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Scientific Program
8th World Congress on Mass Spectrometry, will be organized around the theme “ Utilising the Latest Developments in Mass Spectrometry and Proteomics”
Euro Mass Spectrometry 2019 is comprised of 14 tracks and 108 sessions designed to offer comprehensive sessions that address current issues in Euro Mass Spectrometry 2019.
Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.
Register now for the conference by choosing an appropriate package suitable to you.
Application of Mass Spectrometry includes the ion and weights separation. The samples are usually introduced through a heated batch inlet, heated direct insertion probe, or a gas chromatography. Ionization mass spectrometry (ESI-MS) which has become an increasingly important technique in the clinical laboratory for structural study or quantitative measurement of metabolites in a complex biological sample. MS/MS applications are plentiful. Mass spectrometry is an analytical method with high specificity and a growing presence in laboratory medicine. Various types of mass spectrometers are being used in an increasing number of clinical laboratories around the world, and, as a result, significant improvements in assay performance are occurring rapidly in areas such as toxicology, endocrinology, and biochemical markers. This review serves as a basic introduction to mass spectrometry
- Track 1-1Mass spectrometry in the pharmaceutical industry
- Track 1-2Chromatography Mass Spectrometry
- Track 1-3Chromatography Mass Spectrometry
- Track 1-4Market growth and new era of mass spectrometry
- Track 1-5Mass Spectrometry in petroleum, Space Science, astrobiology and atmospheric chemistry
- Track 1-6Mass spectrometry in food analysis, industry and environmental analysis
- Track 1-7Mass spectrometry in biology, Life Science and Biotechnology
- Track 1-8Mass Spectrometry in Metabolomics
- Track 1-9Mass Spectrometry in Polymers and Molecular Surfaces/Films
The search of metabolites which are present in biological samples and the comparison between different samples allow the construction of certain biochemical patterns. The mass spectrometry (MS) methodology applied to the analysis of biological samples makes it possible for the identification of many metabolites. The 100 chromatograms were concatenated in a vector. This vector, which can be plotted as a continuous (2D pseudospectrum), greatly simplifies for one to understand the subsequent dimensional multivariate analysis. To validate the method, samples from two human embryos culture medium were analyzed by high-pressure liquid chromatography–mass spectrometry (HPLC–MS). They work on the principle that many microorganisms have their own unique mass spectral signature based on the particular proteins and peptides that are present in the cells. Identification of unknown peaks in gas chromatography (GC/MS)-based discovery metabolomics is challenging, and remains necessary to permit discovery of novel or unexpected metabolites that may allergic diseases processes and/or further our understanding of how genotypes relate to phenotypes. Here, we introduce two new technologies and advances in pharmaceutical analytical methods that can facilitate the identification of unknown peaks. First, we report on a GC/Quadrupole-Orbitrap mass spectrometer that provides high mass accuracy, high resolution, and high sensitivity analytic detection.
- Track 2-1Metabolomics/Lipidomics: new MS technologies
- Track 2-2Emerging separation technologies
- Track 2-3Hybrid Mass Spectrometry
- Track 2-4Approaches in glycoproteins and glycans
- Track 2-5MS Approaches in Carbohydrates ,microbes and biomolecule analysis
- Track 2-6Atom probe tomography
- Track 2-7Protein phosphorylation and non covalent interaction
- Track 2-8Advances in isolation, enrichment and separation
- Track 2-9Lipidomics, metabolomics and ultratrace analysis
- Track 2-10Nano scale and microfluidic separations
- Track 2-11Complementary Techniques and Multitechnique Approaches (XPS, GD-MS, ...)
