Enhancement of ectopic bone formation by bone morphogenetic protein-2 released from a heparin-conjugated poly(L-lactic-co-glycolic acid) scaffold

In this study, a heparin-conjugated poly(l-lactic-co-glycolic acid) (HP-PLGA) scaffold was developed for the sustained delivery of bone morphogenetic protein-2 (BMP-2), and then used to address the hypothesis that BMP-2 delivered from this scaffold could enhance ectopic bone formation. We found the amount of heparin conjugated to the PLGA scaffolds could be increased up to 3.2-fold by using scaffolds made from star-shaped PLGA, as compared to scaffolds made from linear PLGA, and that the release of BMP-2 from the HP-PLGA scaffold was sustained for at least 14 days in vitro. The BMP-2 released from the HP-PLGA scaffold stimulated an increase in alkaline phosphatase (ALP) activity of osteoblasts for 14 days in vitro, suggesting that the HP-PLGA scaffold delivery system releases BMP-2 in a bioactive form for a prolonged period. By contrast, BMP-2 release from unmodified (no heparin) PLGA scaffolds induced a transient increase in ALP activity for the first 3 days and a decrease thereafter. In vivo bone formation studies showed the BMP-2-loaded HP-PLGA scaffolds induced bone formation to a much greater extent than did either BMP-2-loaded unmodified PLGA scaffolds or unloaded (no BMP-2) HP-PLGA scaffolds, with 9-fold greater bone formation area and 4-fold greater calcium content in the BMP-2-loaded HP-PLGA scaffold group compared to the BMP-2-loaded unmodified PLGA scaffold group. Collectively, these results demonstrate that the HP-PLGA delivery system is capable of potentiating the osteogenic efficacy of BMP-2, and underscore its importance as a possible bone regeneration strategy.     

In vitro evaluation of electrospun silk fibroin/nano-hydroxyapatite/BMP-2 scaffolds for bone regeneration

Bone tissue engineering by using osteoinductive scaffolds seeded with stem cells to promote bone extracellular matrix (ECM) production and remodeling has evolved into a promising approach for bone repair and regeneration. In order to mimic the ECM of bone tissue structurally and compositionally, nanofibrous silk fibroin (SF) scaffolds containing hydroxyapatite (HAP) nanoparticles and bone morphogenetic protein 2 (BMP-2) were fabricated in this study using electrospinning technique. The microstructure, mechanical property, biocompatibility, and osteogenic characteristics were examined. It was found that the HAP nanoparticles were successfully incorporated in the SF nanofibers (diameter, 200–500 nm). The mechanical properties of SF/HAP/BMP-2 composite scaffolds increased with HAP content when it was less than 20 wt%, after which the mechanical properties dropped as HAP content increased. Cell culture tests using bone marrow mesenchymal stem cells (BMSCs) showed that the scaffolds had good biocompatibility and promoted the osteogenic differentiation of BMSCs. Therefore, the electrospun SF/HAP/BMP-2 scaffolds may serve as a promising biomaterial for bone tissue engineering.     

Integration of a calcined bovine bone and BMSC-sheet 3D scaffold and the promotion of bone regeneration in large defects

Reconstruction of large area bone defect with mechanical integrity to the skeleton is important for patient's rehabilitation. However with the limitation of scaffold material and suitable seed cell sources, the best treating strategy remains to be identified though various tissue engineering methods were reported. In this study, we investigated the feasibility of applying calcined bovine bone (CBB) which was coated by allograft bone marrow mesenchymal stem cells (BMSC)-sheet as a 3D scaffold material in bone repairing tissue engineering. The new scaffold material was implanted into osteoporosis rat cranial bone defects and repairing critical size bone defects (8 mm diameter). Data showed that CBB-BMSC-sheet combination had a stronger potential in osteogenic differentiation and mineralized formation both in vitro and in vivo than CBB-BMSC combination. In in vitro study BMSC-sheet had a more feasible characteristic upon bone repairing including richer ECM, larger mineralized area and stronger ALP activity in addition with a significant higher mRNA expression of osteogenic maker such as BMP-2, b-FGF, Col 1a1, OSX and Runx-2 than the control group. In in vivo study 3D reconstruction of micro CT, HE staining and bone strength results showed that newly formed bone in CBB-BMSC-sheet group was significant higher than that in CBB-BMSC group at 4, 8 and 12 weeks after transplantation in the aspect of area and volume. What was more, results indicated that allograft BMSC-sheet had survivaled in the scaffold material and participated in the newly formed bone which had the same thickness with surrounding autologous bone tissues after transplantation. Results of our study demonstrated that CBB-BMSC-sheet combination was a promising strategy in healing of large area bone defect in osteoporosis.     

