The analysis of impurities in drugs is a very important part. This paper focuses on the important role of the source analysis of impurities and focuses on the development of analytical techniques in the process of impurity research, especially the development of mass spectrometry technology in structure identification. Source analysis of impurities Impurities in a drug can arise from manufacturing as well as distribution. According to ICH guidelines, drug impurities can be divided into organic impurities, inorganic impurities, residual solvents, and other impurities. The concept of "Quality by Design (QbD)" is introduced in the study of drug impurities, which can initially delineate the impurity spectrum of the product according to the synthesis mechanism of the specific process, the starting material, and the basic structure of each intermediate before drug production. Source analysis of impurities is the basis for formulating drug impurity control strategies, especially for the source analysis of toxic impurities. The reagents, intermediates, and by-products in all synthesis and production processes should be analyzed, and the potential impurities that may be produced and the actual impurities should be analyzed. After the synthesis of API, although the active compound of the drug does not contain the "alerting structure" after toxicity analysis, the genotoxicity of the compound containing the warning structure should be considered in the production process. Methods for studying impurities In the process of drug development, the analysis of drug impurities is key. Therefore, in impurity research, a clear idea of impurity structure and appropriate impurity analysis techniques can greatly shorten the time of impurity research and promote the rapid development of drug research. 1. Impurity pretreatment technology The pretreatment of impurities is accompanied by the pretreatment of pharmaceutical active ingredients. However, the content of impurities in drugs is low and their structure is quite different from that of principal components. Therefore, the conventional pretreatment and detection methods of pharmaceutical active ingredients (such as HPLC-UV analysis directly after the initial mobile phase is dissolved) are not necessarily suitable for drug impurities. Different pretreatment techniques should be selected for different samples. (1)Detecting samples with low sensitivity The pretreatment of derivatization is usually used for the samples with low sensitivity, such as the introduction of chromophores to produce UV response, or the addition of ionizable groups to increase the ionization efficiency. (2) Low-concentration impurities The selection of pretreatment methods for low-concentration impurities is determined by the type of impurities, such as forced degradation of degradation products to increase the concentration of degradation products, etc. However, conventional degradation methods often introduce other impurities, which will interfere with the impurity spectrum study of special impurities. (3) Samples that are easy to contaminate the instrument Different instruments have different conditions of use, so the pre-treatment of complex samples can prolong the service life of the instrument. For example, the mobile phase containing non-volatile salts cannot be used in the mass spectrometer detector, so the two-dimensional liquid chromatography technology can be used to separate the peaks in the first dimension and retain the sample into the sample ring when the LC-MS conditions are established. The second liquid phase uses an MS-acceptable mobile phase and a desalting column to elute the sample from the sample ring to "desalt" the analyte to protect the MS spectrum. 2. Impurity separation technology The content of impurities in drugs is low, and the qualitative and quantitative analysis of impurities cannot be achieved by direct determination. Therefore, the impurity should be separated to obtain a single component of the impurity, to achieve the detection of the impurity. In recent years, liquid chromatography and supercritical fluid technology have developed rapidly.