Michael B. Keogh

Substrate stiffness and contractile behaviour modulate the functional maturation of osteoblasts on a collagen–GAG scaffold

Anchorage-dependent cells respond to the mechanical and physical properties of biomaterials. One such cue is the mechanical stiffness of a material. We compared the osteogenic potential of collagen-glycosaminoglycan (CG) scaffolds with varying stiffness for up to 6 weeks in culture. The mechanical stiffness of CG scaffolds were varied by cross-linking by physical (dehydrothermal (DHT)) and chemical (1-ethyl-3-(3-dimethyl aminopropyl) carbodiimide (EDAC) and glutaraldehyde (GLUT)) methods. The results showed that all CG substrates allowed cellular attachment, infiltration and osteogenic differentiation. CG scaffolds treated with EDAC and GLUT were mechanically stiffer, retained their original scaffold structure and resisted cellular contraction. Consequently, they facilitated a 2-fold greater cell number, probably due to the pore architecture being maintained, allowing improved diffusion of nutrients. On the other hand, the less stiff substrates cross-linked with DHT allowed increased cell-mediated scaffold contraction, contracting by 70% following 6 weeks (P < 0.01) of culture. This reduction in scaffold area resulted in cells reaching the centre of the scaffold quicker up to 4 weeks; however, at 6 weeks all scaffolds showed similar levels of cellular infiltration, with higher cell numbers found on the stiffer EDAC- and GLUT-treated scaffolds. Analysis of osteogenesis showed that scaffolds cross-linked with DHT expressed higher levels of the late stage bone formation markers osteopontin and osteocalcin (P < 0.01) and increased levels of mineralisation. In conclusion, the more compliant CG scaffolds allowed cell-mediated contraction and supported a greater level of osteogenic maturation of MC3T3 cells, while the stiffer, non-contractible scaffolds resulted in lower levels of cell maturation, but higher cell numbers on the scaffold. Therefore, we found scaffold stiffness had different effects on differentiation and cell number whereby the increased cell-mediated contraction facilitated by the less stiff scaffolds positively modulated osteoblast differentiation while reducing cell numbers.

Three hours of perfusion culture prior to 28 days of static culture, enhances osteogenesis by human cells in a collagen GAG scaffold†

In tissue engineering, bioreactors can be used to aid in the in vitro development of new tissue by providing biochemical and physical regulatory signals to cells and encouraging them to undergo differentiation and/or to produce extracellular matrix prior to in vivo implantation. This study examined the effect of short term flow perfusion bioreactor culture, prior to long‐term static culture, on human osteoblast cell distribution and osteogenesis within a collagen glycosaminoglycan (CG) scaffold for bone tissue engineering. Human fetal osteoblasts (hFOB 1.19) were seeded onto CG scaffolds and pre‐cultured for 6 days. Constructs were then placed into the bioreactor and exposed to 3 × 1 h bouts of steady flow (1 mL/min) separated by 7 h of no flow over a 24‐h period. The constructs were then cultured under static osteogenic conditions for up to 28 days. Results show that the bioreactor and static culture control groups displayed similar cell numbers and metabolic activity. Histologically, however, peripheral cell‐encapsulation was observed in the static controls, whereas, improved migration and homogenous cell distribution was seen in the bioreactor groups. Gene expression analysis showed that all osteogenic markers investigated displayed greater levels of expression in the bioreactor groups compared to static controls. While static groups showed increased mineral deposition; mechanical testing revealed that there was no difference in the compressive modulus between bioreactor and static groups. In conclusion, a flow perfusion bioreactor improved construct homogeneity by preventing peripheral encapsulation whilst also providing an enhanced osteogenic phenotype over static controls. Bioeng. 2011; 108:1203–1210.

Innovations in Gene and Growth Factor delivery systems for Diabetic Wound Healing.

The rise in lower extremity amputations due to nonhealing of foot ulcers in diabetic patients calls for rapid improvement in effective treatment regimens. Administration of growth factors (GFs) are thought to offer an off‐the‐shelf treatment; however, the dose‐ and time‐dependent efficacy of the GFs together with the hostile environment of diabetic wound beds impose a major hindrance in the selection of an ideal route for GF delivery. As an alternative, the delivery of therapeutic genes using viral and nonviral vectors, capable of transiently expressing the genes until the recovery of the wounded tissue offers promise. The development of implantable biomaterial dressings capable of modulating the release of either single or combinatorial GFs/genes may offer solutions to this overgrowing problem. This article reviews the state of the art on gene and protein delivery and the strategic optimization of clinically adopted delivery strategies for the healing of diabetic wounds.

Pro-angiogenic impact of SDF-1α gene-activated collagen-based scaffolds in stem cell driven angiogenesis

ABSTRACT Ensuring an adequate angiogenic response during wound healing is a prevailing clinical challenge in biomaterials science. To address this, we aimed to develop a pro‐angiogenic gene‐activated scaffold (GAS) that could activate MSCs to produce paracrine factors and influence angiogenesis and wound repair. A non‐viral polyethyleneimine (PEI) nanoparticles carrying a gene encoding for stromal derived factor‐1 alpha (SDF‐1&agr;) was combined with a collagen‐chondroitin sulfate scaffold to produce the GAS. The ability of this platform to enhance the angiogenic potential of mesenchymal stem cells (MSCs) was then assessed. We found that the MSCs on GAS exhibited early over‐expression of SDF‐1&agr; mRNA with the activation of angiogenic markers VEGF and CXCR4. Exposing endothelial cells to conditioned media collected from GAS supported MSCs promoted a 20% increase in viability and 33% increase in tubule formation (p<0.05). Furthermore, the conditioned media promoted a 50% increase in endothelial cell migration and wound closure (p<0.005). Gene expression analysis of the endothelial cells revealed that the functional response was associated with up‐regulation of angiogenic genes; VEGF, CXCR4, eNOS and SDF‐1&agr;. Overall, this study shows collagen‐based scaffolds combined with SDF‐1&agr; gene therapy can provide enhanced pro‐angiogenic response, suggesting a promising approach to overcome poor vasculature during wound healing.

Awareness of Healthcare Workers to Total Parenteral Feeding in Neonatal Units

Result: Sixty-two (80%) were aware of the risks of administering TPN. Different policies and guidelines were followed depending on the institution. Fifty-four (69%) respondents thought that TPN preparation should be carried out under sterile conditions; 63 (80%) preferably by a pharmacist rather than in the ward by doctors or nurses. Low staff satisfaction was found in 19 (67%) because the pharmacy did not prepare the TPN.