The osteogenesis of bacterial cellulose scaffold loaded with bone morphogenetic protein-2

Bacterial cellulose (BC) is a nanofibrous biological material with attractive physicochemical properties and biocompatibility. Its fiber is similar to the collagenous fiber of bone. To explore if BC could be utilized as a localized delivery system to increase the local concentration of cytokines for tissue engineering, we prepared the BC scaffold from Acetobacter xylinum X-2 (A.?xylinum X-2) and investigated the osteogenic potential of the BC scaffold coated with bone morphogenetic protein-2 (BMP-2). The data showed that BC had a good biocompatibility and induced differentiation of mouse fibroblast-like C2C12 cells into osteoblasts in the presence of BMP-2 in?vitro, as demonstrated by alkaline phosphatase (ALP) activity assays. Within a certain range (0?～?3?μg/scaffold), the osteogenic activity of induced osteoblasts was positively correlated to the concentrations of BMP-2. In in?vivo subcutaneous implantation studies, BC scaffolds carrying BMP-2 showed more bone formation and higher calcium concentration than the BC scaffolds alone at 2 and 4 weeks, respectively. The ALP activity assay and the measurement of calcium concentration of BC scaffolds also showed that more new bone was developed in the BC scaffolds carrying BMP-2 than in the BC scaffolds alone. Our studies suggest that BC is a good localized delivery system for BMPs and would be a potential candidate in bone tissue engineering.     

Creation of bony microenvironment with CaP and cell-derived ECM to enhance human bone-marrow MSC behavior and delivery of BMP-2

Extracellular matrix (ECM) comprises a rich meshwork of proteins and proteoglycans, which not only contains biological cues for cell behavior, but is also a reservoir for binding growth factors and controlling their release. Here we aimed to create a suitable bony microenvironment with cell-derived ECM and biodegradable β-tricalcium phosphate (β-TCP). More specifically, we investigated whether the ECM produced by bone marrow-derived mesenchymal stem cells (hBMSC) on a β-TCP scaffold can bind bone morphogenetic protein-2 (BMP-2) and control its release in a sustained manner, and further examined the effect of ECM and the BMP-2 released from ECM on cell behaviors. The ECM was obtained through culturing the hBMSC on a β-TCP porous scaffold and performing decellularization and sterilization. SEM, XPS, FTIR, and immunofluorescent staining results indicated the presence of ECM on the β-TCP and the amount of ECM increased with the incubation time. BMP-2 was loaded onto the β-TCP with and without ECM by immersing the scaffolds in the BMP-2 solution. The loading and release kinetics of the BMP-2 on the β-TCP/ECM were significantly slower than those on the β-TCP. The β-TCP/ECM exhibited a sustained release profile of the BMP-2, which was also affected by the amount of ECM. This is probably because the β-TCP/ECM has different binding mechanisms with BMP-2. The β-TCP/ECM promoted cell proliferation. Furthermore, the BMP-2-loaded β-TCP/ECM stimulated reorganization of the actin cytoskeleton, increased expression of alkaline phosphatase and calcium deposition by the cells compared to those without BMP-2 loading and the β-TCP with BMP-2 loading.     

