Induced pluripotent stem cell (iPSC) possesses high potentials in regeneration medicine. It has been used in several applications such as disease mechanism study, drug development, stem cell therapy, and tissue engineering. Because of the problem of ethical controversy which hinders the development of embryonic stem cell research, iPSC is a better platform for the stem cell research. The first generation of iPSC is generated from somatic cells by virus infection. Therefore, the safety issue should be concerned because of the possibility of gene mutation and carcinogenesis. To solve this problem, there has been different ways to generate iPSC. One of them is the protein-based method. The research in protein delivery with efficiency and safety is still under development. Comparing to the traditional dosage form, drug delivery system has many advantages such as drug protection, the improvement of half-life, controlling release, and active targeting. The nanoparticle is one of drug delivery system, which is reported to enhance the efficiency in protein delivery. In this study, I try to force express Yamanaka factors in Hs68 by protein-based reprogramming proteins (RPs) delivery with Gelatin-PEI nanoparticle to generate the absolutely safe iPSC. First, Gelatin-PEI nanoparticles were produced. The average diameter of them was about 100 nm, and the zeta potential on the surface was +43.2. The MTT assay showed that Gelatin-PEI nanoparticles are safe with the acceptable cytotoxicity. In the experiment of BSA binding assay, Gelatin-PEI nanoparticles could bind with BSA, and the highest efficiency was achieved when the wt/wt equal to 1. For the functional test after delivery, eGFP was cloned and expressed in E.coli system, and then it was purified by Ni-NTA spin column. The last, in the experiment of eGFP delivery into Hs68 cell line, Gelatin-PEI nanoparticle was capable of carrying eGFP, internalizing to Hs68, and helping it escape from endosome. These data indicated Gelatin-PEI nanoparticle is a high potential Nanocarrier in protein delivery. Next, RPs was cloned and expressed in BL21. BL21 StarTM (DE3) strain was used to express RPs with relative high expression level. The small RNA sequence was produced and identified to guide RPs to activate the Nanog-luc gene expression. Further functional tests of RPs delivery system should be evaluated in the future. Overall, I expect to develop a new method to generate iPSC for clinical application.