Erythropoietin (EPO), a well-known hematopoietic cytokine, recently has been found with neuroprotection effect and is considered as a potential therapeutic candidate for neurological diseases. Although delivery of short-term high-dose EPO seemed to improve patients’ neuromuscular functions, yet excessive EPO resulted in systematically high hematocrit and increased thrombotic risks. Therefore, new therapeutic strategy of regionally-provided EPO for neurological diseases at non-toxic level needed to be designed. In our study, we aimed to (1) establish an EPO-overexpressed NIH/3T3 fibroblast cell line, EPO-3T3-EGFP, and (2) verify its possible neuroprotection ability. Mouse EPO cDNA was subcloned into pCMS-EGFP vector and transfected into NIH/3T3 cells. After G418 stable clone selection, a stable EPO-overexpressed EPO-3T3-EGFP cell line was established. The expression of EPO was analyzed by reverse-transcriptase PCR, (RT-PCR), quantitative real-time PCR (Q-PCR), immunocytochemistry, Western blot and ELISA. We found that EPO mRNA expression level was elevated in EPO-3T3-EGFP cells analyzed by RT-PCR and Q-PCR. More EPO product from EPO-3T3-EGFP cells was demonstrated by immunocytochemical data and Western assays. We also found abundant amount of the secreted EPO from EPO-3T3-EGFP cells by ELISA analysis. In order to further confirm the neuroprotection ability of secreted EPO, a cell model of neurodegeneration, PC12-INT-EGFP cells, was used. Previous study showed that abnormal cytoskeletal aggregation and neuronal cell death could be observed after nerve growth factor (NGF) induction for PC12 cells with the overexpression of neuronal intermediate filament α-internexin. After supplementation with conditioned medium prepared from EPO-3T3-EGFP cells, cell survival rate was significantly increased in PC12-INT-EGFP cells. We found that some aggregated green fluorescent α-INT-EGFP (overexpressed-α-internexin with EGFP-tagged) of PC12-INT-EGFP cells was disaggregated and transported into neurite dynamically. Subsequently, acceleration of neurite outgrowth in PC12-INT-EGFP cells was also found during 24-48 hour treatment. Our immunostaining results also showed that the distribution of NF-M (neurofilament medium polypeptide), phosphorylated-NF-M and α-INT-EGFP in PC12-INT-EGFP cells were less aggregated in the perikaryal region and transported into neurite after supplied with conditioned medium from EPO-3T3-EGFP cells. In conclusion, our results showed effective neuroprotection of secreted EPO by the established EPO-overexpressed NIH/3T3 cell line which could provide a potential material for future in vivo studying on cell-based therapies for neurological diseases via secreting EPO on a short-term, high-dose and regional basis.