Polymersome nanoparticles for delivery of Wnt-activating small molecules

Spatiotemporal control of drug delivery is important for a number of medical applications and may be achieved using polymersome nanoparticles (PMs). Wnt signalling is a molecular pathway activated in various physiological processes, including bone repair, that requires precise control of activation. Here, we hypothesise that PMs can be stably loaded with a small molecule Wnt agonist, 6-bromoindirubin-3′-oxime (BIO), and activate Wnt signalling promoting the osteogenic differentiation in human primary bone marrow stromal cells (BMSCs). We showed that BIO-PMs induced a 40% increase in Wnt signaling activation in reporter cell lines without cytotoxicity induced by free BIO. BMSCs incubated with BIO-PMs showed a significant up-regulation of the Wnt target gene AXIN2 (14?±?4 fold increase, P?<?0.001) and a prolonged activation of the osteogenic gene RUNX2. We conclude that BIO-PMs could represent an innovative approach for the controlled activation of Wnt signaling for promoting bone regeneration after fracture.     

Interconversion potential of cloned human marrow adipocytes in vitro

Information on the interconversion potential of adipocytes and other end cells characteristic of the stromal fibroblastic cell lineages, key in the understanding of bone turnover in metabolic diseases such as osteoporosis, is limited. The object of the present study was: i) to isolate relatively pure populations of adipocytes from human bone marrow; ii) to clone single adipocytes from these populations; and iii) to examine in vitro the interconversion potential of the progeny of these single-cloned adipocytes between the osteogenic and adipogenic phenotypes. Adipogenic colonies were isolated from the low-density floating fraction of normal bone marrow cells cultured in adipogenic media for 4 days. Single adipocytes were isolated and cloned by limiting dilution. Cloned adipocytes were found to dedifferentiate into fibroblast-like cells, and subsequently to differentiate into two morphologically distinct cell types: osteoblasts and adipocytes in appropriate culture systems. The adipocytic phenotype was confirmed by morphology, oil red O staining, and immunocytochemistry using antiserum to aP2. The osteogenic phenotype was confirmed by alkaline phosphatase, osteocalcin immunostaining using specific osteocalcin antiserum, and formation of mineralized cell aggregates. These findings demonstrate the extent of plasticity between the differentiation of adipocytic and osteogenic cells in human bone marrow stromal cell cultures. We have shown the ability of isolated clonal adipogenic cells to redifferentiate into cells of the osteogenic and adipogenic lineage and the interconversion potential of human marrow stromal cells in vitro. These results provide further evidence that the osteogenic and adipogenic cells share a common multipotential precursor.     

Pleiotrophin/Osteoblast-stimulating factor 1: dissecting its diverse functions in bone formation.

OSF-1, more commonly known as pleiotrophin (PTN) or heparin-binding growth-associated molecule (HB-GAM), belongs to a new family of secreted HB proteins, which are structurally unrelated to any other growth factor family. The aims of this study were to dissect the diverse functions of PTN in bone formation. The study showed that PTN was synthesized by osteoblasts at an early stage of osteogenic differentiation and was present at sites of new bone formation, where PTN was stored in the new bone matrix. Low concentrations (10 pg/ml) of PTN stimulated osteogenic differentiation of mouse bone marrow cells and had a modest effect on their proliferation, whereas higher concentrations (ng/ml) had no effect. However, PTN did not have the osteoinductive potential of bone morphogenetic proteins (BMPs) because it failed to convert C2C12 cells, a premyoblastic cell line, to the osteogenic phenotype, whereas recombinant human BMP-2 (rhBMP-2) was able to do so. When PTN was present together with rhBMP-2 during the osteoinductive phase, PTN inhibited the BMP-mediated osteoinduction in C2C12 cells at concentrations between 0.05 pg/ml and 100 ng/ml. However, when added after osteoinduction had been achieved, PTN enhanced further osteogenic differentiation. An unusual effect of PTN (50 ng/ml) was the induction of type I collagen synthesis by chondrocytes in organ cultures of chick nasal cartilage and rat growth plates. Thus, PTN had multiple effects on bone formation and the effects were dependent on the concentration of PTN and the timing of its presence. To explain these multiple effects, we propose that PTN is an accessory signaling molecule, which is involved in a variety of processes in bone formation. PTN enhances or inhibits primary responses depending on the prevailing concentrations, the primary stimulus, and the availability of appropriate receptors.     

