Abstract In order to study the possibility of repairing bone defect by cryopreserved vascularized bone allograft, 8 dogs were divided into 2 groups. In the experimental group, 15% dimethylsulfoxide (DMSO) was used as a cryoprotective agent, the posterior segments of dog s rib, pedicled with intercostal vesseles, were cryopreserved by a two-step freezing procedure,stored in liquid nitrogen for 96 hours, and then transplanted as allografts to theiliac bone defects of recipients by vascular anastomosis. In the control group, the autografts were transplanted in the same procedure. Immunosuppersive agents were administrated postoperatively for 3 weeks. The specimens were analyzed by immune response monitoring (IL-2, T cell subsets), SPECT scanning, angiography and pathologic examination. The results showed that the allografts had good blood supply and active osteocyte metabolism, bone healing of the allografts was perfect at 3 months and no evidence of immunologic rejection. The process of bone healing of allografts should be further investigated.
Objective To investigate the effects of different temperatures on the system of in vitro physiological environment fostering limbs. Methods Twenty-four limbs were harvested from 6 adult Bama mini pigs and were randomly divided into 4 groups (n=6) according to different temperatures: limbs were placed in in vitro physiological environment foster-ing limbs at 26℃ (group A), 4℃ (group B), 10℃ (group C), and 18℃(group D). After 12 hours of perfusion, the morphology observation was done for the structure and ultrastructure changes of the skeletal muscle by light microscope and transmission electron microscope. The mRNA levels of tumor necrosis factor α (TNF-α) and interleukin 1β (IL-1β) were detected by real-time fluorescent quantitative PCR (RT-qPCR). Results Histological results showed that the skeletal muscle exhibited mild edema, integrity of the sarcolemma, and occasional perivascular inflammatory cell infiltration in groups B, C, and D, meanwhile, the cells of group C had normal morphology; however, muscle fibers degenerated, muscle cells were seriously damaged, a great number of inflammatory cells infiltrated in the fractured muscle fibers in group A. Transmission electron microscope results showed as follows: the muscle fibers arranged in disorder, and many focal solubility necrosis occurred in group A; the muscle fibers arranged in order relatively and sarcolemma was still intact, with mild swelling and flocculent degenerative mitochondria in group B; a large number of muscle fibers arranged in order and regularity with clear sarcomere in group C; and the muscle fibers arranged in disorder and irregularity and partly dissolved in group D. RT-qPCR results showed that the expressions of inflammatory factor TNF-α and IL-1β mRNA in group A were significantly higher than those in groups B, C, and D (P lt; 0.05); the expressions were significantly lower in groups B and C than in group D, and in group C than in group B (P lt; 0.05). Conclusion In the system of in vitro physiological environment fostering limbs, temperature plays an important role in the preservation of amputated limbs. It is suggested that 10℃ can significantly attenuate the reperfusion-induced skeletal muscle cell injuries in this system.
Objective To investigate an effect of differenttemperature cryopreservation of the two-step freezing method on the Schwann cell biological activity in the peripheral nerve of the rat. Methods Eighty femaleSD rats were randomly divided into 8 groups of 10 rats each. One was the control group and 7 were the experimental groups. Two 2-cm-long sciatic nerve segments were respectively taken from both legs of each rat. In the control group, the sciatic nerve segments did not undergo the treatment of cryopreservation; however, in the 7 experimental groups, the sciatic nerve segments respectively underwent the different temperature cryopreservation of the twostep freezing method at -20℃, -30℃, -40℃, -50℃, -60℃, -70℃ and -80℃. The sciatic nerve segments were cryopreserved for 2 hours,and then placed into the liquid nigrtrogen at -196℃. After 48 hours of storage,the nerve segments werethawed quickly in the 37℃ water bath box for 1 minute. Then, the sciatic nerve segments each group were harvested. The cells of the sciatic nerve were incubated with Calcein-AM for 15 minutes. The average fluorescence intensity of the cells was measured by the flow cytometry. The nerve fibers were also incubated with Calcein-AM for 15 minutes. The fluorescence intensity of the cells was analyzed by the confocal fluorescence microscope. The Schwann cell biological activity intensity was measured. Results The fluorescence intensity in the -40℃ group was the best and the Schwann cell biological activity in this group was thebest among all the groups(P<0.01). The fluorescence intensity in the 8 groups measured by the flow cytometry was as follows:242.522 0±9.568 4 in the control group,168.677 0±10.207 0 in the -20 ℃ group,214.992 0±8.329 1 in the -30 ℃ group,235.526 0±9.280 5 in the -40 ℃ group,222.434 0±8.515 5 in the -50 ℃ group,217.409 0±9.515 7 inthe -60 ℃ group,132.376 0±13.459 7 in the -70 ℃ group, and 108.132 0±16.033 1 in the -80 ℃ group. The fluorescence intensity detected by the confocal fluorescence microscope was as follows:143.700 0±5.567 8 in the control group,119.700 0±5.161 5 in the -20 ℃ group,121.300 0±4.347 4 in the -30 ℃ group,700 0±5.012 2 in the -40 ℃ group,121.000 0±4.546 1 in the -50 ℃ group,118.400 0±4.9261 in the -60 ℃ group,81.200 0±5.116 4in the -70 ℃ group,and 79. 000 0±5.716 4 in the -80 ℃ group. Conclusion The Schwann cell biological activity treated by the two-step freezing methodcan be preserved and the activity is cryopreserved best at -40 ℃.
