Fluorescent nanodiamond (FND) is a potent fluorescent probe possessing several unique properties such as　excellent biocompatibility, facile surface modification, high tissue-penetrable red fluorescence, and outstanding photostability. The neutral and negatively charged nitrogen-vacancy (NV0 and NV-) defect centers embedded in the　diamond lattice is responsible for the far red photon emission from this novel nanomaterial. FNDs are excellent biolabels and could be used to probe intricate biochemical processes. Fluorescence resonance energy transfer (FRET) has recently been widely introduced to study biomolecular configuration, enzyme kinetics and protein-protein interactions. Therefore, as a donor, with its perfect photostability, FND paves the way for a FND-based biosensor. In this thesis, we investigate the fluorescence spectra of 19-nm-sized FND conjugated with near-infrared dye (IRDye 800 CW) and demonstrate that it is possible to approach the FRET efficiency up to 30% between 23-nm-sized FND and dye molecules co-embedded in a poly-lysine matrix. We measured the changes in both fluorescence intensity and lifetime of FNDs before and after photobleaching of near-infrared dye. Moreover, according to Monte Carlo simulations, on an average, each FND transfers its energy to 10 dye molecules attached to its periphery. These results set the stage for FND-based single particle bio-labeling or molecular ruler with nanometric resolution.