An ex vivo model for chondrogenesis and osteogenesis

Loss of bone and cartilage are major healthcare issues. At present, there is a paucity of therapies for effectively repairing these tissues sustainably in the long term. A tissue engineering approach using advanced functional scaffolds may provide a clinically acceptable alternative. In this study, an innovative mineralized alginate/chitosan scaffold was used to provide tailored microenvironments for driving chondrogenesis and osteogenesis from single and mixed populations of human articular chondrocytes and human bone marrow stromal cells. Polysaccharide capsules were prepared with combinations of these cell types with the addition of type I or type II collagen to augment cell-matrix interactions and promote the formation of phenotypically distinct tissues and placed in a rotating (Synthecon) bioreactor or held in static 2D culture conditions for up to 28 days. Significant cell-generated matrix synthesis was observed in human bone marrow bioreactor samples containing type I collagen after 21-28 days, with increased cell proliferation, cell activity and osteocalcin synthesis. The cell-generated matrix was immuno-positive for types I and II collagen, bone sialoprotein and type X collagen, a marker of chondrogenic hypertrophy, demonstrating the formation of a mature chondrogenic phenotype with areas of new osteoid tissue formation. We present a unique approach using alginate/collagen capsules encapsulated in chitosan to promote chondrogenic and osteogenic differentiation and extracellular matrix formation and the potential for tissue-specific differentiation. This has significant implications for skeletal regeneration and application.     

Bone and metal: An orthopaedic perspective on osseointegration of metals

The area of implant osseointegration is of major importance, given the predicted significant rise in the number of orthopaedic procedures and an increasingly ageing population. Osseointegration is a complex process involving a number of distinct mechanisms affected by the implant bulk properties and surface characteristics. Our understanding and ability to modify these mechanisms through alterations in implant design is continuously expanding. The following review considers the main aspects of material and surface alterations in metal implants, and the extent of their subsequent influence on osseointegration. Clinically, osseointegration results in asymptomatic stable durable fixation of orthopaedic implants. The complexity of achieving this outcome through incorporation and balance of contributory factors is highlighted through a clinical case report.     

The role of vibration and drainage in femoral impaction bone grafting

Vibration is commonly used in civil engineering applications to efficiently compact aggregates. This study examined the effect of vibration and drainage on bone graft compaction and cement penetration in an in vitro femoral impaction bone grafting model with the use of 3-dimensional micro-computed tomographic imaging. Three regions were analyzed. In the middle and proximal femoral regions, there was a significant increase in the proportion of bone grafts with a reciprocal reduction in water and air in the vibration-assisted group (P < .01) as compared with the control group, suggesting tighter graft compaction. Cement volume was also significantly reduced in the middle region in the vibration-assisted group. No difference was observed in the distal region. This study demonstrates the value of vibration and drainage in bone graft compaction, with implications therein for clinical application and outcome.     

Interactions with nanoscale topography: adhesion quantification and signal transduction in cells of osteogenic and multipotent lineage

Polymeric medical devices widely used in orthopedic surgery play key roles in fracture fixation and orthopedic implant design. Topographical modification and surface micro-roughness of these devices regulate cellular adhesion, a process fundamental in the initiation of osteoinduction and osteogenesis. Advances in fabrication techniques have evolved the field of surface modification; in particular, nanotechnology has allowed the development of nanoscale substrates for the investigation into cell-nanofeature interactions. In this study human osteoblasts (HOBs) were cultured on ordered nanoscale pits and random nano "craters" and "islands". Adhesion subtypes were quantified by immunofluorescent microscopy and cell-substrate interactions investigated via immuno-scanning electron microscopy. To investigate the effects of these substrates on cellular function 1.7 k microarray analysis was used to establish gene profiles of enriched STRO-1+ progenitor cell populations cultured on these nanotopographies. Nanotopographies affected the formation of adhesions on experimental substrates. Adhesion formation was prominent on planar control substrates and reduced on nanocrater and nanoisland topographies; nanopits, however, were shown to inhibit directly the formation of large adhesions. STRO-1+ progenitor cells cultured on experimental substrates revealed significant changes in genetic expression. This study implicates nanotopographical modification as a significant modulator of osteoblast adhesion and cellular function in mesenchymal populations.