Investigating the biological response of human mesenchymal stem cells to titanium surfaces.

BACKGROUND: We have investigated the behaviour of a newly characterised population of haemarthrosis fluid-derived human mesenchymal stem cells (HF-hMSCs) with titanium (Ti) surfaces. METHODS: HF-hMSCs were seeded onto round cannulated interference (RCI; Smith and Nephew) screws or control Ti discs and cultured under pro-osteogenic conditions. RESULTS: Electron microscopy showed the attachment and spreading of HF-hMSCs across both Ti surfaces during the early stages of osteogenic culture; however, cells were exclusively localised to the basal regions within the vertex of the Ti screws. In the later stages of culture, an osteoid matrix was deposited on the Ti surfaces with progressive culture expansion and matrix deposition up the sides and the top of the Ti Screws. Quantification of cellular content revealed a significantly higher number of cells within the Ti screw cultures; however, there was no difference in the cellular health. Conversely, alizarin red staining used as both a qualitative and quantitative measure of matrix calcification was significantly increased in Ti disc cultures compared to those of Ti screws. CONCLUSIONS: Our results suggest that the gross topography of the metal implant is able to create microenvironment niches that have an influence on cellular behaviour. These results have implications for the design of advanced tissue engineering strategies that seek to use cellular material to enhance biological remodelling and healing following tissue reconstruction.

Biocompatibility and enhanced osteogenic differentiation of human mesenchymal stem cells in response to surface engineered poly(D,L-lactic-co-glycolic acid) microparticles.

Tissue engineering strategies can be applied to enhancing osseous integration of soft tissue grafts during ligament reconstruction. Ligament rupture results in a hemarthrosis, an acute intra-articular bleed rich in osteogenic human mesenchymal stem cells (hMSCs). With the aim of identifying an appropriate biomaterial with which to combine hemarthrosis fluid-derived hMSCs (HF-hMSCs) for therapeutic application, this work has investigated the biocompatibility of microparticles manufactured from two forms of poly(D,L-lactic-co-glycolic acid) (PLGA), one synthesized with equal monomeric ratios of lactic acid to glycolic acid (PLGA 50:50) and the other with a higher proportion of lactic acid (PLGA 85:15) which confers a longer biodegradation time. The surfaces of both types of microparticles were functionalized by plasma polymerization with allylamine to increase hydrophilicity and promote cell attachment. HF-hMSCs attached to and spread along the surface of both forms of PLGA microparticle. The osteogenic response of HF-hMSCs was enhanced when cultured with PLGA compared with control cultures differentiated on tissue culture plastic and this was independent of the type of polymer used. We have demonstrated that surface engineered PLGA microparticles are an appropriate biomaterial for combining with HF-hMSCs and the selection of PLGA is relevant only when considering the biodegradation time for each biomedical application.

Low oxygen tension is critical for the culture of human mesenchymal stem cells with strong osteogenic potential from haemarthrosis fluid.

Satisfactory osseous tissue integration of the soft tissue graft with bone is the mainstay of healing following surgical reconstruction of the anterior cruciate ligament (ACL). However, tissue remodelling is slow and significantly impacts on quality of life by delaying return to work and sport and accelerating the onset of degenerative diseases such as osteoarthritis. Delivery of multipotent human mesenchymal stem cells (hMSCs) at surgery could enhance osseous tissue integration. We aim to use hMSCs derived from haemarthrosis fluid (HF) (the intra-articular bleed accrued post-trauma) which is aspirated and discarded as clinical waste. With the aim of improving our bioprocessing methodologies for clinical translation we have investigated the effect of low oxygen tension on the derivation and osteogenic potential of this novel HF-hMSC population. Mononuclear cells were isolated from HF aspirated samples and divided for derivation and culture under normal or low oxygen tension. HF-hMSCs were derived from 100 % of cultures under low oxygen tension compared to 71 % for normal oxygen tension; this was coupled with increased CFU-Fs. We investigated the osteogenic potential and cellular health of HF-hMSC populations following ex vivo expansion. HF-hMSC populations showed enhanced matrix mineralisation and cellular health when differentiated under low oxygen tension. This positive effect of low oxygen on osteogenesis and cellular health was reduced with prolonged culture. These data demonstrate that derivation and culture of HF-hMSC populations under low oxygen tension will enable the translation of a cellular therapy for the treatment of broad patient numbers with optimal osteogenic potency and cellular vitality.