Improved Bone Formation Research Articles

The Effects of Ascorbic Acid and Garlic on Bone Mineralization in Lead Exposed Pregnant Rats

Background: Lead exposure during pregnancy may impair skeletal development. Oxidative stress is one of the important mechanisms for lead toxicity effects. The aim of this study was to investigate ascorbic acid and garlic effects on bone mineralization in lead exposed pregnant rats. Materials and Methods: In this experimental study, 50 pregnant Wistar rats were randomly divided into 5 groups; group (L) exposed to lead acetate, group (L+C) exposed to lead acetate and ascorbic acid (vitamin C), group (L+G) exposed to lead acetate and garlic juice, sham group treated with tap water plus 0.4 mL/L normal hydrogen chloride (HCl) and 0.5 mg/L sugar, control group without any intervention. All treatments were done during pregnancy. After birth, blood and bone lead levels were measured and then all neonates were sacrificed, and their right tibia bone processed for alizarin red and Alcian blue staining. Results: Blood lead levels in L group increased significantly in both mothers and their neonate compared to control animals. In addition, the neonates born to L group showed markedly higher lead concentrations in their bone than that of controls. In contrast, we found no significant changes in blood and bone lead levels in lead exposed neonates that received ascorbic acid and garlic. Bone formation in neonates of L group was clearly disrupted. Interestingly, both ascorbic acid and garlic treatments could apparently improve bone formation during pregnancy in lead exposed neonates. Conclusion: Ascorbic acid and garlic consumption during pregnancy may improve the deleterious effects of lead exposure on bone mineralization.

The Effects of Ascorbic Acid and Garlic on Bone Mineralization in Lead Exposed Pregnant Rats

Background:: Lead exposure during pregnancy may impair skeletal development. Oxidative stress is one of the important mechanisms for lead toxicity effects. The aim of this study was to investigate ascorbic acid and garlic effects on bone mineralization in lead exposed pregnant rats. Materials and Methods:: In this experimental study, 50 pregnant Wistar rats were randomly divided into 5 groups; group (L) exposed to lead acetate, group (L+C) exposed to lead acetate and ascorbic acid (vitamin C), group (L+G) exposed to lead acetate and garlic juice, sham group treated with tap water plus 0.4 mL/L normal hydrogen chloride (HCl) and 0.5 mg/L sugar, control group without any intervention. All treatments were done during pregnancy. After birth, blood and bone lead levels were measured and then all neonates were sacrificed, and their right tibia bone processed for alizarin red and Alcian blue staining. Results:: Blood lead levels in L group increased significantly in both mothers and their neonate compared to control animals. In addition, the neonates born to L group showed markedly higher lead concentrations in their bone than that of controls. In contrast, we found no significant changes in blood and bone lead levels in lead exposed neonates that received ascorbic acid and garlic. Bone formation in neonates of L group was clearly disrupted. Interestingly, both ascorbic acid and garlic treatments could apparently improve bone formation during pregnancy in lead exposed neonates. Conclusion:: Ascorbic acid and garlic consumption during pregnancy may improve the deleterious effects of lead exposure on bone mineralization.

Tissue engineering for bone regeneration and osseointegration in the oral cavity

ObjectiveThe focus of this review is to summarize recent advances on regenerative technologies (scaffolding matrices, cell/gene therapy and biologic drug delivery) to promote reconstruction of tooth and dental implant-associated bone defects. MethodsAn overview of scaffolds developed for application in bone regeneration is presented with an emphasis on identifying the primary criteria required for optimized scaffold design for the purpose of regenerating physiologically functional osseous tissues. Growth factors and other biologics with clinical potential for osteogenesis are examined, with a comprehensive assessment of pre-clinical and clinical studies. Potential novel improvements to current matrix-based delivery platforms for increased control of growth factor spatiotemporal release kinetics are highlighting including recent advancements in stem cell and gene therapy. ResultsAn analysis of existing scaffold materials, their strategic design for tissue regeneration, and use of growth factors for improved bone formation in oral regenerative therapies results in the identification of current limitations and required improvements to continue moving the field of bone tissue engineering forward into the clinical arena. SignificanceDevelopment of optimized scaffolding matrices for the predictable regeneration of structurally and physiologically functional osseous tissues is still an elusive goal. The introduction of growth factor biologics and cells has the potential to improve the biomimetic properties and regenerative potential of scaffold-based delivery platforms for next-generation patient-specific treatments with greater clinical outcome predictability.

