Lanthanum phosphate/chitosan scaffolds enhance cytocompatibility and osteogenic efficiency via the Wnt/β-catenin pathway

Nanobiotechnology:

Abstract

Background

Fabrication of porous scaffolds with great biocompatibility and osteoinductivity to promote bone defect healing has attracted extensive attention.

Methods

In a previous study, novel lanthanum phosphate (LaPO4)/chitosan (CS) scaffolds were prepared by distributing 40- to 60-nm LaPO4 nanoparticles throughout plate-like CS films.

Results

Interconnected three dimensional (3D) macropores within the scaffolds increased the scaffold osteoconductivity, thereby promoting cell adhesion and bone tissue in-growth. The LaPO4/CS scaffolds showed no obvious toxicity and accelerated bone generation in a rat cranial defect model. Notably, the element La in the scaffolds was found to promote osteogenic differentiation of bone marrow mesenchymal stem cells (BMSCs) through the Wnt/β-catenin signalling pathway and induced high expression of the osteogenesis-related genes alkaline phosphatase, osteocalcin and Collagen I (Col-I). Moreover, the LaPO4/CS scaffolds enhanced bone regeneration and collagen fibre deposition in rat critical-sized calvarial defect sites.

Conclusion

The novel LaPO4/CS scaffolds provide an admirable and promising platform for the repair of bone defects.

© The Authors Haoran Hu, Peipei Zhao, Jiayu Liu, Qinfei Ke, Changqing Zhang, Yaping Guo and Hao Ding | Contributed equally

Background

A substantial challenge remains in the treatment of bone defects caused by skeletal injury or bone disease [123]. Although autogenous bone grafts are recognized as the “gold standard”, their clinical application is restricted because of certain shortcomings, such as limited availability, additional pain, donor-position morbidity and infection risk [4]. Alternatively, various bone repair materials, including beta-tricalcium phosphate (β-TCP), hydroxyapatite (HA), bioactive glass (BG) and CS, have been recently developed [56]. These biomaterials exhibit admirable biocompatibility and bioconductivity, but their limited osteoinductivity cannot meet the demands of patients, especially those with osteoporosis and metabolic disorders [7]. Consequently, developing a novel and osteoinductive platform for bone regenerations is a high priority.

The cell response and bone regeneration capacities of bone scaffolds can be improved by loading scaffolds with osteogenic growth factors/therapeutic drugs or doping with bioactive elements [8910]. The introduction of bone morphogenetic protein 2, parathyroid hormone, vascular endothelial growth factor, bone forming peptide 1, or platelet derived growth factor in bone scaffolds effectively stimulates the osteogenic process of BMSCs and the formation of new bone tissues [1112]; however, the high concentrations of the released growth factors may cause side effects in the human body [13]. Another strategy is to incorporate bioactive elements in bone scaffolds to enhance cell proliferation, differentiation and bone regeneration [141516]. Lanthanum (La), one of rare earth elements (REEs) found in the human body, participates in stem cell differentiation, tissue regeneration and metabolism [17]. La can delay vascular calcification for patients with hyperphosphataemic renal bone disease and shows positive phosphate binding effects in bone metabolism [18]. Osteoclast formation and function are attenuated by LaCl3 via down-regulation of rankl-induced Nf-κb and Nfatc1 activities [19]. In addition, lanthanum-containing nanoparticles have been reported as X-ray-mediated agents for tumour therapy [20]. Among the La-based bioceramics, LaPO4 nanoparticles have attracted special attention because of their intrinsic photoluminescence property, low toxicity and good drug delivery behaviour [212223]. Up to now, LaPO4 nanoparticles have been widely used as imaging agents, drug carriers, and biomarkers [2425]. To the best of our knowledge, LaPO4-coordination scaffolds have rarely been reported as bone regeneration materials, and their role in osteogenesis remains unclear.

Human bone has a complex inorganic–organic porous architecture, in 3D connected macrochannels facilitate nutrition transference and vascular and bone tissue in-growth [26]. CS, a common polysaccharide that is non-toxic, naturally degrades and exhibits good biocompatibility, has been widely used for bone repair materials [162728].

Inspired by the architecture of natural bones, a novel and promising LaPO4/CS scaffold was constructed using a freeze-drying technique. This is the first report showing that LaPO4 nanoparticles in LaPO4/CS scaffolds rapidly promote the osteogenesis activity of BMSCs, and the underlying mechanism was attributed to Wnt/β-Catenin pathway activation (Scheme 1). A skull bone repair model in Sprague–Dawley (S–D) rats further demonstrated that the LaPO4/CS scaffolds significantly accelerate new bone regeneration compared with β-TCP/CS scaffolds. These exciting findings present a promising strategy for design and fabrication of novel REE-based biomaterials for skeletal treatments.

Scheme 1

Scheme 1

Lanthanum phosphate/chitosan scaffolds for bone defect therapy

Experimental section

Preparation of LaPO4 nanoparticles

LaPO4 nanoparticles were fabricated by a chemical precipitation method. In brief, 2.9877 g La(NO3)3·6H2O and 0.9112 g (NH4)2HPO4 was separately dispersed in 100 mL deionized water. Then, the pH of an (NH4)2HPO4 solution was adjusted to 11–12 by adding NH3·H2O solution. The La(NO3)3 solution was dropwise dropped into the (NH4)2HPO4 solution under continuous agitation at room temperature (RT). After 2.5 h, the mixture was stirred further for 1 h at 90 °C and then stirred for 24 h at RT. The precipitates were washed with deionized water and alcohol until the products were neutral. Finally, LaPO4 nanoparticles were produced after drying at 60 °C for 24 h and calcination at 1000 °C for 3 h. Moreover, the β-TCP nanoparticles that served as the control group were prepared via a solid-state reaction [2930]. Calcium carbonate and ammonium phosphate (dibasic) mixtures at a molar ratio of 3:2 were calcined at 1000 °C for 3 h.

Preparation of LaPO4/CS composite scaffold

Briefly, 4.0 g of CS powder was dissolved in 100 mL acetic acid solution (2.0 vol.%) to form a homogeneous CS solution. Then, 4.0 g of LaPO4 was added into the CS solution, and the solution was stirred for 2 h. The mixture was injected into wells in 24-well or 96-well plates. The samples were frozen at − 20 °C for 12 h and then freeze-dried in a freeze drier at − 60 °C for 48 h. The as-obtained precursor scaffolds were dipped in 0.1 mol/l sodium hydroxide solution for 24 h, followed by washing with deionized water for 6 days. β-TCP/CS scaffolds were prepared by the same method.