New mass spectrometry (MS) methods, collectively known as data independent analysis and hyper reaction monitoring, have recently emerged. The analysis of peptides generated by proteolytic digestion of proteins, known as bottom-up proteomics, serves as the basis for many of the protein research undertaken by mass spectrometry (MS) laboratories. Discovery-based or shotgun proteomics employs data-dependent acquisition (DDA). Herein, a hybrid mass spectrometer first performs a survey scan, from which the peptide ions with the intensity above a predefined threshold value, are stochastically selected, isolated and sequenced by product ion scanning. n targeted proteomics, selected environmental Monitoring (ERM), also known as multiple reaction monitoring (MRM), is used to monitor a number of selected precursor-fragment transitions of the targeted amino acids. The selection of the SRM transitions is normally calculated on the basis of the data acquired previously by product ion scanning, repository data in the public databases or based on a series of empirical rules predicting the Enzyme structure sites.
- Track 3-1Advances in sample preparation and MS Interface design
- Track 3-2Cs-SIMS, MeV-SIMS , FIB-SIMS and In-situ liquid SIM
- Track 3-3MALDI-TOF, SELDI-TOF and TOF-SIMS
- Track 3-4ICP-MS and IRMS
- Track 3-5Accelerator Mass Spectrometry
- Track 3-6Triple Quadrupole GC-MS/LC-MS, the next evolution
- Track 3-7Physical and Biophysical Mass Spectrometry
- Track 3-8Proteomic and mass spectrometry technologies for biomarker discovery
- Track 3-9Single-cell MALDI mass spectrometry imaging
- Track 3-10Biomolecular imaging mass spectrometry
There are many types of ionization techniques are used in mass spectrometry methods. The classic methods that most chemists are familiar with are electron impact (EI) and Fast Atom Bombardment (FAB). These techniques are not used much with modern mass spectrometry except EI for environmental work using GC-MS. Electrospray ionization (ESI) - ESI is the ionization technique that has become the most popular ionization technique. The electrospray is created by putting a high voltage on a flow of liquid at atmospheric pressure, sometimes this is assisted by a concurrent flow of gas. Atmospheric Pressure Chemical Ionization (APCI) - APCI is a method that is typically done using a similar source as ESI, but instead of putting a voltage on the Electrospray Tandem Mass Spectrometry Newborn Screening itself, the voltage is placed on a needle that creates a corona discharge at atmospheric pressures. Matrix Assisted Laser Electrophoresis is a technique of ionization in which the sample is bombarded with a laser. The sample is typically mixed with a matrix that absorbs the radiation biophysics and transfer a proton to the sample. Gas-Phase Ionization.
- Track 4-1Nanospray ionisation
- Track 4-2Microelectronics
- Track 4-3Separation Techniques in Analytical Chemistry
- Track 4-4Ion Mobility Spectrometry
- Track 4-5Ionization techniques and Data processing
- Track 4-6Particle bombardment
- Track 4-7Field desorption and ionisation
- Track 4-8Gas Phase ionisation
- Track 4-9Matrix asisted laser desorption ionization
- Track 4-10Matrix asisted laser desorption ionization
- Track 4-11Atmospheric pressure chemical ionization
- Track 4-12Electrospray ionization
- Track 4-13Positive or negative ionisation
Liquid chromatography-mass spectrometry analysis of small molecules from biofluids requires sensitive and robust assays. Because of the very complex nature of many biological samples, efficient sample preparation protocols to remove unwanted components and to selectively extract the compounds of interest are an essential part of almost every bioanalytical workflow. High-performance liquid chromatography (HPLC) is a separation technique that can be used for the analysis of organic molecules and ions. HPLC is based on mechanisms of adsorption, partition and ion exchange, depending on the type of stationary phase used. HPLC involves a solid stationary phase, normally packed inside a stainless-steel column, and a liquid mobile phase. Separation of the components of a solution results from the difference in the relative distribution ratios of the solutes between the two phases. HPLC can be used to assess the purity and/or determine the content of many pharmaceutical bioprocessing substances. It can also be used to determine enantiomeric composition, using suitably modified mobile phases or chiral stationary phases. Individual separation mechanisms of adsorption, partition and ion exchange rarely occur in isolation since several principles act to a certain degree simultaneously.In a very environmental monitoring, hydrophilic molecules will tend to associate with each other (like water drops on an oily surface). The hydrophilic molecules in the mobile phase will tend to adsorb to the surface on the inside and outside of a particle if that surface is also hydrophilic. Increasing the polarity of the mobile phase will subsequently decrease the adsorption and ultimately cause the sample molecules to exit the column. This mechanism is called Normal Phase Analytical Chromatography. It is a very powerful technique that often requires non-polar solvents. Due to safety and environmental concerns this mode is used mostly as an analytical technique and not for process applications.
