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Orthopaedic Proceedings
Vol. 100-B, Issue SUPP_16 | Pages 75 - 75
1 Nov 2018
Hoey D
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Osteoporosis affects millions globally and current anti-catabolic treatments are limited by significant side-effects. Osteoporosis arises when skeletal stem cells (SSC) no longer sufficiently replenish osteoblasts, leading to net bone loss. A key regulator of SSC behaviour is physical loading, yet the mechanisms by which SSCs sense and respond to changes in their mechanical environment are virtually unknown. Primary cilia are nearly ubiquitous ‘antennae-like’ cellular organelles that have very recently emerged as extracellular chemo/mechano-sensors and thus, are strong candidates to play an important role in regulating SSC responses in bone. This paper will demonstrate that the SSC primary cilium plays an important role in loading-induced bone formation via initial chemosensation and transduction of the potent chemokine TGFβ1 regulating SSC recruitment to the bone surface and secondly it will be shown that the primary cilium is a cAMP responsive mechanosensor directly regulating SSC mechanotransduction via localisation of adenylyl cyclase 6 to the ciliary microdomain. Finally, it will be shown that targeting the cilium therapeutically can be an effective approach to enhance both biochemical and biophysically induced SSC osteogenesis contributing to bone formation, demonstrating a novel anabolic therapy for bone loss diseases such as osteoporosis


Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XXXIX | Pages 204 - 204
1 Sep 2012
Smith J Dawson J Aarvold A Jones A Ridgway J Curran S Dunlop D Oreffo R
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Background. Replacing bone lost as a consequence of trauma or disease is a major challenge in the treatment of musculoskeletal disorders. Tissue engineering strategies seek to harness the potential of stem cells to regenerate lost or damaged tissue. Bone marrow aspirate (BMA) provides a promising autologous source of skeletal stem cells (SSCs) however, previous studies have demonstrated that the concentration of SSCs required for robust tissue regeneration is below levels present in iliac crest BMA, emphasising the need for cell enrichment strategies prior to clinical application. Aims. To develop a novel strategy to enrich skeletal stem cells (SSCs) from human BMA, clinically applicable for intra-operative orthopaedic use. Methods. Iliac crest BMA was purchased from commercial suppliers and femoral canal BMA was obtained with informed consent from older patients undergoing total hip replacement. 5 to 40ml of BMA was processed to obtain 2–8 fold volume reductions. SSC function was assessed by assays for fibroblastic colony-forming units (CFU-F). Cell viability and seeding efficiency of processed and unprocessed aspirates applied to allograft was assessed. Results. Iliac crest BMA from 15 patients was enriched for SSCs in a processing time of only 15 minutes. Femoral BMA from 15 patients in the elderly cohort was concentrated up to 5-fold with a corresponding enrichment of viable, functional SSCs as confirmed by flow cytometry, CFU-F assays and histological analysis. The SSC enrichment of bone marrow aspirate significantly enhanced cell seeding efficiency onto allograft confirming the utility of this approach for application to bone regeneration. Conclusion. The ability to rapidly enrich BMA demonstrates the potential of this strategy for intra-operative application to enhance bone healing. The development of this device offers immediate potential for clinical application to reduce morbidity in many scenarios associated with local bone stock loss. Further analysis in vivo is ongoing prior to clinical tests


Orthopaedic Proceedings
Vol. 100-B, Issue SUPP_15 | Pages 54 - 54
1 Nov 2018
Riffault M Johnson G Hoey D
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Bone tissue experiences continued remodelling in response to changes in its biochemical and biophysical environment. Given the finite lifespan of osteoblasts, this continued bone formation requires replenishment from a progenitor population. Although this is largely believed to be from a skeletal stem cell population, given the limitation in in-vivo markers for this cell type, progress in demonstrating this mechanism is limited. Therefore, we characterized the LepR-Cre mouse strain and evaluated whether LepR positive cells are the progenitor population and if they contribute to the osteoblast population over time and in mechanically-induced bone formation in-vivo. Transgenic mouse strains; B6.129(Cg)-Leprtm2(cre)Rck/J to study LepR-expressing cells and B6.Cg-Gt(ROSA)26Sortm9(CAG-tdTomato)Hze/J as a reporter strain were obtained from Jackson Laboratories. Characterization studies were performed on LepR:tdTomato mice at embryonic stage (19.5dpc), 8 and 12 weeks old. Mice (12 weeks old) were subjected to compressive tibia loading with a 11N peak load for 40 cycles, every other day for 2 weeks. Histological analysis reveal that LepR is expressed from the embryonic stage in various organs including bones. LepR positive cells are found around blood vessels and on bone surfaces. Flow cytometry analysis show the amount of LepR positive cells negative for CD45 and Ter-119 markers inside the bone marrow increases over time and following tibial loading. Mechanical loading induces an increase in bone mass and bone parameters. This model allows us to track and evaluate the role of LepR positive cells as bone forming cells, and to decipher the role of these cells in mechanically-induced bone formation


Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XXXIX | Pages 163 - 163
1 Sep 2012
Smith J Sengers B Aarvold A Tayton E Dunlop D Oreffo R
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Recently, the osteoregenerative properties of allograft have been enhanced by addition of autogenous skeletal stem cells to treat orthopaedic conditions characterised by lost bone stock. There are multiple disadvantages to allograft, and trabecular tantalum represents a potential alternative. This metal is widely used, although in applications where there is poor initial stability, or when it is used in conjunction with bone grafting, loading may need to be limited until sound integration has occurred. Strategies to speed up implant incorporation to surrounding bone are therefore required. This may improve patient outcomes, extending the clinical applications of tantalum as a substitute for allograft. Aim. To use tissue engineering strategies to enhance the reconstructive properties of tantalum, as an alternative to allograft. Methods. Human bone marrow stromal cells (5×10. 5. cells/ml) were cultured on blocks of trabecular tantalum or allograft for 28 days in basal and osteogenic media. Molecular profiling, confocal and scanning electron microscopy, as well as live/dead staining and biochemical assays were used to detail cell adherence, proliferation and phenotype. Results. Cells displayed extensive adherence and proliferation throughout trabecular tantalum. Samples cultured in osteogenic conditions showed abundant matrix production. Electron microscopy confirmed significant cellular growth through tantalum to a depth of 5mm. In contrast to cells cultured with allograft in both basal and osteogenic conditions, cell proliferation and biochemical assays showed significantly higher activity with tantalum than allograft. Furthermore, alkaline phosphatase (ALP) assay and molecular profiling confirmed no significant difference in expression of ALP, Runx-2, Col-1 and Sox-9 between cells cultured on tantalum and allograft. Conclusions. These studies demonstrate trabecular tantalum supports cell growth and osteogenic differentiation at least as well as allograft. Trabecular tantalum represents a good alternative to allograft for tissue engineering osteoregenerative strategies in the context of lost bone stock. Further mechanical testing and in vivo studies are on-going


The Journal of Bone & Joint Surgery British Volume
Vol. 94-B, Issue 6 | Pages 848 - 855
1 Jun 2012
Tayton ER Smith JO Aarvold A Kalra S Dunlop DG Oreffo ROC

When transferring tissue regenerative strategies involving skeletal stem cells to human application, consideration needs to be given to factors that may affect the function of the cells that are transferred. Local anaesthetics are frequently used during surgical procedures, either administered directly into the operative site or infiltrated subcutaneously around the wound. The aim of this study was to investigate the effects of commonly used local anaesthetics on the morphology, function and survival of human adult skeletal stem cells. Cells from three patients who were undergoing elective hip replacement were harvested and incubated for two hours with 1% lidocaine, 0.5% levobupivacaine or 0.5% bupivacaine hydrochloride solutions. Viability was quantified using WST-1 and DNA assays. Viability and morphology were further characterised using CellTracker Green/Ethidium Homodimer-1 immunocytochemistry and function was assessed by an alkaline phosphatase assay. An additional group was cultured for a further seven days to allow potential recovery of the cells after removal of the local anaesthetic. A statistically significant and dose dependent reduction in cell viability and number was observed in the cell cultures exposed to all three local anaesthetics at concentrations of 25% and 50%, and this was maintained even following culture for a further seven days. This study indicates that certain local anaesthetic agents in widespread clinical use are deleterious to skeletal progenitor cells when studied in vitro; this might have relevance in clinical applications


Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_16 | Pages 36 - 36
19 Aug 2024
Ma C Goodnough LH Zhao L Chow SK Wang Y Chan CKF Goodman SB
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Bone marrow stem cells (BMSCs) represent a collection of different cell types exhibiting stem cell characteristics but with notable heterogeneity. Among these, Skeletal Stem Cells (SSCs) represent a distinct matrix subgroup within BMSC and demonstrate a specialized capacity to facilitate bone formation, recruit chondrocytes, and contribute to hematopoiesis. SSCs play a pivotal role in orchestrating the functions of skeletal organs. Local ischemia has a significant impact on cell survival and function. We hypothesize that bone ischemia induces alterations in the differentiation potential of SSCs, consequently influencing changes in bone structure. We mechanically dissected tissue from the necrotic segment in the femoral head and more normal appearing areas from the femoral neck of specimens from 5 patients diagnosed with osteonecrosis of the femoral head (ONFH). These tissues were enzymatically broken down into individual cell suspensions. Utilizing fluorescence-activated cell sorting (FACS) based on specific surface markers indicative of human skeletal stem cells (hSSC), namely CD45- CD235a- CD31- TIE2- Podoplanin (PDPN)+ CD146- CD73+ CD164+, we isolated a distinct cell population. Subsequent in vitro evaluations, focusing on clonogenicity, osteogenesis, and chondrogenesis were conducted to assess the functional prowess of these SSCs. Moreover, we introduced BMP2 at a concentration of 50ng/ml to SSCs extracted from necrotic regions to potentially reinstate their osteogenic capabilities. We effectively isolated SSCs from both Necrotic and Non-necrotic Zones. We observed an augmented clonal formation capacity and chondrogenesis ability of SSCs isolated from the necrotic region, accompanied by a significant decline in osteogenic ability (P<0.01), an effect not reversible even with the addition of BMP2. Ischemia adversely affects the proliferation and function of SSCs, resulting in a diminished osteogenic capacity and an insensitivity to BMP2, ultimately leading to structural alterations in bone tissue


Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_1 | Pages 126 - 126
2 Jan 2024
Schmidt S Klampfleuthner F Diederichs S
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The signaling molecule prostaglandin E2 (PGE2), synthesized by cyclooxygenase-2 (COX-2), is immunoregulatory and reported to be essential for skeletal stem cell function. Nonsteroidal anti-inflammatory drugs (NSAIDs) are widely used in osteoarthritis (OA) analgesia, but cohort studies suggested that long-term use may accelerate pathology. Interestingly, OA chondrocytes secrete high amounts of PGE2. Mesenchymal stromal cell (MSC) chondrogenesis is an in vitro OA model that phenocopies PGE2 secretion along with a hypertrophic OA-like cell morphology. Our aim was to investigate cause and effects of PGE2 secretion in MSC-based cartilage neogenesis and hypertrophy and identify molecular mechanisms responsible for adverse effects in OA analgesia. Human bone marrow-derived MSCs were cultured in chondrogenic medium with TGFβ (10ng/mL) and treated with PGE2 (1µM), celecoxib (COX-2 inhibitor; 0.5µM), AH23848/AH6809 (PGE2 receptor antagonists; 10µM), or DMSO as a control (n=3–4). Assessment criteria were proteoglycan deposition (histology), chondrocyte/hypertrophy marker expression (qPCR), and ALP activity. PGE2 secretion was measured (ELISA) after TGFβ withdrawal (from day 21, n=2) or WNT inhibition (2µM IWP-2 from day 14; n=3). Strong decrease in PGE2 secretion upon TGFβ deprivation or WNT inhibition identified both pathways as PGE2 drivers. Homogeneous proteoglycan deposition and COL2A1 expression analysis showed that MSC chondrogenesis was not compromised by any treatment. Importantly, hypertrophy markers (COL10A1, ALPL, SPP1, IBSP) were significantly reduced by PGE2 treatment, but increased by all inhibitors. Additionally, PGE2 significantly decreased ALP activity (2.9-fold), whereas the inhibitors caused a significant increase (1.3-fold, 1.7-fold, 1.8-fold). This identified PGE2 as an important inhibitor of chondrocyte hypertrophy. Although TGFβ and WNT are known pro-arthritic signaling pathways, they appear to induce a PGE2-mediated antihypertrophic effect that can counteract pathological cell changes in chondrocytes. Hampering this rescue mechanism via COX inhibition using NSAIDs thus risks acceleration of OA progression, indicating the need of OA analgesia adjustment


Orthopaedic Proceedings
Vol. 100-B, Issue SUPP_15 | Pages 8 - 8
1 Nov 2018
Oreffo R
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Advances in our understanding of skeletal stem cells and their role in bone development and repair, offer the potential to open new frontiers in bone regeneration. However, the ability to harness these cells to replace or restore the function of traumatised or lost skeletal tissue as a consequence of age or disease remains a significant challenge. We have developed protocols for the isolation, expansion and translational application of skeletal cell populations with cues from developmental biology informed by in vitro and ex vivo models as well as, nanoscale architecture and biomimetic niche development informing our skeletal tissue engineering approaches. We demonstrate the importance of biomimetic cues and delivery strategies to directly modulate differentiation of human adult skeletal cells and, central to clinical application, translational studies to examine the efficacy of skeletal stem and cell populations in innovative scaffold compositions for orthopaedics. While a number of challenges remain multidisciplinary approaches that integrate developmental and engineering processes as well as cell, molecular and clinical techniques for skeletal tissue engineering offer significant promise. Harnessing such approaches across the hard tissue interface will ultimately improve the quality of life of an increasing ageing population


Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XVIII | Pages 26 - 26
1 May 2012
Jones A Aarvold A New A Dunlop D Oreffo R
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AIM. Avascular necrosis (AVN) of the femoral head is a potentially debilitating disease of the hip in young adults. Impaction bone grafting (IBG) of morcellised fresh frozen allograft is used in a number of orthopaedic conditions. This study has examined the potential of skeletal stem cells (SSC) to augment the mechanical properties of impacted bone graft and we translate these findings into clinical practice. STUDY DESIGN. We have examined the effect of SSC density on augmentation of bone formation. An in vitro model was developed to replicate the surgical IBG process. Plain allograft was used as the control, and the SSC's seeded at a density of 5×103, 5×104 and 2×105 cells per cc of allograft for the experimental groups. All samples were cultured for 2 weeks and mechanically tested to determine shear strength using the Mohr Coulomb failure curve. The approach was translated to 3 patients with early avascular necrosis (AVN) of the femoral head. The patient's bone marrow was concentrated in theatre using a centrifugation device and the concentrated fraction of SSC's were seeded onto milled allograft. The patient's necrotic bone was drilled, curetted and replaced with impacted allograft seeded with SSC's. Osteogenic potential of concentrated and unconcentrated marrow was simultaneously compared in vitro by colony forming unit assays. RESULTS. The mechanical properties of the impacted allograft was significantly improved as a function of increasing SSC density. The difference compared to the control plain allograft was highly significant at the 2×105 level (p=0.001). Autologous SCC's on impacted bone allograft was subsequently applied in 3 patient cases and up to two year follow up demonstrates no deleterious effect. Critically the analysis of concentrated marrow demonstrated a higher SSC count in vitro than plain marrow aspirate. DISCUSSION. We have demonstrated the potential of skeletal stem cells to augment the mechanical properties of impacted bone allograft in a laboratory model and subsequently translated these findings into a new technique for the treatment of AVN of the femoral head. Such an approach provides not only improved mechanical support to the overlying cartilage but critically improved biology for new bone formation. The early clinical results are encouraging and indicate potential use also in fracture non-unions and void filling of bone defects


Orthopaedic Proceedings
Vol. 88-B, Issue SUPP_III | Pages 392 - 392
1 Oct 2006
He Q Wan C Li G
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Introduction: The existence of circulating skeletal stem cells in the peripheral blood from different species including adult mouse and human has been found and documented. The circulating skeletal stem cells may provide a new source of stem cells that may be used for bone regeneration and tissue engineering applications. The aim of this study was to investigate the existence of circulating osteogenic stem cells in the rat peripheral blood, and to compare their osteogenic potentials with bone marrow mesenchymal stem cells (BMMSCs). Methods: Whole blood from twelve female 3-month old SD rats was harvested by cardiac puncture and bone marrows were also collected. Mononuclear cells from both bone marrow and peripheral blood (PBMNCs) were isolated by Lymphoprep density gradient centrifugation method, and plated at a density of 300000 to 400000/cm2 in flasks with á-MEM medium and 15% FCS. The colony forming efficiency (CFE) was calculated after 10–14 days culture. The osteogenic, adipogenic, and chondrogenic differentiation potential of both BMMSCs and peripheral blood mononuclear cell subset were examined and compared under different specific culture conditions. In addition, both BMMSCs and peripheral blood mononuclear cell subset were seeded into absorbable porous calcium phosphate substitute and implanted subcutaneously into SCID mice for 12 weeks, and the implants were examined histologically. Results: After 10–14 days in culture, the adherent fibroblast-like colonies were formed in the PBMNCs, with CFE ranging from 1.3 to 3.5 per 10000000 cells. Under osteogenic conditions, both BMMSCs and PBMNCs subset were positive for bone markers such as ALP, type I collagen and osteocalcin; bone nodules were formed in BMMSCs and PBMNCs subset long-term culture with positive Von Kossa and Alizarin Red S staining. Under adipogenic conditions, PBMNCs subset and BMMSCs were positive for Oil Red O and C/EBP á immunostaining. For chondrogenic differentiation studies, PBMNCs subset and BMMSCs were positive for type II collagen and they had Alcian blue positive nodules formation. After implantation with calcium phosphate substitutes in SCID mice for 12 weeks, osteoid and bony tissues were evident in the implants both loaded with PBMNCs subset and BMSCSs. Conclusions: A subset of mononuclear cells that have multi-differentiation potential similar to BMMSCs exists in the rat peripheral blood. Our present study has shown that these circulating stem cells possess osteogenic potential in vitro and in vivo. Further work is ongoing to investigate the roles of PBMNCs subset in fracture healing and their recruiting and homing mechanisms