Characterization

LaPO4 nanoparticles and LaPO4/CS scaffolds were coated with a thin gold layer, and then their morphologies were characterized by field-emission scanning electron microscopy (SEM; S-4800, Hitachi, Japan). The accelerating voltage was 5 kV and the working distance was kept at approximately 7 mm. The element compositions were determined by energy dispersive spectrometry (EDS; Quantax 400, Bruker) at an accelerating voltage of 20 kV. The microstructures of LaPO4nanoparticles were characterized by high resolution transmission electron microscopy (HRTEM; JEM-2100, JEOL, Japan) and selected area electron diffraction (SAED) at 200kv. The phases of the samples were characterized by X-ray powder diffraction (XRD; D/Max-2200, Rigaku, Japan) using Cu Kα radiation at 40 kV with a scanning speed of 5º/min in the range of 2θ = 10°–70°. The functional groups in samples were detected by Fourier transform infrared spectroscopy (FTIR; Frontier, PerkinElmer, USA) in a wavenumber range of 4000–500 cm−1 with a resolution of 4 cm−1 at 100 ~ 230 V. A Malvern Zetasizer (Nano ZS90; Malvern Instruments Ltd. UK) was employed for dynamic light scattering (DLS) measurements after the LaPO4 particles were dispersed in ultrapure water. The organic and inorganic percentages of the scaffolds were calculated according to thermogravimetric analysis (TG; Perkin-Elmer) with a heating rate of 10 °C/min. The as-used purge gas was dry air with a flow rate of 50 mL/min and a heating rate of 10 °C/min.

Cell isolation and culture

Rat bone marrow mesenchymal stem cells (BMSCs) were isolated from the femur of S–D rats using a Ficoll density gradient and then allowed to proliferate in minimum essential medium α (Gibco) with 10% foetal bovine serum (Gibco), penicillin (100 U/mL) and streptomycin (100 μg/mL) (Gibco) in an incubator with 5% CO2 at 37 °C. The cells used in this study were from passages 3–7.

Cell morphology on scaffolds

To observe the attachment of cells on both LaPO4/CS and β-TCP/CS scaffolds, BMSCs were cultured on the scaffolds at a density of 2.0 × 104 cells/mL in a 24-well plate. After 3 days of incubation, the cells were fixed with 2.5% glutaraldehyde, washed with phosphate buffer saline (PBS), dehydrated by ethanol, and freeze-dried at − 80 °C. Finally, SEM (S-4800, Hitachi, Japan) was utilized to observe the samples.

Cell toxicity and proliferation on scaffolds

To estimate the cell toxicity and proliferation of the scaffold, on days 1, 3 and 7, Cell Counting Kit 8 (CCK-8; Dojindo, Japan) was adopted measure the cell viability. In brief, 1.0 × 104 BMSCs were co-cultured with scaffolds in a 24-well plate for the given days. At each time point, 450 μL of culture medium with 50 μL (10%) of CCK-8 reagent was added to the samples. The cells were incubated for 2 h, and then, the absorbance at 450 nm was measured with a microplate reader (Bio-Rad, USA).

Alkaline phosphatase (ALP) activity assay and staining

To carry out the ALP activity assay and staining, BMSCs were seeded on the LaPO4/CS and β-TCP/CS scaffolds for 7 and 14 days in a 24-well transwell plate at a primary density of 2.0 × 104 cells/mL, with cells in the lower chamber and the scaffolds in the upper chamber. At each time point, the ALP activity was determined via the p-nitrophenyl-phosphate (pNPP) method, and ALP staining was conducted via the 5-bromo-4-chloro-3-indolyl phosphate/tetranitroblue tetrazolium chloride (BCIP/NBT) method according to the manufacturer’s instructions. For the ALP activity assay, the samples were washed twice with PBS and lysed with 0.1% Triton X-100, and then pNPP (Beyotime Biotechnology, China) was added for 60 min at 37 °C. Last, 1 M NaOH solution was added to quench the chromogenic reaction, and the absorbance at 405 nm of each sample was recorded. For ALP staining, a BCIP/NBT kit (Beyotime Biotechnology, China) was used to stain the samples, which were photographed with both a digital camera (Canon, Japan) and a microscope (Leica, Germany).

Extracellular matrix (ECM) mineralization evaluation

Cells were cultured in a 24-well transwell plate. After 7 and 14 days of culture, the cells were fixed with 2.5% glutaraldehyde and washed twice with PBS. The samples were stained with 1 mM alizarin red (Cyagen, USA) for 10 min. Finally, images were acquired with both a digital camera and a microscope.

Osteogenesis-related gene expression

Cells were seeded on the LaPO4/CS and β-TCP/CS scaffolds at a density of 2.0 × 104cells/mL in a 6-well plate for 7 and 14 days, and then, Trizol (Invitrogen) was used to extract messenger RNA (mRNA) from the cells, and Moloney Murine Leukemia Virus (M-MLV) Reverse Transcriptase (Takara) was used to synthesize the complementary DNA (cDNA). qPCRSuperMix (BioTNT), forward and reverse primers and cDNA were loaded onto a 384-well plate, and the reverse transcription-polymerase chain reaction (RT-PCR) procedure was performed using a Sequence Detection System (7900 HT, ABI). The primers used in this study are shown in Table 1, and GAPDH was used as the internal control gene.

Table 1

Real-time polymerase chain reaction primers used in this study

Gene

Accession number

Primers (up: forward; down: reverse)

Product size (bp)

GAPDH

NM_017008.4

GCAAGAGAGAGGCCCTCAG

TGTGAGGGAGATGCTCAGTG

74

OCN

NM_013414.1

TCACTCTGCTGGCCCTGACT

CCCTCCTGCTTGGACATGAA

100

ALP

NM_013059.1

CATCATCATGTTCCTGGGAG

GACCTGAGCGTTGGTGTTGT

163

Col-I

NM_053304.1

GGCGAGTGCTGTCCTTTCTG

CTTCCCCATCATCTCCGTTCTCTTCC

434

Western blotting

The protein in rBMSCs from different groups was extracted with cell lysis buffer and proteinase inhibitor after 7 and 14 days of culture. A bicinchoninic acid Protein Assay Kit (Cell Signaling Technology) was used to quantify the protein concentrations. Each protein sample was loaded onto sodium dodecyl sulfate–polyacrylamide gel electrophoresis gels for electrophoresis (Millipore) and then transferred to polyvinylidene difluoride membranes. After blocking with Quickblock™ (Beyotime), the membrane was incubated with primary antibody targeting phosphorylated glycogen synthase kinase-3β (p-GSK3β), glycogen synthase kinase-3β (GSK3β), β-Catenin and GAPDH at 4 °C overnight and then with secondary antibodies at RT for 2 h.