- Track 5-1Developments in Liquid Chromatography and HPLC
- Track 5-2Molecular Exclusion Chromatography
- Track 5-3Ion Exchange Chromatography
- Track 5-4Partition Chromatography
- Track 5-5Partition Chromatography
- Track 5-6Instrumentation principles involving in Chromatography and HPLC
- Track 5-7Application of High Performance Liquid Chromatography (HPLC)
- Track 5-8Recent Novel Techniques in Chromatography
- Track 5-9Chromatography Industry and Market Analysis
- Track 5-10Chromatography Industry and Market Analysis
- Track 5-11Separation Techniques in Analytical Chemistry
- Track 5-12Developments in ion chromatography
- Track 5-13Developments in Gas Chromatography
- Track 5-14Advances in Various Chromatographic Techniques
- Track 5-15Advances in HPLC and affinity chromatography
- Track 5-16HPLC Fingerprinting in Bioinformatics and Computational Biology
Mass spectrometry (MS) - based proteomics allows the sensitive and accurate quantification of almost complete proteomes of complex biological fluids and tissues. At the moment, however, the routinely usage of MS-based proteomics is prevented and complicated by the very complex work flow comprising sample preparation, chromatography, MS measurement followed by data processing and evaluation. The new technologies, products and assays developed by Precision Proteomics could help enabling and establishing mass spectrometry (MS) - based proteomics in academic and pharmaceutical research as well as in clinical diagnostics.
- Track 6-1 Proteomics from Discovery to Function and its applications
- Track 6-2Analytical Science and Separation Techniques
- Track 6-3Mass spectrometry data analysis in proteomics
Mass spectrometry (MS) - based proteomics allows the sensitive and accurate quantification of almost complete proteomes of complex biological fluids and tissues. At the moment, however, the routinely usage of MS-based proteomics is prevented and complicated by the very complex work flow comprising sample preparation, chromatography, MS measurement followed by data processing and evaluation. The new technologies, products and assays developed by Precision Proteomics could help enabling and establishing mass spectrometry (MS) - based proteomics in academic and pharmaceutical research as well as in clinical diagnostics.
- Track 7-1Proteomics in Computational and Systems Biology
- Track 7-2Neuroproteomics & Neurometabolomics
- Track 7-3Proteomics Technologies
There are many types of ionization techniques are used in mass spectrometry methods. The classic methods that most chemists are familiar with are electron impact (EI) and Fast Atom Bombardment (FAB). These techniques are not used much with modern mass spectrometry except EI for environmental work using GC-MS. Electrospray ionization (ESI) - ESI is the ionization technique that has become the most popular ionization technique. The electrospray is created by putting a high voltage on a flow of liquid at atmospheric pressure, sometimes this is assisted by a concurrent flow of gas. Atmospheric Pressure Chemical Ionization (APCI) - APCI is a method that is typically done using a similar source as ESI, but instead of putting a voltage on the Electrospray Tandem Mass Spectrometry Newborn Screening itself, the voltage is placed on a needle that creates a corona discharge at atmospheric pressures. Matrix Assisted Laser Electrophoresis is a technique of ionization in which the sample is bombarded with a laser. The sample is typically mixed with a matrix that absorbs the radiation biophysics and transfer a proton to the sample. Gas-Phase Ionization.
