Improving periprosthetic bone is essential for implant fixation and reducing peri-implant fracture risk. This studied examined the individual and combined effects of iPTH and mechanical loading at the cellular, molecular, and tissue level for periprosthetic cancellous bone. Adult rabbits had a porous titanium implant inserted bilaterally on the cancellous bone beneath a mechanical loading device on the distal lateral femur. The right femur was loaded daily, the left femur received a sham loading device, and half of the rabbits received daily PTH. Periprosthetic bone was processed up to 28 days for qPCR, histology, and uCT analysis. We observed an increase in cellular and molecular markers of osteoblast activity and decrease in adipocytic markers for both treatments, with small additional effects in the combined group. Loading and iPTH led to a decrease and increase, respectively, in osteoclast number, acting through changes in RANKL/OPG expression. Changes in SOST and beta-catenin mRNA levels suggested an integral role for the Wnt pathway. We observed strong singular effects on BV/TV of both loading (1.53 fold) and iPTH (1.54 fold). Combined treatment showed a small additive effect on bone volume. In conclusion, loading and iPTH act through a pro-osteoblastic/anti-adipocytic response and through control of bone turnover via changes in the RANKL/OPG pathway. These changes led to a small additional, but not synergistic, increase in bone volume with the combined therapy.

Angiogenesis and the ability to provide appropriate vascular supply are crucial for skeletal tissue engineering. The aim of this study was to investigate the angiogenic potential of human dental pulp stromal cells (HDPSCs) and stro-1 positive populations as well as their role in tissue regeneration (the clinical reality).

HDPSC were isolated from the pulp tissues of human permanent teeth by collagenase digestion. STRO-1 positive cells were enriched using monoclonal anti- STRO-1 and anti- CD45 PE conjugated antibodies together with and fluorescence activated cell sorting (FACS). Cells isolated by FACS were grown to passage4 and cultured as monolayers or on 3D Matrigel scaffold in endothelial cell growth medium-2 (EGM-2) with/without 50ng/mL of vascular endothelial growth factor (VEGF). Cells cultured in alpha MEM supplemented with 10% FCS were used as controls. After 24, 48 and 72 hours angiogenic marker expression (CD31, CD34, vWF and VEGFR-2) was determined by qRT-PCR and immuno-histochemistry.

Using three different donors, 0.5-1.5% of total HDPSCs population was characterized as STRO-1+/CD45- cells At each time point cells cultured as monolayer in EGM-2 with VEGF showed up regulation of CD31 and VEGFR-2 expression compared to the control group while expression of CD34 and vWF remained unaffected. However on Matrigel, all four genes were up regulated to different extents. CD31 and VEGFR-2 were up regulated to a greater degree compared to CD34 and vWF. Changes in gene expression in both cell types were time dependent. Immuno-histochemical staining confirmed that the HDPSCs cultured in the test group showed positive staining for the four angiogenic markers (CD31, CD34 vWF and VEGFR-2) when grown in both monolayer and 3D Matrigel culture compared to control cultures. When cultured on Matrigel (but not Monolayer) for 7 days, HDPSC formed tube-like structures in the VEGF treated group.

This indicates the potential of use HDPSCs and their STRO-1 positive population for angiogenesis to enhance skeletal tissue repair and/or regeneration toward translational research for clinical benefit.

Stromal cells derived from human dental pulp (HDPSCs) are of current interest for applications in skeletal tissue engineering. Angiogenesis and revascularization of bone grafts or bone constructs in vivo are of paramount importance for bone tissue regeneration and/or fracture healing. The aim of this study was to investigate the angiogenic and osteogenic potential of HDPSCs in combination with Bioglass¯ scaffolds in vitro and in vivo.

