Objective To establ ish a two-dimensional biological printing technique of hBMSCs so as to control the cell transfer process and keep cell viabil ity after printing. Methods Bone marrow (5 mL) was obtained from healthy volunteer. The hBMSCs were regularly subcultured to harvest cells at passage 2, which were adjusted to the single cell suspensionat a density of 1 × 106/mL. The experiment was divided into 3 groups: printing group 1 in which cells underwent propidium iodide (PI) fluorescent label ing, then were transferred by rapid prototype biological printer (interval in x-axis 300 μm, interval in y-axis 1 500 μm), and laser scanning confocal microscope was appl ied to observe cell fluorescence; printing group 2 in which cells received no PI label ing and were cultured for 2 hours after transfer, Live/Dead viabil ity Kit was adopted to detect cell viabil ity and laser scanning confocal microscope was appl ied to observe cell fluorescence; half of the cells in printing group receiving no Live/Dead viabil ity Kit detection were cultured for 7 days, then inverted microscope was used to observe cell morphology, routine culture was conducted after the adherence of cells, the growth condition of cells was observed dynamically; control group in which steps were the same as the printing group 2 except that cell suspension received no printing. Results Laser scanning confocal microscope observation on the cells in printing group 1 revealed the “cell ink droplets” were distributed regularly and evenly in the two-dimensional layer and each contained 15-35 cells, meeting the requirement of designing two-dimensional cell printing. The cells in printing group 2 went through cell viabil ity test, laser scanning confocal microscope observation showed the fluorescence of cells 30 minutes after cell incubation. There was no significant difference between the control group and the printing groups in terms of cell viabil ity. The printed cells presented normal adherence, good morphology and good growth state 7 days after routine culture. Conclusion Biological printing technique can real ize the oriented, quantificational and regulardistribution of hBMSCs in the two-dimensional plane and lays the foundation for the construction of three-dimensional cellprinting or even organ printing system.
Objective To introduce the research of cell transplantation for treating intervertebral disc degeneration. Methods The original articles in recent years about cell transplantation for treating intervertebral disc degeneration were extensively reviewed, and retrospective and comprehensive analysis was performed. Results Transplantation of intevertebraldisc-derived cells or BMSCs by pure cell transplantation or combined with collagen scaffold into intervertebral disc couldexpress nucleus pulposus-l ike phenotype. All the cells transplanted into intervertebral disc could increase extracellular matrix synthesis and rel ieve or even inhibit further intervertebral disc degeneration. Conclusion Cell transplantation for treating intervertebral disc degeneration may be a promising approach.
【Abstract】 Objective To review the recent progress of BMSCs acting as seeding cell for tissue engineeredcartilage. Methods The recent ten years l iterature about BMSCs acting as seeding cell for tissue engineered cartilage was extensively reviewed. Results Scaffold provided an optimal environment for the growth of BMSCs. Cytokine and gene del ivery could promote BMSCs to differentiate toward chondrocytes. All of them played important roles in the field of cartilage tissue engineering. Conclusion The improvement of three-dimensional scaffolds, the rational use of cytokine, and the enhancement of gene del ivery will promote the development of cl inical cartilage reconstruction.