Orthopaedic Proceedings
Vol. 100-B, Issue SUPP_15 | Pages 74 - 74
1 Nov 2018
Eichholz KF Hoey DA
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The architecture within which cells reside is key to mediating their specific functions within the body. In this study, we use melt electrospinning writing (MEW), a recently developed 3D printing technology unique in its ability to generate ECM like fibres and control their deposition, to fabricate cell micro-environments with various fibrous architectures to study their effect on human stem cell behaviour. We designed, built and optimised a MEW apparatus and used it to fabricate four different platform designs of 10.4±2μm fibre diameter, with angles between fibres on adjacent layers of 90°, 45°, 10° and R (random). Characterisation was conducted via scanning electron microscopy (SEM) imaging and tensile testing, and human skeletal stem cells (hSSCs) were seeded to scaffolds to study the effect of architecture on cell morphology and mechanosensing. Cell morphology was significantly altered between groups, with cells on 90° scaffolds having a lower aspect ratio, greater spreading, greater cytoskeletal tension and nuclear YAP expression. Long term cell culture studies were then conducted to determine the differentiation potential of scaffolds in terms of alkaline phosphatase activity, collagen and mineral production. Across these studies, an increased cell spreading in 3-dimensions is seen, with decreasing alignment of architecture correlated with enhanced osteogenesis, as seen by significant fold increases in ALP (2.8), collagen (2.5) and calcium (3.6) in the 90° scaffold architecture compared to 10°. This study therefore highlights the critical role of fibrous architecture in regulating stem cell behaviour with implications for tissue engineering and disease progression


Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_8 | Pages 76 - 76
1 Apr 2017
Goriainov V Pedersen R Gadegaard N Dunlop D Oreffo R
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Background. Following endosteal uncemented orthopaedic device implantation, the initial implant/bone interface retains spaces and deficiencies further exacerbated by pressure necrosis and resultant bone resorption. This implant-bone space requires native bone infill through the process of de novo osteogenesis. New appositional bone formation on the implant surface is known as contact osteogenesis and is generated by osteogenic cells, including skeletal stem cells (SSCs), colonising the implant surface and depositing the extracellular bone matrix. Surface nanotopographies provide physical cues capable of triggering SSC differentiation into osteoblasts, thus inducing contact osteogenesis, translated clinically into enhanced osseointegration and attainment of secondary stability. The current study has investigated the in vitro and in vivo effects of unique nanotopographical pillar substrates on SSC phenotype and function. Methods. Adult human SSCs were immunoselected, enriched using STRO-1 antibody and cultured on control and test surfaces for 21 days in vitro. The test groups comprised Ti-coated substrates with planar or modified surfaces with nanopillar. Osteoinductive potential was analysed using qPCR and immunostaining to examine gene expression and protein synthesis. Results. Following in vitro (n=5) culture on nanopillars, the expression of osteogenic genes (ALP, Collagen 1, OPN and OCN) and of Osteopontin protein (a bone matrix protein), on Ti pillars were both significantly enhanced when compared to control or Ti planar surfaces. Conclusions. Discrete raised surface nanopillars modulate adult SSC populations in the absence of any chemical cues and enhance their osteogenic properties, an effect not observed on planar Ti constructs. Hence, these findings herald exciting opportunities to improve the implant surface design, implant osseointegration, and, ultimately, implant survival. Level of evidence. Original experimental study


Orthopaedic Proceedings
Vol. 98-B, Issue SUPP_2 | Pages 4 - 4
1 Jan 2016
Latham J Goriainov V Pedersen R Gadegaard N Dunlop D Oreffo R
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Background. In 2012, the National Joint Registry recorded 86,488 primary total hip replacements (THR) and 9,678 revisions (1). To date aseptic loosening remains the most common cause of revision in hip and knee arthroplasty, accounting for 40% and 32% of all cases respectively and emphasising the need to optimise osseointegration in order to reduce revisions. Clinically, osseointegration results in asymptomatic stable durable fixation of orthopaedic implants. Osseointegration is a complex process involving a number of distinct mechanisms affected by the implant surface topography, which is defined by surface orientation and surface roughness. Micro- and nano-topography levels have discrete effects on implant osseointegration and yet the role on cell function and subsequent bone implant function is unknown. Nanotopography such as collagen banding is a critical component influencing the SSC niche in vivo and has been shown to influence a range of cell behaviours in vitro (2,3). We have used unique fabricated nanotopographical pillar substrates to examine the function of human bone stem cells on titanium surfaces. Aim. To investigate the effect of nanotopographical cues on adult skeletal stem cell (SSC) fate, phenotype and function within in-vitro environments. Materials and methods. Adult human skeleltal stem cells (SSCs) were immunoselected and enriched using STRO-1 antibody and cultured on tissue culture plastic (TCP) and titanium-coated nanotopgraphical substrates (illustrated in Figure 1). Following culture, metabolic activity of SSCs on TCP and Ti substrates was compared. Subsequently, osteoinductive potential was analysed under basal and osteogenic conditions (four groups: TCP in basal media, TCP in osteogenic media, Ti planar substrates basal and Ti pillar substrates basal). Results. At 7 days, cell metabolic activity was significantly enhanced on Ti substrates, specifically on Ti pillars of defined height in comparison to TCP (Figure 2). Following culture on defined topographies for 21 days, expression of the bone matrix protein, osteopontin, on Ti pillars was significantly enhanced when compared to TCP or Ti planar (Figure 3). Conclusion. We demonstrate the ability of discrete raised nanopillars to modualte adult SSC populations in the absence of any chemical cues. These results indicate the potential of discrete and defined nanopillar constructs to stimulate SSC function, an effect not observed on planar Ti constructs. These findings herald exciting opportunities to improve the bioactivity of implant design and, ultimately, osseointegration with clinical implications therein


Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XXXVII | Pages 145 - 145
1 Sep 2012
Tayton E Kalra S Briscoe A Aarvold A Smith J Lanham S Fahmy S Howdle S Shakesheff K Dunlop D Oreffo R
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Background. Impaction bone grafting with milled human allograft is the gold standard for replacing lost bone stock during revision hip surgery. Problems surrounding the use of allograft include cost, availability, disease transmission and stem subsidence (usually due to shear failure of the surrounding allograft). Aims. To investigate various polymers for use as substitute allograft. The ideal graft would be a composite with similar mechanical characteristics as allograft, and with the ability to form de novo bone. Methods. High and low molecular weight (MW) forms of three different polymers (polylactic acid (PLA), poly (lactic-co-glycolic) acid (PLGA) and polycaprolactone (PCL)) were milled, impacted into discs, and then tested in a custom built shear testing rig, and compared to allograft. A second stage of the experiment involved the addition of skeletal stem cells (SSC) to each of the milled polymers, impaction, 8 days incubation, and then tests for cell viability and number, via fluorostaining and biochemical (WST-1, DNA) assays. Results. The shear strengths of both high/ low MW PLA, and high/low MW PLGA were significantly higher than those of milled allograft but high and low MW PCL was poor to impact, and had significantly lower shear strengths. Fluorostaining showed good cell survival on high MW PLA, high MW PCL and both high and low MW PLGA. These findings were confirmed on both DNA and WST-1 assays. Conclusions. High MW PLA as well as high and low MW PLGA performed well both in mechanical testing and cell compatibility studies. These three polymers are good contenders to produce a living composite for use as substitute human allograft in impaction bone grafting


Orthopaedic Proceedings
Vol. 91-B, Issue SUPP_II | Pages 269 - 269
1 May 2009
Giannicola G Cinotti G Riminucci M Corsi A Ferrari E Mancini U Citro G Sacchetti F Sacchetti B Bianco P Postacchini F
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Aims: Aims of this study was to perform a quantitatively evaluation of newly formed bone, vascular density (VD) and their correlation in animal model of posterolateral spinal fusion based on skeletal stem cells (SSCs) combined with a coral. Methods: 15 rabbits received cell-material constructs, 15 rabbits were sham-operated (decortication of transverse apophyses), 15 rabbits received material alone. After 6 months the animals were sacrified. We performed a semi-quantitative and quantitative histologycal analysis of the fusion mass. To assess the VD, sections of the fusion mass were immunolabelled for alpha-smooth muscle actin as a vascular marker. Results: No complete fusion was observed in all groups and no bone was formed in the interapophyseal region. Aboundant newly formed bone was observed in the peri-apophyseal regions in 60% of cases. The quantitative analysis showed a significantly higher amount of bone and VD in animals treated with cells and/or biomaterial alone compared to sham (p< 0.05). Periapophyseal VD and new bone formation was significantly higher compared to interapophyseal region in all groups (p< 0.05). Positive correlation exist between newly formed bone and vascolar density (p = 0,0009). Conclusions: Interapophyseal region is scarcely vascolarized. The study shows a positive correlation between VD and osteogenesis. The inadequacy of staminal cells could be related with the poor survival after the implant. For the use of stam cells in the APL are necessary more studies in order to clarify the survival and in situ differentiation of the grafted cells in short and mid term


Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XXXVI | Pages 20 - 20
1 Aug 2012
Tayton E Fahmy S Aarvold A Smith J Kalra S Briscoe A Purcell M Shakesheff K Howdle S Dunlop D Oreffo R
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Impaction bone grafting with milled human allograft is the gold standard for replacing lost bone stock during revision hip surgery. Problems surrounding the use of allograft include cost, availability, disease transmission and stem subsidence (usually due to shear failure of the surrounding allograft). The aim of this study was to investigate various polymers for use as substitute allograft. The ideal graft would be a composite with similar mechanical characteristics as allograft, and with the ability to form de novo bone. High and low molecular weight (MW) forms of three different polymers (polylactic acid (PLA), poly (lactic co-glycolic) acid (PLGA) and polycaprolactone (PCL)) were milled, impacted into discs, and then tested in a custom built shear testing rig, and compared to allograft. A second stage of the experiment involved the addition of skeletal stem cells (SSC) to each of the milled polymers, impaction, 8 days incubation, and then tests for cell viability and number, via fluorostaining and biochemical (WST-1) assays. The shear strengths of both high/ low MW PLA, and high/low MW PLGA were significantly higher than those of milled allograft (P<0.001, P<0.001, P<0.005 and P<0.005) but high and low MW PCL was poor to impact, and had significantly lower shear strengths (P<0.005, P<0.001). Fluorostaining showed good cell survival on high MW PLA, high MW PCL and high MW PLGA. These findings were confirmed with WST-1 assays. High MW PLA as well as high MW PLGA performed well both in mechanical testing and cell compatibility studies. These two polymers are good contenders to produce a living composite for use as substitute human allograft in impaction bone grafting, and are currently being optimised for this use via the investigation of different production techniques and in-vivo studies


Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XXIV | Pages 12 - 12
1 May 2012
Aarvold A Smith J Edwards C Tayton E Gent E Oreffo RC
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Background. Unicameral bone cysts (UBCs) are difficult to treat and have a high recurrence rate. Their pathogenesis is unknown making targeted therapies difficult. Attributed causes include venous and interstitial fluid obstruction, oxygen free radicals, lysosomal enzymes, prostaglandins and genetic factors. Skeletal stem cells (SSCs) are osteoblast precursors critical to bone formation and cyst fluid may influence their growth, however the association between SSCs and cyst fluid has never been investigated. Aim. To investigate the effect of UBC fluid on SSC growth. Methods. Fluid was aspirated from a UBC in the proximal femur of a nine year old boy and centrifuged to isolate the acellular supernatant. SSCs were harvested from bone marrow of a haematologically normal adult and cultured with graded concentrations of cyst fluid in culture media (0,10,25,50%). Cell growth was assessed by alkaline phosphatase staining, and cytokine levels in the fluid were measured. Results. High levels of cytokines known to be chemo-attractive for cells of the of macrophage-monocyte lineage were found, including Macrophage Chemotactic Protein-1 (1853pg/ml), Monokine Induced by γ-interferon (656pg/ml), Macrophage Inflammatory Protein (MIP)-1α (401pg/ml) and MIP-1β (34pg/ml) suggesting a role of osteoclasts in UBC pathogenesis. Furthermore, SSC growth in vitro was reduced in cyst fluid in a concentration dependent manner. Conclusion. This is the first time altered SSC and osteoprogenitor function has been associated with the fluid of a UBC. A negative effect on osteogenesis was demonstrated, the precise mechanisms of which are under investigation, and macrophage-monocyte chemokines suggest high osteoclast activity. This study has indicated a role of the cyst fluid in limiting osteogenesis and bone turnover, which may explain the high failure rate for current interventions. More patients are needed to validate these findings


Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XXXIX | Pages 212 - 212
1 Sep 2012
Tayton E Purcell M Briscoe A Kalra S Aarvold A Smith J Fahmy S Shakesheff K Howdle S Dunlop D Oreffo R
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Aims. Disease transmission, availability and economic costs of allograft have resulted in significant efforts into finding an allograft alternative for use in impaction bone grafting (IBG). Biotechnology offers the combination of skeletal stem cells (SSC) with biodegradable polymers as a potential solution. Recently polymers have been identified with both structural strength and SSC compatibility that offer the potential for clinical translation. The aim of this study was to assess whether increasing the porosity of one such polymer via super critical CO. 2. fluid foaming (SCF) enhanced the mechanical and cellular compatibility characteristics for use as an osteogenic alternative to allograft in IBG. Methods. High molecular weight PLA scaffolds were produced via traditional (solid block) and SCF (porous) techniques, and the differences characterised using scanning electron microscopy (SEM). The polymers were milled, impacted, and mechanical comparison between traditional vs SCD created scaffolds and allograft controls was made using a custom shear testing rig, as well as a novel agitation test to assess cohesion. Cellular compatibility tests for cell number, viability and osteogenic differentiation using WST-1 assays, fluorostaining and ALP assays were determined following 14 day culture with SSC's. Results. SEM showed increased porosity of the SCF produced PLA scaffolds, with pores between 50–100µm. Shear testing showed the SCF polymer exceeded the shear strength of allograft controls (P< 0.001). Agitation testing showed greater cohesion between the particles of the SCF polymer (P< 0.05). Cellular studies showed increased cell number, viability and osteogenic differentiation on the SCF polymer compared to traditional polymer (P< 0.05) and allograft (P< 0.001). Conclusions. The use of supercritical C0. 2. to generate PLA scaffolds significantly improves the cellular compatibility and cohesion compared to traditional non-porous PLA, without substantial loss of mechanical shear strength. The improved characteristics are critical for clinical translation as a potential osteogenic composite for use in IBG


Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XXXIX | Pages 211 - 211
1 Sep 2012
Tayton E Fahmy S Aarvold A Smith J Kalra S Briscoe A Shakesheff K Howdle S Dunlop D Oreffo R
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Aims. Impaction bone grafting with milled human allograft is the gold standard for replacing lost bone stock during revision hip surgery. Problems surrounding the use of allograft include cost, availability, disease transmission and stem subsidence (usually due to shear failure of the surrounding allograft). The aim of this study was to investigate various polymers for use as substitute allograft. The ideal graft would be a composite with similar mechanical characteristics as allograft, and with the ability to form de novo bone. Methods. High and low molecular weight (MW) forms of three different polymers (polylactic acid (PLA), poly (lactic co-glycolic) acid (PLGA) and polycaprolactone (PCL)) were milled, impacted into discs, and then tested in a custom built shear testing rig, and compared to allograft. A second stage of the experiment involved the addition of skeletal stem cells (SSC) to each of the milled polymers, impaction, 8 days incubation, and then tests for cell viability and number, via fluorostaining and biochemical (WST-1) assays. Results. The shear strengths of both high/low MW PLA, and high/low MW PLGA were significantly higher than those of milled allograft (P< 0.001, P< 0.001, P< 0.005 and P< 0.005) but high and low MW PCL was poor to impact, and had significantly lower shear strengths (P< 0.005, P< 0.001). Fluorostaining showed good cell survival on high MW PLA, high MW PCL and high MW PLGA. These findings were confirmed with WST-1 assays. Conclusions. High MW PLA as well as high MW PLGA performed well both in mechanical testing and cell compatibility studies. These two polymers are good contenders to produce a living composite for use as substitute human allograft in impaction bone grafting, and are currently being optimised for this use via the investigation of different production techniques and in-vivo studies


Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XXXVI | Pages 23 - 23
1 Aug 2012
Tayton E Purcell M Aarvold A Smith J Kalra S Briscoe A Fahmy S Shakesheff K Howdle S Dunlop D Oreffo R
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Disease transmission, availability and economic costs of allograft have resulted in significant efforts into finding an allograft alternative for use in impaction bone grafting (IBG). Biotechnology offers the combination of skeletal stem cells (SSC) with biodegradable polymers as a potential solution. Recently polymers have been identified with both structural strength and SSC compatibility that offer the potential for clinical translation. The aim of this study was to assess whether increasing the porosity of one such polymer via super critical CO2 dissolution (SCD) enhanced the mechanical and cellular compatibility characteristics for use as an osteogenic alternative to allograft in IBG. High molecular weight PLA scaffolds were produced via traditional (solid block) and SCD (porous) techniques, and the differences characterised using scanning electron microscopy (SEM). The polymers were milled, impacted, and mechanical comparison between traditional vs SCD created scaffolds and allograft controls was made using a custom shear testing rig, as well as a novel agitation test to assess cohesion. Cellular compatibility tests for cell number, viability and osteogenic differentiation using WST-1 assays, fluorostaining and ALP assays were determined following 14 day culture with SSCs. SEM showed increased porosity of the SCD produced PLA scaffolds, with pores between 50-100 micrometres. Shear testing showed the SCD polymer exceeded the shear strength of allograft controls (P<0.001). Agitation testing showed greater cohesion between the particles of the SCD polymer (P<0.05). Cellular studies showed increased cell number, viability and osteogenic differentiation on the SCD polymer compared to traditional polymer (P<0.05) and allograft (P<0.001). The use of supercritical C02 to generate PLA scaffolds significantly improves the cellular compatibility and cohesion compared to traditional non-porous PLA, without substantial loss of mechanical shear strength. The improved characteristics are critical for clinical translation as a potential osteogenic composite for use in impaction bone grafting