Wei-Wen Hu

Electrical stimulation to promote osteogenesis using conductive polypyrrole films

In this study, we developed an electrical cell culture and monitoring device. Polypyrrole (PPy) films with different resistances were fabricated as conductive surfaces to investigate the effect of substrate-mediated electrical stimulation. The physical and chemical properties of the devices, as well as their biocompatibilities, were thoroughly evaluated. These PPy films had a dark but transparent appearance, on which the surface cells could be easily observed. After treating with the osteogenic medium, rat bone marrow stromal cells cultured on the PPy films differentiated into osteoblasts. The cells grown on the PPy films had up-regulated osteogenic markers, and an alkaline phosphatase activity assay showed that the PPy films accelerated cell differentiation. Alizarin red staining and calcium analysis suggested that the PPy films promoted osteogenesis. Finally, PPy films were subjected to a constant electric field to elucidate the effect of electrical stimulation on osteogenesis. Compared with the untreated group, electrical stimulation improved calcium deposition in the extracellular matrix. Furthermore, PPy films with lower resistances allowed larger currents to stimulate the surface cells, which resulted in higher levels of mineralization. Overall, these results indicated that this system exhibited superior electroactivity with controllable electrical resistance and that it can be coated directly to produce medical devices with a transparent appearance, which should be beneficial for research on electrical stimulation for tissue regeneration.

Use of biotinylated chitosan for substrate-mediated gene delivery.

To improve transfection efficiency of nonviral vectors, biotinylated chitosan was applied to complex with DNA in different N/P ratios. The morphologies and the sizes of formed nanoparticles were suitable for cell uptake. The biotinylation decreased the surface charges of nanoparticles and hence reduced the cytotoxicity. The loading capacities of chitosan were slightly decreased with the increase of biotinylation, but most of the DNA molecules were still complexed. Using different avidin-coated surfaces, the interaction between biotinylated nanoparticles to the substrate may be manipulated. The in vitro transfection results demonstrated that biotinylated nanoparticles may be bound to avidin coated surfaces, and the transfection efficiencies were thus increased. Through regulating the N/P ratio, biotinylation levels, and surface avidin, the gene delivery can be optimized. Compared to the nonmodified chitosan, biotinylated nanoparticles on biomaterial surfaces can increase their chances to contact adhered cells. This spatially controlled gene delivery improved the gene transfer efficiency of nonviral vectors and could be broadly applied to different biomaterial scaffolds for tissue engineering applications.

The regulation of DNA adsorption and release through chitosan multilayers.

To sustain transgene expression, chitosan was studied to immobilize DNA using layer-by-layer assembly to form polyelectrolyte multilayers (PEMs). Higher DNA concentrations and longer deposition periods demonstrated more DNA adsorptions to PEMs. By adjusting pH and the molecular weight of chitosan, PEM structures were manipulated. Chitosan molecules adsorption to PEMs increased when they were at pH 6 because of their low protonation. Furthermore, the configuration of chitosan favored a coiled-form when the pH was high, as the intramolecular repulsion decreased. Therefore, interdiffusion of polyelectrolytes in PEMs was promoted to increase DNA adsorption, especially for chitosan with high molecular weight. For the release experiments, because PEMs fabricated by lower pH chitosan owned less chitosan molecules, DNA release was enhanced. However, this phenomenon did not happen to chitosan with high molecular weight, which should be due to the entanglement between polymer chains. This comprehensive approach should be beneficial to substrate-mediated gene delivery applications.

The control of cell orientation using biodegradable alginate fibers fabricated by near-field electrospinning

For spatially controlling cell alignment, near field electrospinning (NFES) was developed to direct-write alginate fiber patterns. Compared to randomly electrospun fibers, NFES fibers guided the extension of HEK 293T cells and the levels of cell alignment increased with decreasing fiber distances. However, these guiding fibers were unfavorable for cell adhesion and limited cell growth. To preserve cell alignment ability and improve biocompatibility, the stability of patterned alginate fibers was adjusted by regulating the level of ion crosslinking. These partially crosslinked NFES fibers demonstrated parallel line-patterns in the initial stage while gradually degraded with time. The reduction of fiber density increased the available area for cell growth and enhanced cell viability. On the other hand, aligned cells were still found on these degraded patterns, suggesting that cell morphologies were mainly guided during cell seeding. This dynamically controlled fiber pattern system fulfilled the need of controlling cell orientation and biocompatibility, thus was potential to modify scaffold surfaces for tissue engineering application.