Objective To compare the effect of mosaicplasty, mosaicplasty with gene enhanced tissue engineering and mosaicplasty with the gels of non-gene transduced BMSCs in alginate on the treatment of acute osteochondral defects. Methods Western blot test was conducted to detect the expression of hTGF-β1, Col II and Aggrecan in 3 groups, namely hTGF-β1 transduction group, Adv-βgal transduction group and blank control group without transduction. Eighteen 6-month-old Shanghai mascul ine goats weighing 22-25 kg were randomized into groups A, B and C (n=6). BMSCs were isolatedfrom the autologous bone marrow of groups B and C, and were subcultured to get the cells at passage 3. In group B, the BMSCs were transduced with hTGF-β1. For the animals of 3 groups, acute cyl indrical defects 5 mm in diameter and 3 mm in depth were created in the weight bearing area of the medial femoral condyle of hind l imbs. In group A, the autologous osteochondral mosaicplasty was performed to repair the defect; in group B, besides the mosaicplasty, the dead space between the cyl indrical grafts and the host cartilage were injected with the suspension of hTGF-β1 gene transduced autogenous BMSCs in sodium alginate, and CaCl2 was dropped into it to form calcium alginate gels; in group C, the method was the same as the group B, but the BMSCs were not transduced. General condition of the goats after operation was observed, the goats were killed 12 and 24 weeks after operation to receive gross and histology observation, which was evaluated by the histological grading scale of O’Driscoll, Keeley and Salter. Immunohistochemistry and TEM observation were performed 24 weeks after operation. Results Western blot test showed the expression of the hTGF-β1, Col II and the Aggrecan in the hTGF-β1 transduction group were significantly higher than that of the Adv-βgal transduction and the blank control groups. All the goats survived until the end of experiment and all the wounds healed by first intention. Gross observation revealed the boundaries of the reparative tissue in group B were indistinct, with smooth and continuous surfaces of the whole repaired area; while there were gaps in the cartilage spaces of groups A and C. Histology observation showed the dead space between the cyl indrical grafts in group A had fibrocartilage-l ike repair tissue, fill ing of fibrous tissue or overgrowth of the adjacent cartilage; the chondrocytes in group B had regular arrangements, with favorable integrations; while the dead space between the cyl indrical grafts in group C had fibrocartilage-l ike repair tissue, with the existence of gaps. The histology scores of group B at different time points were significantly higher than that of groups A and C, and group C was better than group A (P lt; 0.05); for group B, significant difference was detected between 12 weeks and 24 weeks in the histology score (P lt; 0.05). Immunohistochemistry staining for Col II 24 weeks after operation showed the chondrocytes and lacuna of the reparative tissue in group B was obviously stained, while groups A and C presented l ight staining. TEM observation showed there were typical chondrocytes in the reparative tissue in group B, while parallel or interlaced arrangement collagen fiber existed in groups A and C. Conclusion Combining mosaicplasty with tissue engineering methods can solve theproblem caused by single use of mosaicplasty, including the poor concrescence of the remnant defect and poor integration with host cartilages.
【Abstract】 Objective To evaluate the biocompatibil ity of the sheep BMSCs cultured on the surface of photografting modified copolymers of 3-hydroxybutyrate and 3-hydroxyvalerate(PHBV). Methods BMSCs were isolated from bone marrow of the posterior il iac crest of a 6-month old sheep by whole marrow adherent culture method. The 3rd passage BMSCs were seeded onto modified PHBV and conventional PHBV films, or three-dimension scaffolds. Cell-adhesion rates were calculated by hemocytometer at 1, 2 and 6 hours after seeded. Cell morphology was examined by scanning electron microscope when the BMSCs were cultured for 3 days, 1 week and 3 weeks. Cell cycle was analyzed by flow cytometry at 5 days after seeded. The content of protein in BMSCs was determined by BCA assay and the content of DNA was quantified by Hoechst 33258 assay at 4, 8 and 12 days after seeded. Results At 1 hour after seeded, cell-adhesion rate on modified PHBV films (52.7% ± 6.0%) was significantlyhigher than that of conventional PHBV films (37.5% ± 5.3%) (P lt; 0.05); At 2 and 6 hours after seeded, cell-adhesion rate of modified PHBV films was similar to that of PHBV films (P gt; 0.05). The surface of modified PHBV film was rougher. In the early culture stage, more cells adhered to modified PHBV and the cells displayed much greater spreading morphology. Furthermore, ECM on modified PHBV were richer. There were no significant differences between the trial team and the control on the cell cycle and the content of DNA and protein of BMSCs (P gt; 0.05). Conclusion Photografting modification on PHBV can promote BMSCs’ adhesion and enhance their biocompatibil ity.