The effect of crosslinking heparin to demineralized bone matrix on mechanical strength and specific binding to human bone morphogenetic protein-2

Demineralized bone matrix (DBM) is a collagen-based scaffold, but its low mechanical strength and limited BMP-2 binding ability restrict its application in bone repair. It is known that heparin could be immobilized onto scaffolds to enhance their binding of growth factors with the heparin-binding domain. Here, we crosslinked heparin to DBM to increase its BMP-2 binding ability. To our surprise, the mechanical strength of DBM was also dramatically increased. The compression modulus of heparin crosslinked DBM (HC-DBM) have improved (seven-fold increased) under wet condition, which would allow the scaffolds to keep specific shapes in vivo. As expected, HC-DBM showed specific binding ability to BMP-2. Additional studies showed the bound BMP-2 exerted its function to induce cell differentiation on the scaffold. Subcutaneous implantation of HC-DBM carrying BMP-2 showed higher alkaline phosphatase (ALP) activity (2 weeks), more calcium deposition (4 and 8 weeks) and more bone formation than that of control groups. It is concluded that HC-DBM has increased mechanical intensity as well as specific BMP-2 binding ability; HC-DBM/BMP-2 enhances the osteogenesis and therefore could be an effective medical device for bone repair.     

Enhanced osteogenic activity of bone morphogenetic protein-2 by 2-O-desulfated heparin

The objective of this study was to investigate the effect of heparin sulfate groups on the osteogenic activity of bone morphogenetic protein-2 (BMP-2) in vitro and in vivo. Three types of desulfated (DS) derivatives of heparin (2-O-DS, 6-O-DS, and N-DS) were prepared and their bioactivity in rat bone marrow derived mesenchymal stem cells (MSC) in the absence or presence of BMP-2 was evaluated. When cultured with the 2-O-DS derivative and BMP-2 MSC showed enhanced proliferation, alkaline phosphatase activity, and Runx2 mRNA expression, compared with heparin and other derivatives. A similar tendency was observed for MSC cultured on two-dimensional substrates coated with heparin or the derivatives and in three-dimensional hydrogels containing heparin or the derivatives. A binding experiment demonstrated a greater binding affinity of 2-O-DS for BMP-2 than that of heparin and the other derivatives. Following implantation into the back subcutis of mice significantly greater ectopic bone formation in terms of bone weight, amount of calcium, and histology were observed for the gelatin hydrogels incorporating 2-O-DS and containing BMP-2. In addition, the gelatin hydrogels incorporating 2-O-DS showed controlled release of BMP-2 in vitro and in vivo. These findings demonstrated that the 2-O-DS derivative of heparin has a synergistic effect on the in vitro and in vivo osteogenic activity of BMP-2.     

Accelerated bonelike apatite growth on porous polymer/ceramic composite scaffolds in vitro

Although biodegradable polymer/ceramic composite scaffolds can overcome the limitations of conventional ceramic bone substitutes, the osteogenic potential of these scaffolds needs to be further enhanced for efficient bone tissue engineering. In this study, bonelike apatite was efficiently coated onto the scaffold surface by using polymer/ceramic composite scaffolds instead of polymer scaffolds and by using an accelerated biomimetic process to enhance the osteogenic potential of the scaffold. The creation of bonelike, apatite-coated polymer scaffold was achieved by incubating the scaffolds in simulated body fluid (SBF). The apatite growth on porous poly(D,L-lactic-co-glycolic acid)/nanohydroxyapatite (PLGA/ HA) composite scaffolds was significantly faster than on porous PLGA scaffolds. In addition, the distribution of coated apatite was more uniform on PLGA/HA scaffolds than on PLGA scaffolds. After a 5-day incubation period, the mass of apatite coated onto PLGA/HA scaffolds incubated in 5 x SBF was 2.3-fold higher than PLGA/HA scaffolds incubated in 1 x SBF. Furthermore, when the scaffolds were incubated in 5 x SBF for 5 days, the mass of apatite coated onto PLGA/HA scaffolds was 4.5-fold higher than PLGA scaffolds. These results indicate that the biomimetic apatite coating can be accelerated by using a polymer/ceramic composite scaffold and concentrated SBF. When seeded with osteoblasts, the apatite-coated PLGA/HA scaffolds exhibited significantly higher cell growth, alkaline phosphatase activity, and mineralization in vitro compared to the apatite-coated PLGA scaffolds. Therefore, the apatite-coated PLGA/HA scaffolds may provide enhanced osteogenic potential when used as scaffold for bone tissue engineering.     