22-Oxacalcitriol attenuates bone loss in nonobese type 2 diabetes

Active vitamin D is a major therapeutic agent for bone disease. Although some studies have reported that vitamin D ameliorates bone disease related to diabetes, the mechanism remains unclear. Our study investigated the effect of the vitamin D receptor activator 22-oxacalcitriol (OCT) on bone disease in a rat model of diabetes. OCT was administered at a dose of 0.2μg/kg three times per week for 10weeks. We performed blood and urine analyses, single energy X-ray absorptiometry, micro-computed tomography, bone histomorphometry, and oxidative stress assessment in rats at 30weeks of age. OCT did not affect hemoglobin A1c or serum calcium levels. Bone mineral density (BMD), bone volume in the cortical and trabecular bones, and bone turnover were decreased in rats with diabetes. OCT treatment increased BMD and bone formation and tended to increase bone volume in the trabecular bone, but did not change bone volume in the cortical bone or bone resorption. The urinary oxidative stress marker 8-hydroxydeoxyguanosine (8-OHdG) excretion and the number of 8-OHdG-positive cells in bone were increased in rats with diabetes, and OCT treatment suppressed these increases. Our data suggest that OCT attenuated bone loss in a rat model of diabetes. This attenuation may be partially mediated by improved bone formation resulting from the antioxidative effect of OCT.

Prostaglandin dependent control of an endogenous estrogen receptor agonist by osteoblasts.

Estrogen receptor (ER) activation has complex effects on bone cells, and loss of circulating estradiol adversely affects skeletal status in women. Hormone replacement therapy effectively circumvents bone loss after menopause, but enhances disease risk in other tissues. Here we show that prostaglandin E2 (PGE2) augments the activity of an osteoblast-derived selective ER modulator, ObSERM. The stimulatory effect of PGE2 is replicated in part by either the PG receptor EP3 agonist 17-phenyl trinor PGE2 or by the PG receptor FP agonist PGF2α⋅ Whereas activation of the various PG receptors induces multiple downstream signals, the response to PGE2 was mimicked by activators of protein kinase C, and suppressed by inhibition of protein kinase C but not by inhibition of protein kinase A. Moreover, inhibition of nitric oxide synthesis and activation of the PTH and Wnt pathways increases ObSERM activity. Our studies therefore reveal that ObSERM activity is controlled in distinct ways and revise our understanding of ER activation within bone by agents or events associated with PG expression. They also predict ways to sustain or improve bone formation, fracture repair, and surgical healing without adding the risk of disease in other tissues where ER activation also has important biological functions.

Heterotopic bone formation in the musculus latissimus dorsi of sheep using β-tricalcium phosphate scaffolds: evaluation of an extended prefabrication time on bone formation and matrix degeneration

We previously generated viable heterotopic bone in living animals and found that 3 months of intrinsic vascularization improved bone formation and matrix degeneration. In this study, we varied the pre-vascularization time to determine its effects on the kinetics of bone formation and ceramic degradation. Two 25-mm-long cylindrical β-tricalcium phosphate scaffolds were filled intraoperatively with autogenous iliac crest bone marrow and implanted in the latissimus dorsi muscle in six sheep. To examine the effect of axial perfusion, one scaffold was surgically implanted with (group C) or without (group D) a central vascular bundle. All animals were sacrificed 6 months postoperatively and histomorphometric measurements were compared to previous results. All implanted scaffolds exhibited ectopic bone growth. However, bone growth was not significantly different between the 3-month (group A, 0.191±0.097 vs. group C, 0.237±0.075; P=0.345) and 6-month (group B, 0.303±0.105 vs. group D, 0.365±0.258; P=0.549) pre-vascularization durations, regardless of vessel supply; early differences between surgically and extrinsically vascularized constructs disappeared after 6 months. Here, we describe a reliable procedure for generating ectopic bone in vivo. A 3-month pre-vascularization duration appears sufficient and ceramic degradation proceeds in accordance with bone generation, supporting the hypothesis of cell-mediated resorption.

