Our PinAAcle™ 500 is the world’s first completely corrosion-resistant flame atomic absorption (AA) spectrometer, designed to withstand the harshest environments and most corrosive samples. It offers superior durability, longer life, lower maintenance costs, and the fastest return on investment of any flame AA.
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The PinAAcle 500 is a robust, fully-integrated, flame-only benchtop system, ideal for laboratories needing a reliable, easy-to-use, yet high-performance flame AA. It is equipped with an innovative touchscreen interface with the flexibility to operate via its easy-to-use Syngistix Touch™ software or the more comprehensive, optional Syngistix™ for AA Software.
The PinAAcle 500 is designed for:
The PinAAcle 500 is engineered to deliver an uncompromising level of performance at an unbeatable price, putting the industry’s most robust, reliable flame AA within reach of even the most budget-conscious laboratories. Discover an instrument engineered to outlast and outperform… and take your laboratory to a new PinAAcle of productivity and profitability.
|21 CFR Part 11 Compatible||Yes|
|Model Name||PinAAcle 500|
|Product Brand Name||PinAAcle|
The performance of this method was validated by assessing the Standard Reference Materials (SRMs) from the US National Institute of Standards and Technology (NIST) and China National Institute of Metrology (NIM) as well as by comparing these results with those obtained using inductively coupled plasma mass spectrometry (ICP-MS) after complete sample digestion by microwave method.
This application note describes an accurate and reliable microwave-assisted sample pretreatment procedure for the determination of arsenic, cadmium and lead in spices using graphite furnace atomic absorption spectrophotometry (GFAAS).
Increased knowledge about the nutrient content of biological organisms is essential for a thorough understanding of ecological stoichiometry and nutrient transport in and among ecosystems.
With an inherent toxicity, a tendency to accumulate in the food chain and a particularly low removal rate through excretion, lead (Pb), cadmium (Cd) and arsenic (As) cause harm to humans even at low concentrations.
The efficient production of these nutritionally fortified breakfast cereals requires careful formulation and uniformity batch to batch. Ongoing analytical measurement of nutritional additives and the total micronutrient content in the cereal is one way in which food producers can quantify the quality and consistency of their cereal products. The ability to quickly, accurately, and easily analyze their samples is also key to timely data reporting, allowing real-time batch adjustments to be made and enhancing continuous process control. Food producers must also meet nutritional labeling guidelines which require an accurate assessment of micronutrients for regulatory labeling compliance.
This work demonstrates the ability to accurately measure nutritional elements in a variety of fresh and dried fruits by flame atomic absorption using a FAST Flame sample automation for high sample throughput.
This work demonstrates the ability to rapidly and accurately measure nutritional elements in fruit juices using flame AA with a FAST Flame sample automation system.
This work demonstrates the ability to accurately measure nutritional elements in a variety of milk types by flame atomic absorption using FAST Flame sample automation for high sample throughput.
Soil is used in agriculture, where it serves as the primary nutrient base for the plants. Soil material is a critical component in the mining and construction industries. Soil serves as a foundation for most construction projects.
The fertilizer industry helps to ensure that farmers have the nutrients they need to grow enough crops to meet the world's requirements for food, feed, fiber and energy.
For many years, graphite furnace atomic absorption spectrophotometry (GFAAS) has been a reliable technique and the preferred method for this heavy metals analysis of tea leaves.
Elemental analysis of fuel oil is an important step in quantifying its quality. While ICP-OES and ICP-MS instrumentation may receive more attention when it comes to metals analyses, FAAS is a viable option particularly in the petroleum industry.
Arsenic can find its way into food through a variety of paths. In the recent past, various organic arsenicals were used as herbicides and antimicrobial agents in growth fields as well as applied directly on fruits and fruit trees.
Contamination of industrial and municipal water supplies with arsenic (As), selenium (Se), and mercury (Hg) can occur from natural deposits, industrial discharge, runoff from mining, landfill and agricultural operations.