Procedures for Implantation of the Scaffolds into Animals

All animal surgical procedures were approved by the Animal Care and Experiment Committee of Shanghai Jiao Tong University Affiliated Sixth People’s Hospital. Twenty adult S–D rats (8 weeks old; weight 250 ± 25 g) were anaesthetized by intraperitoneal injection of chloral hydrate sodium (250 mg/kg). An incision with a sagittal length of 1.5–2.0 cm was made on the scalp, and then, two full-thickness 5-mm-diameter defects were made on both sides of the skull with an electric trephine drill. The scaffolds implanted were 5 mm in diameter and 2 mm in thickness and randomly implanted into each cranial defect. The rats were intraperitoneally injected with fluorochromes under anaesthesia as follows: 25 mg/kg tetracycline (Sigma, USA) on week 3, 30 mg/kg alizarin red (Sigma, USA) on week 6 and 20 mg/kg calcein (Sigma, USA) on week 9. On week 12, all rats were sacrificed by intraperitoneal injection with an overdose of hydrate sodium, and the calvarias were obtained.

Micro-CT and histomorphometric analyses

The skull specimens were scanned using micro-computerized tomography (micro-CT, Skyscan, Belgium). Scanning was performed with a 100 kV/100 μA X-ray source with an isotropic voxel size of 18 μm. The images were used to reconstruct tomograms with a 3D Creator software (Skyscan Software). Bone mineral density (BMD) and the ratio of bone volume/tissue volume (BV/TV) were measured with CTAn (Skyscan Software) based on the reconstructed micro-CT images.

Histological analysis

For histological analysis, the specimens were dehydrated in a graded alcohol series for 3 days and then embedded in methyl methacrylate without decalcification. The non-decalcified samples were cut with a diamond saw (SP1600, Leica) and ground to approximately 150 μm in thickness. After fluorescence labelling, the specimens were evaluated with a confocal laser scanning microscope (Leica). After Van Gieson’s (VG) staining, the specimens were observed with an optical microscope (Leica).

Statistical analysis

Statistical analyses were performed using SPSS 20.0 (SPSS Inc., Chicago, IL, USA). All the data were expressed as mean ± standard deviation and analysed by one-way analysis of variance with Bonferroni’s post hoc test. Statistical significance was indicated when p < 0.05.

Results

Morphologies and Structures of LaPO4/CS Scaffolds

Inspired by the hierarchical architecture of bone, LaPO4/CS scaffolds were constructed according to the following steps: (i) coprecipitation preparation of LaPO4 nanoparticles; and (ii) freeze–drying synthesis of the LaPO4/CS scaffolds. SEM and TEM images showed that the as-obtained LaPO4 nanoparticles exhibited irregular shapes with sizes of approximately 40–60 nm (Fig. 1a, d). The nanostructure of LaPO4 can increase the surface energy, easily resulting in the agglomeration of these nanoparticles (Fig. 1a). The hydrodynamic sizes of LaPO4agglomerates were mainly distributed at around 500 nm, as detected by a Malvern Zetasizer Nano ZS90 instrument (Additional file 1: Figure S1). As shown in the EDS spectrum (Fig. 1c), the elements La, P and O were present in the LaPO4nanoparticles, and Al was present in the aluminium foil. La was uniformly dispersed within the LaPO4 nanoparticles (Fig. 1b). A representative HRTEM image taken from an individual LaPO4 nanoparticle showed a lattice spacing of 4.138 Å and 5.227 Å, which can be indexed to the (1¯011¯01) and (101) crystal planes of LaPO4, respectively (Fig. 1e). The SAED pattern the LaPO4 nanoparticles exhibited bright spots, indicating a monocrystal structure with a [011¯011¯] zone axis.

Fig. 1

Fig. 1

Characterization of LaPO4 nanoparticles: a SEM image; b image showing La distribution; cEDS spectrum; d TEM image; e HRTEM image; f SAED pattern

The phases of the LaPO4/CS scaffolds were investigated by XRD patterns using pure CS and LaPO4 as control groups (Fig. 2). The characteristic peaks of LaPO4nanoparticles indicated a monoclinic phase with a space group of P21/n(14) (JCPDS 16-0382) [31]. As we know, the structure units of CS include β-(1,4)-2-acetamido-2-β-d-glucose and β-(1,4)-2-amido-2-β-d-glucose units [32]. The diffraction peaks at approximately 20° and 28° revealed that the pure CS exhibited semi-crystalline features (Fig. 2a). Compared with the pure CS and LaPO4, only characteristic peaks of LaPO4 were detected in the LaPO4/CS scaffolds due to the lower crystallinity of CS relative to LaPO4 (Fig. 2).

Fig. 2

Fig. 2

XRD patterns of samples: a CS; b LaPO4 particles; c LaPO4/CS composite scaffold

The functional groups of the LaPO4/CS scaffolds were demonstrated by FTIR spectra using pure CS powders and LaPO4 as control groups. The LaPO4/CS scaffolds possessed the characteristic bands of both LaPO4 and CS (Fig. 3). For the LaPO4/CS scaffolds and CS powders (Fig. 3a, c), the bands at 1662, 1595 and 894 cm−1 corresponded to the amide-I vibration, N–H deformation vibration and N–H wagging vibration in amino groups, respectively [33]. The C-O stretching vibration bands were located at 1072/1034 cm−1, and the bridge oxygen stretching vibration bands were located at 1152 cm−1 [34]. The characteristic bands of PO 4 3-groups were observed in both the LaPO4/CS scaffolds and LaPO4 nanoparticles. The P-O antisymmetric stretching vibration (v3) band was located at 993 and 954 cm−1, and the antisymmetric deformation vibration (v4) band was located at 615 cm−1 [3536].