Mesoporous bioactive glass nanolayer-functionalized 3D-printed scaffolds for accelerating osteogenesis and angiogenesis.

The hierarchical microstructure, surface and interface of biomaterials are important factors influencing their bioactivity. Porous bioceramic scaffolds have been widely used for bone tissue engineering by optimizing their chemical composition and large-pore structure. However, the surface and interface of struts in bioceramic scaffolds are often ignored. The aim of this study is to incorporate hierarchical pores and bioactive components into the bioceramic scaffolds by constructing nanopores and bioactive elements on the struts of scaffolds and further improve their bone-forming activity. Mesoporous bioactive glass (MBG) modified β-tricalcium phosphate (MBG-β-TCP) scaffolds with a hierarchical pore structure and a functional strut surface (∼100 nm of MBG nanolayer) were successfully prepared via 3D printing and spin coating. The compressive strength and apatite-mineralization ability of MBG-β-TCP scaffolds were significantly enhanced as compared to β-TCP scaffolds without the MBG nanolayer. The attachment, viability, alkaline phosphatase (ALP) activity, osteogenic gene expression (Runx2, BMP2, OPN and Col I) and protein expression (OPN, Col I, VEGF, HIF-1α) of rabbit bone marrow stromal cells (rBMSCs) as well as the attachment, viability and angiogenic gene expression (VEGF and HIF-1α) of human umbilical vein endothelial cells (HUVECs) in MBG-β-TCP scaffolds were significantly upregulated compared with conventional bioactive glass (BG)-modified β-TCP (BG-β-TCP) and pure β-TCP scaffolds. Furthermore, MBG-β-TCP scaffolds significantly enhanced the formation of new bone in vivo as compared to BG-β-TCP and β-TCP scaffolds. The results suggest that application of the MBG nanolayer to modify 3D-printed bioceramic scaffolds offers a new strategy to construct hierarchically porous scaffolds with significantly improved physicochemical and biological properties, such as mechanical properties, osteogenesis, angiogenesis and protein expression for bone tissue engineering applications, in which the incorporation of nanostructures and bioactive components into the scaffold struts synergistically play a key role in the improved bone formation.

Wnt signaling: an emerging target for bone regeneration.