HDPSCs, isolated by collagenase digestion, were either maintained as monolayers or dynamically seeded on 3D Bioglass¯ scaffolds and cultured under either basal or osteogenic conditions for 2 and 4 weeks. Expression of osteogenic (COL1A1, ALP, RUNX2 and OC) and angiogenic markers (VEGFR2, CD34 and PECAM1) was determined using qRT-PCR. Alternatively, constructs were either cultured in vitro under basal/osteogenic conditions for 6 weeks or sealed in diffusion chambers which were then implanted intraperitoneally in immunosuppressed mice for 8 weeks. Retrieved constructs were fixed and embedded for histology and immunohistochemistry using antibodies against COL1, RUNX2, OC, VEGFR2, CD34 and PECAM1. qRT-PCR showed no significant differences in gene expression of osteogenic markers between basal and osteogenic media for both 3D construct and monolayers.

However when comparing 3D constructs to monolayers: COL1A1 showed a significantly lower expression (p< 0.05) in 3D compared to 2D at 2 weeks in both culture conditions, and this pattern was reversed after 4 weeks. ALPL was significantly lower in 3D constructs at 2 weeks under both conditions (p<0.01), and was significantly higher in basal conditions at 4 weeks (p<0.05). RUNX2 showed higher expression in 3D constructs at all time points and under both conditions while OC showed lower expression in 3D constructs at 2 weeks and higher expression at 4 weeks under both conditions. For the angiogenic markers, 3D constructs under osteogenic conditions showed an increase of expression in VEGFR2 and PECAM1 at 2 weeks followed by a decrease at week 4, while CD34 expression was undetected in 3D constructs at all times and under both sets of culture conditions. The expression of VEGFR2 and PECAM 1 under both conditions and at both time points was greater in 3D constructs compared to monolayers. After 8 weeks, the in vivo retrieved constructs showed no signs of inflammatory reactions. Immunohistology confirmed positive staining of osteogenic and angiogenic markers in 3D constructs from both in vitro and in vivo experiments with a greater staining intensity seen in the in vivo constructs. Furthermore, the in vivo constructs showed more intense sirius red staining and higher intensity of immunostaining using antibodies to type 1 collagen, with higher calcification as indicated by alizarin red staining.

In conclusion, this study indicated that a combination of HDPSCs and Bioglass¯ scaffolds has potential to provide a suitable microenvironment for angiogenic and osteogenic differentiation of HDPSCs which is essential for bone regeneration in preclinical and/or clinical applications.

Objective

Human bone marrow stromal cells (HBMSCs) are multipotent and can form bone, cartilage or other tissues under different inductive conditions. The aim of this study was to investigate the effects of enamel matrix derivative (EMD) on the growth and osteogenic differentiation of HBMSCs.

Introduction

P-15 (GTPGPQGIAGQRGVV), a fifteen residue synthetic peptide, is a structural analogue of the cell binding domain of Type 1 collagen and creates a biomimetic environment for bone repair when immobilized on anorganic bovine mineral (ABM) scaffolds. ABM-P-15 scaffolds have been shown to enhance bone marrow stromal cell growth and differentiation. This study aimed at evaluating the osteogenic potential of human dental pulp stromal cells (HDPSCs) compared to human bone marrow stromal cells (HBMSCs) in monolayer and on 3D ABM-P-15 scaffolds in vitro and in vivo.

Introduction: Articular cartilage has limited capacity for regeneration. Tissue engineering strategies offer future hope for cartilage replacement and repair. In an attempt to mimic functional native cartilage for tissue repair, current research focuses on construct/implant designs that simulate an embryonic like microenvironment to promote cellular differentiation along a chondrogenic lineage. The aim of the present study was, for the first time, to illustrate the differences between human neonatal and adult chondrocytes along with bone marrow stromal cells (HBMSCs) to differentiate the factors that promote chondrogenesis and maintain functional homeostasis.

Material and Methods: Adult chondrocytes, neonatal chondrocytes and HBMSCs were cultured in monolayers for 1, 2 and 3 weeks in basal or chondrogenic media. Expression of transcription factor Sox9, Aggrecan (ACAN) and Collagen type II (COL2A)was compared via real time polymerase chain reaction (q-PCR). Alternatively, cells were seeded onto 3D PLGA scaffolds and cultured in vitro for 3 and 6 weeks in basal or chondrogenic media. Paraffin sections of the constructs were stained with Alcian blue/ Sirius red and expression of Collagen type II and Aggrecan was visualised via immunohistochemistry.

