Enhanced neuronal differentiation of pheochromocytoma 12 cells on polydopamine-modified surface.

Since pheochromocytoma 12 (PC12) cells have the ability of neuronal differentiation upon nerve growth factor (NGF) treatment, they are a good model for studying the neuronal differentiation. Establishing a strong adhesion of PC12 cells to the culture substrate may increase neuronal differentiation, and the use of L-3,4-dihydroxyphenylalanine (L-DOPA), which is responsible for the adhesive property of mussel adhesive proteins (MAPs), is a feasible strategy for such strong adhesion. We hypothesized that a polydopamine-modified surface can promote PC12 cell adhesion and subsequent neuronal differentiation. We examined whether polydopamine-modified surface promotes PC12 cell adhesion, and further evaluated the neuronal differentiation of these cells. The polydopamine modification enhanced the cell adhesion and viability, and also promoted the neuronal differentiation of NGF-stimulated PC12 cells, as evidenced by the elongation of neurites and expression of neuronal differentiation markers, by increasing the activation of NGF/Trk-Rho GTPase signal pathway. Our findings will help develop an improved strategy for functionalizing biomaterial substrates for less-adhesive cells including neural cells.

Enhanced nerve growth factor efficiency in neural cell culture by immobilization on the culture substrate.

Nerve growth factor (NGF) immobilization on a culture substrate may dramatically reduce the amount of NGF required for pheochromocytoma (PC12) cell culture. Coverslips on which NGF had been immobilized, or with NGF added to the culture medium daily, were used to culture PC12 cells. We examined the effects of adding 5, 10, or 100 ng of NGF to cultures daily, and compared them to the effects of immobilizing 5, 10, or 100 ng of NGF on culture substrates in a single dose. Cultures with 10 or 5 ng NGF added daily showed dramatically decreased cell viability, mitochondrial metabolic activity, and neuronal differentiation compared to cultures with 100 ng NGF added daily, while also exhibiting increased apoptosis. In contrast, a single dose of 100 ng immobilized NGF yielded results similar to 100 ng NGF added daily (total: 300 ng over 3 days), and 10 or 5 ng immobilized NGF showed far better results than 10 or 5 ng NGF added daily. These results demonstrate that NGF immobilization can dramatically reduce the amount of NGF required in neuronal cell culture.

The effect of the controlled release of nerve growth factor from collagen gel on the efficiency of neural cell culture.

In this study, we tested the hypothesis that the amount of nerve growth factor (NGF) required for pheochromocytoma (PC12) cell culture can be dramatically reduced by controlled release of NGF from a collagen gel coating on the culture surface. Cells were cultured on collagen gels loaded with various amounts of NGF. As a control, PC12 cells were cultured on collagen gels with daily addition of various amounts of NGF to the culture medium. After an initial 12h burst, NGF was steadily released from the gels for 4 days. Apoptotic activity and cell viability were determined using terminal uridine nick end labeling and the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay, respectively. Neuronal differentiation was determined using immunocytochemistry and Western blot analysis. Compared to 100 ng NGF daily addition (300 ng over 3 days), 1 ng NGF daily addition showed dramatically decreased cell viability and neuronal differentiation and increased apoptotic activity. In contrast, collagen gels loaded with 10 ng NGF yielded cell viability, apoptotic activity, and neuronal differentiation similar to those of culture with 100 ng NGF daily addition. Our method reduced the amount of NGF required for PC12 cell culture to 1/3th of that used in daily addition without affecting cell viability, apoptosis, or differentiation. This method could economize large-scale culture of stem cells by reducing the amount of costly growth factors needed.

Controlled release of nerve growth factor from fibrin gel.

Nerve growth factor (NGF) is known to promote the axonal regeneration in injured nerve system. Delivery of NGF for a long period in a controlled manner may enhance the regeneration efficacy. In this study, we investigated whether NGF can be released from fibrin gel for a long period in a controlled manner. We also investigated whether sustained delivery of NGF using fibrin gel can enhance the efficacy of NGF in vitro. The addition of heparin to fibrin gel decreased the rate of NGF release from the fibrin gel. As the concentrations of thrombin and fibrinogen in fibrin gel increased, the NGF release rate decreased significantly, and the initial release burst decreased. NGF was released for up to 14 days in vitro. The bioactivity of NGF released from fibrin gel was assessed by morphological changes of pheochromocytoma (PC12) cells cultured in the presence of NGF-containing fibrin gel. NGF released from fibrin gel exhibited significantly higher degrees of PC12 cell viability and differentiation than NGF added in a free form daily into the culture medium. This study demonstrates that fibrin gel can release NGF in a sustained, controlled manner and in a bioactive form.