- Track 8-1LC-NMR-MS
- Track 8-2HPLC-ESI-MS
- Track 8-3HPLC-CE-MS
- Track 8-4LA-ICP-MS
- Track 8-5MC-ICP-MS
- Track 8-6LC-MC-ICPMS
- Track 8-7FlFFF-ICP-MS
- Track 8-8HPLC-ICP-MS
- Track 8-9GC-ICP-MS
Mass spectrometry experiment (MS) is a high-throughput experimental method that characterizes molecules by their mass-to-charge ratio. The MS is composed of sample preparation, molecular ionization, detection, and instrumentation analysis processes. MS is beneficial in that it is generally fast, requires a small amount of sample, and provides high accuracy measurements. For these reasons, MS alone or combined with other structural proteomics techniques is widely used for various molecular biology analysis purposes. Examples of the analysis include post-translations modifications in proteins, identification of vibrational components in proteins, and analysis of protein conformation and dynamics. We will focus on MS-coupled methods that provide information about conformation and dynamics of the protein being studied. For a comprehensive review on MS procedures and for a review on various types of MS-coupled methods. The performance of a mass spectrometer will be severely impaired by the lack of a good vacuum in the ion transfer region of the mass Analyzer. As the vacuum deteriorates it will become insufficient to maintain biomedical instrumentation in the operating mode. If the foreline pump is not maintained, the oil may become so contaminated that the optimum pumping is no longer possible. Initially, gas transport and metabolism ballasting may clean the oil. If the oil has become discoloured then it should be changed according to the pump manufacturers’ maintenance manual. When rotary pumps are used to pump away conflict resolution, the solvent can become dissolved in the oil causing an increase in backing line pressure. Gas ballasting is a means of purging the oil to remove dissolved contaminants
- Track 9-1Hyper reaction monitoring
- Track 9-2Data independent analysis, representation and acquisition
- Track 9-3General symptom and chromatographic symptom
- Track 9-4Temperature and pressure symptom
- Track 9-5Emerging Tools in Mass Spectrometry
- Track 9-6Safty and regulatory certification
- Track 9-7MSD hardware description
- Track 9-8Troubleshooting tips and tricks
As per Fundamentals of Mass Spectrometry, Mass spectrometry is an analytical tool used for measuring the molecular mass of a sample. Ionization is the atom or molecule is ionized by knocking one or more electrons off to give a positive ion. This is true even for things which you would normally expect to form negative ions or never form ions at all. Most mass spectrometers work with positive ions. New Ion activation methods for tandem mass spectrometry; this is followed by tandem mass spectrometry, which implies that the activation of ions is distinct from the laboratory research, and that the precursor and product ions are both characterized independently by their mass/charge ratios. As per the Frost and Sullivan report pharmaceutical analytical market is growing on an average 0.4% annually. This report studies the global mass spectrometry market over the forecast period of 2013 to 2018. Once analyte ions are formed in the gas phase, a variety of mass analyzers are available and used to separate the ions according to their mass-to-charge ratio (m/z). Mass spectrometers operate with the dynamics of charged particles in electric and magnetic particles in vacuum described by the Lorentz force law and Newton’s second law of motion.
- Track 10-1Instrumentation and method development
- Track 10-2MS dynamics and theory of gas phase ions
- Track 10-3New ion activation methods in mass spectrometry
- Track 10-4Protein sample and Charged peptide fragments
Mass spectrometry (MS) - based proteomics allows the sensitive and accurate quantification of almost complete proteomes of complex biological fluids and tissues. At the moment, however, the routinely usage of MS-based proteomics is prevented and complicated by the very complex work flow comprising sample preparation, chromatography, MS measurement followed by data processing and evaluation. The new technologies, products and assays developed by Precision Proteomics could help enabling and establishing mass spectrometry (MS) - based proteomics in academic and pharmaceutical research as well as in clinical diagnostics.