Results: For monolayer cultures of all three cell types, at week 1, expression of all three genes was down regulated in basal medium compared to levels in chondrogenic medium. By week 2, q-PCR revealed an increased expression of Col2A in chondroinduced neonatal chondrocytes compared to adult chondrocytes and HBMSCs. A steady increase in SOX9 expression was observed with time in all three cell types in chondrogenic medium. However, SOX9 expression in week 2 was higher for each cell type in basal medium compared with chondrogenic medium. ACAN expression by HBMSCs was greatly enhanced compared with that of neonatal and adult chondrocytes after 2 weeks in chondrogenic medium. By week 3, basal cultures of all cell types showed an overall lower level of gene expression compared with chondroinduced cells. 3D constructs revealed the formation of cartilage like tissue for all three cell types with the presence of a prominent superficial layer and middle zone in the chondroinduced constructs. A superficial layer was also observed in constructs cultured in basal media but there was no evidence of any other characteristic zones. A fibrous capsule had formed around the chondroinduced tissue by week 6. Thinnest capsules were observed for constructs seeded with neonatal cells, with thickest capsules in constructs seeded with HBMSCs. Immunohistochemistry revealed a greater presence of aggrecan and type II collagen in the chondroinduced constructs compared to those cultures in basal media.

Conclusion: This comparative study indicates a major difference between the microenvironment of human neonatal chondrocytes, adult chondrocytes and HBMSCs. The expression of high amounts of COL2A and ACAN (considered to be middle to late markers in chondrogenesis) in week 1 in neonatal chondrocytes indicates a difference in temporal gene expression during chondrogenesis or in maintaining cartilage homeostasis. The study provides potentially useful information to inform cell-based therapies for cartilage regeneration.

Articular cartilage has limited regenerative potential. Regeneration via autografts or cell therapy is clinically efficacious but the extent of regenerative success depends upon use of an appropriate cell source. The aim of this study was to compare the proliferative and chondrogenic potentials of three human cell types (human bone marrow stromal cells - HBMSCs, neonatal and adult chondrocytes) commonly used in cartilage tissue engineering.

HBMSCs, neonatal and adult chondrocytes (passage 2) were cultured in basal and chondrogenic media. At 2, 4 and 6 days, the cells were analysed for morphology and doubling time. Alkaline phosphatase specific activity (ALPSA) was quantified for each group at 2, 4 and 6 weeks. Chondrogenic potential of each cell type was assessed via a pellet culture model. Cryosections were stained with Alcian blue/Sirius Red.

HBMSCs showed either elongated or polymorphic phenotypes, with a doubling time of 40 h. Neonatal chondrocytes showed a uniform spindle shape and had the shortest doubling time (16 h). Adult chondrocytes, were also spindle shaped, though slightly larger than the neonatal cells, with a longer doubling time of 22 h. Expression of ALPSA in basal media was of the order HBMSCs > adult chondrocytes > , neonatal chondrocytes. In chondrogenic culture, this order changed to adult chondrocytes > HBMSCs > neonatal chondrocytes. In 3D pellet cultures, all three cell types stained positive for Alcian Blue and showed the presence of chondrocyte-like cells enclosed in lacunae.

This comparative study suggests that neonatal chondrocytes are the most proliferative with lowest ALP expression. However, in terms of clinical applications, HBMSCs may be better for cartilage regeneration given their lower ALP expression under chondrogenic conditions when compared with adult chondrocytes under the same conditions. The study has provided information to inform clinical cell therapy for cartilage regeneration.