Objective To compare the effect of two different methods of cell seeding on spatial distribution and gene expression of hBMSCs in biocoral scaffold in vitro cultures. Methods The composite of hBMSCs and biocoral scaffold was prepared by traditional seeding (group A) and fibrin glue seeding (group B). The seeding efficiency was measured after 30 minutes of incubation in group B and after 3 hours in group A. At 2, 7, 14 and 21 days after culture, the samples were harvestedand the serial longitudinal sections were cut for each embedded composite. The sections were stained with DAPI and were measured using fluorescence microscope with apotome under serial optical sections. The cell number in every 10 × objective field was automatically measured by AxioVision image analysis software and levels (from seeding surface to bottom L1-L5) or columns (from centre to margin) for comparing cell distribution were set up. The specific osteogenic genes [osteonectin (ON), core binding factor α1 (Cbfα1), osteocalcin (OC)] expression was measured by RT-PCR. Results The seeding efficiency was significantly higher in group B (88.32% ± 4.2%) than in group A (66.51% ± 12.33%, P lt; 0.01). At 2 days after culture, the cell number from L1 to L4 decreased gradully in two groups (P lt; 0.05); in the cell number of different columns, there was no significant difference in group A (Pgt; 0.05) whereas significant difference in group B (P lt; 0.05); there was no significant difference in gene expression between two groups (P gt; 0.05). At 7 days after culture, the cell number was less than that at 2 days in group A and there was significant difference among levels (P lt; 0.05). The cell number and osteogenic gene expression increased sharply and there appeared uniform cell distribution in group B (P gt; 0.05). The gene expression of ON and Cbfα1 in group B was higher than that in group A (Plt; 0.05). At 14 days after culture, the cell number in levels or columns in group A decreased sharply and was less than that at 7 days (P lt; 0.05); whereas the cell number was similar to that at 7 days in group B (P gt; 0.05). The OC gene expression reached the highest level in group B at 14 days. The gene expression was higher in group B than in group A (P lt; 0.05). At 21 days after culture, there was significant difference in the cell number among levels and in the gene expression between group A and group B (P lt; 0.05); there was no significant difference in the cell number among columns in two groups (Pgt; 0.05). In addition, the cell number of most levels and columns in group B was more than that in group A at 7, 14 and 21 days after culture (P lt; 0.05). Conclusion More uniform cell distribution with rapid prol iferation and osteogenic differentiation is available in different levels or columns of scaffold by fibrin glue seeding than by traditional seeding.
【Abstract】 Objective To investigate the secretion of target gene and differentiation of BMSCs transfected by TGF-β1 and IGF-1 gene alone and together into chondrocytes and to provide a new method for culturing seed cells in cartilage tissue engineering. Methods The plasmids pcDNA3.1-IGF-1 and pcDNA3.1-TGF-β1 were ampl ified and extracted, then cut by enzymes, electrophoresed and analyzed its sequence. BMSCs of Wistar rats were separated and purificated by the density gradient centrifugation and adherent separation. The morphologic changes of primary and passaged cells were observed by inverted phase contrast microscope and cell surface markers were detected by immunofluorescence method. According to the transfect situation, the BMSCs were divided into 5 groups, the non-transfected group (Group A), the group transfected by empty vector (Group B), the group transfected by TGF-β1 (Group C), the group transfected by IGF-1 (Group D) and the group transfected both by TGF-β1 and IGF-1 (Group E). After being transfected, the cells were selected, then the prol iferation activity was tested by MTT and expression levels were tested by RT-PCR and Western blot. Results The result of electrophoresis showedthat sequence of two bands of the target genes, IGF-1 and TGF-β1, was identical with the sequence of GeneBank cDNA. A few adherent cells appeared after 24 hours culture, typical cluster formed on the forth or fifth days, and 80%-90% of the cells fused with each other on the ninth or tenth days. The morphology of the cells became similar after passaging. The immunofluorescence method showed that BMSCs were positive for CD29 and CD44, but negative for CD34 and CD45. A few cells died after 24 hoursof transfection, cell clone formed at 3 weeks after selection, and the cells could be passaged at the forth week, most cells became polygonal. The boundary of some cells was obscure. The cells were round and their nucleus were asymmetry with the particles which were around the nucleus obviously. The absorbency values of the cells tested by MTT at the wavelength of 490 nm were0.432 ± 0.038 in group A, 0.428 ± 0.041 in group B, 0.664 ± 0.086 in group C, 0.655 ± 0.045 in group D and 0.833 ± 0.103 in group E. The differences between groups A, B and groups C, D, E were significant (P lt; 0.01). The differences between groups A and B or between C, D and E were not significant (P gt; 0.05)。RT-PCR and Western blot was served to detect the expression of the target gene and protein. TGF-β1 was the highest in group C, 0.925 0 ± 0.022 0, 124.341 7 ± 2.982 0, followed by group E, 0.771 7 ± 0.012 0, 101.766 7 ± 1.241 0(P lt; 0.01); The expression of IGF-1 was the highest in group E, 1.020 0 ± 0.026 0, 128.171 7 ± 9.152 0, followed by group D, 0.465 0 ± 0.042 0, 111.045 0 ± 6.248 0 (P lt; 0.01). And the expression of collagen II was the hignest in group E, 0.980 0 ± 0.034 0, 120.355 0 ± 12.550 0, followed by group C, 0.720 0 ± 0.026 0, 72.246 7 ± 7.364 0(P lt; 0.01). Conclusion The repairment of cartilage defects by BMSCs transfected with TGF-β1 and IGF-1 gene together hasa good prospect and important significance of cl inic appl ication in cartilage tissue engineering.