Fig. 3

Fig. 3

FTIR spectra of samples: a CS; b LaPO4 particles; c LaPO4/CS composite scaffold

The morphologies of LaPO4/CS scaffolds were characterized by SEM, as shown in Fig. 4. The LaPO4/CS scaffolds possessed 3D interconnected macrochannels with pore sizes of approximately 200 µm (Fig. 4a). These interlinked macropores, which were formed due to volatilization of ice crystals during the freeze-drying procedure, can promote body fluid exchange and bone tissue in-growth [26]. The CS films were connected together, and the macropores were present among the films. Moreover, the LaPO4 nanoparticles were distributed within or on the CS films, and they presented a granule-stacking structure because of their small particle sizes (Fig. 4b). A La surface scan map of La further demonstrated the presence of LaPO4 nanoparticles within the scaffolds (Fig. 4c). The EDS spectrum indicated that the LaPO4/CS composite scaffolds were composed of the elements La, P, O and C (Fig. 4d). The elements La and P were ascribed to the LaPO4nanoparticles, and C was ascribed to the CS. The TG curves indicated that the volatilization of adsorbed water took place at 40–100 °C, while the decomposition of CS occurred at 100–550 °C (Additional file 1: Figure S2). The percentages of different components in the scaffolds could be calculated according to the TG curves. The percentages of adsorption water, LaPO4 and CS in the LaPO4/CS scaffolds were approximately 9%, 47% and 44%, respectively (Additional file 1: Figure S2a). The percentages of adsorption water, LaPO4 and CS in the LaPO4/CS scaffolds were approximately 7%, 47% and 46%, respectively (Additional file 1: Figure S2b).

Fig. 4

Fig. 4

Characterization of LaPO4/CS scaffolds: ab SEM images; c surface scan map of La; d EDS spectrum

In Vitro Cytocompatibility and Osteogenesis Ability of LaPO4/CS Scaffolds

The cytocompatibility and osteogenesis ability of the LaPO4/CS scaffolds were assessed using rBMSCs as the cell model and β-TCP/CS scaffolds as the control group. SEM images indicated that the rBMSCs attached tightly to the films of both the LaPO4/CS scaffolds and β-TCP/CS scaffolds after 3 days of culture (Fig. 5a). Long cell pseudopodia spread well and stretched gradually into the scaffold interior through the interconnected macropore channels. The cells on both the LaPO4/CS scaffolds and β-TCP/CS scaffolds continuously proliferated from day 1 to day 7, as shown by the CCK-8 results (Fig. 5b). Notably, the cell number on the LaPO4/CS scaffolds was significantly greater than that on the β-TCP/CS scaffolds (#p < 0.05, Fig. 5b) after culture for 1, 3 or 7 days, suggesting that the LaPO4/CS scaffolds remarkably supported the proliferation of rBMSCs compared with the β-TCP/CS scaffolds.

Fig. 5

Fig. 5

a SEM images of the LaPO4/CS and β-TCP/CS scaffolds after 3 days of incubation with rBMSCs. b CCK-8 results on days 1, 3 and 7; c ALP activity results on days 7 and 14 (#: a significant difference compared with the β-TCP/CS group (p < 0.05))

The osteogenesis ability of the LaPO4/CS scaffolds was determined by ALP activity, ALP staining and mineralization evaluation assays. ALP activity is an early osteogenic differentiation marker secreted by stem cells. The ALP activity in the LaPO4/CS group was significantly higher than that in the β-TCP/CS group (Fig. 5c, #p < 0.05). ALP staining images further demonstrated that the cells co-cultured with the LaPO4/CS scaffolds produced more ALP than those with cultured with the β-TCP/CS scaffolds at days 7 and 14 (Fig. 6b). Meanwhile, macroscopic and microscopic alizarin red staining images revealed that the rBMSCs in the LaPO4/CS group generated more ECM mineralization than those in the β-TCP/CS group at days 7 and 14 (Fig. 6a). Taken together, the in vitro cell tests suggest that both the LaPO4/CS and β-TCP/CS scaffolds present excellent cytocompatibility, and the LaPO4/CS scaffolds exhibited better osteogenic effects than the β-TCP/CS scaffolds.

Fig. 6

Fig. 6

a Alizarin red staining and b ALP staining results shown via macroscopic and microscopic observation after cell culture for 7 and 14 days

To further investigate the underlying osteogenesis mechanism of the LaPO4/CS scaffolds, the expression of osteogenesis-related genes in the BMSCs co-cultured with the LaPO4/CS and β-TCP/CS scaffolds was evaluated by RT-PCR and western blot analysis (Fig. 7). After culture for 7 or 14 days, the expression levels of ALP and osteocalcin (OCN) in the LaPO4/CS group were significantly increased compared with those in the β-TCP/CS group (Fig. 7a, b). Although the expression level of Col-I showed no significant difference between the LaPO4/CS and β-TCP/CS group at day 7, the Col-I expression level in the former was much greater than that in the latter at day 14 (Fig. 7c). Moreover, western blotting results revealed that the LaPO4/CS scaffolds obviously enhanced the expression of phosphorylated Gsk3β and β-Catenin compared with the β-TCP/CS scaffolds (Fig. 7d). Gsk3β and β-Catenin are key proteins in the Wnt/β-catenin pathway. Therefore, it can be inferred that the LaPO4/CS scaffolds enhance osteogenesis activity by activating the Wnt/β-catenin signalling way.

Fig. 7

Fig. 7

mRNA expression of osteogenic-related genes in rBMSCs, ALP (a), OCN (b) and Col-I (c), on days 7 and 14 (#a significant difference compared with β-TCP/CS (p < 0.05)). d p-Gsk3β, Gsk3β, β-Catenin and GAPDH expression measured via western blotting at days 7 and 14. GAPDH was used as the internal reference

Bone regeneration ability in vivo

The in vivo bone formation capacity of the LaPO4/CS scaffolds was evaluated using critical-sized calvarial bone defect models. 3D reconstructed micro-CT images indicated that the LaPO4/CS scaffolds had a better ability to promote new bone formation in the cranial defects than the β-TCP/CS scaffolds after 12 weeks of implantation (Fig. 8a). Simultaneously, the calculated BMD and BV/TV values confirmed the above conclusion. The LaPO4/CS group showed a higher BMD (0.577 ± 0.053) than the β-TCP/CS group (0.379 ± 0.037) (Fig. 8b, p < 0.05). The BV/TV ratio in the LaPO4/CS scaffold group was also increased up to 49.87 ± 2.91% compared with the β-TCP/CS group (37.85 ± 2.44%) (Fig. 8c, #p < 0.05).

