Based on the principles of tissue engineering, the strategy to regenerate the damaged pulp tissue by using dental-derived stem cells with proper biomaterials as scaffold becomes the most potential treatment model in vital pulp therapy. However, regeneration of functional dentin and pulp tissue with vascularization is still a big challenge. The biphasic hyaluronic acid gel, containing cross-linked hyaluronic acid (cHA) as the major component for the strength and stability and non-crosslinked HA (ncHA) as additive for releasing small HA fragments to modulate cell function, could present the injectability via proper degree of cross-linkage and particle sizes, which are beneficial for pulp regeneration. In this study, we developed a novel scaffold for pulp regeneration based on biphasic hyaluronic acid granules (biHAG) with long-term and static statin releasing to stimulate the mineralization proteins and angiogenesis factor via drug delivery system of lovastatin using PLGA as carrier. The 2% cross-linked hyaluronic acid granules (HAG) with particle size of 420 μm were prepared via the crosslinking agent of 1,4-butanediol diglycidyl ether (BDDE). biHAG were prepared by physical mixing 10% to 40% (wt%) of ncHA with HAG, then polylactic-co-glycolic acid nanoparticles with lovastatin (PLGA-Lova) were added to obtain the biHAG with PLGA-Lova (Lova@biHAG). The physical properties, drug release behavior and biocompatibility of the materials were further investigated. The results showed the residual BDDE in HAG fitted to the FDA regulation. The swelling ratio, fluid properties and injectability of biHAG increased significantly when the ratio of ncHA increasing. The addition of PLGA-Lova slightly enhanced their fluid properties but no significant effects on the general rheological properties. In addition, biHAG and Lova@biHAG could be injected through 25G needle, but HAG100 only could be easy injected through 23G needle due to less fluid properties. HAG and biHAG presented the honeycomb microstructure. Compared with HAG100, a fine network structure related to nHA were observed in biHAG. Lova@biHAG presented the same microstructure with biHAG except few PLGA-Lova particles were observed. Lovastatin release behavior of Lova@biHAG were similar to that of PLGA-Lova, but only 60% of lovastatin releasing were found in Lova@biHAG compared to PLGA-Lova. After co-culture with dental pulp stem cells (DPSC) for 1 day, similar cell morphology was observed in all groups, in which most cells presented spherical or hemispherical shape and some with spread-out morphology. Unlike intact cell surface found in HAG100 and biHAG, the cells with defects of small holes and depression were observed in Lova@biHAG, which may relate to excessive concentration of lovastatin detected in extract model. After co-culture for 5 days, the cell numbers increased significantly in all groups, indicating biHAG were suitable for DPSC cell growth. Using extract model, no significant differences in cell viability and cell death of DPSC were found among all groups, proving the good biocompatibility of materials. However, the potential cytotoxicity of Lova@biHAG to mineralizing rat pulpal cell-1 (MRPC-1) was found by showing over 60% cell death compared to that of control and biHAG. In summary, biHAG presented the proper fluid properties and good injectablility and biocompatibility, indicating their potential using in pulp regeneration. In addition, we established a protocol to mix biHAG with PLGA-Lova and obtain Lova@biHAG successfully. No detrimental effect of biHAG on lovastatin release behavior of PLGA-Lova was found. But, excessive releasing of lovastatin of Lova@biHAG caused the potential toxicity. The proper mixing ratio of PLGA-Lova to biHAG should be further investigated in the future to stimulate dentin regeneration and angiogenesis.