The influence of controlled mechanical loading on osseointegration was investigated using an in vivo device implanted in the distal lateral femur of five male rabbits. Compressive loads (1 MPa, 1 Hz, 50 cycles/day, 4 weeks) were applied to a porous coated titanium cylindrical implant (5mm diameter, 2mm width, 75% porosity, 350ìm average pore diameter) and the underlying cancellous bone.. The contralateral limb served as an unloaded control. MicroCT scans at 28 μm resolution were taken of a 4 × 4mm cylindrical region of interest that included cancellous bone below the implant. A scanning electron microscope with a backscattered electron (BSE) detector was used to quantify the percent bone ingrowth and periprosthetic bone in undecalcified sections through the same region of interest. A mixed effects model was used to account for the correlation of the outcome measures within rabbits.. The percent bone ingrowth was significantly greater in the loaded limb (19 +/− 4%) compared to the unloaded control limb (16 +/− 4%, p=0.016) as measured by BSE imaging. The underlying cancellous periprosthetic tissue bone volume fraction was not different between the loaded (0.26 +/− 0.06) and unloaded control limb (0.27 +/− 0.07, p=0.81) by microCT. BSE imaging also showed no difference in the percent area of periprosthetic bone (27 +/− 10% loaded vs. 23 +/− 10% unloaded, p=0.25). Cyclic mechanical loading significantly enhanced bone ingrowth into a titanium porous coated surface compared to the unloaded controls.

Introduction: Influence of beta-blockers against fracture is controversial. Role of beta-blockers in fracture treatment not explored.

Objective: to analyze influence of propranolol, a beta-blocker, on fracture healing in a mouse model.

Materials and Methods: Fracture and intramedullary nailing on right femur of 8 week, male C57BL/6 mice. Daily propranolol in drinking water: 0 (control), 4 (low dose) and 20 (high dose) mg/kg 3 week: microcomputed tomography (microCT), histological analyses 6 week: microCT, mechanical testing N = 5 üC 9/group Statistics: two-way ANOVA. Á = 0.05.

Results: From 3 to 6 weeks, callus volume and bone mineral content (BMC) decreased, and tissue mineral density increased significantly in control groups. Callus volume and BMC decreased significantly in low dose groups. No significance in high dose groups. No significance with treatment. At 3 weeks, callus area and woven bone percentage not different with treatment. At 6 weeks, ultimate torque not different with treatment or fracture. Within the control groups, twist at ultimate torque significantly lower in fractured bones. Torsional rigidity increased significantly in fractured bones, but not different with treatment.

Discussion: Most studies based on population observation or manipulation of sympathetic signaling using intact animal bones. The current fracture model may have created neural damage, thereby interrupting the sympathetic pathway and negating its regulation of bone metabolism. Whether neural signaling is compromised by fracture treatment requires further study and may be critical to the action of beta-blockers in bone.

A combination of stem cell therapy and tissue engineering is emerging as one of the most promising approaches for skeletal tissue repair and regeneration. Osteoinduction of human bone marrow mesenchymal stem cells (MSCs) is initiated through local signals or growth factors, of which the bone morphogenetic proteins (BMPs) are the best characterised. Cytomodulin-1 (CM-1), a synthetic heptapeptide with functional similarity to members of the TGF-B super family, has been classified as a novel growth factor associated with osteoinduction of MSCs. However, the effects of CM-1 on human bone MSCs are still unclear. The aim of this study was to determine any effects for CM-1 and its scrambled control (CM-1 SCRAM) on the proliferation and differentiation of human bone marrow MSCs along the osteogenic lineage.

Primary human bone marrow MSCs were cultured in the presence of CM-1 and CM-1 SCRAM at a range of concentrations (10-8M – 10-6M) in vitro for up to three weeks. 100 ng/mL of recombinant human BMP-2 (rhBMP-2) was used as a positive control. At the end of the culture period, histological and biochemical assays were carried out on the cultures.

Biochemical assays revealed that 10-7M of CM-1 significantly stimulated alkaline phosphatase specific activity compared with the negative control group (P< 0.05) in a similar way to the rhBMP-2 positive control group. These data were supported by an observed increase in positive alkaline phosphatase staining in the 10-7M of CM-1 and rhBMP-2 treated cells. However, total DNA content was not significantly different between any of the groups.

