Welcome Message

We are thrilled to extend our warmest greetings to all the participants, distinguished speakers, researchers, and experts from around the world who have gathered here to explore the cutting-edge advancements in the fields of Mass Spectrometry and Chromatography.

Tokyo, renowned for its rich cultural heritage and technological marvels, serves as the perfect backdrop for this gathering of brilliant minds. Our program features a diverse range of sessions, keynote presentations, workshops, and poster sessions, ensuring that there is something for everyone, from seasoned experts to newcomers in the field.

We extend our heartfelt gratitude to our sponsors, organizers, and the scientific community for making this event possible. Together, we are advancing the frontiers of science and technology, pushing the boundaries of what is possible in Mass Spectrometry and Chromatography.

Once again, a warm welcome to the 11th International Conference on Mass Spectrometry and Chromatography. Let's embark on this enlightening journey together!

About Conference

This conference could serve as a platform for involvement, sharing, and exploration of new fields of mass spectroscopy and chromatography research and activity. We will have a better understanding of present and future research perspectives as a result of the conference.

It is an international forum for discussing various separation techniques and mass spectroscopy techniques that will pique your interest in learning about recent advancements and what more can be done.

It is an international forum for debating the benefits, advantages, and applications of herbal plant-based traditional medicines, which are widely used to treat diseases and health concerns in everyday life. You can present a paper, network for potential collaboration, expand your knowledge and uncover solutions, express your thoughts, study beyond your field of interest, and publish a paper, among other things.

Target Audience

• Experts in mass spectroscopy and chromatography
• Research heads from research centres
• Professors and teachers from universities and institution
• Doctors from different medical colleges
• Marketing teams
• Manufactures for analytical instruments.
• Post-doctoral and PhD students working on techniques.
• Graduate and post graduate student

Session and Tracks

Track 1. Mass Spectrometry

Mass spectrometry is an important chemical analysis technique. In chemistry and pharmaceutics, mass spectrometry offers a wide range of applications. In the pharmaceutical industry, drug analysis and mass spectrometry development are more important. A molecule's molecular mass is crucial in determining its character. In cancer treatment, mass spectrometry plays an important role. SimGlycan is a programme that analyses mass spectrometry data. Acceleration of Ionization Detection of Deflection

Ionisation
Acceleration
Deflection
Detection

Track 2. Principle of Mass Spectrometry

Mass spectrometry is an analytical technique for determining the quantity of a substance or identifying unknown substances. The procedure entails converting the sample into a gaseous state, which is then distinguished by the mass to charge ratio (m/z). The abundance and availability of ions in the mass spectrum are used to distinguish them. The plot of ion abundance versus charge-to-mass ratio is shown in the mass spectrum. Ion provides information about the structure and type of the sample's primary molecule.

Track 3. Applications in Mass Spectrometry

Mass spectrometry is a powerful analytical technique with a wide range of applications in biology, chemistry, and physics. It has applications in disease characterization and biomarker research, ionic-molecular interactions, isotope abundance determination in nature and in atomic reactions, atomic masses determination of stable and radioactive isotopes, and analysis of glycans, lipids, proteins and peptides, oligonucleotides, organic chemistry, polymer chemistry, and structure evaluation.

Applications of mass spectrometry in proteomics
Applications of mass spectrometry in metabolomics
Applications of mass spectrometry in environmental analysis
Applications of mass spectrometry in pharmaceutical analysis
Applications of mass spectrometry in forensic analysis
Clinical applications of mass spectrometry

Track 4. Spectroscopy

The study of how matter interacts with electromagnetic radiation is known as spectroscopy. Spectroscopy includes techniques such as X-ray photoelectron spectroscopy, infrared absorption spectroscopy, ultraviolet and visible absorption spectroscopy, nuclear magnetic resonance spectroscopy, and Raman spectroscopy. Sensitivity and selectivity are employed in astronomy and biological sciences through spectroscopy.

Atomic absorption spectroscopy (AAS)
Atomic emission spectroscopy (AES)
Atomic fluorescence spectroscopy (AFS)

Track 5. Chromatography

Chromatography technique of separating the chemical substances into its individual components. Various type of chromatography is there Column chromatography, Ion-exchange chromatography, Affinity chromatography, Paper chromatography, Thin-layer chromatography, Gas chromatography. In Chemical industry chromatography is an important technique has lot of application. Chromatography has lot of application in food industry, Forensic Science, Molecular Biology Studies, Polymer Synthesis, Bioinformatics.

