Resources

Proteomics Databases



Metabolomics Databases

• • Quantification of Free Sulfhydryl Groups in Rat Cells

  Quantitative analysis of free thiol groups in rat cells is an important research direction in the fields of cell biology and molecular biology, especially in studying biological processes such as oxidative stress, signal transduction, and cell death. Free thiol groups, particularly reduced glutathione (GSH) and protein thiols (-SH), play a crucial role in maintaining the redox balance within cells.

• • Blood Vessel Tissue Metabolic Flux Analysis

  The analysis of metabolic flux in blood vessel tissue is particularly important in contemporary biomedical research. This analysis not only helps in understanding the complex mechanisms of vascular health and disease but also has significant implications for the prevention, diagnosis, and treatment of cardiovascular diseases. MtoZ Biolabs utilizes cutting-edge metabolomics technology to provide in-depth and comprehensive solutions for the analysis of metabolic flux in blood vessel tissue.

• • Single-Cell Mass Cytometry Analysis of Kidney Tissue

  The health and function of kidney tissue is a crucial sign of overall health in the human body. In recent years, the development of Single-cell Mass Cytometry technology has provided a new perspective for the study of kidney diseases. MtoZ Biolabs uses this advanced technology to provide accurate and in-depth insights for single-cell level analysis of kidney tissue.

• • Analysis of Substances Related to ATP Metabolism in Brain Tissue

  The health and function of brain tissue are directly influenced by its energy metabolism status, in which ATP (adenosine triphosphate) plays a crucial role as the main energy molecule and is involved in neural signal transmission, cellular repair, and overall brain tissue health. Therefore, in-depth analysis of ATP and related metabolites in brain tissue is of great significance for understanding brain function, disease mechanisms, and developing therapeutic strategies.

• • Serum Protein Full Spectrum Analysis

  Serum, the vital fluid that flows within every person's body, contains a wealth of protein information. These proteins not only directly participate in life activities, but also play a crucial role in the occurrence, development, and treatment of diseases. Serum proteome analysis, which comprehensively identifies and quantifies all proteins in a serum sample, provides a powerful tool for disease diagnosis, biomarker discovery, and drug development.

• • Lipidomics MALDI Imaging of Escherichia Coli

  Escherichia coli (E. coli) is a common bacterium widely distributed in nature and belongs to Gram-negative bacteria. In the fields of modern microbiology and biotechnology, precise analysis of the lipid composition of E. coli is particularly important. MALDI imaging technology combines the high sensitivity of MALDI mass spectrometry with the spatial resolution of imaging technology, which can directly observe and analyze the distribution of lipid molecules at the cellular and even tissue levels.

• • Molecular Weight and Isoelectric Point Analysis of Proteins

  Molecular Weight Analysis 1. SDS-PAGE (Sodium Dodecyl Sulfate-PolyAcrylamide Gel Electrophoresis): SDS-PAGE is a commonly used method for determining protein molecular weight. By conducting electrophoresis in a gel containing SDS (sodium dodecyl sulfate), proteins separate according to their molecular weight. After electrophoresis, proteins can be visualized through staining, and by comparison with standard proteins of known molecular weight, the molecular weight of sample proteins can be estimated.

• • Peptide Circular Dichroism Spectroscopy

  Peptide Circular Dichroism (CD) is a powerful spectroscopic technique primarily used for studying the secondary structure of peptides and proteins. It is based on a simple principle: when optically active substances such as peptides absorb circularly polarized light, specific spectral signals are generated. These signals can reveal structural features of proteins and peptides, such as α-helices, β-folded structures, and random coil structures.

• • Organic Acids in Cardiac Tissue

  The analysis of organic acids in cardiac tissue is crucial in the study of cardiac physiology and pathology. Organic acids are not only key intermediates in cardiac metabolism, but also play important roles in regulating energy supply, pH balance, and electrolyte balance in cardiac muscle cells. Therefore, a detailed analysis of organic acids in cardiac tissue is of great value in understanding cardiac function, diagnosing cardiac diseases, and developing new treatment strategies.

• • 4D Label-Free Proteomics Technology and Applications

  4D label-free proteomics is an advanced protein analysis method that combines Data Independent Acquisition (DIA) and label-free quantification strategies. This technique allows for the systematic analysis of protein expression changes in biological samples without the use of chemical labels. Due to its efficiency and accuracy, 4D label-free proteomics has widespread applications in biomedical research, biomarker identification, and drug development.