Growth factors are important in regulating cellular functions, including cell signaling, proliferation, migration and differentiation. However, growth factors in body niche may be rapidly degraded or otherwise rendered inactive before reaching their target, and biomaterial systems designed to deliver growth factors for tissue repaired are therefore often ineffective and costly. Large amounts of growth factors are frequently needed to effect cellular outcomes, although such large quantities has the risk to damage cells and tissues. The method of immobilization of growth factors to biomaterial substrates has emerged as a way to improve the stability and persistence of growth factor delivered to cells or tissues, and even be more advance to enable the dynamic control chemical properties over material surface. In this study we designed the material surface with cleavable binding site to immobilized osteo-inductive growth factor, and cleave it to remove the growth factor. The outcome of osteogenesis related mRNA and phosphate calcium deposition will be done. BMPs play important roles in bone and cartilage regeneration. Among BMPs, BMP-2 has very strong osteo-induction activity. Previous studies have shown that BMP-2 can enhance the osteogenesis of mesenchymal stem cells (MSCs), and de novo orthotopic or ectopic bone formation. In this study we established the bone marrow derived MSCs from SD rats. MSCs were negatively selected by CD11b and CD45 antibody. The expression of CD29, CD90, CD11b, CD45, CD34, CD31 and CD86 on bone marrow derived MSCs was characterized using flow cytometry. Their ability to differentiate into adipocytes, chondrocytes, osteoblast, and colony formation were also proved. Additionally, we modified the surface of culture dishes with vapor-based synthesis parylene A. Then Immobilized with rhBMP-2. The results of Infrared reflection-absorption spectroscopy (IRRAS) and quartz crystal microbalancing (QCM) assay proved that rhBMP-2 is binding on the surface. Alizarin red staining and mRNA expression of alkaline phosphotase (ALP) show significantly higher (p<0.05) than control while MSCs were differentiated on it for 14 days. Furthermore, we modified the parylene A with disulfide bond (parylene S-S). Try to modulate the cells differentiation via redox thiol−disulfide interchange reaction with 10mM Glutathione (GSH) treatment. CCK-8-assay and alizarin red staining reveal that GSH treatment has no significant effect on cell viability and differentiated performance. In the experiment we separately treat GSH on day0, day4, day8, day12 in differentiation process to break the disulfide bond then replace differentiation medium to eliminate released rhBMP-2. The result of qPCR assay shows that the mRNA expression of ALP were getting higher from day0 to control, reveal that the differentiation level were affected by the treatment. This cleavable mechanism for attaching/detaching biomolecules has the potential to install growth factor on material surface and cleave it when deactivation is required.