Resources
Proteomics Databases
Metabolomics Databases
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• Workflow of KEGG Pathway Annotation and Enrichment Analysis
The Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analysis is a widely-used tool in modern biological research, particularly in fields such as genomics, transcriptomics, and metabolomics. The KEGG database aggregates extensive information on genes, compounds, reactions, and their interactions, facilitating the biological annotation of omics data and providing insight into gene function relationships within networks.
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• Principle of KEGG Pathway Annotation and Enrichment Analysis
In bioinformatics and systems biology, the Kyoto Encyclopedia of Genes and Genomes (KEGG) database is a major resource for the systematic study of biomolecular functions. The KEGG database contains extensive information on metabolic and signaling pathways, making it an essential tool for understanding molecular networks and gene functions.
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• The Role of Primary Structure in the Immunogenicity of Biopharmaceuticals
Biological products are drugs or other biological preparations manufactured using biotechnology, widely used in disease treatment and health improvement. The primary structure plays a crucial role in the immunogenicity research of biological products. The primary structure refers to the amino acid sequence of proteins or polypeptides in biological products, which determines the structure and function of the biological products.
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• iTRAQ Quantitative Proteomics
iTRAQ (Isobaric Tags for Relative and Absolute Quantitation) is an isotope tagging technology for relative and absolute quantitation, extensively used in proteomics research. iTRAQ technology marks proteins or peptides to achieve protein quantification analysis, thereby revealing the dynamic changes of proteins in biological processes. The core of iTRAQ technology is to use isotope labeling reagents to label protein samples. These labeling reagents consist of two parts: the balance region and the re......
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• Optimizing Mass Spectrometry Quantification Techniques for Protein
The technology of mass spectrometry detection of proteins has penetrated into the fields of biomedical, food detection, pharmaceutical analysis, etc., such as the analysis of protein content in drugs, or the discovery of disease biomarkers. However, the accuracy and efficiency of this method are still limited by many factors, such as sample processing, matrix effects, etc. Next, let's break down each step and delve into how to optimize the quantitative techniques for mass spectrometry detection of pro......
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• LC-MS Proteomics Technical Points From Sample Preparation to Data Analysis
In the field of biological sciences, the study of proteomics has become an important means to explore the complexity of biological systems. Liquid Chromatography-Mass Spectrometry (LC-MS) is one of the core technologies of proteomics. Sample Preparation Sample preparation is a critically important step in LC-MS proteomics, as it directly relates to the accuracy and reliability of subsequent analyses. High-quality sample preparation requires meticulous design and operation.
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Immunoprecipitation is an important experimental technique used in the field of biopharmaceuticals to study protein interactions. In this process, antibodies bind specifically to target proteins, and the complexes are then separated by precipitation techniques for further analysis. However, due to the complexity and specificity of the samples, immunoprecipitation experiments may face challenges such as low purity and non-specificity.
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• Glycosylation Modification Omics Analysis From Qualitative to Quantitative
Protein is one of the most important functional molecules in cells, and studying protein modification is of great significance for a deeper understanding of its biological function. Among them, glycosylation modification, as a common and important way of protein modification, has attracted much attention from researchers. Glycomics is a systematic method for studying protein glycosylation modification. Through this method, we can fully understand the types, locations, and quantities of glycosylation m......
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• Optimizing Sample Preparation Steps for Label-Free Semi-Quantitative Chemical Proteomics
Label-free semi-quantitative proteomics is an important proteomics method that can quantitatively analyze the differential expression of proteins in cells or tissues. In this process, sample preparation is a key factor affecting the accuracy of the results. Optimizing sample preparation steps can maximize the reliability and repeatability of experiments. Sample Pretreatment In label-free semi-quantitative proteomics, sample pre-treatment is the first step to consider.
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• The Importance and Application of P-value Adjustment in Differential Analysis of Proteomics
Proteomics is a scientific field that studies the complete set of proteins, their structures, and functions in organisms. In proteomics research, differential analysis is a critical step that helps us identify the differences in protein expression between different samples. The p-value is a commonly used statistical indicator in differential analysis, which can evaluate whether the observed difference is statistically significant.
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