Most bacteria in natural habitats live as biofilms, in which bacterial cells are embedded in matrices of extracellular polymeric substances adherent to a surface. Recent studies have revealed that the biofilm mode of living increases the survival rate of bacteria by e.g., acquiring extremely high antibiotic resistance. Although unique structures and functions of biofilms have attracted much attention in many disciplines of science, it remains challenging to study biofilms in vivo and in situ as well as with high chemical specificity. In the present study, we focus on the biofilms of the bacterial species of practical interest known as Rhodococcus sp. SD-74 and monitor the process of its biofilm development using Raman microspectroscopy and imaging. Because Raman spectroscopy is nondestructive and label-free, and is less hampered by the presence of water, Raman microspectroscopy and imaging are an ideal tool to study biofilms in situ. We successfully obtained detailed distribution and composition changes within R. sp. SD-74 biofilm during the development process. We found that the concentration of carotenoids in the biofilm matrix drastically increases as biofilm development proceeds. To interpret this phenomenon of carotenoid accumulation, we hypothesize that carotenoids act as an antioxidant in R. sp. SD-74 biofilms and counter possible oxidative stress. Raman imaging experiments performed under different light-illumination conditions support this hypothesis.