About Conference
It is a great pleasure
and an honour to extend our warm invitation to attend the "International Conference on Mass Spectrometry and Proteomics”, on June 25-27, 2018 in Dublin,
Ireland, which includes prompt keynote presentations, oral talks, poster
presentations and exhibitions. This conference brings together individuals who
are interested in fields of mass spectrometry, proteomics, chromatography and
analytical chemistry and approaching towards the conference gives best platform
to explore the ideas and issues concerned to relevant topic and generate
solutions.

This unites all the participants from across the globe. It is a
platform to share their experience and their ideas for research work results to
implement in further research work. As scientists, and other researchers all
fascinated by the study of the global use of mass spectrometry. We are
particularly concerned about understanding the uses of mass spectrometry in the
field of chemistry and analytical science. We welcome you to our site to join
with us. At this site, you can learn about membership in the society, the
society journal, our newsletter and conferences.
Why to
attend???
·
Meet
experts and influencers face to face
·
Conferences provide a great opportunity to
network where most people can help each other uncover ideas and spark
inspiration.
·
To learn new things in your field
·
Conferences Build Your Knowledge Base
·
Encounter new vendors and suppliers
·
Attending a conference allows you to grow and
challenge yourself
·
Attending conferences grow your professional
network
·
Position your company as a champion
·
Network with leaders and influencers from the
scientific, academic and R&D communities
Target
Audience:
Directors,
Presidents, CEO’s from companies, Industrial Experts, Business Intelligence
Experts, Scientists, Research Associates, Vice Presidents, Manufacturers, Brand
Marketers, Advertising Agency Executives, Professors and Students from Academia.
Speaker benefits
at Mass Spectrometry Congress 2018:
o
Opportunity
to Chair/Co-chair a session of your
interest
Library of Abstracts which brings worldwide exposure to the researchers and
speakers participate in our conferences.
o
Speaker
and Abstract pages created in Google on your name would get worldwide
acknowledgment to your research profile
o
Opportunity
to get sponsorship for your projects
o
Opportunity
to moderate the conference
o
Career
Guidance Workshops to the Graduates, Doctorates and Post-Doctoral Fellows
o
Accepted
Abstracts will be published in respective supporting journals, each abstract
will be labeled with a DOI provided
by Cross Ref.
o
Speaker
will be felicitated with Certificate
o
Best
Poster Competitions and Young Researcher Competitions
o
B2B
meetings
o
All
attendees can avail 21 CPD Credits
(Continuing Professional Development)
o
Certificate
Accreditation by the International
Organizing Committee (IOCM)
o
Abstracts
will be published in conference souvenir & international journals
Welcome Message
Allied Academies invites all the participants from all over the world to
attend "International Conference on Mass Spectrometry and Proteomics”,
on June 25-27, 2018 in Dublin, Ireland which includes prompt keynote
presentations, oral talks, poster presentations, sponsors and exhibitions.
Allied
Academies is a scientific
association known for promoting scientific temperament and has been performing
very well in Business and Management and is a perfect platform for our readers.
It is established in the year 1997. The main motto is making the information on
science and technology. It is a specialized medical and science publisher that
operates in collaboration with the association and societies. This
publishing house has been built on the base of esteemed academic and research
institutions including The College of Audiologists and Speech Language
Pathologists of Ontario (CASLPO), The Association for Public Safety
Communications Officials of Canada (APCO), The Canadian Vascular Access
Association (CVAA), and The Canadian Society of Internal Medicine (CSIM).
Mass Spectrometry Congress aims to bring together the
prominent researchers, academic scientists, and research scholars to exchange
and share their experiences on all aspects of Mass Spectrometry. It is also an
interdisciplinary platform for researchers, practitioners and educators to
present and discuss the most recent advances, trends, and concerns as well as
practical challenges and solutions adopted in the fields of Mass Spectrometry
and Proteomics.
Sessions and Tracks
Track 1: Fundamentals in Mass Spectrometry
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.
Track 2: Applications of Mass Spectrometry
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 chromatograph. 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. Mass spectrometry is an analytical meth ods 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 biochemicalmarkers. This review serves as a basic introduction to mass spectrometry, its
uses, and associated challenges in the clinical laboratory and ends with a
brief discussion of newer methods with the greatest potential for Clinical and
Diagnostic Research.