A novel application of indolicidin for gene delivery.

A bovine derived antimicrobial peptide, indolicidin (IL), was studied of its new application for gene transfer. Plasmid DNA was complexed with both IL and polyethylenimine (PEI) as ternary particles. Compared to DNA/IL complexes, the DNA/IL/PEI particles demonstrated high zeta potentials, small particle sizes, and superior loading efficiencies, suggesting the incorporation of polycations can support IL for gene delivery. For in vitro experiments, these ternary particles significantly improved gene transfection efficiencies over the sole administrations of IL or PEI. This synergistic effect revealed that IL and PEI may play different roles for gene transfer. Our results suggest that IL should be a potential carrier for gene delivery. As our knowledge, our study should be the first article indicating the carrier ability of IL for gene transfer.

The Regulation of Osteogenesis Using Electroactive Polypyrrole Films

To evaluate the effect of electrical conductivity of biomaterials on osteogenesis, polypyrrole (PPy) was fabricated by oxidative chemical polymerization as substrates for cell culture. Through adjusting the concentrations of monomer and initiator, polypyrrole films with different electrical conductivities were fabricated. These fabricated polypyrrole films are transparent enough for easy optical microscopy. Fourier transform infrared spectroscopy, X-ray spectroscopy and four-point probe were used to assess the microstructures, surface chemical compositions and electrical sheet resistance of films, respectively. Results indicate that higher monomer and initiator concentration leads to highly-branched PPy chains and thus promotes the electron mobility and electrical conductivity. Selected polypyrrole films then were applied for culturing rat bone marrow stromal cells. Cell viability and mineralization assays reveal that not only these films are biocompatible, but also capable of enhancing the calcium deposition into the extra cellular matrix by the differentiated cells.

The consideration of indolicidin modification to balance its hemocompatibility and delivery efficiency

Indolicidin (IL) is an antimicrobial peptide (AMP), which has been utilized as a cell penetrating peptide (CPP) for drug delivery. However, the hemolysis restricts its clinical application. Therefore, we investigated the delivery efficiency and hemocompatibility of IL and its derivatives. The transportation of fluorophore to NIH/3T3 cells could be improved either by in accompany with these peptides or in the form of peptide-conjugates. The hydrophobicity scales of these peptides were calculated according to their residues, which were compared to their effects on hemolysis as well as cell uptake efficiency. The results suggested that the cell penetrability of IL and its derivatives was related to their hydrophobicity scales based on the octanol-interface scale (ΔGoct-if), whereas their hemolysis levels depended on the hydrophobicity scales based on interface (ΔGwif). Consequently, we designed two peptides, IL-R57F89 and SAP10, to validate the correlation. These two peptides had similar ΔGwif; however, the ΔGoct-if of SAP10 was much higher than that of IL-K7F89. Both IL-R57F89 and SAP10 demonstrated extremely low hemolysis. Compared to the limit cell uptake of SAP10, IL-R57F89 greatly promoted the delivery efficiency. These results were consistent to our prediction, suggesting that hydrophobicity scales should be a useful preliminary guidance for AMP-derived CPP design.