Apatite-coated collagen scaffold for bone morphogenetic protein-2 delivery

Bone morphogenetic proteins (BMPs) are the most potent osteoinductive growth factors. BMP-2 is clinically used for spine fusion and bone fracture healing. Commercially available BMP-2 uses a type I collagen scaffold as a carrier, but it only releases BMP-2 for a short period of time, which may release the bone formation efficacy. In the present study, we hypothesize that apatite coating of a collagen scaffold increases the release period as well as the osteogenic efficacy of BMP-2. Apatite coating was achieved by incubating collagen scaffolds in simulated body fluids (SBFs). Apatite coating on collagen scaffolds was confirmed by X-ray diffraction, electron spectroscopy for chemical analysis, attenuated total reflectance-Fourier transform infrared spectroscopy, and scanning electron microscopy. The rate and period of BMP-2 release from apatite-coated collagen scaffolds varied depending on the concentration of SBFs used. The 5× and 10× SBF apatite-coated collagen scaffolds released 91.8%±11.5% and 82.2%±13.1% of their loaded BMP-2 over 13 days in vitro, respectively, whereas noncoated collagen scaffold released 98.3%±2.2% over the initial one day. BMP-2 released from apatite-coated collagen scaffold significantly increased the alkaline phosphatase activity of cultured osteoblasts, compared with BMP-2 released from noncoated collagen scaffold. Computed tomography and histomorphometry showed that BMP-2 delivery using apatite-coated collagen scaffolds resulted in 2.5-fold higher bone formation volume and 4.0-fold higher bone formation area than BMP-2 delivery using noncoated collagen scaffolds. This study shows that simple apatite coating of a collagen scaffold results in a BMP-2 carrier that renders long-term release of BMP-2 and dramatically enhances osteogenic efficacy.     

In vivo bone formation following transplantation of human adipose-derived stromal cells that are not differentiated osteogenically

A number of studies have shown in vivo bone regeneration by transplantation of osteogenic cells differentiated in vitro from adipose-derived stromal cells (ADSCs). However, the in vitro osteogenic differentiation process requires an additional culture period, and the dexamethasone that is generally used in the process may be cytotoxic. Here, we tested the hypothesis that ADSCs that are not differentiated osteogenically in vitro prior to transplantation would extensively regenerate bone in vivo when exogenous bone morphogenetic protein-2 (BMP-2) is delivered to the transplantation site. We fabricated a poly(dl-lactic-co-glycolic acid)/hydroxyapatite (PLGA/HA) composite scaffold with osteoactive HA that is highly exposed on the scaffold surface. This scaffold was able to release BMP-2 over a 4-week period in vitro. Human ADSCs cultured on BMP-2-loaded PLGA/HA scaffolds for 2 weeks differentiated toward osteogenic cells expressing alkaline phosphatase (ALP), osteopontin (OPN), and osteocalcin (OCN) mRNA, while cells on PLGA/HA scaffolds without BMP-2 expressed only ALP. To study in vivo bone formation, PLGA/HA scaffolds (group 1), BMP-2-loaded PLGA/HA scaffolds (group 2), undifferentiated ADSCs seeded on PLGA/HA scaffolds (group 3), and undifferentiated ADSCs seeded on BMP-2-loaded PLGA/HA scaffolds (group 4) were implanted into dorsal, subcutaneous spaces of athymic mice. Eight weeks after implantation, group 4 exhibited a 25-fold greater bone formation area and 5-fold higher calcium deposition than group 3. Bone regeneration by transplanted human ADSCs in group 4 was confirmed by expression of human-specific osteoblastic genes, ALP, collagen type I, OPN, OCN, and bone sialoprotein, while group 3 expressed much lower levels of collagen type I and OPN mRNA only. This study demonstrates the feasibility of extensive in vivo bone regeneration by transplantation of ADSCs without prior in vitro osteogenic differentiation, and that a PLGA/HA composite BMP-2 delivery system stimulates bone regeneration following transplantation of undifferentiated human ADSCs.     