Liquid Chromatography
Gas Chromatography
Thin-Layer Chromatography
Paper Chromatography.

Track 6. Proteomics

Proteomics is the large-scale study of proteins and proteomes. Proteins are vital parts of functional living organisms, Proteomics refers to the large-scale experimental protein purification and mass spectrometry analysis. Proteomic technologies are used for identification and quantification of overall proteins present content of a cell, tissue or an organism. Mass spectrometry with LC–MS-MS and MALDI-TOF/TOF being widely used equipment is the central among current proteomics. Proteomics is also useful in disease diagnosis, gene function, chromatography, electrophoresis, Quantitative techniques, crystallography, Bioinformatics analysis.

Protein expression proteomics.
Structural proteomics.
Functional proteomics

Track 7. Analytical Chemistry

The study of acquiring, processing, and transmitting information about the composition and structure of matter is known as analytical chemistry. Analytical chemistry is the study and use of tools and procedures for separating, identifying, and quantifying materials. Separation, identification, and quantification may be used alone or in combination with other methods in practise. Separation is the process of isolating analytes. Quantitative Analysis determines the numerical amount or concentration, whereas qualitative analysis identifies analytes. Classical wet chemical procedures and current instrumental methods make up analytical chemistry. Separations such as precipitation, extraction, and distillation are used in traditional qualitative procedures. Color, odder, melting point, boiling point, radioactivity, and reactivity can all be used to identify a substance. Quantitative analysis that uses mass or volume changes to quantify amount is known as traditional quantitative analysis.

Gravimetric
Volumetric
Optical
Electrical
Separation

Track 8. Capillary Electrophoresis

Peptide/protein capillary electrophoresis analysis. Capillary is a tiny tube that is placed between two buffer reservoirs and separated using an electric field. Electrophoretic mobility and electro osmosis are used to separate the samples. It is used in micro preparative techniques, haemoglobin electrophoresis, DNA sequencing, polymorphism analysis, and forensic applications for purity and structural confirmation. CE-MS combines the benefits of both CE and MS in a single study to deliver high separation efficiency and molecular mass information.

Capillary zone electrophoresis (CZE)
Capillary isotachophoresis (CITP)
Micellar electro kinetic capillary chromatography (MECC)
Capillary gel electrophoresis (CGE)
Capillary isoelectric

Track 9. Mass Spectrometry Instrumentation

A Mass Spectrometer produces ions from the sample under inquiry, separates them based on their mass-to-charge ratio (m/z), and then records the relative abundance of each ion type. The instrument is made up of three main parts. Analyzer, Detector System, and Ion Source The operations should always be carried out by a mass spectrometer.

In the ionisation source, generate ions from the sample. In the mass analyzer, separate these ions according to their mass-to-charge ratio. Fragment the selected ions and analyse the fragments in a second analyser at the end. Using the detector that converts ions into electrical signals, detect the ions emerging from the last analyzer and measure their abundance. Process the detector signals that are sent to the computer and use feedback to control the instrument.

Ionizer
Deflector
Detector

Track 10. Mass Spectrometry in Pharmaceutical Industry

In the pharmaceutical sector, mass spectrometry is a valuable tool. The pharmaceutical industry discovers drugs, develops them, and manufactures them for use as medications. The method of drug analysis is mass spectrometry. We check the drug's potency by analysing the procedure. Mass spectrometry has a wide range of applications in drug metabolism, pharmacokinetics, and pharmacodynamics, as well as preclinical and clinical research.

Track 11. New Approaches in Mass Spectrometry

The mass spectrometry (MS) procedure applied to the studies of biological samples and helps in identifying various metabolite. The metabolites which are available in biological examples and the comparison studies between different samples help in the construction of certain biochemical patterns. mass spectrometry continued to develop into a powerful multi-dimensional Technology for the use in an analytical and bioanalytical technique of nucleic acids, amino acids, peptides, proteins, carbohydrates, lipids, and etcetera and in categorizing the field of genomics, proteomics, metabolomics, lipidomic

Identification of unknown peaks in gas chromatography helps in understanding the unexpected allergic process and how genotypes relate to phenotypes mass spectrometer that permits high mass accuracy, high resolution, and high sensitivity analyte detection.

