Objective To sum up the experimental and clinical history as wellas latest development of repair of growth plate injury Methods Recent articles about repair of growth plate injury were extensively reviewed and major reparative methods were introduced, especially including tissue engineering research on growth plate.Results Repair of growth plate injury was a great difficulty inexperimental study and clinical treatment of pediatric orthopedics. Transplantation of free growth plate and cartilage were unfavorably used because of lack ofblood supplement. Although circulation problem was solved by transplantation ofvascularized growth plate, autografts of epiphyseal cartilage were involved in limitation of donor, and allografts of epiphyseal cartilage induced immunological reaction. Noncartilaginous tissue and material could only prevent formation of bony bridge in small defect of growth plate and lacked ability of regenerative repair. Transplantationof tissue engineered cartilage and chondrocytes might be a choice for repair ofgrowth plate injury Conclusion Owing to lack of safe and effective methods ofrepairing growth plate injury, research on chondrocyte and tissue engineered cartilage should be further done.
【Abstract】 Objective To develop a novel cartilage acellular matrix (CACM) scaffold and to investigate its performance for cartilage tissue engineering. Methods Human cartilage microfilaments about 100 nm-5 μm were prepared after pulverization and gradient centrifugation and made into 3% suspension after acellularization treatment. After placing the suspension into moulds, 3-D porous CACM scaffolds were fabricated using a simple freeze-drying method. The scaffolds were cross-l inked by exposure to ultraviolet radiation and immersion in a carbodiimide solution 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide hydrochloride and N-hydroxysucinimide. The scaffolds were investigated by histological staining, SEM observation and porosity measurement, water absorption rate analysis. MTT test was also done to assess cytotoxicity of the scaffolds. After induced by conditioned medium including TGF-β1, canine BMSCs were seeded into the scaffold. Cell prol iferation and differentiation were analyzed using inverted microscope and SEM. Results The histological staining showed that there are no chondrocytefragments in the scaffolds and that toluidine blue, safranin O and anti-collagen II immunohistochemistry staining werepositive. The novel 3-D porous CACM scaffold had good pore interconnectivity with pore diameter (155 ± 34) μm, 91.3% ± 2.0% porosity and 2 451% ± 155% water absorption rate. The intrinsic cytotoxicity assessment of novel scaffolds using MTT test showed that the scaffolds had no cytotoxic effect on BMSCs. Inverted microscope showed that most of the cells attached to the scaffold. SEM micrographs indicated that cells covered the scaffolds uniformly and majority of the cells showed the round or ell iptic morphology with much matrix secretion. Conclusion The 3-D porous CACM scaffold reserved most of extracellular matrix after thoroughly decellularization, has good pore diameter and porosity, non-toxicity and good biocompatibil ity, which make it a suitable candidate as an alternative cell-carrier for cartilage tissue engineering.
To study how to repair the cartilage defect according to the principles of tissue engineering with acellular cartilage matrix as scaffold material. Methods The ear cartilage was obtained from a New Zealand white rabbit(weighing 2.4 kg )and then treated by a modified Courtman’s four-step method to produce the acellular cartilage matrix. Eighteen New Zealand white rabbits (aged 6 months, weighing 2.4-2.6 kg) with no sex l imit were divided into three groups. Forevery rabbit, two pieces of ear cartilage measured 1 cm × 1 cm were excised in each ear. Defects were repaired as follows: group A with the combined graft of acellular cartilage matrix and perichondium, group B with acellular cartilage matrix and group C with perichondium. Three animals in each group were killed 4 and 12 weeks postoperatively, respectively. Tissue samples obtained were analyzed with gross observation, hematoxyl in-eosin stain, Safranine O-alcian blue stain and type II collagen messenger RNA in situ hybridization respectively. Results In gross observation, the repaired sites in groups A and B were not change meaningfully in their shape 4 weeks postoperatively; but they felt a bit of thicker and harder 12 weeks postoperatively. In group C two repaired sites formed scabs at 2 weeks and perforated at 5 weeks. In histological observation, there was a sl ight inflammatory reaction surrounding the acellular cartilage matrix 4 weeks after it was implanted in groups A and B. The inflammatory cells were mainly lymphocytes. The perichondrium graft in group C was collapsed in the defects in HE stain. The defect sites were negative for Safranine O-alcian blue stain and type II collagen mRNA in situ hybridization in all groups. At 12 weeks cells were found in the acellular matrix which arranged in irregular manner in group A in HE stain and was positive for Safranine O-alcian blue stain and type II collagen mRNA in site hybridization. In groups B and C, no new cell was found in HE stain and the repaired sites were negative for Safranine O-alcian blue stain and type II collagen mRNA in situ hybridization. Conclusion Acellular
