Dual-Microstructured Porous, Anisotropic Film for Biomimicking of Endothelial Basement Membrane.

Human endothelial basement membrane (BM) plays a pivotal role in vascular development and homeostasis. Here, a bioresponsive film with dual-microstructured geometries was engineered to mimic the structural roles of the endothelial BM in developing vessels, for vascular tissue engineering (TE) application. Flexible poly(ε-caprolactone) (PCL) thin film was fabricated with microscale anisotropic ridges/grooves and through-holes using a combination of uniaxial thermal stretching and direct laser perforation, respectively. Through optimizing the interhole distance, human mesenchymal stem cells (MSCs) cultured on the PCL film's ridges/grooves obtained an intact cell alignment efficiency. With prolonged culturing for 8 days, these cells formed aligned cell multilayers as found in native tunica media. By coculturing human umbilical vein endothelial cells (HUVECs) on the opposite side of the film, HUVECs were observed to build up transmural interdigitation cell-cell contact with MSCs via the through-holes, leading to a rapid endothelialization on the PCL film surface. Furthermore, vascular tissue construction based on the PCL film showed enhanced bioactivity with an elevated total nitric oxide level as compared to single MSCs or HUVECs culturing and indirect MSCs/HUVECs coculturing systems. These results suggested that the dual-microstructured porous and anisotropic film could simulate the structural roles of endothelial BM for vascular reconstruction, with aligned stromal cell multilayers, rapid endothelialization, and direct cell-cell interaction between the engineered stromal and endothelial components. This study has implications of recapitulating endothelial BM architecture for the de novo design of vascular TE scaffolds.

Effect of silver content on the antibacterial and bioactive properties of silver-substituted hydroxyapatite.

The long-term success of a biomaterial used during surgery may be compromised by infection. A possible effective solution is to make the biomaterial osteoconductive and antibacterial. A range of silver-substituted hydroxyapatite (AgHA) of up to 1.1 wt. % of Ag was synthesized. AgHA displayed a rod-like morphology of dimensions ~50 nm in length and ~15 nm in width. Phase-pure AgHA was demonstrated in the X-ray diffraction patterns and Fourier transform infrared spectroscopy spectra. Comparing with hydroxyaptite (HA), 0.5AgHA exhibited a 3-log reduction in the number of bacteria. Diffusion of the entrapped Ag(+) ions towards the crystal structure surface was revealed by an increase of 6 at. % Ag in the X-ray photoelectron spectroscopy results. Furthermore, less than 0.5 ppm of Ag(+) ions being released from 0.5AgHA into the deionized water medium was evidenced from the inductively coupled plasma mass spectrometry results. AgHA produced by co-precipitation gave rise to minimal release of Ag(+) ions. It was hypothesized that the diffused surface Ag(+) ions damaged the bacteria cell membrane and impede its replication. With the culturing time, significant increase in the number of human mesenchymal stem cells (p < 0.05) was demonstrated on 0.5AgHA.

Biocompatibility studies and characterization of poly(3-hydroxybutyrate-co-3-hydroxyhexanoate)/polycaprolactone blends.

Poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) (PHBHHx) is a biocompatible and bioresorbable copolymer that has generated research interest as a bone scaffold material. However, its brittleness and degradation characteristics can be improved upon. We hypothesized that blending with medical-grade polycaprolactone (PCL) can improve degradation and mechanical characteristics. Here, we report the development of solvent-blended PHBHHx/PCL for application as a potential biomaterial for tissue engineering. Enhanced yield strength, yield strain and Young's modulus occurred at 30/70 blend when compared with PHBHHx and PCL. Polarized light microscopy demonstrated PHBHHx and PCL to exist as morphologically and optically distinct phases and, together with thermal analyses, revealed immiscibility. Hydrophilicity improved with the addition of PCL. Accelerated hydrolytic studies suggested predictable behavior of PHBHHx/PCL. Notably, 30/70 blend exhibited similar degradation behavior to PCL in terms of changes in crystallinity, molecular weight, morphology, and mass loss. Finally, human fetal mesenchymal stem cells (hfMSCs) were evaluated on PHBHHx/PCL using live/dead assay and results suggested encouraging hfMSC adhesion and proliferative capacity, with near-confluence occurring in PHBHHx and 30/70 blend after 5 days. Taken together, these are encouraging results for the further development of PHBHHx/PCL as a potential biomaterial for tissue engineering.

Biomimetic three-dimensional anisotropic geometries by uniaxial stretch of poly(ε-caprolactone) films for mesenchymal stem cell proliferation, alignment, and myogenic differentiation.

Anisotropic geometries are critical for eliciting cell alignment to dictate tissue microarchitectures and biological functions. Current fabrication techniques are complex and utilize toxic solvents, hampering their applications for translational research. Here, we present a novel simple, solvent-free, and reproducible method via uniaxial stretching for incorporating anisotropic topographies on bioresorbable films with ambitions to realize stem cell alignment control. Uniaxial stretching of poly(ε-caprolactone) (PCL) films resulted in a three-dimensional micro-ridge/groove topography (inter-ridge-distance: ~6 µm; ridge-length: ~90 µm; ridge-depth: 200-900 nm) with uniform distribution and controllable orientation by the direction of stretch on the whole film surface. When stretch temperature (Ts) and draw ratio (DR) were increased, the inter-ridge-distance was reduced and ridge-length increased. Through modification of hydrolysis, increased surface hydrophilicity was achieved, while maintaining the morphology of PCL ridge/grooves. Upon seeding human mesenchymal stem cells (hMSCs) on uniaxial-stretched PCL (UX-PCL) films, aligned hMSC organization was obtained. Compared to unstretched films, hMSCs on UX-PCL had larger increase in cellular alignment (>85%) and elongation, without indication of cytotoxicity or reduction in cellular proliferation. This aligned hMSC organization was homogenous and stably maintained with controlled orientation along the ridges on the whole UX-PCL surface for over 2 weeks. Moreover, the hMSCs on UX-PCL had a higher level of myogenic genes' expression than that on the unstretched films. We conclude that uniaxial stretching has potential in patterning film topography with anisotropic structures. The UX-PCL in conjunction with hMSCs could be used as "basic units" to create tissue constructs with microscale control of cellular alignment and elongation for tissue engineering applications.