If we understood how to control the choice between cell self-renewal, proliferation, and differentiation, then theoretically we would have the ability to expand a limited population of adult progenitor cells and then, at will, to induce their timely differentiation to restore the function of a tissue or organ. In terms of skeletal homeostasis and bone repair, the Wnt pathway is among the most attractive targets for such therapeutic intervention. There is now a substantial literature supporting a role of Wnt signaling in skeletogenesis and a growing appreciation for the functions of Wnt in regulating stem cell and skeletal cell behavior. Wnts are secreted proteins that bind to receptors on the surfaces of stem and osteoprogenitor cells and, once bound, initiate a cascade of intracellular events that eventually lead to the transcription of target genes.1 Wnt signals perpetuate the self-renewal and proliferation of stem cells,2 while in osteoprogenitor cells, Wnt signals induce their differentiation.3 Through these mechanisms, Wnt signaling regulates bone mass.4 For example, activating mutations (eg, gene mutations that lead to gain-of-Wnt-function) in humans causes high-bone-mass phenotypes such as van Buchem disease,5 whereas inactivating mutations causes osteopenic diseases such as osteoporosis-pseudoglioma syndrome.6 These genetic data raise the possibility that modulation of the Wnt pathway is a viable path for improving bone formation in patients. Early clinical trials support this hypothesis: in phase II trials, elevating Wnt signaling by systemic delivery of antibodies against the Wnt antagonist sclerostin resulted in an increase in bone mineral density in patients with osteoporosis.7 Enthusiasm for these types of therapies is, however, tempered by serious safety concerns.8 Lessons learned from the adverse events associated with recombinant human bone morphogenetic protein-2 strongly suggest that introduction of a potent growth or stem cell factor into the human body should be approached with the utmost caution.9 Unlike the life-long process of bone remodeling in which imbalances require chronic drug therapy to correct, bone regeneration in response to trauma occurs within a compressed time frame and within a confined location. Although the time scale and body location are different, the molecular and cellular machinery driving bone accrual is the same; consequently, we study how Wnt signaling can be amplified at an injury site to accelerate bone regeneration. This approach enables us to study the effect of Wnt signaling on stem and osteoprogenitor cells within a defined location at a precise time. Studies in this area by our groups and by others provide ample evidence that targeting the Wnt pathway is a feasible strategy for accelerating bone healing. The act of bone injury activates endogenous Wnt signaling, and in the young patient, this endogenous Wnt signal is sufficient to lead to robust bone healing.3,10 In older animals, this endogenous Wnt signal drops, and with it, a precipitous decline in bone regeneration occurs.11 We tested a strategy to augment the body’s natural Wnt response to skeletal damage: Wnt-3a protein is reconstituted in association with a liposomal membrane,12 an arrangement that mimics the means by which endogenous Wnts are transported between cells.13 Treating a fracture with this liposomal Wnt-3a results in significantly faster and more robust bone healing, with earlier onset of mineralization and new osteoid deposition than happens normally in young animals.14 Thus, liposomal Wnt treatment effectively potentiates the endogenous Wnt signal that is initiated by injury and, in doing so, accelerates bone healing. Given the safety concerns surrounding the use of bone morphogenetic proteins to augment skeletal healing, future methods aimed at enhancing bone regeneration must confine the proliferative effects of these potent agents both spatially and temporally. We recently tested such an approach in which bone graft from aged rabbits was incubated ex vivo with liposomal Wnt-3a. This strategy allowed more precise control over the duration and dose of exposure and also permitted rinsing of the bone graft to remove any protein that had not been internalized by cells of the bone graft. Two interesting findings were reported: First, bone graft material from aged animals undergoes apoptosis immediately upon harvest, which was significantly reduced by incubation with the liposomal Wnt-3a. Second, bone defects treated with the Wnt-3a–activated bone graft from elderly animals behaved similar to bone grafts from juvenile animals, giving rise to significantly more bone than an autograft alone. Together, these data suggest a viable, safe strategy for the treatment of skeletal injuries, especially for individuals with diminished healing potential.11

Histomorphometric, radiographic and biomechanical analyses of platelet rich plasma associated with autogenous bone graft

Objective: The aim of this study was to evaluate the effectiveness of platelet rich plasma with and without autogenous bone graft in the bone repair of surgical defects in rabbit tibias. Materials and Methods: In this research, 25 adult male rabbits were used. Two defects have been performed in each tibia, divided into four groups: control (C = defect naturally left to heal by clot formation), autogenous (A = bone defect + autogenous graft), PRP (PRP = bone defect + PRP) and autogenous + PRP (PRPA = bone defect + autogenous graft + PRP). All the defects were covered with a dPTFE membrane. Five other animals were sacrificed at 15, 30, and 60-day postoperatively. The pieces containing the defects were processed for histological and histomorphometric analysis. Other five animals were sacrificed after 30 and 60 days and submitted to biomechanical analysis, and all the specimens were sent to the radiographic evaluation of optical density. Results: The biomechanical, radiographic, and histomorphometric results showed larger resistance, optical density, and improving bone formation in the groups A and PRPA when compared with the groups C and PRP. Conclusion: This study showed there was not an improvement in the radiographic, mechanical, and bone formation parameters when PRP was used individually or associated to the autogenous bone graft.

Autologous serum improves bone formation in a primary stable silica-embedded nanohydroxyapatite bone substitute in combination with mesenchymal stem cells and rhBMP-2 in the sheep model.

