Accurate and precise localization of intracellular nucleic acids is crucial for regulating genetic information transcription and diagnosing diseases. Although intracellular nucleic acid imaging methods are available for various cell types, their widespread utilization is impeded by the intricate nature of the process and its exorbitant cost. Recently, numerous intracellular nucleic acid labeling techniques based on clustered regularly interspaced short palindromic repeats (CRISPR) have been established due to their modularity, flexibility, and specificity. In this work, we present various CRISPR methods that are currently employed for visualizing intracellular genomic sequences and RNA, based on their detection principles and application scenarios. Furthermore, we discuss the advantages and drawbacks of the existing CRISPR imaging methods, as well as future research directions. We anticipate that with continued refinement, more advanced CRISPR‐based imaging techniques can be developed to better elucidate the localization and dynamics of intracellular nucleic acids, thereby providing a powerful tool for molecular biology research and clinical molecular pathology diagnosis.