Objective To investigate the effect of “two-phase” tissue engineered cartilage constructed by autologous marrow mesenchymal stem cells(MSCs) and allogeneic bone matrix gelatin(BMG) in repairing articular cartilage defects. Methods Thirty-twoNew Zealand white rabbits were involved in the experiment. “Two-phase” allogeneic BMG scaffold (one side of porous cancellous bone and the other side of cortical bone; 3 mm both in diameter and in thickness) was prepared from iliac bone and limb bone of 5 rabbits by sequentially chemical method. The MSCs wereseparated from 18 New Zealand white rabbits and induced to express chondrocyticphenotype. The chondrocyte precursor cells were seeded onto “two-phase” allogeneic BMG to construct tissue engineering cartilage. Masson’s trichrome staining, PAS staining and scanning electronic microscopic observation were carried out at 1, 3 and 5 weeks. The defects of full thickness articular cartilage(3 mm both in diameter and in depth) were made at both sides of femoral medial condyles in 27 rabbits(including 18 of separated MSCs and the remaining 9). The defects were repaired with the tissue engineered cartilage at the right side (group A, n=18), with BMG at the left side(group B, n=18), and without any implant at both sides in the remaining 9 rabbits as a control( group C, n=18). After 1, 3 and6 months, the 6 specimens of femoral condyles were harvested in 3 groups, respectively. Gross observation, Masson’s trichrome and Alcian blue staining, modified Wakitani scoring and in situ hybridization of collagen type Ⅱ were carried out to assess the repair efficacy of tissue engineered cartilage. Results The “two-phase” BMG consisted of the dense cortical part and the loose cancellous part. In cancellous part, the pore size ranged 100-800 μm, in which the chondrocyte precursor cells being induced from MSCs proliferated and formed the cell-rich cartilaginous part of tissue engineered cartilage. In cortical part, the pore size ranged 10-40 μm, on which the cells arranged in a layer and formed the hard part of subchondral bone. After 1 month of transplantation, the cartilage and subchondral bone were regenerated in group A; during observation, the regenerated cartilage graduallythinned, but defect was repaired and the structure of the articular surface ansubchondral bone was in integrity. In groups B and C, defects were not repaired, the surrounding cartilage of defect was abrased. According to the modified Wakitani scoring, the indexes in group A were significantly higher than those in group B and C(Plt;0.01) except the thickness of cartilage at 6 months. The positive cell rate of in situ hybridization for collagen type Ⅱ in group A was also higher than those in groups B and C(Plt;0.01). Conclusion “Two-phase” allogeneic BMG is a prospective scaffold for tissue engineered cartilage,which combines with autologous chondrocyte precursor cells induced from MSCs toconstruct the tissue engineering cartilage. The tissue engineered cartilage can repair defects of articular cartilage and subchondral bone.
Objective To study the feasibility of using mice marrow stromal stem cells(MSCs) as seed cells for tissue engineering cartilage to embed the seed cells in acellular cartilage matrix of human auricle. Methods Acellular cartilage matrix was made from human auricle cartilage. The MSCs were isolated from the nucleated cells fraction of mice marrow by centrifuge.The MSCs were embedded in acellular cartilage matrix. After 10 day’s combined culture, the specimens were observed with optical and electrical microscope.Results The MSCs could well proliferate in the acellular cartilage matrix. The cells were not well-distributed in acellular cartilage matrix. There were more cells in the peripheral part of the matrix than in the central part of the matrix. Most of the cells were in cartilaginous lacunae. There were 1 or 2 cells in every cartilaginous lacunae.Conclusion The MSCs can be used as seed cells of tissue engineering and can well proliferate in the acellular cartilage matrix and become tissue engineering cartilage.