Objective To evaluate sex determining region of the Y (Sry) as a engrafting track of the transplanted BMSCs survival and new bone formation in the osteonecrosis of the femoral head (ONFH) of rabbit. Methods Fortynine 4-5-month-old New Zealand White rabbits were included, weighing 2.0-2.5 kg, 48 females and 1 male. BMSCs of the rabbits were isolated by density gradient separation method, the third passage cells were marked by 1, 1’-dioctadecyl-3, 3, 3’, 3’-tetramethyl indocarbocyanine perchlorate (DiI) and the concentration of cell suspension was 2.5 × 108/ mL. The animal model of ONFH were establ ished with 48 female rabbits by injecting l iquid nitrogen, and femoral head was not dislocated.The animal model were divided into 3 groups, 16 rabbits in each group. Group A only establ ished animal model as control. Autologous BMSCs (4 μL) marked by DiI was transplanted in the ONFH models of the group B. Allogenic BMSCs (4 μL) marked by DiI was transplanted in ONFH models of the group C. The femoral head were observed by X-ray, HE staining and Masson staining, and the regenerating trabecular volume percentages was determined at 2, 4, 6 and 8 weeks after operation respectively. The examples of the heart, lung, l iver, spleen and kidney were obtained. The transplanted BMSCs were traced by fluorescence microscope, the Sry gene expression was detected by PCR for cells survival. Results All rabbits survived till the end of experiment. The X-ray showed gradual necrosis in the femoral head of group A. HE and Masson staining results indicated that compared with the group A, the recovery condition of the necrotic femoral head in the groups B and C was better. At each time of groups B and C, the regenerating trabecular volume percentages were higher than that of the group A significantly (P lt; 0.01). There was no significant difference between groups B and C (P gt; 0.05). The cells marked by DiI were not founded in the tissues of the heart, lung, l iver, spleen and kidney in groups B and C at each time. PCR showed that the expression of Sry gene were not observed at the heart, lung, l iver, spleen and kidney of three groups at each time. The expression of Sry gene was clearly identified in the femoral head of all 16 rabbits in the group C at each time point. Conclusion Allografting of BMSCs transplanted into the femoral head can survive and induce new bone formation without redistribution.