Polycaprolactone-based fused deposition modeled mesh for delivery of antibacterial agents to infected wounds.

Infections represent a significant source of site morbidity following tissue trauma. Scarring and tissue adhesion remain the challenging issues yet to be solved. Prolonged inflammation and morphology of the re-epithelisated layer are important considerations. We hypothesized that the solution lies not only in the biochemistry of biomaterial but also the micro-architecture of the scaffold used as the matrix for wound healing. Targeted delivery of antibiotics may provide an efficacious means of infection control through adequate release. Here, we study the use of 3-dimensional polycaprolactone-tricalcium phosphate (PCL-TCP) mesh for the delivery of gentamicin sulphate (GS) fabricated using a solvent-free method. PCL-TCP meshes incorporated with varying loads of GS were evaluated in vitro for elution profile, antimicrobial efficacy and cytotoxicity. Results showed that PCL-TCP meshes incorporated with 15 wt% GS (PT15) efficiently eliminate bacteria within 2 h and demonstrate low cytotoxicity. Subsequently, PT15 meshes were evaluated using an infected full thickness wound mice model, and observed to eliminate bacteria in the wounds effectively. Additionally, mice from the PT15 treatment group (TG) showed no observable signs of overall infection through neutrophil count by day 7 and displayed efficient wound healing (94.2% wound area reduction) by day 14. Histology also showed significantly faster healing in TG through neo-collagen deposition and wound re-epithelisation. The meshes from TG were also observed to be expelled from wounds while gauze fibers from CG were integrated into wounds during healing.

A comparison of bioreactors for culture of fetal mesenchymal stem cells for bone tissue engineering.

Bioreactors provide a dynamic culture system for efficient exchange of nutrients and mechanical stimulus necessary for the generation of effective tissue engineered bone grafts (TEBG). We have shown that biaxial rotating (BXR) bioreactor-matured human fetal mesenchymal stem cell (hfMSC) mediated-TEBG can heal a rat critical sized femoral defect. However, it is not known whether optimal bioreactors exist for bone TE (BTE) applications. We systematically compared this BXR bioreactor with three most commonly used systems: Spinner Flask (SF), Perfusion and Rotating Wall Vessel (RWV) bioreactors, for their application in BTE. The BXR bioreactor achieved higher levels of cellularity and confluence (1.4-2.5x, p < 0.05) in large 785 mm(3) macroporous scaffolds not achieved in the other bioreactors operating in optimal settings. BXR bioreactor-treated scaffolds experienced earlier and more robust osteogenic differentiation on von Kossa staining, ALP induction (1.2-1.6×, p < 0.01) and calcium deposition (1.3-2.3×, p < 0.01). We developed a Micro CT quantification method which demonstrated homogenous distribution of hfMSC in BXR bioreactor-treated grafts, but not with the other three. BXR bioreactor enabled superior cellular proliferation, spatial distribution and osteogenic induction of hfMSC over other commonly used bioreactors. In addition, we developed and validated a non-invasive quantitative micro CT-based technique for analyzing neo-tissue formation and its spatial distribution within scaffolds.

Beyond cell capture: antibody conjugation improves hemocompatibility for vascular tissue engineering applications.

Antibody-conjugated surfaces are being studied for cardiovascular implant applications to capture endothelial progenitor cells and promote endothelialization. However, despite the large amount of literature on endothelial progenitor cell capture efficiency, little effort has been made to understand acute blood responses to the modified surfaces. We hypothesize that CD34 antibody conjugation passivates surfaces against procoagulatory events, and thus improves hemocompatibility. To test this hypothesis, we subjected the modified films to hemocompatibility tests to evaluate contact activation, platelet adhesion and activation, as well as whole blood clotting response to the films. Here, we demonstrate the alteration of blood responses due to polyacrylic acid (PAAc) engraftment and subsequent antibody conjugation on biaxially stretched polycaprolactone (PCL) films. Compared to PCL, PAAc-engrafted PCL (PCL-PAAc) and CD34-antibody-conjugated films (PCL-PAAC-CD34) resulted in a four- to ninefold (p < 0.001) reduced platelet activation. PCL-PAAc, however, resulted in an increased contact activation on thromboelastography, and a poorer blood compatibility index assay (43.4% +/- 2.3% vs. 60.9% +/- 2.5%, p < 0.05). PCL-PAAC-CD34, on the other hand, resulted in delayed clot formation (r = 19.3 +/- 1.5, k = 6.8 +/- 0.6 min) and reduced platelet adhesion and activation, and yielded the highest blood compatibility index score, indicating least thrombogenicity (69.3% +/- 3.2%). Our results suggest that CD34 antibody conjugation significantly improved the hemocompatibility of PAAc-conjugated PCL.