New therapeutic strategies are required for critical size bone defects, because the gold standard of transplanting autologous bone from an unharmed area of the body often leads to several severe side effects and disadvantages for the patient. For years, tissue engineering approaches have been seeking a stable, axially vascularized transplantable bone replacement suitable for transplantation into the recipient bed with pre-existing insufficient conditions. For this reason, the arteriovenous loop model was developed and various bone substitutes have been vascularized. However, it has not been possible thus far to engineer a primary stable and axially vascularized transplantable bone substitute. For that purpose, a primary stable silica-embedded nanohydroxyapatite (HA) bone substitute in combination with blood, bone marrow, expanded, or directly retransplanted mesenchymal stem cells, recombinant human bone morphogenetic protein 2 (rhBMP-2), and different carrier materials (fibrin, cell culture medium, autologous serum) was tested subcutaneously for 4 or 12 weeks in the sheep model. Autologous serum lead to an early matrix change during degradation of the bone substitute and formation of new bone tissue. The best results were achieved in the group combining mesenchymal stem cells expanded with 60 μg/mL rhBMP-2 in autologous serum. Better ingrowth of fibrovascular tissue could be detected in the autologous serum group compared with the control (fibrin). Osteoclastic activity indicating an active bone remodeling process was observed after 4 weeks, particularly in the group with autologous serum and after 12 weeks in every experimental group. This study clearly demonstrates the positive effects of autologous serum in combination with mesenchymal stem cells and rhBMP-2 on bone formation in a primary stable silica-embedded nano-HA bone grafting material in the sheep model. In further experiments, the results will be transferred to the sheep arteriovenous loop model in order to engineer an axially vascularized primary stable bone replacement in clinically relevant size for free transplantation.

Tumor necrosis factor improves vascularization in osteogenic grafts engineered with human adipose-derived stem/stromal cells.

The innate immune response following bone injury plays an important role in promoting cellular recruitment, revascularization, and other repair mechanisms. Tumor necrosis factor-α (TNF) is a prominent pro-inflammatory cytokine in this cascade, and has been previously shown to improve bone formation and angiogenesis in a dose- and timing-dependent manner. This ability to positively impact both osteogenesis and vascular growth may benefit bone tissue engineering, as vasculature is essential to maintaining cell viability in large grafts after implantation. Here, we investigated the effects of exogenous TNF on the induction of adipose-derived stem/stromal cells (ASCs) to engineer pre-vascularized osteogenic tissue in vitro with respect to dose, timing, and co-stimulation with other inflammatory mediators. We found that acute (2-day), low-dose exposure to TNF promoted vascularization, whereas higher doses and continuous exposure inhibited vascular growth. Co-stimulation with platelet-derived growth factor (PDGF), another key factor released following bone injury, increased vascular network formation synergistically with TNF. ASC-seeded grafts were then cultured within polycaprolactone-fibrin composite scaffolds and implanted in nude rats for 2 weeks, resulting in further tissue maturation and increased angiogenic ingrowth in TNF-treated grafts. VEGF-A expression levels were significantly higher in TNF-treated grafts immediately prior to implantation, indicating a long-term pro-angiogenic effect. These findings demonstrate that TNF has the potential to promote vasculogenesis in engineered osteogenic grafts both in vitro and in vivo. Thus, modulation and/or recapitulation of the immune response following bone injury may be a beneficial strategy for bone tissue engineering.

Bisphosphonate-associated atypical sub-trochanteric femur fractures: Paired bone biopsy quantitative histomorphometry before and after teriparatide administration