Hydrogels derived from demineralized and decellularized bone extracellular matrix

The extracellular matrix (ECM) of mammalian tissues has been isolated, decellularized and utilized as a scaffold to facilitate the repair and reconstruction of numerous tissues. Recent studies have suggested that superior function and complex tissue formation occurred when ECM scaffolds were derived from site-specific homologous tissues compared with heterologous tissues. The objectives of the present study were to apply a stringent decellularization process to demineralized bone matrix (DBM), prepared from bovine bone, and to characterize the structure and composition of the resulting ECM materials and DBM itself. Additionally, we sought to produce a soluble form of DBM and ECM which could be induced to form a hydrogel. Current clinical delivery of DBM particles for treatment of bone defects requires incorporation of the particles within a carrier liquid. Differences in osteogenic activity, inflammation and nephrotoxicity have been reported with various carrier liquids. The use of hydrogel forms of DBM or ECM may reduce the need for carrier liquids. DBM and ECM hydrogels exhibited sigmoidal gelation kinetics consistent with a nucleation and growth mechanism, with ECM hydrogels characterized by lower storage moduli than the DBM hydrogels. Enhanced proliferation of mouse primary calvarial cells was achieved on ECM hydrogels, compared with collagen type I and DBM hydrogels. These results show that DBM and ECM hydrogels have distinct structural, mechanical and biological properties and have the potential for clinical delivery without the need for carrier liquids.     

Segmental bone regeneration using a load-bearing biodegradable carrier of bone morphogenetic protein-2

Segmental defect regeneration has been a clinical challenge. Current tissue-engineering approach using porous biodegradable scaffolds to delivery osteogenic cells and growth factors demonstrated success in facilitating bone regeneration in these cases. However, due to the lack of mechanical property, the porous scaffolds were evaluated in non-load bearing area or were stabilized with stress-shielding devices (bone plate or external fixation). In this paper, we tested a scaffold that does not require a bone plate because it has sufficient biomechanical strength. The tube-shaped scaffolds were manufactured from poly(propylene) fumarate/tricalcium phosphate (PPF/TCP) composites. Dicalcium phosphate dehydrate (DCPD) were used as bone morphogenetic protein-2 (BMP-2) carrier. Twenty-two scaffolds were implanted in 5mm segmental defects in rat femurs stabilized with K-wire for 6 and 15 weeks with and without 10 microg of rhBMP-2. Bridging of the segmental defect was evaluated first radiographically and was confirmed by histology and micro-computer tomography (microCT) imaging. The scaffolds in the BMP group maintained the bone length throughout the duration of the study and allow for bridging. The scaffolds in the control group failed to induce bridging and collapsed at 15 weeks. Peripheral computed tomography (pQCT) showed that BMP-2 does not increase the bone mineral density in the callus. Finally, the scaffold in BMP group was found to restore the mechanical property of the rat femur after 15 weeks. Our results demonstrated that the load-bearing BMP-2 scaffold can maintain bone length and allow successfully regeneration in segmental defects.     