Objective To investigate the effect of allogeneic chondrocytes-calcium alginate gel composite under the intervention of low intensive pulsed ultrasound (LIPUS) for repairing rabbit articular cartilage defects. Methods Bilateral knee articular cartilage were harvested from 8 2-week-old New Zealand white rabbits to separate the chondrocytes by mechanical-collagen type II enzyme digestion. The 3rd passage chondrocytes were diluted by 1.2% sodium alginate to 5 × 106 cells/mL, then mixed with CaCl2 solution to prepare chondrocytes-calcium alginate gel composite, which was treated with LIPUS for 3 days (F0: 1 MHz; PRF: 1 kHz; Amp: 60 mW/cm2; Cycle: 50; Time: 20 minutes). An articular cartilage defect of 3 mm in diameter and 3 mm in thickness was established in both knees of 18 New Zealand white rabbits (aged 28-35 weeks; weighing, 2.1-2.8 kg), and divided into 3 groups randomly, 6 rabbits in each group: LIPUS group, common group, and model group. Defect was repaired with LIPUS-intervention gel composite, non LIPUS-intervention gel composite in LIPUS group and common group, respectively; defect was not treated in the model group. The general condition of rabbits was observed after operation. The repair effect was evaluated by gross and histological observations, immunohistochemical staining, and Wakitani score at 8 and 12 weeks after operation. Results Defect was filled with hyaline chondroid tissue and white chondroid tissue in LIPUS and common groups, respectively. LIPUS group was better than common group in the surface smooth degree and the degree of integration with surrounding tissue. Defect was repaired slowly, and the new tissue had poor elasticity in model group. Histological observation and Wakitani score showed that LIPUS group had better repair than common group at 8 and 12 weeks after operation; the repair effect of the 2 groups was significantly better than that of model group (P lt; 0.05); and significant differences in repair effect were found between at 8 and 12 weeks in LIPUS and common groups (P lt; 0.05). The collagen type II positive expression area and absorbance (A) value of LIPUS and common groups were significantly higher than those of model group (P lt; 0.05) at 8 and 12 weeks after operation, and the expression of LIPUS group was superior to that of common group at 12 weeks (P lt; 0.05); and significant differences were found between at 8 and 12 weeks in LIPUS group (P lt; 0.05), but no significant difference between 2 time points in common and model groups (P gt; 0.05). Conclusion Allogeneic chondrocytes-calcium alginate gel composite can effectively repair articular cartilage defect. The effect of LIPUS optimized allogeneic chondrocytes-calcium alginate gel composite is better.
Objective To study the effect of platelet lysate (PL) on chondrogenic differentiation of human umbil ical cord derived mesenchymal stem cells (hUCMSCs) in vitro. Methods Umbil ical cords were voluntarily donated by healthy mothers. The hUCMSCs were isolated by collagenase digestion and cultured in vitro. The surface markers of the cells were detected by flow cytometer. According to different components of inductive medium, the cultured hUCMSCs were divided into 3 groups: group A [H-DMEM medium, 10% fetal bovine serum (FBS), and 10%PL]; group B [H-DMEM medium, 10%FBS,10 ng/mL transforming growth factor β1 (TGF-β1), 1 × 10-7 mol/L dexamethasone, 50 μg/mL Vitamin C, and 1% insul intransferrin- selenium (ITS)]; and group C (H-DMEM medium, 10%FBS, 10 ng/mL TGF-β1, 1 × 10-7mol/L dexamethasone, 50 μg/ mL vitamin C, 1%ITS, and 10%PL). The hUCMSCs were induced in the mediums for 2 weeks. Toluidine blue staining was used to detect the secretion of chondrocyte matrix. Immunofluorescence method was used to identify the existence of collagen trpe II. The expressions of Aggrecan and collagen type II were detected by semiquantitative RT-PCR. Results Flow cytometer results showed that the hUCMSCs did not express the surface markers of hematopoietic cell CD34, CD45, and human leukocyte antigen DR, but expressed the surface markers of adhesion molecule and mesenchymal stem cells CD44, CD105, and CD146. Toluidine blue staining and immunofluorescence showed positive results in group C, weak positive results in group B, and negative results in group A. Semiquantitative RT-PCR showed the expressions of Aggrecan and collagen type II at mRNA level in groups B and C, but no expression in group A. The mRNA expressions of Aggrecan and collagen type II were higher in group C than in group B (P lt; 0.05). Conclusion Only 10%PL can not induce differentiation of hUCMSCs into chondrocytes, but it can be a supplement to the induced mediums. PL can improve hUCMSCs differentiating into chondrocytes obviously in vitro. This study provides new available conditions for constructing tissue engineered cartilage.
Objective To investigate the effect of homograft of marrow mesenchymal stem cells (MSCs) seeded onto poly-L-lactic acid (PLLA)/gelatin on repair of articular cartilage defects. Methods The MSCs derived from36 Qingzilan rabbits, aging 4 to 6 months and weighed 2.5-3.5 kg were cultured in vitroand seeded onto PLLA/gelatin. The MSCs/ PLLA/gelatin composite was cultured and transplanted into full thickness defects on intercondylar fossa. Thirty-six healthy Qingzilan rabbits were made models of cartilage defects in the intercondylar fossa. These rabbits were divided into 3 groups according to the repair materials with 12 in each group: group A, MSCs and PLLA/gelatin complex(MSCs/ PLLA/gelatin); group B, only PLLA/gelatin; and group C, nothing. At 4,8 and 12 weeks after operation, the gross, histological and immunohistochemical observations were made, and grading scales were evaluated. Results At 12 weeks after transplantation, defect was repaired and the structures of the cartilage surface and normal cartilage was in integrity. The defects in group A were repaired by the hylinelike tissue and defects in groups B and C were repaired by the fibrous tissues. Immunohistochemical staining showed that cells in the zones of repaired tissues were larger in size, arranged columnedly, riched in collagen Ⅱ matrix and integrated satisfactorily with native adjacent cartilages and subchondral bones in group A at 12 weeks postoperatively. In gross score, group A(2.75±0.89) was significantly better than group B (4.88±1.25) and group C (7.38±1.18) 12 weeks afteroperation, showing significant differences (P<0.05); in histological score, group A (3.88±1.36) was better than group B (8.38±1.06) and group C (13.13±1.96), and group B was better than group C, showing significant differences (P<0.05). Conclusion Transplantation of mesenchymal stem cells seeded onto PLLA/gelatin is a promising way for the treatment of cartilage defects.