Hydrostatic pressure enhances mitomycin C induced apoptosis in urothelial carcinoma cells

OBJECTIVES Urothelial carcinoma (UC) of the bladder is the second most common cancer of the genitourinary system. Clinical UC treatment usually involves transurethral resection of the bladder tumor followed by adjuvant intravesical immunotherapy or chemotherapy to prevent recurrence. Intravesical chemotherapy induces fewer side effects than immunotherapy but is less effective at preventing tumor recurrence. Improvement to intravesical chemotherapy is, therefore, needed. METHODS AND MATERIALS Cellular effects of mitomycin C (MMC) and hydrostatic pressure on UC BFTC905 cells were assessed. The viability of the UC cells was determined using cellular proliferation assay. Changes in apoptotic function were evaluated by caspase 3/7 activities, expression of FasL, and loss of mitochondrial membrane potential. RESULTS Reduced cell viability was associated with increasing hydrostatic pressure. Caspase 3/7 activities were increased following treatment of the UC cells with MMC or hydrostatic pressure. In combination with 10 kPa hydrostatic pressure, MMC treatment induced increasing FasL expression. The mitochondria of UC cells displayed increasingly impaired membrane potentials following a combined treatment with 10 μg/ml MMC and 10 kPa hydrostatic pressure. CONCLUSIONS Both MMC and hydrostatic pressure can induce apoptosis in UC cells through an extrinsic pathway. Hydrostatic pressure specifically increases MMC-induced apoptosis and might minimize the side effects of the chemotherapy by reducing the concentration of the chemical agent. This study provides a new and alternative approach for treatment of patients with UC following transurethral resection of the bladder tumor.

Development of an indolicidin-derived peptide by reducing membrane perturbation to decrease cytotoxicity and maintain gene delivery ability

Indolicidin (IL) is a cationic antimicrobial peptide and our previous study has demonstrated its potential as a cell penetrating peptide (CPP) to promote gene delivery. However, the cytotoxicity of IL arisen from its membrane perturbation capacity may restrict its clinical application. To promote gene delivery safety and efficiency, an almost mirror-symmetric IL derivative, SAP10 (RRWKFFPWRR-CONH2), was designed in this study. All-atom molecular dynamics (MD) simulations were performed to understand the association between SAP10 and model lipid bilayers. By comparison with IL, SAP10 with high positively charged density resisted its deep insertion into lipid bilayers, which thus reduced its perturbation to lipid bilayers and improved biocompatibility. Consequently, we further mixed SAP10, polyethylenimine (PEI) and DNA to form the ternary nanocomplexes for gene delivery investigation. Both IL and SAP10 weakened the interaction between to DNA and PEI, which may be beneficial to promote the dissociation of internalized DNA from the carrier molecules. In vitro experiments demonstrated that the SAP10-associated ternary nanocomplexes highly promoted the transfection efficiency to various cells with low cytotoxicity. The effect of the SAP10 on promoting gene delivery was mainly contributed by the adsorbed peptides on the nanoparticles rather than the free ones. In particular, the dose of SAP10 could be increased to broaden the administration window, which ensured its safety on transfection. Therefore, our results suggested the argument that the designed SAP10 is a safe and an efficient peptide to promote PEI-mediated gene delivery.

The effects of substrate-mediated electrical stimulation on the promotion of osteogenic differentiation and its optimization: DCEF EFFECTS ON OSTEO-DIFFERENTIATION AND ITS OPTIMIZATION

To explore the effect of electrical stimulation (ES) on osteogenesis, a polypyrrole (PPy)-made electrical culture system was developed to provide a direct-current electric field (DCEF). This DCEF device was applied to treat differentiated rat bone marrow stromal cells (rBMSCs) once in different stages of osteo-differentation to investigate its temporal effects. The mineralization results showed that the DCEF treatment not only accelerated cell differentiation but also promoted the saturation levels, and the ES on day 8 was the group demonstrated the optimal result. The gene regulation analysis indicated that the DCEF treatment immediately increased the levels of genes related to osteo-differentiation, especially Runx2. Because Runx2 is a crucial transcriptional factor of osteogenesis, the ES-caused improvement of mineralization was likely contributed by the extension of its expression. Further, different ES modes were investigated of their efficacy on bone matrix deposition. Square waves with different parameters including frequency, offset, amplitude, and duty cycle were systematically examined. In contrast to constant voltage, square waves demonstrated periodical changes of current through substrate to significantly improve mineralization, and the efficiencies highly depended on both frequency and intensity. Through this comprehensive study, DCEF treating condition was optimized, which should be beneficial to its application on osteogenesis promotion.