结合3D打印技术构建聚己内酯-骨细胞外基质复合支架及体外骨诱导性能

BACKGROUND: Scholars are still looking for ideal bone tissue-engineered scaffolds, and  three-dimensional (3D) printing technology is a novel construction method. In the meanwhile, bone extracellular matrix is becoming a hotspot in osteogenic induction. OBJECTIVE: To construct the polycaprolactone/bone extracellular matrix scaffold using 3D printing technology and co-culture method, and to detect its osteogenic property. METHODS: 216 3D-printed polycaprolactone scaffolds were divided into group A (96 pores, n=72) and group B(48 pores, n=144). Passage 5 bone marrow mesenchymal stem cells from Sprague-Dawley rats were seeded onto the two kinds of polycaprolactone scaffolds, and the group A was used for alizarin red staining and Masson staining, while the group B for collagen and glycosaminoglycan detection at 1, 2 and 3 weeks of incubation. Afterwards, the scaffolds at 1, 2 and 3 weeks of culture were decellularized and labeled as groups AE1, AE2, AE3, BE1, BE2 and BE3. Then passage 5 bone marrow mesenchymal stem cells from Sprague-Dawley rats were seeded onto each scaffold again, and the former three groups underwent alizarin red staining, and the latter three were used for calcium, alkaline phosphatase activity and DNA quantitative analysis at 1, 2 and 3 weeks of culture. RESULTS AND CONCLUSION: Masson staining, glycosaminoglycan and hydroxyproline quantitative analysis showed that the extracellular matrix on the composite scaffold increased with time. Alkaline phosphatase activity revealed that the composite scaffold had a significantly stronger osteogenic differentiation than the normal polycaprolactone scaffold (P < 0.05). Alizarin red staining and calcium quantitative analysis showed that the mineralization of the composite scaffold was more obvious than that of the normal polycaprolactone scaffold (P < 0.05), but the total DNA analysis did not differ significantly between scaffolds. These results suggest that the composite scaffold with extracellular matrix is constructed successfully using the 3D technology and co-culture method and exhibits a better osteoinductivity.     

Effect of self-assembled nanofibrous silk/polycaprolactone layer on the osteoconductivity and mechanical properties of biphasic calcium phosphate scaffolds

We here present the first successful report on combining nanostructured silk and poly(ε-caprolactone) (PCL) with a ceramic scaffold to produce a composite scaffold that is highly porous (porosity ∼85%, pore size ∼500 μm, ∼100% interconnectivity), strong and non-brittle with a surface that resembles extracellular matrix (ECM). The ECM-like surface was developed by self-assembly of nanofibrous structured silk (20-80 nm diameter, similar to native collagen found in ECM) over a thin PCL layer which is coated on biphasic calcium phosphate (BCP) scaffolds. The effects of different concentrations of silk solution on the mechanical and physical properties of the scaffolds were also comprehensively examined. Our results showed that using silk only (irrespective of concentration) for the modification of ceramic scaffolds could drastically reduce the compressive strength of the modified scaffolds in aqueous media, and the modification made a limited contribution to improving scaffold toughness. Using PCL/nanostructured silk the compressive strength and modulus of the modified scaffolds reached 0.42 MPa (compared with 0.07 MPa for BCP) and ∼25 MPa (compared with 5 MPa for BCP), respectively. The failure strain of the modified scaffold increased more than 6% compared with a BCP scaffold (failure strain of less than 1%), indicating a transformation from brittle to elastic behavior. The cytocompatibility of ECM-like composite scaffolds was investigated by studying the attachment, morphology, proliferation and bone-related gene expression of primary human bone-derived cells. Cells cultured on the developed scaffolds for 7 days had significant up-regulation of cell proliferation (∼1.6-fold higher, P < 0.001) and osteogenic gene expression levels (collagen type I, osteocalcin and bone sialoprotein) compared with the other groups tested.     