Objective To evaluate the feasibility and the value of the layered cylindric collagenhydroxyapatite composite as a scaffold for the cartilage tissue engineering after an observation of how it absorbs the chondrocytes and affe cts the cell behaviors. Methods The chondrocytes were isolated and multiplied in vitro, and then the chondrocytes were seeded onto the porous collagen/h ydro xyapatite composite scaffold and were cultured in a three-dimensional environme n t for 3 weeks. The effects of the composite scaffold on the cell adhesivity, proliferation, morphological changes, and synthesis of the extracellular matrix were observed by the phase-contrast microscopy, histology, scanning electron micros copy, and immunohistochemistry. Results The pore diameter of the upper layer of the collagen-hydroxyapatite composite scaffold was about 147 μm. and the porosity was 89%; the pore diameter of the bottom layer was about 85 μm and the porosity was 85%. The layered cylindric collagenhydroxyapatite composite scaffold had good hydrophilia. The chondrocytes that adhered to the surface of the scaffold, proliferated and migrated into the scaffold after 24 hours. The chondrocytesattached to the wall of the microholes of the scaffold maintained a rounded morphology and could secrete the extracellular matrix on the porous scaffold. Conclusion The layered cylindric collagenhydroxyapatite composite scaffold has a good cellular compatibility, and it is ber in the mechanical property than the pure collagen. It will be an ideal scaffold for the cartilage tissue enginee ring.
Objective To explore heterotopic chondrogenesis of canine myoblasts induced by cartilage-derived morphogenetic protein 2 (CDMP-2) and transforming growth factor β1 (TGF-β1) which were seeded on poly (lactide-co-glycolide) (PLGA) scaffolds after implantation in a subcutaneous pocket of nude mice. Methods Myoblasts from rectus femoris of 1-year-old Beagle were seeded on PLGA scaffolds and cultured in medium containing CDMP-2 and TGF-β1 for 2 weeks in vitro. Then induced myoblasts-PLGA scaffold, uninduced myoblasts-PLGA scaffold, CDMP-2 and TGF-β1-PLGA scaffold, and simple PLGA scaffold were implanted into 4 zygomorphic back subcutaneous pockets of 24 nude mice in groups A, B, C, and D, respectively. At 8 and 12 weeks, the samples were harvested for general observation, HE staining and toluidine blue staining, immunohistochemical staining for collagen type I and collagen type II; the mRNA expressions of collagen type I, collagen type II, Aggrecan, and Sox9 were determined by RT-PCR, the glycosaminoglycans (GAG) content by Alician blue staining, and the compressive elastic modulus by biomechanics. Results In group A, cartilaginoid tissue was milky white with smooth surface and slight elasticity at 8 weeks, and had similar appearance and elasticity to normal cartilage tissue at 12 weeks. In group B, few residual tissue remained at 8 weeks, and was completely degraded at 12 weeks. In groups C and D, the implants disappeared at 8 weeks. HE staining showed that mature cartilage lacuna formed of group A at 8 and 12 weeks; no cartilage lacuna formed in group B at 8 weeks. Toluidine blue staining confirmed that new cartilage cells were oval and arranged in line, with lacuna and blue-staining positive cytoplasm and extracellular matrix in group A at 8 and 12 weeks; no blue metachromatic extracellular matrix was seen in group B at 8 weeks. Collagen type I and collagen type II expressed positively in group A, did not expressed in group B by immunohistochemical staining. At 8 weeks, the mRNA expressions of collagen type I, collagen type II, Aggrecan, and Sox9 were detected by RT-PCR in group A at 8 and 12 weeks, but negative results were shown in group B. The compressive elastic modulus and GAG content of group A were (90.79 ± 1.78) MPa and (10.20 ± 1.07) μg/mL respectively at 12 weeks, showing significant differences when compared with normal meniscus (P lt; 0.05). Conclusion Induced myoblasts-PLGA scaffolds can stably express chondrogenic phenotype in a heterotopic model of cartilage transplantation and represent a suitable tool for tissue engineering of menisci.