Fig. 8

Fig. 8

a Micro-CT results of 3D reconstructed and 2D sagittal images and the BMD (b) and BV/TV (c) results (#a significant difference compared with β-TCP/CS, p < 0.05). d New bone formation and mineralization determined by fluorochrome-labelling analysis. Row 1 (yellow) shows tetracycline at week 2, row 2 (red) shows alizarin red at week 4, row 3 (green) shows calcein at week 6, and row 4 shows merged images of the three fluorochromes for the same group

The newly formed bone was characterized at different weeks post-operation via histological analysis of triple fluorescence labelling, specifically tetracycline (yellow) at week 3, calcein (green) at week 6 and alizarin red (red) at week 6 (Fig. 8d). Stronger density and a more widely spread area of fluorescence were detected in the LaPO4/CS group than in the β-TCP/CS group. Moreover, VG staining (Fig. 9) suggested more collagen fibres were present surrounding the sites of the LaPO4/CS scaffolds than surrounding the β-TCP/CS scaffolds, indicating that the LaPO4/CS scaffolds exhibited better potential for collagenous matrix formation. Taken together, the micro-CT reconstruction, fluorescence labelling and VG staining results demonstrated that the LaPO4/CS scaffolds could better enhance both in vivo new bone formation and collagen formation than the β-TCP/CS scaffolds.

Fig. 9

Fig. 9

Transmitted light images of Van Gieson’s picrofuchsin-stained sections of rat calvarial defects with implanted scaffolds at 12 weeks post-implantation. New bone is shown in red, and the scaffold is shown in black

Discussion

Developments in nanotechnology, molecular biology and nanomedicine have facilitated the fabrication of various biomedical materials [3738]. To date, a large number of bone repair materials have been developed for treating bone defects; however, their low bone-forming ability still cannot meet the demands of patients, especially those with osteoporosis and metabolic disorders [6]. Notably, REEs play a pivotal role in regulating the function and performance of bone tissues. Hence, here, novel LaPO4/CS scaffolds were developed for the first time for use as bone repair materials.

Excellent osteoconductivity and biocompatibility are prerequisites for bone tissue engineering materials. It has been reported that CS has biological and chemical similarities to natural tissues, which could promote the proliferation of mesenchymal cells such as BMSCs and stimulate its differentiation [3940]. Combination of natural chitin-calcium-carbonate-protein complexes can result in hardening of the CS scaffold [41]. The 3D CS-based scaffolds were reported to provide a proper space for new bone tissue regeneration with optimal size of 200-600 µm to facilitate osteoconduction and bone growth [42]. During the freeze-drying process, a 3D interconnected macroporous structure with pore sizes of approximately 200 μm was produced by using ice crystals as templates (Fig. 4). The large macropores not only provided enough spaces for cell adhesion and pseudopodium migration (Fig. 5a) but also supported the in-growth of bone tissues and cells (Figs. 7 and 8).

Moreover, the LaPO4/CS scaffolds exhibited excellent biocompatibility, and the chemical components in the scaffolds were non-toxic. On one hand, BMSCs cultured on the scaffolds proliferated continuously from 1 to 7 days (Fig. 5b); on the other hand, no rejection reaction was observed after implantation of the scaffolds into calvarial bone defect sites (Fig. 9). The above in vitro and in vivo results suggest that LaPO4/CS scaffolds offer great osteoconductivity, cytocompatibility and histocompatibility.

The osteoinductivity of bone scaffolds plays a key role in inducing in vivo new bone formation. To enhance osteogenesis activity, various bioactive elements such as Li, Mg and Sr, are widely incorporated into bone scaffolds [141516]. For example, Mg2+ ions released from implants induce overexpression of calcitonin receptor-like receptor and receptor activity-modifying protein, and thus promote new bone growth [15]. For strontium hydroxyapatite [SrHAP, Ca10−xSrx(PO4)6(OH)2], the synergetic effect between Ca2+ and Sr2+ ions remarkably increases osteogenic-related gene expression levels and promotes ECM mineralization [16]. La has been reported to penetrates all intercellular spaces and the newly forming bone matrix to enhance the mineral deposition [43], showing its osteoblast potential in tissue engineering. Recent years, La has also been tested to improve proliferation, osteogenic differentiation and mineralization in vitro [44] and stimulates bone formation in a rat model in vivo [45]. In this work, relatively integrated in vivo and in vitro experiments were carried out to obtain a comprehensive understanding of the effects of La3+ on the osteogenesis process. Compared with the β-TCP/CS scaffolds, the LaPO4/CS scaffolds presented a better cell proliferation performance (Fig. 5b), indicating positive effects of La on BMSCs. Moreover, the LaPO4/CS scaffolds induced higher ALP activity and ECM mineralization than the β-TCP/CS scaffolds, as demonstrated by the ALP activity assay, ALP staining and alizarin red staining (Figs. 5c and 6), which accelerates new bone formation and mineralization.

To determine the mechanism of LaPO4/CS scaffolds in osteogenesis, RT-PCR analysis and western blotting were employed to measure the expression levels of osteogenic-related genes and proteins. The RT-PCR analysis (Fig. 7a–c) revealed that the expression of ALP, OCN and Col-I were up-regulated by the LaPO4/CS scaffolds. ALP is one of the key enzymes in BMSC differentiation and osteogenesis [46], and higher ALP expression indicates an enhancement of bone formation in vitro. OCN and Col-I are components of mature bone, and their presence indicates early ECM mineralization. Meanwhile, western blotting was used to assess the cellular signalling processes in BMSCs and verified that LaPO4/CS scaffolds up-regulated the expression of Wnt/β-catenin pathway components (Fig. 7d).

