Lipidomics is a rapidly expanding research field in which multiple techniques are utilized to quantitate the hundreds of chemically distinct lipids in cells and determine the molecular mechanisms through which they facilitate cellular function. Recent developments in electrospray ionization mass spectrometry (ESI/MS) have made possible, for the first time, the precise identification and quantification of alterations in a cell's lipidome after cellular perturbations. This review provides an overview of the essential role of ESI/MS in lipidomics, presents a broad strategy applicable for the generation of lipidomes directly from cellular extracts of biological samples by ESI/MS, and summarizes salient examples of strategies utilized to conquer the lipidome in physiologic signaling as well as pathophysiologically relevant disease states. Because of its unparalleled sensitivity, specificity, and efficiency, ESI/MS has provided a critical bridge to generate highly accurate data that fingerprint cellular lipidomes to facilitate insight into the functional role of subcellular membrane compartments and microdomains in mammalian cells. We believe that ESI/MS-facilitated lipidomics has now opened a critical door that will greatly increase our understanding of human disease. -Han, X., and R. W. Gross. Lipidomics is a rapidly expanding research field fueled by recent advances in, and novel applications of, electrospray ionization mass spectrometry (ESI/MS). Lipidomics is focused on identifying alterations in lipid metabolism and lipid-mediated signaling processes that regulate cellular homeostasis during health and disease. Research in lipidomics incorporates multiple techniques to quantify the precise chemical constituents in a cell's lipidome, identify their cellular organization (subcellular membrane compartments and domains), delineate the biochemical mechanisms through which lipids interact with each other and with crucial membrane-associated proteins, determine lipid-lipid and lipid-protein conformational space and dynamics, and quantify alterations in lipid constituents after cellular perturbations. Through the detailed quantification of a cell's lipidome (e.g., lipid classes, subclasses, and individual molecular species), the kinetics of lipid metabolism, and the interactions of lipids with cellular proteins, lipidomics has already provided new insights into health and disease. The true power and promise of lipidomics, however, is only beginning to be realized.Decades of painstaking research in the 1970s and 1980s developed a straight and reversed-phase HPLC system that could "rapidly" (30 min) separate phospholipid classes, molecular species, and regioisomers into individual chemical constituents (1-6). These techniques, however, were labor intensive and required sensitive separation methods for which quantitation was difficult, because the → * transition during UV detection was not strictly proportional to mass content (7). Moreover, these procedures could not meet the needs for the application of lipidomi...