Track 3: New Approaches in Mass Spectrometry
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. 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 an advances in pharmaceutical analyticalmethods 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 analyte detection.
Track 4: Mass Spectrometry in Pharmaceutical Analysis
Mass spectrometry is
one of the important tools in the analysis of pharmaceuticals. It is a
technique used to measure the characteristic of a sample, likely to be
availability of new instrumentations and ionization techniques which used to
solve bio analytical problems. It
consists of both qualitative and quantitative aspects. And it is associated
with drug discovery and drug development process.
Track 5: Recent Advances and Development in Mass Spectrometry
New mass spectrometry
(MS) methods, collectively known as data independent analysis and hyperreaction 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). 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 6: Mass Spectrometry in Toxicology
Toxicology is aimed to
correlate the quantitative and qualitative relationship between the poison and
their behavioural effects. So as it focus on elucidation of the mechanisms of
actions of poisons, Mass spectroscopy has become important analytical technique
used in the toxicological analysis of drugs, poisons, and their metabolites of
both. Mass spectroscopy applies all fields of toxicology, such as
environmental, clinical, and forensic toxicology.
Track 7: Mass spectrometry Imaging
Mass spectrometry
imaging is a technique used in mass spectrometry to visualize the spatialdistribution 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 analyse multiple
samples at once, and can prove to be lacking if researchers do not have prior
knowledge of the samples being studied.
Track 8: IonizationTechniques
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 FastAtom Bombardment (FAB). These techniques are not used much with modern mass
spectrometry except EI for environmental work using GC-MS. Electrosprayionization (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.
Track 9: Mass Spectrometry in Analytical Science
Mass spectrometry is a
way to measure the mass of ions which are electrically charged species and
derived from atoms or molecules. This technique is used to explore the chemical
molecules. And used to know the fundamental atomic and molecular processes as a
technique. It helps to control the process in chemical and biological
industries, diagnosis diseases, discover new drugs, and protect the
environment.
Track 10: Mass Spectrometry Configurations and Separation Techniques
Mass Spectrometry
Configurations and Techniques is regards to Mass Spectrometry configuration of
source, analyzer, and detector becomes conventional in practice, often a
compound acronym arises to designate it, and the compound acronym may be better
known among nonspectrometrists than the component acronyms. The Mass
Spectrometry instrument consists of three major components those are Ion
Source: For producing gaseous ions from the substance being studied; Analyzer:
For resolving the ions into their characteristics mass components according to
their mass-to-charge ratio and Detector System: For detecting the ions and
recording the relative abundance of each of the resolved ionic species. Charged
ions of various sizes are generated on the sample slide and MALDI is the
abbreviation for "Matrix Assisted Laser Desorption/Ionization.
Track 11: Chromatography
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.
Track 12: High Performance Liquid Chromatography (HPLC)
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. It is a very powerfultechnique 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 13: HyphenatedTechniques (LC-NMR-MS, HPLC-ESI-MS, MC-ICP-MS, HPLC-ICP-MS, UPLC-Q-TOF/MS)
A Hyphenated technique is combination or
coupling of two different analytical techniques with the help of proper
interface.Chromatography - Produces pure or nearly pure fractions of chemical
components in a mixture. Spectroscopy – Produces selective information for
identification using standards or library spectra. The hyphenated technique is
developed from the coupling of a separation technique and an online
spectroscopic detection technology. The number of existing techniques has been
combined to expand the utility.
Track 14: Mass spectrometry in environmental analysis
Liquid chromatography (LC) is becoming a
popular separation technique in environmental analysis. Most LC nowadays is
High Performance Liquid Chromatography (HPLC) which uses small particles packed
together at high pressure. While gas chromatography still remains popular in
environmental analysis, particularly for volatile and non-polar compounds, it
does not lend itself to analyzing compounds which are polar, non-volatile,
thermolabile or have a high molecular weight. For such compounds, LC is better.
LC-MS is the most popular
Track 15: Maintenance,Troubleshooting, Data Analysis and Experimentation in Mass Spectrometry
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 analysisprocesses. ms is beneficial in that it is generally fast, requires a small
amount of sample, and provides high accuracy measurements. 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.
Track 16: Proteomics
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.