ObjectivesBisphosphonate-associated atypical sub-trochanteric femur fractures (ASFF) may be seen with long-term bisphosphonate use, though these fractures are also seen in patients never exposed to bisphosphonates. One theory for the mechanism of action whereby bisphosphonates may induce these ASFF is over-suppression of bone turnover. Bisphosphonates suppress bone turnover, but in bisphosphonate clinical trials, over-suppression defined whether by maintaining the biochemical markers of bone turnover below the defined reference range or by quantitative bone histomorphometry, has not been observed. MethodsWe studied 15 clinic patients referred to The Colorado Center for Bone Research (CCBR) after they had a bisphosphonate-associated ASFF and performed quantitative bone histomorphometry both before and after 12 months of teriparatide (20µg SQ/day). All patients had been on long-term alendronate (mean = 7 years, range: 6–11 years) and had already had intramedullary rods placed when first seen (6 weeks to 7 months after rod placement). Alendronate had been discontinued in all patients at the time of their first clinic visit to CCBR. All of the fractures fulfilled The American Society for Bone and Mineral Research major radiological criteria for ASFF. ResultsThree key dynamic histomorphometric features show that 7 of the 15 patients had unmeasurable bone formation, mineralizing surface, and mineral apposition, while the other 8 patients had measurable dynamic parameters; although for all 15 patients, the mean values for all 3 dynamic parameters was far below the average for the published normal population. Administration of teriparatide was associated with an increase in all 3 dynamic histomorphometric parameters. Baseline bone turnover markers did not correlate with the baseline histomorphometry. While there is heterogeneity in the bone turnover in patients with bisphosphonate ASFF, there is a large portion in this uncontrolled series that had absent bone turnover at the standard biopsy site (iliac crest). Discontinuation of the bisphosphonate and administration of the anabolic agent, teriparatide was associated with improvement in bone turnover. ConclusionsWhile our study does not establish causality or address the ability of teriparatide to prevent progression of early stress fracture to displaced fractures, it does suggest that teriparatide may improve bone formation in these patients. Our study should stimulate other investigations using larger sample sizes and early stress fractures to see if anabolic agents can reverse these fractures from becoming displaced.

Human perivascular stem cell-based bone graft substitute induces rat spinal fusion.

Adipose tissue is an attractive source of mesenchymal stem cells (MSCs) because of its abundance and accessibility. We have previously defined a population of native MSCs termed perivascular stem cells (PSCs), purified from diverse human tissues, including adipose tissue. Human PSCs (hPSCs) are a bipartite cell population composed of pericytes (CD146+CD34-CD45-) and adventitial cells (CD146-CD34+CD45-), isolated by fluorescence-activated cell sorting and with properties identical to those of culture identified MSCs. Our previous studies showed that hPSCs exhibit improved bone formation compared with a sample-matched unpurified population (termed stromal vascular fraction); however, it is not known whether hPSCs would be efficacious in a spinal fusion model. To investigate, we evaluated the osteogenic potential of freshly sorted hPSCs without culture expansion and differentiation in a rat model of posterolateral lumbar spinal fusion. We compared increasing dosages of implanted hPSCs to assess for dose-dependent efficacy. All hPSC treatment groups induced successful spinal fusion, assessed by manual palpation and microcomputed tomography. Computerized biomechanical simulation (finite element analysis) further demonstrated bone fusion with hPSC treatment. Histological analyses showed robust endochondral ossification in hPSC-treated samples. Finally, we confirmed that implanted hPSCs indeed differentiated into osteoblasts and osteocytes; however, the majority of the new bone formation was of host origin. These results suggest that implanted hPSCs positively regulate bone formation via direct and paracrine mechanisms. In summary, hPSCs are a readily available MSC population that effectively forms bone without requirements for culture or predifferentiation. Thus, hPSC-based products show promise for future efforts in clinical bone regeneration and repair.

Agave fructans: their effect on mineral absorption and bone mineral content.

In this study we investigate the effect that Agave fructans as new prebiotics have on mineral absorption improvement. Forty-eight 12-week-old C57BL/6J mice were used in this study. Forty mice were ovariectomized and eight were sham-operated controls. Mice were fed standard diets or diets supplemented with 10% Agave fructans or 10% inulin fructans. Calcium and magnesium were evaluated as well as their excretion in feces. Osteocalcin levels were also measured; femur structure was studied by scanning electron microscopy. Other parameters, such as food intake, body weight, glucose, and short-chain fatty acid content, were recorded. Calcium in plasma and bone increased in Agave fructan groups (from 53.1 to 56 and 85 mg/L and from 0.402 to 0.474 and 0.478 g/g, respectively) and osteocalcin increased in all fructan groups (>50%). Scanning electron microscopy showed that fructans were able to mitigate bone loss. In conclusion, we demonstrated that supplementation with Agave fructans prevents bone loss and improves bone formation.

