The ability to monitor the activity of specific cell types in vivo is critical for understanding the complex interplay between various neuronal populations driving freely moving behavior. Existing methods, such as optogenetic tagging (i.e., Optotagging 1 ), have proven useful for identifying cell types in in vivo electrophysiological recordings during freely moving behavior. However, electrophysiological recordings are limited in their capacity to track the same neuronal populations across long periods of time (days to weeks). Single-photon miniscope imaging offers the advantage of tracking the same cells across weeks to months; however, it is difficult to distinguish different cell types within the recorded population. Here, we present "chemotagging," a technique that allows for the identification of specific cell types in in vivo calcium imaging recordings. This protocol offers a method for tagging cell types with chemogenetic tools like Designer Receptors Exclusively Activated by Designer Drugs (DREADDs) 2 , while simultaneously recording calcium activity from a pan-neuronal population with calcium indicators. We highlight the key advantages and limitations of chemotagging and its potential implications for neuroscience research.