Track 17: Mass Spectrometry in Proteome Research
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 18: Proteomics and its 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.
Track 19: Spectroscopy
Spectroscopy is the
study of the interaction between matter and electromagnetic radiation.
Historically, spectroscopyoriginated through the study of visible light
dispersed according to its wavelength, by a prism. Later the concept was
expanded greatly to include any interaction with radiative energy as a function
of its wavelength or frequency. Spectroscopic data is often represented by an
emission spectrum, a plot of the response of interest as a function of
wavelength or frequency.
Track 20: Mass Spectrometry in Metabolomics and Lipidomics
Data analysis for
metabolomics typically consists of feature extraction, statistical analysis,
compound identification and biological pathway analysis. The Thermo Scientific™
suite of metabolomics software products allows you to quickly transform complex
data into useful results. HRAM Orbitrap LC-MS is a widely adopted technique for
lipidomics analyses. Together with a comprehensive database and library that provides
accurate lipid identification, this technology enables relative as well as
absolute quantitation from biological samples. Mass spectrometry (MS) is a
central technology in Metabolomics due to its very high sensitivity and
selectivity. Combined with a separation step before the MS-detection (e.g. gas
chromatography (GC), liquid chromatography (LC), convergence chromatography
(UPC2), or capillary electrophoresis (CE)).
Track 21: Nuclear Magnetic Resonance (NMR) Spectroscopy
Nuclear Magnetic
Resonance (NMR) spectroscopy is an analytical chemistry technique used in
quality control and reserach for determining the content andpurity of a sample
as well as its molecular structure. For example, NMR can quantitatively analyze
mixtures containing known compounds. For unknown compounds, NMR can either be
used to match against spectral libraries or to infer the basic structure
directly. Once the basic structure is known, NMR can be used to determine
molecular conformation in solution as well as studying physical properties at
the molecular level such as conformational exchange, phase changes, solubility,
and diffusion. In order to achieve the desired results, a variety of NMR
techniques are available.
Track 22: Clinical application of mass spectrometry
Clinical laboratories
use the MS technology for disease screening, diagnosis of disease and metabolic
disorders, monitoring of drug therapy, identifying drug toxicity and poisoning,
and discovering new biomarkers. Therapeutic monitoring of immunosuppressant
drugs using MS is well established. Limitations of immunoassays such as
nonspecific binding of the antibody and cross-reactivity with metabolites that
often result in overestimation have made the more accurate LC/MS/MS
methodologies the assays of choice. LC/ MS/MS has become the standard for
assay of steroid hormones for diagnosis of endocrine disorders. Vitamin D
analysis by LC/MS/MS is widely used in the clinical laboratory today. Whereas immunoassays
are unable to distinguish between 25-hydroxy vitamins D2 and D3, the LC/MS
methodologies are able to measure these leves.
Track 1: Fundamentals in Mass Spectrometry
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.
Track 2: Applications of Mass Spectrometry
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 chromatograph. 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. Mass spectrometry is an analytical meth ods 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 biochemicalmarkers. This review serves as a basic introduction to mass spectrometry, its
uses, and associated challenges in the clinical laboratory and ends with a
brief discussion of newer methods with the greatest potential for Clinical and
Diagnostic Research.
Track 3: New Approaches in Mass Spectrometry
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. 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 an advances in pharmaceutical analyticalmethods 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 analyte detection.
Track 4: Mass Spectrometry in Pharmaceutical Analysis
Mass spectrometry is
one of the important tools in the analysis of pharmaceuticals. It is a
technique used to measure the characteristic of a sample, likely to be
availability of new instrumentations and ionization techniques which used to
solve bio analytical problems. It
consists of both qualitative and quantitative aspects. And it is associated
with drug discovery and drug development process.
Track 5: Recent Advances and Development in Mass Spectrometry
New mass spectrometry
(MS) methods, collectively known as data independent analysis and hyperreaction 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). 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 6: Mass Spectrometry in Toxicology
Toxicology is aimed to
correlate the quantitative and qualitative relationship between the poison and
their behavioural effects. So as it focus on elucidation of the mechanisms of
actions of poisons, Mass spectroscopy has become important analytical technique
used in the toxicological analysis of drugs, poisons, and their metabolites of
both. Mass spectroscopy applies all fields of toxicology, such as
environmental, clinical, and forensic toxicology.
