Metabolomics, the latest omics science, has been used to explore biomarkers of external stimuli and applied on a variety of fields. The variations in metabolomics, which might come from either biological samples or instrumental operations, usually lead to biased results and incorrect interpretations are not yet solved. In this dissertation, we will discuss some approaches to improve metabolomics data quality and lower these types of variation for more extensive applications by using sample normalization method and differential labeling approach to minimize biological variation and instrumental variations, respectively. We first reported a matrix-induced ion suppression (MIIS)-based method to normalize concentrations using flow injection analysis coupled with electrospray ionization mass spectrometry (FIA-ESI-MS) and applied it to investigate urinary metabolomics and cellular metabolomics. An ion suppression indicator (ISI) was spiked into the sample matrix, and the intensity of the extracted ion chromatogram (EIC) for ISI in a sample matrix was subtracted by EIC for a blank solution and used to calculate the extent to which the signal was reduced by the matrix. A serial dilution of pooled urine samples or reference cell extracts was used to correlate the concentration and level of ion suppression for ISI. A regression equation was used to estimate the relative concentration of unknown samples. The MIIS method was validated for linearity, precision and accuracy. This study demonstrated that the MIIS method is simple, accurate and can contribute to data integrity in urinary and cellular metabolomics studies and reduce biological variations in metabolomics. Differential labeling techniques could provide more informative results and reduce the number of sample injection that decrease the probability of MS source contamination and decline the instrumental variations. We took the analysis of fatty acids as a demonstration case for differential labeling. The analytical platform of fatty acid analysis mainly relies on complicated chemical derivatization with GC-MS. We developed an effective and accurate comparative fatty acid analysis method using differential labeling of D0- and D3- fatty acid methyl ester (FAMEs) to speed up the metabolic profiling of fatty acids in case-control studies. Consequently, for time-course experiments, we also developed a differential labeling on D0-, D3-, D5- isotopes of fatty acid ethyl ester (iFAEEs). In this part, the differential labeling of fatty acid profiling technique was determined to be fast and accurate and allowed the discovery of potential fatty acid biomarkers in a more economical and efficient manner. The approach was applied to the study of drug-induced hepatotoxicity, which revealed a potential toxicity mechanism and the possibility of using fatty acids as surrogate toxicity markers for drug induced liver injury. Conclusively, sample normalization by the MIIS method could greatly decline the biological variations caused metabolomic analytical bias. Differential labeling introduces sharing of the same matrix which could reduce variations contributed by instrument analysis and greatly reduce analytical time. We anticipate that the developed methods could improve data integrity for various metabolomics studies.