Enhanced bone healing around nanohydroxyapatite-coated polyetheretherketone implants: An experimental study in rabbit bone.

To investigate the bone response to threaded polyetheretherketone (PEEK) implants coated with nanohydroxyapatite. A total of 39 PEEK implants were coated with nanocrystalline hydroxyapatite and 39 uncoated implants were used as controls. The implant surface was characterized by optical interferometry and scanning electron microscope. The implants were inserted in the tibia and femur of 13 rabbits. After 6 weeks of healing, quantitative and qualitative analyses were performed. The test implants showed significantly higher removal torque test values compared with the control group. Histomorphometric evaluation demonstrated higher bone-to-implant contact for the test implants; however, there were no differences in bone area between the groups. Qualitative histological analyses demonstrated inflammatory cellular reactions in close vicinity of both implant surfaces. A two-cell layer of foreign body giant cells was observed irrespective of sample type. Our findings demonstrate that implants with a threaded design render good stability to PEEK in both coated and uncoated implants. Nanohydroxyapatite-coated PEEK implants demonstrated improved bone formation compared with uncoated controls.

Mesenchymal Stem Cells and Endothelial Progenitor Cells Stimulate Bone Regeneration and Mineral Density

Alveolar bone deficiency is a major clinical problem in maxillofacial reconstructive surgery. The available surgical techniques to enhance extracortical bone augmentation are generally unpredictable and not satisfying. The aim of the present study is to quantify extracortical bone augmentation and tissue mineral density (TMD) after cotransplantation of peripheral blood-derived endothelial progenitor cells (EPCs) and bone marrow-derived mesenchymal stem cells (MSCs) by microcomputed tomography (micro-CT). Bone regeneration was tested in the guided bone regeneration rat calvaria model. Gold domes filled with beta tricalcium phosphate (β-TCP; control [CNT]) or β-TCP mixed with 5 × 10(5) rat EPCs and 5 × 10(5) rat osteogenic transformed MSCs (EPC/otMSCs) were fixed to the exposed calvaria. Rats were sacrificed after 3 months. Bone volume fraction (BV/TV) and TMD were analyzed using micro-CT. In the middle of the dome, a cylindrical region of interest was defined (it represents the area in which implants are placed) and subdivided into bottom, middle, and top to analyze the effect of the distance from the calvaria on bone formation. In the whole cylinder, BV/TV and TMD were higher in the EPC/otMSC group compared with CNT (BV/TV: 22.9% ± 4.4% versus 29.1 ± 2.2%, P = 0.02; TMD: 937.79 ± 18.68 versus 960.78 ± 5.8 mgHA/ccm, P = 0.03; CNT versus EPC/otMSC, respectively). In each of the three subregions, BV/TV was higher in the EPC/otMSC group compared with CNT (top: 20.25% ± 2.4% versus 23.74% ± 1.5%, P = 0.007; middle: 23.2% ± 4.8% versus 28% ± 2.2%, P = 0.05; bottom: 25.3% ± 7.6% versus 35.7% ± 4.9%, P = 0.02; CNT versus EPC/otMSC, respectively). Three-dimensional quantification by micro-CT demonstrated that cotransplantation of EPC/otMSCs significantly improved bone formation and mineral density.

Improved Bone Formation in Osteoporotic Rabbits with the Bone Morphogenetic Protein-2 (rhBMP-2) Coated Titanium Screws Which Were Coated By Using Plasma Polymerization Technique

Improved Bone Formation in Osteoporotic Rabbits with the Bone Morphogenetic Protein-2 (rhBMP-2) Coated Titanium Screws Which Were Coated By Using Plasma Polymerization Technique

Modulating hydrogel crosslink density and degradation to control bone morphogenetic protein delivery and in vivo bone formation