This study indicated the potential of using CM-1 as an osteogenic growth factor for skeletal tissue regeneration which may provide an alternative approach to meet the major clinical need in orthopaedics and craniofacial surgery.

* Cytomodulin-1 and the scrambled control were genuine gifts from Professor (emeritus) Rajendra S. Bhatnagar at the Department of Bioengineering, University California Berkley, USA.

The use of designer scaffolds to deliver biologically active osteogenic growth factors such as recombinant human bone morphogenetic protein-2 (rhBMP-2) to the sites of tissue regeneration in for example orthopaedics, has tremendous therapeutic implications. The aims of this study were to generate biomimetic biodegradable porous osteogenic scaffolds using a supercritical fluid process to encapsulate rhBMP-2, and to examine the ability of the scaffolds to promote human osteoprogenitor differentiation and bone formation in vitro and in vivo.

The rhBMP-2 encapsulated in Poly(-lactic acid) (PLA) scaffolds (100ng/mg PLA) were generated using an innovative supercritical fluid mixing method. The bioactivity of rhBMP-2 encapsulated PLA scaffolds were confirmed by induction of the C2C12 promyoblast cell line into the osteogenic lineage as detected by alkaline phosphatase expression. No induction of alkaline phosphatase-positive cells was observed using blank scaffolds. BMP-2 released from encapsulated constructs promoted adhesion, migration, expansion and differentiation of human osteoprogenitor cells on 3-D scaffolds. Enhanced matrix synthesis and cell differentiation on growth factor encapsulated scaffolds was observed following culture of human osteoprogenitors on explants of chick femoral bone wedge defects in an ex vivo model of bone formation developed using the chick chorioallantoic membrane model. In vivo studies using diffusion chamber implantation and subcutaneous implantation of human osteoprogenitors on rhBMP-2 encapsulated scaffolds showed morphologic evidence of new bone matrix and cartilage formation in athymic mice as assessed by x-ray analysis, immunocytochemistry and birefringence. These studies provide evidence of controlled release of BMP-2 from biodegradable polymer scaffolds initiating new bone formation in vivo.

The generation of 3-D biomimetic structures incorporating osteoinductive factors such as BMP-2 indicates their potential for de novo bone formation that exploits cell-matrix interactions and, significantly, realistic delivery protocols for growth factors in musculo-skeletal tissue engineering.

The formation of biomimetic environments using scaffolds containing cell recognition sequence and osteo-inductive factors in combination with bone cells offers tremendous potential for bone and cartilage regeneration. In tissues, collagen forms the scaffold by mediating the flux of chemical and mechanical stimuli. Recently, a synthetic 15-residue peptide P-15, related biologically to the active domain of type I collagen, has been found to promote attachment and the osteoblast phenotype of human dermal fibroblasts and periodontal ligament fibroblasts on particulate anorganic bone mineral (ABM). The aim of this study was to exam the ability of the collagen peptide, P-15, to promote human osteoprogenitor attachment, proliferation and differentiation on cell culture surfaces and 3-D scaffolds.

Selected human bone marrow cells were cultured on particulate microporous anorganic bone mineral (‘pure ‘ hydroxyapatite based on x-ray diffraction standard JCPDS9-432) phase and polygalactin vicryl mesh adsorbed with or without P-15 in basal or osteogenic conditions. Cell adhesion, spreading and patterning were examined by light and confocal microscopy following incorporation of cell tracker green and ethidium homodimer fluorescent labels. Osteoprogenitor proliferation and differentiation was assessed by DNA content and alkaline phosphatase specific activity. Growth and differentiation on 3-D ABM structures were examined by confocal and scanning electron microscopy (SEM).