Objective To evaluate the effect of the plasma treated PLGA nerve conduits seeded BMSCs on repairing SD rat sciatic nerve defects. Methods BMSCs were acquired from 30 newborn SD rats. After ampl ified and passaged for 3 times, PLGA nerve conduits were prepared and some of them were treated with plasma. A 1-cm-length sciatic nerve defect wasmade in 30 4-week-old SD rats, then they were randomly divided into 3 groups for three different nerve defects reconstruction methods (n=10). In the experimental group, defect was repaired by plasma treatment and PGLA nerve conduits seeded with BMSCs; in the control group, by normal PLGA nerve conduits seeded with BMSCs; and in the autologous group, by autologous nerve. At 6 weeks after the surgery, the dynamic walking pattern was recorded and the sciatic function index (SFI) was calculated; the electrophysiological test was taken; the gastrocnemius wet weight recovery rate was calculated; and the image analysis of regenerated nerve was made. Results All rats survived after the surgery and l ived to the end of the experiment. At 6 weeks after the surgery, the dynamic walking pattern of the experimental group and autologous group was better than that of the control group. The SFI value of the experimental, control and autologous groups was —51.02 ± 6.54, —58.73 ± 7.87 and —48.73 ± 3.95, respectively, showing statistically significant differences among the experimental group, control group and autologous group (P lt; 0.05). The results of the motor nerve conduction velocity and wave ampl itude showed that there were statistically significant differences between the experimental group and the control group (P lt; 0.05), and between the control group and the autologous group (Plt; 0.01); but no significant difference between the experimental group and autologous group(Pgt; 0.05); The gastrocnemius wet weight recovery rate of the experimental, control and autologous groups was 56.13% ± 4.27%, 43.14% ± 6.52%, 59.47% ± 3.85%, respectively; showing statistically significant differences among experimental group, control group and autologous group (P lt; 0.05). The density, diameter of regenerated nerve fiber as well as neural sheath thickness of the experimental group were all higher than those of the control group (P lt; 0.05) and lower than those of the autologous nerve group (P lt; 0.05); there was significant difference between the control group and the autologous group (P lt; 0.01). Conclusion Plasma treated PLGA nerve conduits seeded with BMSCs can effectively repair sciatic nerve defects and provide a new strategy for the development of tissue engineered nerve to repair the peripheral nerve defects.
Objective To investigate the therapeutic effect of BMSCs- chitosan hydrogel complex transplantation on intervertebral disc degeneration and to provide experimental basis for its cl inical appl ication. Methods Two mill il iter of bone marrow from 6 healthy one-month-old New Zealand rabbits were selected to isolate and culture BMSCs. Then, BMSCs at passage 3 were labeled by 5-BrdU and mixed with chitosan hydrogel to prepare BMSCs- chitosan hydrogel complex. Six rabbitswere selected to establ ish the model of intervertebral disc degeneration and randomized into 3 groups (n=2 per group): control group in which intervertebral disc was separated and exposed but without further processing; transplantation group in which 30 μL of autogenous BMSCs- chitosan hydrogel complex was injected into the center of defected intervertebral disc; degeneration group in which only 30 μL of 0.01 mol/L PBS solution was injected. Animals were killed 4 weeks later and the repaired discs were obtained. Then cell 5-BrdU label ing detection, HE staining, aggrecan safranin O staining, Col II immunohistochemical staining and gray value detection were conducted. Results Cell label ing detection showed that autogenous BMSCs survived and prol iferated after transplantation, forming cell clone. HE staining showed that in the control and transplantation groups, the intervertebral disc had a clear structure, a distinct boundary between the central nucleus pulposus and the outer anulus fibrosus, and the obviously stained cell nuclear and cytochylema; while the intervertebral disc in the degeneration group had a deranged structure and an indistinct division between the nucleus pulposus and the outer anulus fibrosus. Aggrecan safarine O stainning notified that intervertebral disc in the control and transplantation groups were stained obviously, with a clear structure; while the intervertebral disc in the degeneration group demonstrated a deranged structure with an indistinct division between the nucleus pulposus and the anulus fibrosus. Col II immunohistochemical staining showed that the tawny-stained region in the control group was located primarily in the central nucleus pulposus with a clear structure of intervertebral disc, the central nucleus pulposus in the transplantation group was positive with obvious tawny-stained intercellular substances and a complete gross structure, while the stained color in the degeneration group was l ighter than that of other two groups, with a indistinct structure.Gray value assay of Col II immunohistochemical staining section showed that the gray value of the control, the ransplantation and the degeneration group was 223.84 ± 3.93, 221.03 ± 3.53 and 172.50 ± 3.13, respectively, indicating there was no significant difference between the control and the transplantation group (P gt; 0.05), but a significant difference between the control and transplantation groups and the degeneration group (P lt; 0.05). Conclusion The rabbit BMSCs-chitosan hydrogel complex can repair intervertebral disc degeneration, providing an experimental foundation for the cl inical appl ication of injectable tissue engineered nucleus pulposus complex to treat intervertebral disc degeneration.