Bone morphogenetic proteins (BMPs) show promise in therapies for improving bone formation after injury; however, the high supraphysiological concentrations required for desired osteoinductive effects, off-target concerns, costs, and patient variability have limited the use of BMP-based therapeutics. To better understand the role of biomaterial design in BMP delivery, a matrix metalloprotease (MMP)-sensitive hyaluronic acid (HA)-based hydrogel was used for BMP-2 delivery to evaluate the influence of hydrogel degradation rate on bone repair in vivo. Specifically, maleimide-modified HA (MaHA) macromers were crosslinked with difunctional MMP-sensitive peptides to permit protease-mediated hydrogel degradation and growth factor release. The compressive, rheological, and degradation properties of MaHA hydrogels were characterized as a function of crosslink density, which was varied through either MaHA concentration (1–5wt.%) or maleimide functionalization (10–40%f). Generally, the compressive moduli increased, the time to gelation decreased, and the degradation rate decreased with increasing crosslink density. Furthermore, BMP-2 release increased with either a decrease in the initial crosslink density or an increase in collagenase concentration (non-specific MMP degradation). Lastly, two hydrogel formulations with distinct BMP-2 release profiles were evaluated in a critical-sized calvarial defect model in rats. After six weeks, minimal evidence of bone repair was observed within defects left empty or filled with hydrogels alone. For hydrogels that contained BMP-2, similar volumes of new bone tissue were formed; however, the faster degrading hydrogel exhibited improved cellular invasion, bone volume to total volume ratio, and overall defect filling. These results illustrate the importance of coordinating hydrogel degradation with the rate of new tissue formation.

Improved Bone Formation in Osteoporotic Rabbits with the Bone Morphogenetic Protein-2 (rhBMP-2) Coated Titanium Screws Which Were Coated By Using Plasma Polymerization Technique

Delaying of bone fusion in osteoporotic patients underwent spinal stabilization surgery leads to screw loosening, and this causes pseudoarticulation, mobility and fibrosis at vertebral segments. To prevent these complications, the screws coated with recombinant bone morphogenetic protein-2 (rhBMP-2) could be used. To verify this hypothesis, we coated 5 Titanium screws with rhBMP-2 using plasma polymerization method, and also used 10 uncoated screws for making comparison between coated and uncoated screws in different groups. And 15 skeletally mature white New Zealand female rabbits were assigned into three different groups: Group 1(N = 5): No osteoporosis induction and insertion of uncoated Titanium screw into right sacrum of each rabbit in group 1; group 2 (N = 5): Osteoporosis induction and insertion of uncoated Titanium screw into right sacrum of each rabbit in group 2; group 3 (N = 5) rhBMP-2 coated Titanium screw inserted into right sacrum of each rabbit in group 3. In summary, using of these coated screws provides new bone formation, but causes less fibrosis and less inflammation than uncoated screws at the interface between the coated screw and bone. Then the plasma polymerization technique provides controlled releasing of rhBMP-2 from the screw to the bone tissue in osteoporotic rabbits.

Improved Bone Formation in Osteoporotic Rabbits with the Bone Morphogenetic Protein-2 (rhBMP-2) Coated Titanium Screws Which Were Coated By Using Plasma Polymerization Technique

Delaying of bone fusion in osteoporotic patients underwent spinal stabilization surgery leads to screw loosening, and this causes pseudoarticulation, mobility and fibrosis at vertebral segments. To prevent these complications, the screws coated with recombinant bone morphogenetic protein-2 (rhBMP-2) could be used. To verify this hypothesis, we coated 5 Titanium screws with rhBMP-2 using plasma polymerization method, and also used 10 uncoated screws for making comparison between coated and uncoated screws in different groups. And 15 skeletally mature white New Zealand female rabbits were assigned into three different groups: Group 1(N = 5): No osteoporosis induction and insertion of uncoated Titanium screw into right sacrum of each rabbit in group 1; group 2 (N = 5): Osteoporosis induction and insertion of uncoated Titanium screw into right sacrum of each rabbit in group 2; group 3 (N = 5) rhBMP-2 coated Titanium screw inserted into right sacrum of each rabbit in group 3. In summary, using of these coated screws provides new bone formation, but causes less fibrosis and less inflammation than uncoated screws at the interface between the coated screw and bone. Then the plasma polymerization technique provides controlled releasing of rhBMP-2 from the screw to the bone tissue in osteoporotic rabbits.