Track 12. Mass Spectrometry Imaging

Mass spectrometry imaging (MSI) is a technique in mass spectrometry used to visualize the spatial distribution of molecules, as biomarkers, metabolites, peptides or proteins by their molecular masses. Although traditional methodologies like radiochemistry and immunohistochemistry have the same goal as Mass Spectrometry Imaging. The operation principle depends on the spatial information. The two techniques used in MSI are: microprobe and microscope

Track 13. Ionization Techniques

Mass spectrometry follows various type of ionization methods. The important method that the chemist use is electron impact (EI) and Fast Atom Bombardment (FAB). These techniques are not utilized much with present day mass spectrometry apart from EI for ecological work utilizing Gas chromatography mass spectrometry. Electrospray ionization (ESI) is the ionization method that has turned into the most well-known ionization procedure. The electrospray is made by creating a high voltage on a stream of fluid at environmental weight, some of the time this is helped by a simultaneous stream of gas.

Atmospheric Pressure Chemical Ionization
Atmospheric Pressure Photoionization (APPI)
Electrospray ionization (ESI)
Matrix-Assisted Laser Desorption Ionization (MALDI)

Track 14. Hyphenated Techniques

The hyphenated strategy helps in joining a separation technique and an on-line spectroscopic detection technology. hyphenated system had applications in the investigation of biomaterials, particularly natural product. recent advances improvement in the uses of different hyphenated technique, pre-isolation examinations of crude sample or portion from different characteristic sources, separation and on-line recognition of normal items, chemotaxonomic ponders, quality of herbal product and study of metabolomics.

Hyphenated techniques is of both multidimensional separation systems (HPLC-GC) and multidimensional switching systems (FID-MS). Interfaces of various strategies (GC-FTIR) are all the time considered as hyphenation named yet are not really multidimensional. In multidimensional chromatography, the distribution consistent is different in each part, and in this way the analyte will behave differently. In this manner, the detachment in a one-dimensional framework will be expanded in extent to the quantity of chromatographic dimension.

GC-MS
LC-IR
LC-MS
LC-NMR
CE-MS

Track 15. Organic Chemistry

Organic Chemistry is a brunch of chemistry related with structure properties, and reactions of organic compound and materials. Mass Spectrometry is use of analysis molecular mass of higher energy organic compound. Mass Spectrometry is use to determine the stature of natural product, organic compound, which is helpful in chemical reaction.

Stereochemistry
Physical organic chemistry
Polymer Chemistry
Organometallic Chemistry

Track 16. Inorganic Chemistry

Inorganic chemistry is the study of the synthesis, reactions, structures and properties of compounds of the elements. Inorganic chemistry encompasses the compounds - both molecular and extended solids - of everything else in the periodic table, and overlaps with organic chemistry in the area of organometallic chemistry, in which metals are bonded to carbon-containing ligands and molecules. Inorganic chemistry is fundamental to many practical technologies including catalysis and materials (structural, electronic, magnetic etc.), energy conversion and storage, and electronics. Inorganic compounds are also found in biological systems where they are essential to life processes.

Track 17. Mass Spectrometry in Environmental Analysis

Environmental Analysis is referring the part of chemistry which is related with environment. The process examines all the internal or external components, which has an influence on the performance of the organization. The steps involved in environmental analysis identifying, Scanning, Analyzing, Forecasting. Mass Spectrometry is a technical platform for analysis of environmental chemicals. It helps in several ways Protect Human Health by Detecting Environmental Contaminants, Persistent Organic Pollutants, Emerging Contaminants, From Emerging to Emerged.

WOT (strengths, weaknesses, opportunities, threats) analysis
PESTLE (political, economic, social, technological, legal and environmental) analysis
scenario planning

Track 18. Protein Mass Spectrometry

Protein Mass Spectrometry is related with identification of protein. There are two method of ionization of electrospray ionization and matrix assistant laser desorption. Protein synthesis is important in human life. Protein molecule are work as catalyze in biochemical reactions. Hormones are a kind of protein that make connection between cell to cell and regulated the body function. Mass Spectrometry help to protein synthesis. That has lot of function in human body.

Identify single proteins from a gel band or solution
Identify multiple proteins in solution
Identify multiple proteins from a cell extract
Obtain sufficient sequence for cloning

Track 19. Forensic Analysis

Mass Spectrometry in Forensic Analysis is a technology provides a powerful tool for Forensic studies. For forensic researchers investigating their samples for unknown compounds, drug metabolites, chemicals or hazards, novel psychoactive substances that have never been previously detected or characterized. The role of Mass Spectroscopy in forensic science may be characterized as either molecular or elemental analysis. comparatively little volatile nonionic molecules found in a very sort of forensic samples may be analyzed with electron and chemical ionization of single-stage mass analyzers that give relative molecular mass and structural data. Non-polar and polar molecules and their metabolites habitually found in biological matrices along with alternative analytes of forensic interest may be determined by using Electrospray.