The Wnt/β-catenin pathway is an important pathway that regulates osteogenic differentiation activities [47]. The pathway plays a central role in the bone regeneration and is an important regulator of bone formation in the process of osteoblastic differentiation. It also stimulates its downstream pathways that result in affecting several osteogenic processes including not only osteoblast attachment and differentiation but also cell maturation and apoptosis [48]. Moreover, the pathway has also been reported to promote both mineral deposition in ECM and the repair of tissue defect [4950]. The proteins of β-Catenin and Gsk3β are key proteins in the canonical Wnt/β-catenin pathway. The western blotting results suggested that a higher level of GSK3β phosphorylation and increased expression of β-Catenin were induced by LaPO4/CS scaffolds, and this enhancement suggested up-regulation of the Wnt/β-catenin pathway, which would improve cell proliferation and osteogenic differentiation.

In addition, an in vivo study with rat critical-sized calvarial defect sites was conducted to confirm the biofunction of LaPO4/CS scaffolds in bone repair. 3D reconstruction of micro-CT images (Fig. 8a) allowed visualization of the effects of LaPO4/CS scaffolds, and the results were verified by quantitative evaluation of BMD and BV/TV (Fig. 8b, c). Meanwhile, triple fluorochrome and VG staining also showed more bone and collagenous matrix formation at the defect site (Figs. 8d and 9). In summary, LaPO4/CS scaffolds exhibit promising potential for bone regeneration both in vitro and in vivo.

Conclusion

In the present study, LaPO4/CS scaffolds were prepared for bone defect healing. LaPO4 nanoparticles with sizes of 40–60 nm were evenly distributed throughout the surface of the scaffolds. Interconnected 3D macropores were formed due to the connection of the plate-like films, which increased the osteoconductivity of the LaPO4/CS scaffolds for cell adhesion and bone tissue in-growth. The LaPO4/CS scaffolds showed no obvious toxicity or effects on cell morphology, and they accelerated bone generation in a rat cranial defect model. More importantly, controlled release of La3+ from the scaffolds was found to promote osteogenic differentiation of BMSCs through the Wnt/β-catenin pathway and enhance the osteogenesis-regulated gene expression of ALP, OCN and Col-I. Furthermore, the LaPO4/CS scaffolds enhanced bone regeneration and collagen fibre deposition in rat critical-sized calvarial defect sites. In summary, the novel LaPO4/CS scaffolds provide an admirable and promising platform for the treatment of bone defects.

Notes

Abbreviations

LaPO4 : lanthanum phosphate
CS: chitosan
3D: three dimensional
BMSCs: bone marrow mesenchymal stem cells
Col-I: Collagen I
β-TCP: beta-tricalcium phosphate
HA: hydroxyapatite
BG: bioactive glass
BMP-2: bone morphogenetic protein 2
La: Lanthanum
REEs: rare earth elements
S–D: Sprague–Dawley
RT: room temperature
SEM: scanning electron microscopy
EDS: energy dispersive spectrometry
HRTEM: high resolution transmission electron microscope
SAED: selected area electron diffraction
XRD: X-ray powder diffraction
FTIR: Fourier transform infrared spectroscopy
PBS: phosphate buffer saline
CCK-8: Cell Counting Kit 8
ALP: alkaline phosphatase
pNPP: p-nitrophenyl-phosphate
BCIP/NBT: 5-bromo-4-chloro-3-indolyl phosphate/tetranitroblue tetrazolium chloride
ECM: extracellular matrix
mRNA: messenger RNA
M-MLV: Moloney Murine Leukemia Virus
RT-PCR: reverse transcription-polymerase chain reaction
GAPDH: glyceraldehyde-3-phosphate dehydrogenase
p-GSK3β: phosphorylated glycogen synthase kinase-3β
GSK3: glycogen synthase kinase-3β
micro-CT: micro-computerized tomography
BMD: bone mineral density
BV/TV: bone volume/tissue volume
VG: Van Gieson’s
OCN: osteocalcin

Declarations

Authors’ contributions

HH and PZ carried out experiments, analysed data and wrote the paper. YG, HD and CZ designed the study. JL and QF contributed substantially to the sample preparation. All authors read and approved the final manuscript.

Acknowledgements

This research was supported by Natural Science Foundation of China (Nos. 51372152, 81472066, 81601888), Innovation Foundation of Shanghai Education Committee (No. 14ZZ124).

Competing interests

The authors declare that they have no competing interests.

Availability of data and materials

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.

Consent for publication

Not applicable.

Ethics approval and consent to participate

All the animal experiments were conducted in accordance with the guidelines and the ethical standards of the Animal Care and Experiment Committee of Shanghai Jiao Tong University Affiliated Sixth People’s Hospital.

Publisher’s Note (BMC)

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.  Open AccessLanthanum phosphate/chitosan scaffolds …