Track 7: Mass spectrometry Imaging
Mass spectrometry
imaging is a technique used in mass spectrometry to visualize the spatialdistribution 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 analyse multiple
samples at once, and can prove to be lacking if researchers do not have prior
knowledge of the samples being studied.
Track 8: IonizationTechniques
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 FastAtom Bombardment (FAB). These techniques are not used much with modern mass
spectrometry except EI for environmental work using GC-MS. Electrosprayionization (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.
Track 9: Mass Spectrometry in Analytical Science
Mass spectrometry is a
way to measure the mass of ions which are electrically charged species and
derived from atoms or molecules. This technique is used to explore the chemical
molecules. And used to know the fundamental atomic and molecular processes as a
technique. It helps to control the process in chemical and biological
industries, diagnosis diseases, discover new drugs, and protect the
environment.
Track 10: Mass Spectrometry Configurations and Separation Techniques
Mass Spectrometry
Configurations and Techniques is regards to Mass Spectrometry configuration of
source, analyzer, and detector becomes conventional in practice, often a
compound acronym arises to designate it, and the compound acronym may be better
known among nonspectrometrists than the component acronyms. The Mass
Spectrometry instrument consists of three major components those are Ion
Source: For producing gaseous ions from the substance being studied; Analyzer:
For resolving the ions into their characteristics mass components according to
their mass-to-charge ratio and Detector System: For detecting the ions and
recording the relative abundance of each of the resolved ionic species. Charged
ions of various sizes are generated on the sample slide and MALDI is the
abbreviation for "Matrix Assisted Laser Desorption/Ionization.
Track 11: Chromatography
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.
Track 12: High Performance Liquid Chromatography (HPLC)
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. It is a very powerfultechnique 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 13: HyphenatedTechniques (LC-NMR-MS, HPLC-ESI-MS, MC-ICP-MS, HPLC-ICP-MS, UPLC-Q-TOF/MS)
A Hyphenated technique is combination or
coupling of two different analytical techniques with the help of proper
interface.Chromatography - Produces pure or nearly pure fractions of chemical
components in a mixture. Spectroscopy – Produces selective information for
identification using standards or library spectra. The hyphenated technique is
developed from the coupling of a separation technique and an online
spectroscopic detection technology. The number of existing techniques has been
combined to expand the utility.
Track 14: Mass spectrometry in environmental analysis
Liquid chromatography (LC) is becoming a
popular separation technique in environmental analysis. Most LC nowadays is
High Performance Liquid Chromatography (HPLC) which uses small particles packed
together at high pressure. While gas chromatography still remains popular in
environmental analysis, particularly for volatile and non-polar compounds, it
does not lend itself to analyzing compounds which are polar, non-volatile,
thermolabile or have a high molecular weight. For such compounds, LC is better.
LC-MS is the most popular
Track 15: Maintenance,Troubleshooting, Data Analysis and Experimentation in Mass Spectrometry
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 analysisprocesses. ms is beneficial in that it is generally fast, requires a small
amount of sample, and provides high accuracy measurements. 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.
Track 16: Proteomics
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.
Track 17: Mass Spectrometry in Proteome Research
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 18: Proteomics and its 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.
Track 19: Spectroscopy
Spectroscopy is the
study of the interaction between matter and electromagnetic radiation.
Historically, spectroscopyoriginated through the study of visible light
dispersed according to its wavelength, by a prism. Later the concept was
expanded greatly to include any interaction with radiative energy as a function
of its wavelength or frequency. Spectroscopic data is often represented by an
emission spectrum, a plot of the response of interest as a function of
wavelength or frequency.
Track 20: Mass Spectrometry in Metabolomics and Lipidomics
Data analysis for
metabolomics typically consists of feature extraction, statistical analysis,
compound identification and biological pathway analysis. The Thermo Scientific™
suite of metabolomics software products allows you to quickly transform complex
data into useful results. HRAM Orbitrap LC-MS is a widely adopted technique for
lipidomics analyses. Together with a comprehensive database and library that provides
accurate lipid identification, this technology enables relative as well as
absolute quantitation from biological samples. Mass spectrometry (MS) is a
central technology in Metabolomics due to its very high sensitivity and
selectivity. Combined with a separation step before the MS-detection (e.g. gas
chromatography (GC), liquid chromatography (LC), convergence chromatography
(UPC2), or capillary electrophoresis (CE)).