P-15 promoted human osteoprogenitor cell attachment and patterning on particulate bovine anorganic bone mineral phase and polygalactin vicryl mesh over 5–24 hours compared to culture on ABM and vicryl mesh alone as observed by photomicroscopy. Increased alkaline phosphatase specific activity was enhanced following culture on P-15 adsorbed matrices as recognized by enhanced expression of alkaline phosphatase, type I collagen, osteocalcin and cfba-1. The presence of mineralised bone matrix and extensive cell ingrowth and cellular bridging between 3-D ABM matrices and polygalactin vicryl mesh adsorbed with P-15 was observed by confocal microscopy and alizarin red staining. SEM confirmed the 3-D structure of newly formed cell constructs and cellular ingrowth on and between the P-15 modified inorganic bone mineral materials. Negligible cell growth was observed on ABM alone or polygalactin vicryl mesh alone.

These observations demonstrate that the synthetic 15-residue collagen peptide, P-15, when adsorbed to ABM or polygalactin vicryl mesh, can stimulate human osteoprogenitor attachment and spreading. They also demonstrated that P-15 coupled 3-D matrices stimulate human osteoprogenitor differentiation and materialisation. The studies indicate that a synthetic analogue of collagen provides a biomimetic environment supportive for cell differentiation and tissue regeneration and indicate a potential for the use of extracellular matrix cue in the development of biomimetic environments for bone tissue engineering.

Ex vivo gene transfer of osteogenic factors into multipotential stem cells offers potentially important therapeutic implications in a variety of musculoskeletal diseases. One possible approach is the development of a cellular vehicle, namely bone morphogenetic protein (BMP)-producing bone marrow cells, created using adenoviral gene transfer. These transduced cells provide local delivery of BMP for bone formation. The aims of this study were to study the feasibility of gene transfer to human bone osteoprogenitor cells, using adenoviral vectors. Specifically, the aims were to study the efficacy of transduction with an adenoviral vector expressing BMP-2 and then to determine the ability of the transduced cells to produce active BMP-2 and to generate bone ex vivo.

Primary human bone marrow osteoprogenitor cells were expanded in culture and infected with AxCALacZ, a replication-deficient adenoviral vector carrying the E. coli lacZ gene, with a range of multiplicity of infection (MOI) of 6.25 to100. Transduced cells showed positive staining for β-galactosidase using X-Gal with an efficiency close to 100%. Uninfected cells showed no β-galactosidase activity. Efficiency was independent from MOI, however cells infected at the lower MOIs expressed lower levels of β-galactosidase. Following confirmation that primary bone marrow cells could be infected by adenoviral constructs, additional osteoprogenitors were infected with AxCAOBMP-2, a vector carrying the human BMP-2 gene, at a multiplicity of infection of 10–20. In order to determine BMP-2 activity, conditioned media from bone marrow cells expressing BMP-2 was added to promyoblast C₂C₁₂ cells. The promyoblast C₂C₁₂ cells are exquisitely sensitive to BMP-2 with induction of alkaline phosphatase activity (ED₅₀ 20 nM) in a dose-dependant manner. Alkaline phosphatase activity was induced following culture with conditioned media from BMP-2 expressing cells, in a dose dependant manner, confirming successful secretion of active BMP-2. Immunohistochemical staining for alka- line phosphatase in C₂C₁₂ cells also confirmed the bio-chemical observations. Media from uninfected control human bone marrow cells failed to produce a similar effect. The concentration of BMP-2 in the media was estimated to be 5–10 nM/10⁷ cells.

To examine whether adenoviral transfection affected the osteoblast phenotype and their ability to mineralise in vitro, adenovirally-transduced bone marrow cells expressing BMP-2 were seeded onto poly(-lactic acid co÷glycolic acid) (75:25) porous scaffolds (provided by K. Shakesheff and S. Howdle; Nottingham University) and cultured for up to 6 weeks. Expression of alkaline phosphatase activity, type I collagen formation, as well as the synthesis of osteoblast stimulating factor-1 confirmed bone cell differentiation and maintenance of the osteoblast phenotype in extended culture for up to 6 weeks.

These results indicate the ability to deliver active BMP-2 using human bone marrow osteoprogenitor cells following adenoviral infection. The maintenance of osteoblast phenotype in extended culture and generation of mineralised 3-D scaffolds containing such constructs offers a realistic approach to tissue engineer bone for orthopaedic applications.