limits on hydrocarbon levels need to be met. With the increase of hydraulic fracturing in the U.S., more public attention has been focused on the need for regulations and limits.
Spectral sensing is so pervasive that most take it for granted. Even miniature spectrometers have been embraced by late adopters. Yet, spectroscopy has moved beyond routine laboratory and test measurements to take on ever-more sophisticated applications. In this article we explore how familiar spectral sensing technologies—and new ways to exploit them—are today addressing a wider range of measurement problems than ever.
A leader in the field of minimally invasive surgery device development operates state-of-the-art R&D and manufacturing facilities—facilities that depend on today’s most advanced quality assurance/quality testing procedures. To ensure all equipment leaving its production facilities meets the highest performance and reliability standards, the company relies on a QA/QC system made possible by industrial microscope and analyzer solutions.
Life Science researchers have become ever-more dependent on the industry for “kits” that are intended to execute research processes in the laboratory flawlessly. In recognition of this expectation, kit manufacturers now market nearly every product as “guaranteed” or “validated.” This practice has led the research community to feel secure that the products will perform as advertised.
Optical system designers often need to evaluate the effect of different laser beam diameters during prototyping. Although it’s possible to do this by introducing several different beam expanders in sequence, or by stopping the beam down with apertures, variable-magnification beam expanders provide flexibility and performance in an easy-to-use package.
As U.S. energy imports dramatically drop it would appear that renewables investment is in jeopardy, including the biofuels market. There’s some evidence to support this; but if declining or stalled investment is predicated on the limited potential of existing technology, much of which still relies on biomass, the biofuels industry may, in fact, be undergoing a natural transition instead of a decline.
Diamonds aren’t just a girl’s best friend, they’re also R&D’s best friend—or at least a new acquaintance. Many laboratories and companies are embracing synthetic diamond for its elevated super properties in applications ranging from analytical instruments and biomedical sensors to electronics and lasers to water purification.
In order to identify contaminants in industrial products, it’s sometimes necessary to send samples of the contaminated material to a laboratory for analysis. The choice of sampling method and the selection of a shipping container are critical to ensure that a representative sample is obtained, and no additional foreign material (FM) is added to the sample during transport to the laboratory.
Today, big data is a hot topic within almost every industry. May saw the biggest ever European technologists conference on big data, Berlin Buzzwords, while the likes of O'Reilly's Strata conference pull in huge numbers of attendees keen to learn how to adapt to this new world. Despite all the interest, a great deal of confusion remains around big data.
Researchers working in synthetic organic chemistry are under pressure to quickly develop innovative chemical reactions. But with methods largely unchanged over the last 50 years, synthesis possibilities are constrained by limited temperature ranges, demanding experiment supervision and lack of repeatability. New technology is enhancing synthesis by eliminating these challenges.
Surgical and trauma patients are at significant risk for morbidity and mortality from bleeding and/or leaking bodily fluids. With the number and complexity of surgeries rising, so is the need for better hemostatic agents to stop bleeding as quickly as possible. The history of approaches to hemostasis goes back to when people simply used their hands or a tool to apply to a wound to stop bleeding.
Imagine your religious beliefs laid between you and your life. This is what happened in mid-April to Julie Penoyer, a 50-year-old U.K. heart patient and Jahovah’s Witness. Following her religious beliefs, her request when undergoing open-heart surgery was to not receive donated blood products.
In 2012, a team of researchers in London imaged, for the first time, the structure of the DNA double helix. James Watson and Francis Crick discovered DNA 60 years ago by laboriously studying x-ray diffraction images of millions of DNA molecules. However, Dr. Bart Hoogenboom and Dr. Carl Leung used atomic force microscopy (AFM) to directly “feel” the molecule’s structure in a fraction of the time.
Traditional lithography is based on a simple principle: Oil and water don’t mix. The method, first developed by an actor in Bavaria in 1796, used a smooth piece of limestone on which an oil-based image was drawn and overlayed with gum arabic in water. During printing, the ink was attracted to the oil, and was repelled by the gum.
Life science researchers are benefiting from easy-to-use, ultra-fast, automated and integrated platforms that address specific application needs. These platforms combine hardware, software and reagents into integrated, push-button analysis systems capable of transforming workflows which once took several days into minutes.