Human adipose-derived stem cell spheroids incorporating platelet-derived growth factor (PDGF) and bio-minerals for vascularized bone tissue engineering.

Stem cells with mineralized materials have been used for bone regeneration; however, engineering the complex vascularized structure of the natural bone remains a challenge. Here, we developed platelet-derived growth factor (PDGF) and bio-mineral coated fibers which were then assembled with human adipose-derived stem cells (hADSCs) to form spheroids as building blocks for vascularized bone regeneration. The PDGF incorporated within the spheroid increased the proliferation of hADSCs, which was characterized by Ki-67 staining and DNA contents. Furthermore, the PDGF enhanced not only osteogenic differentiation, but also endothelial differentiation of hADSCs; the cells within the spheroids showed significantly greater gene expression by 2.46 ± 0.14 fold for osteocalcin (OCN) and by 12.85 ± 3.36 fold for von Willebrand factor (vWF) than those without PDGF. Finally, at two months following transplantation of PDGF-incorporated spheroids onto in vivo mouse calvarial defect, the regenerated bone area (42.48 ± 10.84%) was significantly enhanced and the greatest number of capillaries and arterioles with indication of transplanted hADSCs were observed. Moreover, millimeter-scale in vitro tissue prepared by fused assembly of the spheroids exhibited greater mRNA expression-associated to endothelial lineage. Taken together, these findings indicate that stem cell spheroids incorporating PDGF and bio-minerals could be used as a module for successful vascularized bone regeneration.

Bioactive Membrane Immobilized with Lactoferrin for Modulation of Bone Regeneration and Inflammation.

Guided bone regeneration refers to the process in which bone defects could be regenerated by facilitated healing through the use of membranes, potentially with the delivery of osteoinductive molecules, however, the regeneration often failed due to inflammation during bone formation. In this study, we developed a membrane immobilized with lactoferrin to modulate both bone regeneration and inflammatory responses. Lactoferrin was immobilized on electrospun nanofibers (LF50) by exploiting an adhesive polydopamine coating method. When human adipose-derived stem cells (hADSCs) were seeded onto the nanofibers, the LF50 significantly increased the osteogenic differentiation. For example, the gene expression of osteopontin was 6.9 ± 2.3 times greater in the cells on LF50 than the cells on unmodified nanofibers without lactoferrin. In addition, the gene expression of tumor necrosis factor-alpha (TNF-α) of the macrophage cell line (RAW264.7) cultured on the LF50 was 0.3 ± 0.1 times reduced, indicating the lactoferrin was able to reduce inflammatory response. With implantation of nanofibers on in vivo mouse calvarial defects, the LF50 resulted in 60.9% ± 4.5% of new bone formation, which was six times greater than the results of other groups. Furthermore, when the fibers were implanted onto the in vivo mouse subcutaneous model challenged with lipopolysaccharide and interferon-γ, the area of inflammatory tissue was significantly reduced in the LF50 implanted group as 0.6 ± 0.1 mm2 as compared with the control group (1.1 ± 0.1 mm2). Taken together, the lactoferrin immobilization onto the nanofiber by polydopamine chemistry may be an effective delivery method for improving bone regeneration while regulating the inflammation. Impact statement In vivo critical-sized bone reconstruction remains challenging due to the severe inflammation, which would be an unavoidable problem during surgical process. Therefore, the present study aims to develop a guided nanofibrous membrane immobilized with lactoferrin, which has dual functions with osteoinduction and anti-inflammation. The lactoferrin-immobilized fibers demonstrated significantly enhanced in vitro osteogenic differentiation of adipose-derived stem cells as well as decreased polarization of macrophage to M1 with relatively reduced amount than that reported from previous reports. We also found that the membrane improved in vivo bone regeneration and decreased inflammatory tissue formation. Taken together, this system would be a new platform for successful bone regeneration.

Performance Analysis of Gravity-Driven Oil-Water Separation Using Membranes with Special Wettability.

A membrane with selective wettability to either oil or water has been utilized for highly efficient, environmentally friendly membrane-based oil-water separation. However, a predictive model, which can be used to evaluate the overall separation performance of the membrane, still needs further development. Herein, we investigate three separation performance parameters, that is, separation efficiency, liquid intrusion pressure, and mass flux in particular, as a function of pore geometry and liquid properties using metallic meshes whose surface wettability is modified by scalable spray coating. We show that the prepared membrane exhibits a separation efficiency over 98% below the intrusion pressure, while the intrusion pressure increases with the decrease of pore size of the membrane. Particularly, we develop a semi-empirical model for the mass flux through the membrane. As application examples of our performance analysis, we successfully predict the separation time for one-way and two-way gravity-driven separation of the oil-water mixture, the decrease of the mass flux due to membrane fouling, and the maximum allowable separation capacity of the given membrane. This work can help to design optimal membrane-based oil-water separation systems for actual industrial applications by providing a selection guideline for separation membranes.

Condensation Heat-Transfer Performance of Thermally Stable Superhydrophobic Cerium-Oxide Surfaces.

We introduce a thin (<200 nm) superhydrophobic cerium-oxide surface formed by a one-step wet chemical process to enhance the condensation heat-transfer performance with improved thermal stability compared to silane-treated surfaces. The developed cerium-oxide surface showed a superhydrophobic characteristic with a low (<5°) contact angle hysteresis because of the unique surface morphology and hydrophobicity of cerium oxide. The surface was successfully incorporated to popular engineering materials including copper, aluminum, and steel. Thermal stability of the surfaces was investigated by exposing them to hot (∼100 °C) steam conditions for 12 h. The introduced ceria surfaces could maintain active dropwise condensation after the thermal stability test, whereas silane-treated surfaces completely lost their hydrophobicity. The heat-transfer coefficient was calculated using the thermal network model incorporating the droplet size distribution and morphology obtained from the microscopic measurement. The analysis shows that the suggested cerium-oxide surfaces can provide approximately 2 times and 5 times higher heat-transfer coefficient before and after the thermal stability test, respectively, mainly because of the decrease in the thermal conduction resistance across droplets. The results indicate that the introduced nanostructured cerium-oxide surface is a promising condenser coating to enhance the droplet mobility and the resulting condensation heat-transfer performance for various thermal and environmental applications, especially those being exposed to hot steam conditions.

Spectroscopic properties of fluoroquinolone antibiotics in water-methanol and water-acetonitrile mixed solvents.

The fluorescence properties of ofloxacin (OFL), norfloxacin (NOR) and flumequine (FLU) were studied in H2O-CH3OH and H2O-CH3CN mixed solvents because these solvents were thought to behave as a biological mimetic system. The emission spectra of OFL and NOR were very sensitive to the composition of the solvents. In the Lippert-Mataga analysis of the steady-state fluorescence data of OFL and NOR, clear reverse solvatochromism was exhibited in both mixed solvents. This observation can be explained by the twisted excited-state intramolecular charge transfer, which is accelerated by water. Theoretical treatments further support these results. The radiative and nonradiative rate constants were analyzed as a function of solvent dipolarity-polarizability (pi*) and hydrogen-bond donor acidity (alpha). These results were well consistent with the suggested mechanism of the excited-state chemical process of OFL and NOR, which depended upon the solvent-solute interactions such as bulk dielectric effects and specific hydrogen-bonding interactions. However, the influence of dielectric effects was more significant. The solvent structures of H2O-CH3CN and the preferential solvation by water were also examined. The emission spectra of FLU do not exhibit any characteristic responses to the properties of the environment.