Siew Lok Toh

A bFGF-releasing silk/PLGA-based biohybrid scaffold for ligament/tendon tissue engineering using mesenchymal progenitor cells

An ideal scaffold that provides a combination of suitable mechanical properties along with biological signals is required for successful ligament/tendon regeneration in mesenchymal stem cell-based tissue engineering strategies. Among the various fibre-based scaffolds that have been used, hybrid fibrous scaffolds comprising both microfibres and nanofibres have been recently shown to be particularly promising. This study developed a biohybrid fibrous scaffold system by coating bioactive bFGF-releasing ultrafine PLGA fibres over mechanically robust slowly-degrading degummed knitted microfibrous silk scaffolds. On the ECM-like biomimetic architecture of ultrafine fibres, sustained release of bFGF mimicked the ECM in function, initially stimulating mesenchymal progenitor cell (MPC) proliferation, and subsequently, their tenogeneic differentiation. The biohybrid scaffold system not only facilitated MPC attachment and promoted cell proliferation, with cells growing both on ultrafine PLGA fibres and silk microfibres, but also stimulated tenogeneic differentiation of seeded MPCs. Upregulated gene expression of ligament/tendon-specific ECM proteins and increased collagen production likely contributed to enhancing mechanical properties of the constructs, generating a ligament/tendon analogue that has the potential to be used to repair injured ligaments/tendons.

Growth factor delivery through electrospun nanofibers in scaffolds for tissue engineering applications

Tissue engineering scaffolds should ideally mimic the natural ECM in structure and function. Electrospun nanofibrous scaffolds are easily fabricated and possess a biomimetic nanostructure. Scaffolds can mimic ECM function by acting as a depot for sustained release of growth factors. bFGF, an important growth factor involved in tissue repair and mesenchymal stem cell proliferation and differentiation, is a suitable candidate for sustained delivery from scaffolds. In this study, we present two types of PLGA nanofibers incorporated with bFGF, fabricated using the facile technique of blending and electrospinning (Group I) and by the more complex technique of coaxial electrospinning (Group II). bFGF was randomly dispersed in Group I and distributed as a central core within Group II nanofibers; both scaffolds showed similar protein encapsulation efficiency and release over 1-2 weeks. Although both scaffold groups favored bone marrow stem cell attachment and subsequent proliferation, cells cultured on Group I scaffolds demonstrated increased collagen production and upregulated gene expression of specific ECM proteins, indicating fibroblastic differentiation. The study shows that the electrospinning technique could be used to prolong growth factor release from scaffolds and an appropriately sustained growth factor release profile in combination with a nanofibrous substrate could positively influence stem cell behavior and fate.

Bioactive nanofibers for fibroblastic differentiation of mesenchymal precursor cells for ligament/tendon tissue engineering applications

Mesenchymal stem cells and precursor cells are ideal candidates for tendon and ligament tissue engineering; however, for the stem cell-based approach to succeed, these cells would be required to proliferate and differentiate into tendon/ligament fibroblasts on the tissue engineering scaffold. Among the various fiber-based scaffolds that have been used in tendon/ligament tissue engineering, hybrid fibrous scaffolds comprising both microfibers and nanofibers have been recently shown to be particularly promising. With the nanofibrous coating presenting a biomimetic surface, the scaffolds can also potentially mimic the natural extracellular matrix in function by acting as a depot for sustained release of growth factors. In this study, we demonstrate that basic fibroblast growth factor (bFGF) could be successfully incorporated, randomly dispersed within blend-electrospun nanofibers and released in a bioactive form over 1 week. The released bioactive bFGF activated tyrosine phosphorylation signaling within seeded BMSCs. The bFGF-releasing nanofibrous scaffolds facilitated BMSC proliferation, upregulated gene expression of tendon/ligament-specific ECM proteins, increased production and deposition of collagen and tenascin-C, reduced multipotency of the BMSCs and induced tendon/ligament-like fibroblastic differentiation, indicating their potential in tendon/ligament tissue engineering applications.

PLGA nanofiber-coated silk microfibrous scaffold for connective tissue engineering.

A modified degumming technique, involving boiling in 0.25% Na2CO3 with addition of 1% sodium dodecyl sulphate and intermittent ultrasonic agitation, was developed for knitted silk scaffolds. Sericin was efficiently removed, while mechanical and structural properties of native silk fibroin were preserved. Biocompatible and mechanically robust hybrid nano-microscaffolds were fabricated by coating these degummed silk scaffolds with an intervening adhesive layer of silk solution followed by electrospun poly-lactic-co-glycolic acid (PLGA) nanofibers. Cell proliferation on the hybrid silk scaffolds was improved by seeding cells on both surfaces of the flat scaffolds. Rolling up and continued culture of the cell-seeded hybrid scaffolds yielded cylindrical constructs that permitted cell proliferation, extracellular matrix deposition, and generated ligament/tendon graft analogs. Although PLGA-based hybrid scaffolds have earlier been proposed for dense connective tissue engineering, rapid biodegradation of PLGA was a drawback. In contrast, the underlying strong and slowly-degrading microfibrous silk scaffold used in this study ensured that the hybrid scaffold maintained adequate mechanical properties for longer periods, which is vital for continued support to the injured ligament/tendon throughout its healing period.

Aligned hybrid silk scaffold for enhanced differentiation of mesenchymal stem cells into ligament fibroblasts.