References

  1. Mohammadi M, Alibolandi M, Abnous K, Salmasi Z, Jaafari MR, Ramezani M. Fabrication of hybrid scaffold based on hydroxyapatite-biodegradable nanofibers incorporated with liposomal formulation of BMP-2 peptide for bone tissue engineering. Nanomedicine. 2018;14(7):1987–97.View ArticleGoogle Scholar
  2. Ahmadzadeh E, Talebnia F, Tabatabaei M, Ahmadzadeh H, Mostaghaci B. Osteoconductive composite graft based on bacterial synthesized hydroxyapatite nanoparticles doped with different ions: from synthesis to in vivo studies. Nanomedicine. 2016;12(5):1387–95.View ArticleGoogle Scholar
  3. Hu H, Cui R, Mei L, Ni S, Sun H, Zhang C, et al. Cytocompatibility and bone-formation potential of se-coated 316L stainless steel with nano-pit arrays. J Biomed Nanotechnol. 2018;14(4):716–24.View ArticleGoogle Scholar
  4. Sun D, Chen Y, Tran RT, Xu S, Xie D, Jia C, et al. Citric acid-based hydroxyapatite composite scaffolds enhance calvarial regeneration. Sci Rep. 2014;4:6912.View ArticleGoogle Scholar
  5. Jang HL, Zheng GB, Park J, Kim HD, Baek HR, Lee HK, et al. In vitro and in vivo evaluation of whitlockite biocompatibility: comparative study with hydroxyapatite and β -tricalcium phosphate. Adv Healthcare Mater. 2016;5(1):128–36.View ArticleGoogle Scholar
  6. Hails LA, Babister JC, Inglis S, Davis SA, Oreffo RO, Mann S. Inhibition of hydroxyapatite nanoparticle-induced osteogenic activity in skeletal cells by adsorption of serum proteins. Small. 2010;6(18):1986–91.View ArticleGoogle Scholar
  7. Abu Elella MH, Mohamed RR, Sabaa MW. Synthesis of novel grafted hyaluronic acid with antitumor activity. Carbohydr Polym. 2018;189:107–14.View ArticleGoogle Scholar
  8. Farokhi M, Mottaghitalab F, Shokrgozar MA, Ou KL, Mao C, Hosseinkhani H. Importance of dual delivery systems for bone tissue engineering. J Control Release. 2016;225:152–69.View ArticleGoogle Scholar
  9. Quinlan E, Lopez-Noriega A, Thompson E, Kelly HM, Cryan SA, O’Brien FJ. Development of collagen-hydroxyapatite scaffolds incorporating PLGA and alginate microparticles for the controlled delivery of rhBMP-2 for bone tissue engineering. J Control Release. 2015;198:71–9.View ArticleGoogle Scholar
  10. Chen YX, Zhu R, Ke QF, Gao YS, Zhang CQ, Guo YP. MgAl layered double hydroxide/chitosan porous scaffolds loaded with PFTα to promote bone regeneration. Nanoscale. 2017;9(20):6765.View ArticleGoogle Scholar
  11. Jiang L, Zhang W, Wei L, Zhou Q, Yang G, Qian N, et al. Early effects of parathyroid hormone on vascularized bone regeneration and implant osseointegration in aged rats. Biomaterials. 2018;179:15–28.View ArticleGoogle Scholar
  12. Luo Z, Zhang S, Pan J, Shi R, Liu H, Lyu Y, et al. Time-responsive osteogenic niche of stem cells: a sequentially triggered, dual-peptide loaded, alginate hybrid system for promoting cell activity and osteo-differentiation. Biomaterials. 2018;163:25–42.View ArticleGoogle Scholar
  13. Xavier JR, Thakur T, Desai P, Jaiswal MK, Sears N, Cosgriff-Hernandez E, et al. Bioactive nanoengineered hydrogels for bone tissue engineering: a growth-factor-free approach. ACS Nano. 2015;9(3):3109–18.View ArticleGoogle Scholar
  14. Clémentlacroix P, Ai M, Morvan F, Romanroman S, Vayssière B, Belleville C, et al. Lrp5-independent activation of Wnt signaling by lithium chloride increases bone formation and bone mass in mice. Proc Natl Acad Sci USA. 2005;102(48):17406–11.View ArticleGoogle Scholar
  15. Zhao D, Witte F, Lu F, Wang J, Li J, Qin L. Current status on clinical applications of magnesium-based orthopaedic implants: a review from clinical translational perspective. Biomaterials. 2017;112:287–302.View ArticleGoogle Scholar
  16. Yong L, Xu Z, Ke Q, Yin W, Chen Y, Zhang C, et al. Strontium hydroxyapatite/chitosan nanohybrid scaffolds with enhanced osteoinductivity for bone tissue engineering. Mater Sci Eng. 2017;72:134–42.View ArticleGoogle Scholar
  17. Zaichick S, Zaichick V, Karandashev V, Nosenko S. Accumulation of rare earth elements in human bone within the lifespan. Metallomics. 2011;3(2):186–94.View ArticleGoogle Scholar
  18. Manabe R, Fukami K, Ando R, Sakai K, Kusumoto T, Hazama T, et al. Effects of switching from calcium carbonate to lanthanum carbonate on bone mineral metabolism in hemodialysis patients. Ther Apher Dial. 2013;17(Supplement S1):35–40.View ArticleGoogle Scholar
  19. Jiang C, Shang J, Li Z, Qin A, Ouyang Z, Qu X, et al. Lanthanum chloride attenuates osteoclast formation and function via the downregulation of rankl-induced Nf-kappab and Nfatc1 activities. J Cell Physiol. 2016;231(1):142–51.View ArticleGoogle Scholar
  20. Yang T, Liang Y, Hou J, Dou Y, Zhang W. Metabolizable lanthanum-coordination nanoparticles as efficient radiosensitizers for solid tumor therapy. J Mater Chem. 2017;5(26):5137–44.View ArticleGoogle Scholar
  21. Chaudan E, Kim J, Tusseau-Nenez S, Goldner P, Malta OL, Peretti J, et al. Polarized luminescence of anisotropic LaPO4: eu nanocrystal polymorphs. J Am Chem Soc. 2018;140(30):9512–7.View ArticleGoogle Scholar
  22. Runowski M, Dabrowska K, Grzyb T, Miernikiewicz P, Lis S. Core/shell-type nanorods of Tb(3+)-doped LaPO4, modified with amine groups, revealing reduced cytotoxicity. J Nanopart Res. 2013;15:2068.View ArticleGoogle Scholar
  23. Rojas JV, Woodward JD, Chen N, Rondinone AJ, Castano CH, Mirzadeh S. Synthesis and characterization of lanthanum phosphate nanoparticles as carriers for (223)Ra and (225)Ra for targeted alpha therapy. Nucl Med Biol. 2015;42(7):614–20.View ArticleGoogle Scholar
  24. Salman AA, Heidelberg T. In situ functionalized fluorescent nanoparticles for efficient receptor coupling. J Nanopart Res. 2014;16(5):1–8.View ArticleGoogle Scholar