- Track 11-1Mass Spectroscopy
- Track 11-2X-ray spectrometry
- Track 11-3Ultrasonic correlation spectroscopy
- Track 11-4X-ray photoelectron spectrometry
- Track 11-5Ultraviolet-visible spectroscopy
- Track 11-6Infrared spectroscopy
- Track 11-7Nuclear magnetic resonance spectroscopy
- Track 11-8Molecular spectroscopy
- Track 11-9Ion Spectroscopy
As per Fundamentals of Mass Spectrometry, Mass spectrometry is an analytical tool used for measuring the molecular mass of a sample. Ionization is the atom or molecule is ionized by knocking one or more electrons off to give a positive ion. This is true even for things which you would normally expect to form negative ions or never form ions at all. Most mass spectrometers work with positive ions. New Ion activation methods for tandem mass spectrometry; this is followed by tandem mass spectrometry, which implies that the activation of ions is distinct from the laboratory research, and that the precursor and product ions are both characterized independently by their mass/charge ratios. As per the Frost and Sullivan report pharmaceutical analytical market is growing on an average 0.4% annually. This report studies the global mass spectrometry market over the forecast period of 2013 to 2018. Once analyte ions are formed in the gas phase, a variety of mass analyzers are available and used to separate the ions according to their mass-to-charge ratio (m/z). Mass spectrometers operate with the dynamics of charged particles in electric and magnetic particles in vacuum described by the Lorentz force law and Newton’s second law of motion.
Mass spectrometry imaging is a technique used in mass spectrometry to visualize the spatial distribution of chemical compositions e.g. compounds, biomarker metabolites, peptides or proteins by their molecular masses. Although widely used traditional methodologies like radiochemistry and immunohistochemistry achieve the same goal as MSI, they are limited in their abilities to analyze multiple samples at once, and can prove to be lacking if researchers do not have prior knowledge of the samples being studied. Emergency Radiology in the field of MSI are MALDI imaging and secondary ion mass spectrometry imaging (SIMS imaging). Imaging Mass Spectrometry is a technology that combines advanced analytical techniques for the analysis of biomedical Chromatography with spatial fidelity. An effective approach for imaging biological specimens in this way utilizes Matrix-Assisted Laser Desorption Ionization Mass Spectrometry (MALDI MS). Briefly, molecules of interest are embedded in an organic matrix compound that assists in the desorption and ionization of compounds on irradiation with a UV laser. The mass-to-charge ratio of the ions are measured using a Tandem Mass Spectrometry over an ordered array of ablated spots. Multiple analytes are measured simultaneously, capturing a representation or profile of the biological state of the molecules in that sample at a specific location on the tissue surface.
- Track 13-1Single-cell MALDI mass spectrometry imaging
- Track 13-2Biomolecular imaging mass spectrometry
- Track 13-3Mass Spectrometry Imaging approaches and applications
Proteomics has become an essential tool for understanding biological systems processes at the molecular level. Plant Proteomics publishes novel and significant research in the field of proteomics that examine the dynamics, functions, and interactions of proteins from plant systems. Nutritional proteomics is quickly developing to utilize little atom substance profiling to bolster incorporation of eating regimen and sustenance in complex biosystems research. Nutrigenomics is a branch of nutritional genomics and is the study of the effects of foods and food constituents on gene expression. Foodomics has been recently defined as a new discipline that studies food and nutrition domains through the application of advanced technologies in which MS techniques are considered indispensable. Applications of Foodomics include the genomic, transcriptomic, proteomic, and/or metabolomic study of foods for compound profiling, authenticity, and/or biomarker-detection related to food quality or safety; the development of new transgenic foods, food contaminants, and whole toxicity studies; new investigations on food bioactivity, food effects on human health. The University of Michigan Nutrition Obesity Research Center (UM NORC) started in 2010, supported by the National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK). The UM NORC is one of 12 U.S. focuses intended to move and backing translational, multi-disciplinary exploration in heftiness and sustenance, over the continuum of fundamental science to applications in people (solution) and populations (public health).
- Track 14-1Protein Biochemistry and Proteomics
- Track 14-2Plant Proteomics and Applications
- Track 14-3Food and Nutritional Proteomics
- Track 14-4Immunoproteomics and Clinical proteomics
- Track 14-5Protein Engineering and Molecular Design
- Track 14-6Protein Engineering and Molecular Design