Track 21: Nuclear Magnetic Resonance (NMR) Spectroscopy
Nuclear Magnetic
Resonance (NMR) spectroscopy is an analytical chemistry technique used in
quality control and reserach for determining the content andpurity of a sample
as well as its molecular structure. For example, NMR can quantitatively analyze
mixtures containing known compounds. For unknown compounds, NMR can either be
used to match against spectral libraries or to infer the basic structure
directly. Once the basic structure is known, NMR can be used to determine
molecular conformation in solution as well as studying physical properties at
the molecular level such as conformational exchange, phase changes, solubility,
and diffusion. In order to achieve the desired results, a variety of NMR
techniques are available.
Track 22: Clinical application of mass spectrometry
Clinical laboratories
use the MS technology for disease screening, diagnosis of disease and metabolic
disorders, monitoring of drug therapy, identifying drug toxicity and poisoning,
and discovering new biomarkers. Therapeutic monitoring of immunosuppressant
drugs using MS is well established. Limitations of immunoassays such as
nonspecific binding of the antibody and cross-reactivity with metabolites that
often result in overestimation have made the more accurate LC/MS/MS
methodologies the assays of choice. LC/ MS/MS has become the standard for
assay of steroid hormones for diagnosis of endocrine disorders. Vitamin D
analysis by LC/MS/MS is widely used in the clinical laboratory today. Whereas immunoassays
are unable to distinguish between 25-hydroxy vitamins D2 and D3, the LC/MS
methodologies are able to measure these leves.
Market Analysis
Market Analysis Report of Mass Spectrometry :
On the basis of technology, the mass
spectrometry market is broadly segmented into single mass spectrometry, hybrid
mass spectrometry, and other mass spectrometry technologies (magnetic sector,
inductively coupled plasma mass spectrometry). In 2017, the hybrid mass
spectrometry segment is expected to account for the largest share of this
market. The extensive applications of hybrid mass spectrometers coupled with
the technological advancements in mass spectrometry are driving the growth of
this segment. Based on application, the mass spectrometry market is further
segmented into pharmaceutical application, biotech application, environmental
testing, food and beverage testing, petrochemical applications, and other
applications. In 2017, the pharmaceutical applications segment is expected to
account for the largest share. Extensive use of mass spectrometry technologies
at various stages of drug development processes and increase in R&D
investments by pharmaceutical industries are driving the growth of the market.
North America accounted for the largest share of the mass spectrometry market
in 2016, followed by Europe. High usage of mass spectrometry in the
pharmaceutical sector, growing funding to favour mass spectroometry market in
the US, high petrol and natural gas production, growing biopharmaceuticals and
biotechnology research & development and funding for innovation based
projects in Canada is expected to drive market during the forecast period. Factors
such as availability of funds for research, growing cosmetics industry in
Germany, growing food safety concerns and increased investments for
pharmaceuticals in the UK, favorable scenario of biotechnology and
pharmaceutical industry in Italy, company’s expansion in France and strong food
and beverage industry in Spain are driving factors of the European mass spectrometry market.

These are top suppliers of Mass Spectrometry:
Agilent Technologies
(US), Thermo Fisher Scientific (US), Waters Corporation (US), and SCIEX
(Subsidiary of Danaher) (US) are the key players in the mass spectrometry
market. Other players involved in this market are Bruker (US), PerkinElmer
(US), JEOL (Japan), Analytik Jena (Germany), Hiden Analytical (UK), Rigaku
(Japan), LECO (US), and DANI Instruments (Italy).

Markets provide
quantified B2B research on 30,000 high growth niche opportunities/threats which
will impact 70% to 80% of worldwide companies’ revenues. Currently servicing
5000 customers worldwide including 80% of global Fortune 1000 companies as
clients. Almost 75,000 top officers across eight industries worldwide
approach.The mass spectrometry community is probably the largest group of
scientists working around a single tool.
Mass spectrometry (MS), arguably the most important analytical
spectroscopic tool of modern times.
There is no single area of experimental science where mass spectroscopy
is not being used. There is no university or research institution in the
developed world without a mass spectrometer.