Ingestion of trace elements from food can be linked to nutrition, disease, and physiological development. Whether they are needed for proper nutritional value or contain toxic elements, the presence of major and minor elements in food needs to be verified to help determine health effects for the consumer. Acute or chronic exposure to heavy metals can lead to damaged nervous system function and have detrimental effects on vital organs. Food safety laboratories performing these analyses are often high-throughput and require a detection tool that is efficient and cost effective.
To protect the integrity of semiconductor and electronics end-products, semiconductor researchers and developers (R&D) and manufacturing QA/QC functions face unique challenges to reduce contaminates, sometimes down to ultra-trace levels. Metal determination in the sub-ppb range are required for the analysis of complex sample matrices and corrosive acids.
To meet these requirements, high-performance analytical techniques such as inductively coupled plasma mass spectrometry (ICP-MS) are preferred for rapid multi-element analysis, however, diagnosing problems can also involve only a few elements, in which graphite furnace atomic absorption spectrometry (GFAAS) is recommended.
Learn how GFAAS can help diagnose problems in semiconductor R&D and QA/QC processes.
This work demonstrates the ability to measure several elements in beer with Flame atomic absorption using the PinAAcle 900. No significant differences were observed between beers in glass bottles or metal cans.
There is an increasing need to monitor the essential element levels in food samples at ever decreasing concentrations. For this purpose, very sensitive, yet rapid and inexpensive methods are necessary. The quantification of trace metals in food samples has routinely been carried out by ICP-OES, ICP-MS, graphite furnace atomic absorption (GFAA) and flame atomic absorption (FAA). Compared with other techniques, FAA has the characteristics of good precision and simplicity with lower cost and minimum operator proficiency.
Foods, infant formula, milk, and water provide significant exposure routes for metal contaminants. The effect of lead exposure at low levels has been well established and levels below toxic have been shown to contribute to behavioral and learning issues. In this work both the GFAA and ICP-MS methods capable at the concentration levels of interest and under control during sample measurement are shown. GFAA has detection limit capability well below the level of concern and provides an economical choice for smaller laboratories or those with a smaller workload. ICP-MS provides excellent detection limits and offers efficient multielement capability for the detection of other hazardous elements in the same run, such as lead.
This work demonstrates the ability of the PinAAcle 900 flame AA spectrometer to measure Cu, Fe, and Mn in wines to comply with Chinese wine import regulations coupled with FAST Flame sample automation for increased throughput.
This work demonstrates the analysis of mineral elements in a variety of drinking waters using the PinAAcle 900 AA spectrometer coupled with a FAST Flame accessory.
This work demonstrates the ability of the PinAAcle 500 Flame AA spectrometer to accurately measure major components in drinking waters.
When mining for precious metals, ores are extracted from the ground and subjected to various sample preparation procedures in order to remove the metals of interest. A commonly used procedure to isolate metals from the ore is fire-assay, which leaves a matrix-free “button” of the metal. This work will focus on the analysis of precious metals in simulated digested precious metal buttons, with an added emphasis on assessing the lowest limits which can be accurately measured.
There are many mineral dietary supplements available in today's marketplace to ensure that mineral deficiencies do not occur in one's diet. The mineral content of these products must be verified for quality control purposes.
Graphite furnace atomic absorption spectrophotometry (GFAAS) has been widely applied to the determination of trace elements in food due to its selectivity, simplicity, high sensitivity, and its capability for accurate determinations in a wide variety of matrices. Edible oils are generally low in trace element concentrations, however, metals such as arsenic (As), lead (Pb), cadmium (Cd), chromium (Cr), and selenium (Se) can be found and are known for their toxicities which affect the health of consumers.
The determination of the inorganic profile of oils is important because of the metabolic role of some elements in the human organism. On the one hand, there is knowledge of the food's nutritional value, which refers to major and minor elements.
