NapFF is a small unique unnatural amino acid. It has a potential to act as a small molecule hydrogelator. This may leads to the formation of NapFF supramolecular hydrogels, a unique type of soft material that consist of water. Apart, from NapFF’s ability to form building blocks for supramolecular self-assembly it has also excellent biocompatibility. Owing, to these properties NapFF have attracted much attention in biochemistry for its application in drug release, inner cellular regulation and enzyme activity analysis. The above mentioned properties of NapFF can further be exploited for its application in tissue engineering, regenerative medicine and minimal invasive threapy. However, before its practical application in these fields there are number of challenges need to be met such as low concentration of cultivated cells with NapFF and liquid form in biocompatibility test, less than the gelation concentrations for three-dimensional (3D) tissue engineering. In this study, we have successfully encapsulated HeLa cells and human bone marrow mesenchymal stem cells (hBMSCs) in 3D supramolecular hydrogel of NapFF in vitro. Quantifying DNA contents and enzyme activities were evaluated by studying the cells proliferation rates, viability and protein expressions. In this study, 3D cells-encapsulating supramolecular hydrogel of NapFF has been fabricated successfully via cell suspensions containing CaCl2 supplement. The FTIR, CD spectra and SEM study, is applied successfully to study the interactions of Ca2+ with the carboxylic acid and amide groups of NapFF. This type of metal ion interaction, also contributes to the self-assembly of hydrogels which further affected the diameter of NapFF nanofibers. In the cell encapsulation experiments, hBMSCs showed better proliferation rate, viability and biodegradability in NapFF supramolecular hydrogel, as compared with HeLa cells. According to gelatin zymography, the matrix metalloproteinase-2 (MMP-2) activity of hBMSCs was approximately 10-fold higher than HeLa cells. We proposed that the difference between enzyme activities in cells have permitted the cell proliferation and NapFF degradation. All of these results indicate that NapFF equipped with the characteristic of cell-type specific 3D cultivation for hBMSCs. Further, to apply this study in 3D printing technique a NapFF supramolecular hydrogel, with a fluorescence molecule embedded on it was prepared. This was done to substitute growth factor in Ca2+-induced NapFF hydrogels, and the diffusion ability is studied. On the basis of these experiments, it is concluded that the diffusion of fluorescence molecule can be suppressed by medium containing CaCl2. The study can also be applied to establish cellular microenvironment, which will be suitable for stem cells proliferation and differentiation.