The concept of contact guidance utilizes the phenomenon of anchorage dependence of cells on the topography of seeded surfaces. It has been shown in previous studies that cells were guided to align along the topographical alignment of the seeding substrate and produced enhanced amounts of oriented extracellular matrix (ECM). In this study, we aimed to apply this concept to a three-dimensional full silk fibroin (SF) hybrid scaffold system, which comprised of knitted SF and aligned SF electrospun fibers (SFEFs), for ligament tissue engineering applications. Specifically, knitted SF, which contributed to the mechanical robustness of the system, was integrated with highly aligned SFEF mesh, which acted as the initial ECM to provide environmental cues for positive cellular response. Mesenchymal stem cells seeded on the aligned hybrid scaffolds were shown to be proliferative and aligned along the integrated aligned SFEF, forming oriented spindle-shaped morphology and produced an aligned ECM network. Expression and production of ligament-related proteins were also increased as compared to hybrid SF scaffolds with randomly arranged SFEFs, indicating differentiative cues for ligament fibroblasts present in the aligned hybrid SF scaffolds. Consequently, the tensile properties of cultured aligned constructs were significantly improved and superior to the counterpart with randomly arranged SFEF. These results thus show that the aligned hybrid scaffold system is promising for enhancing cell proliferation, differentiation, and function for ligament tissue engineering applications.

The elastic response of orthotropic laminated cylindrical shells to low-velocity impact

Abstract This paper presents an analysis of laminated open cylindrical shells subjected to impact loading. A spring-mass model is developed to determine the contact force between the shell and impactor during impact. Based on this model, an analytic function describing the contact force is derived in terms of the material properties and mass of the shell and impactor, as well as the impact velocity. An analytic solution to predict the response of laminated shells subjected to impact is presented. This solution includes both contact deformation and transverse shear deformation. The present analysis is used to predict the response of laminated shells to impact loading and to study the effects of different impact conditions and shell size and curvature on the contact force and central deflection of the shell. The analysis is verified by comparing the present results with those reported by others.

Whole-field determination of surface roughness by speckle correlation

A whole-field method of double-exposure speckle photography is employed to determine metal surface roughness by correlation between two speckle patterns. A movable rectangular aperture that is mounted before an image lens is shifted between the exposures, which results in a decrease in the contrast of the reconstructed Youngs fringes with increasing roughness. The technique permits evaluation of the roughness of particular points on a surface as well as the average roughness of an entire surface. Four sets of random surfaces that were prepared by different machine-finishing processes and with roughnesses ranging from 0.6 to 13 µm have been tested. Different methods have been carried out to process the test data, and a practical method for the evaluation of surface roughness is proposed.

Whole field surface roughness measurement by laser speckle correlation technique

Abstract This paper describes a speckle correlation technique for the determination of surface roughness, ranging from 1.6 to 50 μm . Instead of moving the laser beam, the specimen is rotated to achieve angular speckle correlation (ASC) in the far-field plane. The technique is simple and requires minimum optical alignment. The experimental results show a good agreement with the standard specimen of known roughness. An error analysis on the experiment has been carried out. Together with the theoretical curves, the roughness values can be easily related to the change of incidence angle at a particular visibility of the correlation fringes between two speckle patterns.

In vitro ligament-bone interface regeneration using a trilineage coculture system on a hybrid silk scaffold.

The ligament-bone interface is a complex structure that comprises ligament, fibrocartilage, and bone. We hypothesize that mesenchymal stem cells cocultured in between ligament and bone cells, on a hybrid silk scaffold with sections suitable for each cell type, would differentiate into fibrocartilage. The section of scaffold for osteoblast seeding was coated with hydroxyapatite. A trilineage coculture system (osteoblasts-BMSCs-fibroblasts) on a hybrid silk scaffold was established. RT-PCR results and immunohistochemistry results demonstrated that BMSCs cocultured between fibroblasts and osteoblasts had differentiated into the fibrocartilaginous lineage. The morphological change was also observed by SEM observation. A gradual transition from the uncalcified to the calcified region was formed in the cocultured BMSCs from the region that directly interacted with fibroblasts to the region that directly interacted with osteoblasts. The role of transforming growth factor β3 (TGF-β3) in this trilineage coculture model was also investigated by supplementing the coculture system with 10 ng/mL TGF-β3. The TGF-treated group showed similar results of fibrocartilaginous differentiation of BMSCs with coculture group without TGF-β3 supplement. However, no calcium deposition was found in the cocultured BMSCs in the TGF-treated group. This may indicate TGF-β3 delayed the mineralization process of chondrocytes.

Bio-Electrospraying: A Potentially Safe Technique for Delivering Progenitor Cells

Bio‐electrospraying is fast becoming an attractive tool for in situ cell delivery into scaffolds for tissue engineering applications, with several cell types been successfully electrosprayed. Bone marrow derived mesenchymal progenitor/stem cells (BMSC), which are an important cell source for tissue engineering, have not been explored in detail and the effect of electrospraying on their “stemness” is not known. This study therefore investigates the effects of electrospraying on BMSC viability, proliferation, and multilineage differentiation potential. Electrospraying a BMSC suspension at flow rate of 6 mL/h and voltages of 7.5–15 kV could successfully generate a continuous, stable and linearly directed electrospray of cells. Morphological observation, trypan blue tests and alamar blue based metabolic assays revealed about 88% of these electrosprayed cells were viable, and proliferated at rates similar to native BMSCs. However, at higher voltages, electrospraying became unstable and reduced cell viability, possibly due to electrical or thermal damage to the cells. BMSCs electrosprayed at 7.5 kV also retained their multipotency and could be successfully differentiated into adipogenic, chondrogenic, and osteogenic lineages, demonstrating similar morphology and gene expression levels as induced native BMSCs. These results indicate that bio‐electrospraying could be safely used as a progenitor/stem cell delivery technique for tissue engineering and regenerative medicine applications. Biotechnol. Bioeng. 2010;106: 690–698.