  25. Che D, Zhu X, Liu P, Duan Y, Wang H, Zhang Q, et al. A facile aqueous strategy for the synthesis of high-brightness LaPO 4: eu nanocrystals via controlling the nucleation and growth process. J Lumin. 2014;153(1):369–74.View ArticleGoogle Scholar
  26. Yang B, Yin J, Chen Y, Pan S, Yao H, Gao Y, et al. 2D-black-phosphorus-reinforced 3D-printed scaffolds: a stepwise countermeasure for osteosarcoma. Adv Mater. 2018;30(10):1705611.View ArticleGoogle Scholar
  27. Meng Q, Man Z, Dai L, Huang H, Zhang X, Hu X, et al. A composite scaffold of MSC affinity peptide-modified demineralized bone matrix particles and chitosan hydrogel for cartilage regeneration. Sci Rep. 2015;5:17802.View ArticleGoogle Scholar
  28. Chen J, Pan P, Zhang Y, Zhong S, Zhang Q. Preparation of chitosan/nano hydroxyapatite organic–inorganic hybrid microspheres for bone repair. Colloids Surf. 2015;134:401–7.View ArticleGoogle Scholar
  29. Enderle R, Gotz-Neunhoeffer F, Gobbels M, Muller FA, Greil P. Influence of magnesium doping on the phase transformation temperature of beta-TCP ceramics examined by Rietveld refinement. Biomaterials. 2005;26(17):3379–84.View ArticleGoogle Scholar
  30. Frasnelli M, Sglavo VM. Flash sintering of tricalcium phosphate (TCP) bioceramics. J Eur Ceram Soc. 2018;38(1):279–85.View ArticleGoogle Scholar
  31. Wang X, Zhang L, Zhang Z, Wang X. Effects of pH value on growth morphology of LaPO 4 nanocrystals: investigated from experiment and theoretical calculations. Appl Phys A. 2016;122(5):508.View ArticleGoogle Scholar
  32. Guo YP, Guan JJ, Chen W, Lei Y, Ke QF, Zhang C. Fabrication of hydroxyapatite/chitosan porous materials for Pb(II) removal from aqueous solution. Rsc Adv. 2015;5(32):25462–70.View ArticleGoogle Scholar
  33. Yang F, Wen X, Ke QF, Xie XT, Guo YP. pH-responsive mesoporous ZSM-5 zeolites/chitosan core-shell nanodisks loaded with doxorubicin against osteosarcoma. Mater Sci Eng C Mater Biol Appl. 2018;85:142–53.View ArticleGoogle Scholar
  34. Chen Y, Yu J, Ke Q, Gao Y, Zhang C, Guo Y. Bioinspired fabrication of carbonated hydroxyapatite/chitosan nanohybrid scaffolds loaded with TWS119 for bone regeneration. Chem Eng J. 2018;341:112–25.View ArticleGoogle Scholar
  35. Rajendran V, Ramamoorthy C. Structural and optical properties of LaPO4 nanostructures by the hydrothermal process and its photocatalytic activity. J Inorg Organomet Polym Mater. 2017;27(6):1886–92.View ArticleGoogle Scholar
  36. Wang Z, Li JG, Zhu Q, Kim BN, Sun X. Tartrate promoted hydrothermal growth of highly [001] oriented (La 0.95–x Bi x Eu 0.05)PO 4 (x = 0–0.01) nanowires with enhanced photoluminescence. Mater Design. 2017;126:115–22.View ArticleGoogle Scholar
  37. Kim Y, Yuk H, Zhao R, Chester SA, Zhao X. Printing ferromagnetic domains for untethered fast-transforming soft materials. Nature. 2018;558(7709):274–9.View ArticleGoogle Scholar
  38. Qi GB, Gao YJ, Wang L, Wang H. Self assembled peptide based nanomaterials for biomedical imaging and therapy. Adv Mater. 2018;30(22):1605021.View ArticleGoogle Scholar
  39. Dai T, Tanaka M, Huang YY, Hamblin MR. Chitosan preparations for wounds and burns: antimicrobial and wound-healing effects. Expert Rev Anti Infect Ther. 2011;9(7):857–79.View ArticleGoogle Scholar
  40. Nandi SK, Kundu B, Basu D. Protein growth factors loaded highly porous chitosan scaffold: a comparison of bone healing properties. Mater Sci Eng C Mater Biol Appl. 2013;33(3):1267–75.View ArticleGoogle Scholar
  41. Venkatesan J, Kim SK. Chitosan composites for bone tissue engineering–an overview. Mar Drugs. 2010;8(8):2252–66.View ArticleGoogle Scholar
  42. Saravanan S, Leena RS, Selvamurugan N. Chitosan based biocomposite scaffolds for bone tissue engineering. Int J Biol Macromol. 2016;93(Pt B):1354–65.View ArticleGoogle Scholar
  43. Soares AM, Arana-Chavez VE, Reid AR, Katchburian E. Lanthanum tracer and freeze-fracture studies suggest that compartmentalisation of early bone matrix may be related to initial mineralisation. J Anat. 1992;181(Pt 2):345–56.PubMedPubMed CentralGoogle Scholar
  44. Liu D, Zhang J, Wang G, Liu X, Wang S, Yang M. The dual-effects of LaCl(3) on the proliferation, osteogenic differentiation, and mineralization of MC3T3-E1 cells. Biol Trace Elem Res. 2012;150(1–3):433–40.View ArticleGoogle Scholar
  45. Fumoto T, Ito M, Ikeda K. Lanthanum carbonate stimulates bone formation in a rat model of renal insufficiency with low bone turnover. J Bone Miner Metab. 2014;32(5):484–93.View ArticleGoogle Scholar
  46. Zhang Y, Xia L, Zhai D, Shi M, Luo Y, Feng C, et al. Mesoporous bioactive glass nanolayer-functionalized 3D-printed scaffolds for accelerating osteogenesis and angiogenesis. Nanoscale. 2015;7(45):19207–21.View ArticleGoogle Scholar
  47. Montes A, Guerrero F, Martinez-Moreno JM, Madueno JA, Herencia C, Peralta A, et al. Magnesium inhibits Wnt/beta-catenin activity and reverses the osteogenic transformation of vascular smooth muscle cells. PLoS ONE. 2014;9(2):e89525.View ArticleGoogle Scholar
  48. Manolagas SC, Almeida M. Gone with the Wnts: beta-catenin, T-cell factor, forkhead box O, and oxidative stress in age-dependent diseases of bone, lipid, and glucose metabolism. Mol Endocrinol. 2007;21(11):2605–14.View ArticleGoogle Scholar
  49. Wang W, Zhao L, Ma Q, Wang Q, Chu PK, Zhang Y. The role of the Wnt/beta-catenin pathway in the effect of implant topography on MG63 differentiation. Biomaterials. 2012;33(32):7993–8002.View ArticleGoogle Scholar
  50. Galli C, Piemontese M, Meikle ST, Santin M, Macaluso GM, Passeri G. Biomimetic coating with phosphoserine-tethered poly(epsilon-lysine) dendrons on titanium surfaces enhances Wnt and osteoblastic differentiation. Clin Oral Implants Res. 2014;25(2):e133–9.View ArticleGoogle Scholar