The mid-range model holds up to 40 sample vials. The system thermostats up to 12 vials simultaneously for automated headspace analysis. A sophisticated nesting algorithm optimizes the 'virtual' oven size for maximum throughput.
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Automated headspace sampler with built-in trap and standard PerkinElmer 9mL or 22mL sample vials. Up to 40 vials can be loaded into the removable vial magazine for automated analysis. Overlapping thermostatting of up to 12 vials in Constant Mode for maximum productivity. A patented optimization algorithm adjusts the virtual oven size for maximum throughput. An optional frequency-scanning shaker is available to reduce equilibration time. No optimization of the shaking process is required.
|Maximum Temperature||Oven Max Temp 210 °C|
|Minimum Temperature||Oven Min Temp 35 °C|
|Product Brand Name||TurboMatrix|
Malodor pollution in water has emerged as an increasingly worrisome consequence of continued worldwide urbanization and industrialization. Volatile organic sulfur compounds (VOSCs), such as dimethyl disulfide (DMDS) and dimethyl trisulfide (DMTS), have been identified as a primary contributor to malodor pollution in water, and are considered a serious safety and environmental threat, rendering drinking water sources unpalatable. In this study, a method for the determination of DMDS and DMTS in water was established using a PerkinElmer Clarus® GC/FPD with the TurboMatrix™ HS-40 Trap. The methodology offers a simple, sensitive and efficient means of detecting DMDS and DMTS in water.
Food packaging plays a key role in food safety and public health therefore it must be carefully controlled. The Commission Regulation (EC No. 2023/2006) has made it mandatory to adopt a system of Good Manufacturing Practice (GMP) to ensure a consistently high quality both in production and control process which includes the prohibition of any contacts between printed side of the package and the food inside.
Today’s plastics are some of the most used materials on a global volume basis. Broadly integrated into today’s industrial and commercial lifestyles, they make a major, irreplaceable contribution to virtually every product category.
In this compendium you will find a wide range of applications for polymers, plastics, rubbers and advanced materials. Discover how to put these applications to work for you simply and efficiently.
Residual solvents are used in the manufacture of active pharmaceutical ingredients (APIs), excipients, or in preparation of drug products, and are not removed during the purification processes. Residual solvents are one of the three main impurities in pharmaceutical materials; the other two are organic and inorganic impurities. Residual solvents do not provide any therapeutic benefit and should be removed to the extent possible, fulfilling quality-based requirements as per International Conference on Harmonization (ICH) guidelines – this is one of the standards to control the quality and the purity of the pharmaceutical substances, excipients, or drug products.
This paper will demonstrate the analysis of all three classes of residual solvents by pressure-balanced headspace sample introduction and GC-FID analysis. In addition to a discussion of the instrumental technique, the choice of the diluent will also be studied; two diluents will be used throughout.
Residual solvents are used in the manufacture of active pharmaceutical ingredients (APIs), excipients, or in preparation of drug products and are not removed during the purification processes. Residual solvents are one of the three main impurities in pharmaceutical materials.
Residual solvents do not provide any therapeutic benefit and should be removed to the extent possible, fulfilling quality based requirements as per International Conference on Harmonization (ICH) guidelines – this is one of the standards to control the quality and the purity of the pharmaceutical substances, excipients, or drug products.
This paper will demonstrate the analysis of all three classes of residual solvents by pressure-balanced headspace sample introduction and GC-FID analysis.
Ethylene oxide (EO) is a highly reactive, toxic and flammable gas which can act as an irritant to humans at room temperature. Since the 1950s, EO has been utilized for the sterilization of medical instruments that cannot be exposed to moisture or high temperatures, including those made of polymers, plastics or those containing electronic components. Although the EO method ensures medical instruments can be sterilized without the deleterious effects of high-temperature sterilization, potentially dangerous side effects are possible, namely owing to the hazardous nature of the chemical.
In this application note, a rapid analytical method for the determination of EO in medical supplies was established using a PerkinElmer Clarus® GC/FID with the TurboMatrix™ HS-40. Empower® software was utilized throughout the entire experiment. This method demonstrates results with high efficiency, good linearity, sensitivity and repeatability for EO analysis.
Whether your lab is well established or just starting up, having a single-source partner who can offer turnkey solutions that meet the current regulations is essential to a successful business. For years, we’ve worked with government and contract cannabis laboratories to develop industry-leading methods, technology, and exceptional return on investment. We help drive analytical standards and commit to ensuring your laboratory has maximum uptime. Learn about our various testing methods and applications for cannabis analyses. Let us work with you to build an efficient workflow, so you can focus on growing your business and brand.
Increasing demands for efficiency, productivity, data quality, and profitability pose ongoing challenges for lubricant testing labs, like yours. Whether you need to achieve quick turnaround times, minimize downtime, or maximize lab efficiencies, you can rely on PerkinElmer for a comprehensive set of simple-to-use and proven testing solutions to help you achieve accurate results in record time. Learn more about our solutions.
Headspace Gas Chromatography—for applications involving the solvent-free extraction of volatile compounds, it’s an unsurpassed technique, eliminating the time-consuming steps and risk of human error associated with other GC sample-preparation methods.
Food-packaging material is typically manufactured as a thin film and coated with inks which usually contain multiple, harmful, volatile organics.
Increasing demands for efficiency, productivity, data quality, and profitability pose ongoing challenges for lubricant testing laboratories, like yours, performing new lubricant or in-service oil analyses.
Whether you need to achieve quick turnaround times, minimize downtime, or maximize lab efficiencies, you can rely on PerkinElmer as a trusted partner for simple-to-use and reliable testing solutions.
Partnering with leading global standards organizations and hundreds of oil laboratories, we continually address laboratory needs and ever-changing standards while developing new methods and protocols that conform with ASTM®, regulatory, and customer-defined requirements.
Download this infographic to learn more about our broad range of proven lubricant testing solutions.
Consumables reference guide for the TurboMatrix Headspace. TurboMatrix Headspace and high-sensitivity Headspace Trap samplers provide unparalleled precision and ease of use for numerous GC or GC/MS volatile-analysis applications. The system can manage up to 12 samples simultaneously, ensuring that the next sample is ready for analysis upon completion of the previous run, achieving significant time savings.
The Polymer Market consists of a huge diversity of manufacturers of industrial products running many different processes yet still facing similar challenges. There is more and more pressure to achieve high product quality and reduce costs in order to stay one step ahead of the competition.
This document is intended to provide the newcomer to headspace sampling with a concise summary of the theory and principles of this exciting technique. Enough information is included here for the user to understand the basic concepts and relationships in HS sampling to apply during method development and interpretation of data. Although emphasis is given to the PerkinElmer TurboMatrix HS systems, the document also covers alternative systems so that it should be useful to all potential users of HS systems.