柚皮苷-壳聚糖/羟基磷灰石复合支架修复大鼠颅骨缺损

背景:骨碎补的有效成分柚皮苷具有补肝肾强筋骨的传统功效,能增加骨痂厚度,提高骨折愈合质量。目的:探究载中药骨碎补有效成分柚皮苷壳聚糖/羟基磷灰石复合支架的骨传导和骨诱导性能。方法:将一定钙磷比的羟基磷灰石前体液与含柚皮苷的壳聚糖溶液在碱性条件下原位结晶、冷冻干燥,获得柚皮苷-壳聚糖/羟基磷灰石多孔支架。将15只成年SD大鼠随机分成空白组(n=5)、对照组(n=5)和实验组(n=5),建立直径5 mm颅骨骨缺损模型,空白组未填充生物材料,对照组填充壳聚糖/羟基磷灰石支架,实验组填充柚皮苷-壳聚糖/羟基磷灰石复合支架。术后4周取材,CT扫描观察颅骨修复情况,苏木精-伊红染色观察颅骨修复的形态学,骨形态发生蛋白2和血管内皮生长因子免疫组化染色后观察缺损区域局部成骨活性因子的表达。结果与结论:(1)CT扫描显示,空白组大鼠颅骨未见明显骨生成,仅在缺损边缘可见少量新生骨;对照组于缺损孔隙可见新生骨形成,新生骨较少;实验组骨缺损修复良好,新生骨组织与缺损孔隙周围颅骨密度相似,大面积新生骨广泛填充了缺损孔隙。(2)苏木精-伊红染色显示,空白组缺损区填充以稀薄的疏松网状纤维组织,可见大量炎性反应病灶,...     

A bioactive “self-fitting” shape memory polymer scaffold with potential to treat cranio-maxillo facial bone defects

While tissue engineering is a promising alternative for treating critical-sized cranio-maxillofacial bone defects, improvements in scaffold design are needed. In particular, scaffolds that can precisely match the irregular boundaries of bone defects as well as exhibit an interconnected pore morphology and bioactivity would enhance tissue regeneration. In this study, a shape memory polymer (SMP) scaffold was developed exhibiting an open porous structure and the capacity to conformally “self-fit” into irregular defects. The SMP scaffold was prepared via photocrosslinking of poly(ε-caprolactone) (PCL) diacrylate using a SCPL method, which included a fused salt template. A bioactive polydopamine coating was applied to coat the pore walls. Following exposure to warm saline at T > T_trans (T_trans = T_m of PCL), the scaffold became malleable and could be pressed into an irregular model defect. Cooling caused the scaffold to lock in its temporary shape within the defect. The polydopamine coating did not alter the physical properties of the scaffold. However, polydopamine-coated scaffolds exhibited superior bioactivity (i.e. formation of hydroxyapatite in vitro), osteoblast adhesion, proliferation, osteogenic gene expression and extracellular matrix deposition.     

Biodegradable composite scaffolds incorporating an intramedullary rod and delivering bone morphogenetic protein-2 for stabilization and bone regeneration in segmental long bone defects

In this study, a two-part bone tissue engineering scaffold was investigated. The scaffold consists of a solid poly(propylene fumarate) (PPF) intramedullary rod for mechanical support surrounded by a porous PPF sleeve for osseointegration and delivery of poly(dl-lactic-co-glycolic acid) (PLGA) microspheres with adsorbed recombinant human bone morphogenetic protein-2 (rhBMP-2). Scaffolds were implanted into critical size rat segmental femoral defects with internal fixation for 12 weeks. Bone formation was assessed throughout the study via radiography, and following euthanasia, via microcomputed tomography and histology. Mechanical stabilization was evaluated further via torsional testing. Experimental implant groups included the PPF rod alone and the rod with a porous PPF sleeve containing PLGA microspheres with 0, 2 or 8 μg of rhBMP-2 adsorbed onto their surface. Results showed that presence of the scaffold increased mechanical stabilization of the defect, as evidenced by the increased torsional stiffness of the femurs by the presence of a rod compared to the empty defect. Although the presence of a rod decreased bone formation, the presence of a sleeve combined with a low or high dose of rhBMP-2 increased the torsional stiffness to 2.06 ± 0.63 and 1.68 ± 0.56 N·mm, respectively, from 0.56 ± 0.24 N·mm for the rod alone. The results indicate that, while scaffolds may provide structural support to regenerating tissues and increase their mechanical properties, the presence of scaffolds within defects may hinder overall bone formation if they interfere with cellular processes.