MicroRNAs are short RNA molecules composed of 20-22 nucleotides. They highly accurately indicate cell identity and hence they are useful in labeling cells and tacking lineage commitment. However, this requires accurate microRNA profiling of cells in individual developmental stages. Since microRNAs are important negative regulators of eukaryotic gene expression, microRNA profiling allows better understanding of molecular regulatory networks of important cellular events, such as adult neurogenesis. Adult neurogenesis is the process in which neurons, as well as glia, are generated from neural stem cells. It was found to be responsible for brain regeneration, olfactory discrimination, memory formation and learning. Depression was suggested to be related to dysregulation of neurogenesis. Thus, knowledge in cellular and molecular mechanisms of adult neurogenesis will lay solid foundation to develop therapies to regenerate neural cells after injuries or onsets of neurodegenerative diseases and to understand the cognitive ability, memory formation and learning of the brain. In spite of its importance, investigation into the miRNA profiles and functions in neurogenesis is still infant. This project aimed to establish a preliminary microRNA profile on neurogenesis. Although this was not completed, the project could be extended to a large-scale microRNA profiling in neurogenesis. This would enable future workers to track the lineage commitment, the migration, and the distribution of NSCs and their derived cells accurately by in situ hybridization. Also, the future workers may construct a 2D representation of the changes in miRNA profiles and this may lead to discovery of previously unknown molecular and cellular differences among cells of same cell identity.