Precise and accurate measurements at the regulated levels are an important factor for assuring safe drinking water. U.S. EPA Method 200.91 is the method cited by EPA, Health Canada, and the WHO for the use of graphite furnace atomic absorption spectroscopy (GFAAS). In evaluating a GFAAS system for determination of these elements, it must provide good sensitivity, low noise, limited drift, and accuracy in matrices with high salt content (hard water) that might be found in drinking waters. In this work, the PinAAcle™ 900T, with a unique optical system, is evaluated for the use of EPA Method 200.9 for As, Cd, Pb, Se, and Tl in drinking waters.
The grain industry is very complex. It’s global, diverse, and can also present analytical challenges. Today’s grain users demand more when it comes to quality, safety, and uniformity. In addition, they seek diverse products with unique characteristics.
PerkinElmer is equipped to help the grain industry in its quest to feed the world – nutritiously and economically. Our testing and analysis solutions encompass the three primary areas required for complete knowledge of grains and their derivatives – composition, functionality, and safety.
Food testing labs like yours are constantly challenged with accurately analyzing samples quickly and efficiently - all while striving to reduce costs due to market forces. Your commitment to ensuring meat and seafood are safe for consumption, as demand increases, is an uphill battle.
Our commitment to you: to provide a range of solutions across multiple technologies, products, and services that meets or exceeds the testing needs of food processors. Our solutions offer more efficiency and increased accuracy and sensitivity for better yields in real time with minimal training.
From instrumentation and software to consumables and reagents to service and support, we are dedicated to providing you with end-to-end solutions that ease your everyday challenges of automation, throughput, service, and time to results.
The PerkinElmer PinAAcle 500 - the world’s first flame atomic absorption spectrometer engineered for complete corrosion resistance. Learn more.
With instruments that are the industry standard worldwide, PerkinElmer accessories, consumables, methods and application support meet the most demanding requirements and are the preferred choice in thousands of laboratories globally.
All of the PerkinElmer consumables and supplies for your PerkinElmer PinAAcle 500 Flame AA.
Quality control-monitoring and testing are important in ensuring the quality of palm oil. The quality control parameters are used to judge the quality of palm oil products and it can be monitored and tested to ensure that the palm oil is not deliberately or accidentally adulterated.
Consumers are exposed to low levels of heavy metals on a daily basis and long term exposure can have negative health impacts. Since the elements themselves are distributed unevenly throughout, for example, cereal grain, with the germ and the outer layers having the highest concentrations, analyzing these grains to detect low analyte levels with accuracy and controlled reproducibility is a challenge.
The atomic absorption analysis technique provides a high performance option with features like a closed-furnace design that is sealed at both ends with easily removable bayonet-mount windows. In addition, independently controlled external and internal gas streams provide maximum flexibility, tube life, and sensitivity.
Systems like the PinAAcle™ 900 AA spectrometer make it faster and easier to get from sample to results by reducing your grain method development time, while PerkinElmer consumables and superior services will keep your lab at peak performance.
This document provides detailed instructions regarding the space, accessories and utilities required to operate PerkinElmer’s PinAAcle family of atomic absorption (AA) spectrometers (500 and 900 series) and other major AA accessories.
The production of high-quality graphite components for atomic absorption spectroscopy requires stringent quality control. To ensure high quality and consistency, a specific high-density base graphite material has been developed for use with PerkinElmer graphite furnace systems.
With the onset of the COVID-19 pandemic, the use of face masks by the general public has become a critical personal protective measure to minimize person-to-person transmission. While health care workers use medical or surgical masks, the general population uses non-medical, otherwise known as hygienic, face masks to greatly reduce the transmission of SARS-CoV-2 by capturing droplets and aerosols from those infected with the virus.
In response to the increased demand for both the number and variety of non-medical face masks, many companies are now producing them to meet the public’s need, and with this great variety, the quality and the safety of the face masks must be assessed. This work describes the considerations surrounding metal analysis in hygienic face masks used to prevent the spread of COVID-19.