Deoxyribonucleic acid
DNA
Computer
Handwriting
Bloodstain
Statement analysis

Track 20. Mass Spectrometry in Medicine

Mass Spectrometry in medicine is the most important area to study for the development of medicines. Mass Spectrometry is an analytic technique widely used many laboratories for the development of laboratory medicine. Various types of Mass Spectrometers are used in order to get improvements in assay performance that is occurring rapidly in areas such as toxicology, endocrinology, and biochemical genetics. Mass Spectrometry is a diagnostic system with high specificity and developing vicinity in research facility prescription. Different sorts of Mass Spectrometers are being utilized as a part of an expanding number of clinical research facilities all around the globe. Mass Spectrometry has contributed altogether to the development of restorative science in early decades, especially in connection to medication advancement, in-vitro diagnostics, dietary and natural drug.

Track 21. Pharmacokinetics

Pharmacokinetics is branch of pharmacology which studies how an organism can effect a drug. it is to determine the fate of substances administer to living organism. The substance includes any chemical xenobiotic, pharmaceutical drugs, pesticides, food additives, cosmetics. It has various compartments and the model is LADME.

Track 22. Bioinformatics

The human genome project and other organisms' sequencing studies have created an unparalleled amount of biological data. The ever-evolving science of bioinformatics is in charge of meeting the enormous need for data analysis and interpretation.

Market Analysis

The chromatographic reagents market size is estimated to grow from an USD 5.5 billion 2020 to USD 7.8 billion by 2025, at a CAGR of 7.1% during the forecast period. Market growth is driven largely by factors, such as increasing R&D investments in the pharmaceutical and biotechnology industry, and rapidly increasing importance of chromatography tests for drug approvals. Moreover, growing use of chromatography in proteomics in developing countries is expected to present avenues of growth for market players.

The chromatography reagents market has seen significant growth over the past years; however, due to the unexpected COVID-19 outbreak, the market to witness additional growth in 2020, increasing use of chromatography techniques in the acceptance of various drugs. Furthermore, technological advancements and the increasing importance of chromatography in hospital laboratories, forensic laboratories, and pharmaceutical companies will increase market growth in the forecast period.

Pharmaceutical and biotechnology companies are investing in research to come up with protein-related products to meet the growing needs of the healthcare sector. Chromatography, spectroscopy, PCR, and NGS, among other techniques, are commonly used in proteomic research. Currently, pharmaceutical and biotechnology companies are increasingly adopting these technologies for protein separation and identification during drug discovery and enhancement. The growing public and private investments in pharmaceutical and life science research are driving to acquire and use of chromatography systems. In turn, is increasing the demand and utilization of chromatography reagents across the globe.

The mass spectrometry market size is estimated to grow from an USD 4.1 billion in 2020 to USD 5.6 billion by 2025, at CAGR of 6.5%.  spending on pharmaceutical R&D across the globe, government regulations on drug safety, developing focus on the quality of food products, increase in crude and shale gas production, and growing government initiatives for pollution control and environmental testing are high growth prospects for the mass spectrometry market during the upcoming period.

Mass spectrometry plays an important role in the pharmaceutical industry, from the early stages of drug discovery to late-stage development and clinical trials. Thus, increasing funding in the pharmaceutical and biotechnology industry is expected to improve the growth of the mass spectrometry market.

Developing countries such as China and India give various opportunities for the growth of the mass spectrometry market. Together, China and India generate a huge demand for single mass spectrometers and hybrid spectrometers. The biopharmaceutical industry in these countries is strong and is expected to come up with increasing growth of the spectrometry and chromatography markets.

Young Research Forum

The 11th International Conference On Mass Spectroscopy and Chromatography will present prestigious awards to talented young researchers, scientists, young investigators, post-graduate students, post-doctoral fellows, trainees, and junior faculty in recognition of their outstanding contributions to the conference theme. The Young Scientist Awards make every effort to offer young scientists with a stable professional environment.

The following are the nominees for the 11th International Conference On Mass Spectroscopy and Chromatography's Young Research Awards:

At the Mass Spectrometry Congress 2023 Young Researcher Forum - Outstanding Masters/Ph.D./Post Doctorate thesis work Presentation, only 25 presentations will be accepted.

Benefits of YRF Registration:

You can learn about job advancement and the latest technologies by networking.

Allow for international research collaboration with renowned senior scientists in the field of herbalism.

Young researchers have a once-in-a-lifetime opportunity to learn about various study areas and expand their research knowledge.