Resources

Proteomics Databases



Metabolomics Databases

• • Selection of Antibodies: 10 Steps

  Antibodies possess the ability to specifically recognize antigens, enabling precise detection of the expression and function of target proteins. This is crucial for unraveling biological processes, understanding disease mechanisms, and advancing medical treatment and prevention. Selecting the correct antibodies ensures the accuracy and reliability of experimental results, providing strong support for scientific research and clinical applications.

• • Sequencing of Proteins, Peptides, and Antibodies in Biomedicine

  Protein, peptide, and antibody sequencing technologies play a crucial role in the field of biomedicine. These technologies not only provide researchers with the ability to gain a deep understanding of the structure and function of biomolecules but also offer powerful technical support for precision medicine, drug design optimization, as well as disease diagnosis and treatment.

• • Tandem MS for Amino Acid Sequencing

  Amino acid sequence analysis is an important part of protein structure analysis and has a profound impact on understanding protein function. In recent years, tandem mass spectrometry (MS/MS) has played a crucial role in the analysis of amino acid sequences, with its high sensitivity and accuracy making it the preferred method for amino acid sequence analysis.

• • Antibody Sequencing: Insights for Drug Design

  Antibody sequencing technology is an essential component of modern biotechnology and has made significant advancements in the field of antibody drug design in recent years. Through precise sequencing of antibodies, we can gain in-depth understanding of their structure and functional characteristics, thus providing important basis and inspiration for the design of antibody drugs.

• • Protein Modifications and Metabolome Study in Plant Stems

  Plant stems and veins are important organs in plants, responsible for nutrient and water transportation, as well as the foundation for plant growth and development. The post-translational modified protein groups and metabolome in plant stems and veins are important tools for studying their functions.

• • Plant Root System IEF-Based Protein Isoelectric Point Analysis

  Plant root systems are the main sites for interaction with the soil, where proteins play a key role in regulating plant growth, nutrient absorption, and response to environmental stress. Through IEF technology, researchers can isolate proteins in root samples, and then identify them with other techniques (such as mass spectrometry) to understand their functions.

• • Rotein Content Determination in Rat Cells by Colorimetry

  In the process of biomedical research and drug development, the determination of protein content is a fundamental and crucial experimental technique. It not only helps researchers understand the expression levels of proteins inside and outside cells but also evaluates the efficiency of protein purification and the impact of drugs on protein expression.

• • Analysis of Metal Content in Human Cells

  Metal elements, including iron, zinc, copper, magnesium, and calcium, are crucial for maintaining cellular function and health. These elements play roles in many biochemical processes, including but not limited to enzyme activity regulation, signal transduction, gene expression regulation, and serving as structural components of cells. Therefore, understanding the content and distribution of metal elements within cells is highly important for uncovering their roles in cellular physiology and pathology.

• • Tomato Fruit Tandem Mass Spectrometry Peptide Sequencing

  Tomatoes, as one of the vegetables with the largest cultivation area and highest consumption in the world, not only have a delicious taste but also contain abundant nutrients and bioactive substances. Behind all of this, it is closely related to the expression, modification, and interaction of proteins and peptides in tomato fruits.

• • Single Cell MS Flow Cytometry Analysis of Mouse Cells

  The rapid development of single-cell technology in the field of life sciences has greatly contributed to the understanding of biological system complexity. As a cutting-edge technology in this field, Single-Cell Mass Cytometry (SCMC) provides unprecedented depth and detail for cellular-level biological research through its unique analytical capabilities.