The primary aim of this research was to develop a reliable and efficient approach for isolating neutrophil extracellular traps (NETs) from rat bone marrow. This effort arose due to limitations associated with the traditional method of extracting NETs from peripheral blood, mainly due to the scarcity of available neutrophils for isolation. The study revealed two distinct methodologies for obtaining rat neutrophils from bone marrow: a streamlined one-step procedure that yielded satisfactory purification levels, and a more time-intensive two-step process that exhibited enhanced purification efficiency. Importantly, both techniques yielded a substantial quantity of viable neutrophils, ranging between 50 to 100 million per rat. This efficiency mirrored the results obtained from isolating neutrophils from both human and murine sources. Significantly, neutrophils derived from rat bone marrow exhibited comparable abilities to secrete NETs when compared with neutrophils obtained from peripheral blood. However, the bone marrow-based method consistently produced notably larger quantities of both neutrophils and NETs. This approach demonstrated the potential to obtain significantly greater amounts of these cellular components for further downstream applications. Notably, these isolated NETs and neutrophils hold promise for a range of applications, spanning the realms of inflammation, infection, and autoimmune diseases.