- Stable long-term mass accuracy
- Effortless tuning (Performance Assistant)
- Easy maintenance
Quadrupole Time-of-Flight Liquid Chromatograph Mass Spectrometer
The LCMS-9050 is a quadrupole Time-of-Flight (Q-TOF) mass spectrometer system designed with technologies developed for Shimadzu LCMS series models and that results in among the highest mass accuracy stability levels available. Shimadzu’s proprietary high precision temperature control system inhibits even tiny mass variations caused by external factors, so that the system can be used to measure accurate mass values without worrying about mass calibration. The stable positive/negative high-speed polarity switching technology enables the simultaneous analysis of positive ions/negative ions, contributing to new applications development and heightened analysis efficiency. To ensure that all users can perform analysis easily and efficiently, Shimadzu has aimed to simplify mass calibration, maintenance and other non-analysis procedures. Further, combining this system with Shimadzu’s renowned lineup of varied optional equipment enables greater utilization of the characteristics of Q-TOF while greatly expanding the range of data obtainable.
LCMS-9050
The LCMS-9050 is a Q-TOF mass spectrometer designed for the most reliable and easy acquisition of accurate masses in the real laboratory settings. With the proprietary innovation for fast polarity switching, it has the unique capability for high-confidence identification of challenging compounds and high-throughput screening of multiple unknowns. All sorts of applications are possible by the abundance of optional accessories and front-end configurations that leverage the instrument power. With the LCMS-9050, Shimadzu introduces a new era in time-of-flight mass spectrometry and continues Shimadzu’s tradition of taking on new challenges in LCMS.
Life Science Biomarker Industry Page has been updated
Biomarkers are derived from living organisms and found in tissues, blood, and other bodily fluids. Biomarkers are indicators of biological changes in an organism and are used to diagnose disease, in prognosis, and to evaluate the efficacy and safety of pharmaceuticals. Biomarkers can be nucleic acids, proteins, peptides, lipids, and sugars, and are identified using various “omics” techniques.
Life Science Proteomics Industry Page has been updated
Proteomics is an academic discipline involving the comprehensive study of protein structure and function, typically by mass spectrometry and electrophoresis. Unlike the genome, the cells of an organism do not all contain the same complement of proteins, but different cells contain different proteins at different times. Proteomics uses this phenomenon to enable more efficient drug development and to determine the mechanisms of disease.
Cellulose nanofibers
Given that cellulose nanofibers(CNFs)offer attractive physical characteristics, such as light weight, strength, and hardness, they not only enable materials with advanced functionality, but are expected to be used as a reinforcing material that can reduce the weight of composite materials.
Handbook of Analysis Procedures for EPA method 533, EPA method 537.1 are now available.
The validity of the analysis performed by each laboratory needs to be confirmed by Quality Control (QC). This article section shows the general analytical procedure for fulfilling QC requirements. Note that the procedure could be modified depending on the situation in the lab and analysts.
Shimadzu has released the CLAM-2040, Fully Automated Sample Preparation Module for LCMS
The CLAM-2040 accompanies you on most of the analytical workflow and improves your overall throughput by drastically reducing the sample preparation time. Simply place the blood tubes in position and the CLAM-2040 performs the next steps automatically, from sample extraction, up to the LCMS analysis and data processing.
Per- and Polyfluoroalkyl Substances (PFAS)
Per-and polyfluoroalkyl substances (PFAS) are a group of persistent and harmful chemicals that can be commonly found in the environment globally. These anthropogenic chemicals can come from various sources such as manufacturing, industrial applications, food contact materials and consumer products, and eventually end up and accumulate in the water, soil and living organisms.