PURPOSE:To establish methods for cryopreservation of human retinal pigment epithelial cells (RPEs)and cell culture from thawing of frozen cells. METHODS:Primary cultured RPEs or its first or second passages,added with 10 dimetbylsulfoxide,were kept in --20℃ for 1 to 2 hours,and then further froze to -40~C over night before being placed in liquid nitrogen. The frozen cells were thawed in 60℃ within 2 minutes. Trypan blue staining and immunocytochemical staining with anti-human keratin were performed for cell viability and differentiation. The growth curve was also determined by calculating the total number of cells/well/day. RESULTS:The viable rate from frozen RPEs was 90%. No differences were observed for growth activity between cultures from frozen cells and controls. The cells were positive with anti-human keratin staining. The logarithmic growth phase was during I to 4 days and the doubling time yeas 1.55 days. CONCLUSION: Cryopreservation of RPEs in liquid nitrogen can maintain biological activities of cells with normal growth and features after thaw- ing. This will provide cell lines for in vitro experiments and possibly for cell banks for RPE transplantation for some fundus diseases. (Chin J Ocul Fundus Dis,1997,13:157-159)
Objective As one of the adult stem cells, adi pose-derived stem cells (ADSCs) have become an important seed cell source for tissue engineering recently. But whether the thawed cryopreserved ADSCs could be used to tissue engineered bone remains unknown. To investigate the effect of cryopreservation on the growth and osteogenesis of ADSCs invitro. Methods The ADSCs were isolated from the adipose aspirates by collagenase digestion method. For the experimental group, the 2nd generation cells were stored with a simple method of cryopreservation by slow cool ing with dimethyl sulphoxide as a cryoprotectant and rapid thawing. After cryopreserved in l iquid nitrogen for 4 weeks, ADSCs were recovered and cultured in osteogenic media, with non-cryopreserved ADSCs as the control group. The osteogenic differentiation was evaluated by alkal ine phosphatase (ALP) staining and Al izarin red O staining at 2 and 3 weeks respectively. The cell growth and osteogenesis of ADSCs were further determined using DNA assay and the ALP activity and calcium content were measured. Results The survival percentage of the cryopreserved cells was 90.44% ± 2.62%. The cell numbers and ALP activity increased with osteogenic induction time, and reach plateaus at 7 days and 11 days, respectively. The ALP staining and Al izarin red O staining results were both positive at 2 weeks and 3 weeks after osteogenic induction, respectively. And no significant difference in the cells number, ALP activity, and calcium content were found between experimental group and control group (P gt; 0.05). Conclusion Cryopreservation does not affect the growth and osteogenesis of ADSCs, and the cryopreserved ADSCs can be used as cell source for tissue engineered bone.
Objective o study the feasibility of homologous vascularized nerve transplantation after ultra deep cryopreservation. Methods Vascularized sciatic nerve from 12 female dogs was transplanted after ultra deep cryopreservation. Fortyeight male dogs were divided into 4 groups: ultra deep cryopreservation homologous vascularized nerve (group A), ultra deep cryopreservation homologous nerve (group B), fresh homologous vascularized nerve (group C), and fresh autologous vascularized nerve (group D). The gross appearance, patency rate of arteryand morphological transplanted nerve were observed 1, 4 and 12 weeks after transplantation respectively. Immunological analysis was performed using IL 2 assay and T lymphocyte subpopulations assay after 4 weeks. Image pattern analysis andelectromyogram were observed after 12 weeks. Results In groups A and D, no toe ulcer occurred, the atrophy of later limb and the sense of pain from skin of calf were restore significantly in the postoperative 12th week. In groups B and C, toe ulcer occurred, the atrophy of later limb and the sense of pain from skin of calf were not restored significantly in the postoperative 12thweek. The vessel patency rate of groups A and D was 83.3%, which was significantly higher than that of group C (50%,Plt;0.05). The changes of IL2 and Th, Ts in group C were significantly higher than that in groups A,B,D(Plt;0.01). There were increased vessel and regenerated nerve in transplanted nerve under optical microscope and image pattern analysis in groups A and D. There were shorter latent period of motor evoked potential, greater amplitude of action potenlial and faster motor nerve conducting velocity in groups A and D after 12 weeks. Conclusion The antigenicity of the homologous never and vessel may be reduced significantly by being frozen, and cryopreserved vascularized nerve can transferred successfully without the use of immunosuppressive agents. Vascularized nerve may restore good significantly for the thick nerve.
OBJECTIVE: To investigate the repairing effect of transplantation of allogeneic fetal bone in combination with a covering cryopreserved periosteal allograft to bone defect. METHODS: Twenty Long-eared white male rabbits were chosen as experimental model of bilateral 12 mm combined bony and periosteal radial defect. Cryopreserved allograft periosteum with allogeneic fetal bone were implanted in the left defect as experimental side and fetal bone was simply transplanted in the right defect as control side. Bone repair process in the two groups were compared by macroscopy, microscopy, roentgenograms and the contents of calcium and phosphate in the defect area at 2, 4, 8 and 12 weeks after transplantation. RESULTS: There was significant statistic difference in the contents of calcium and phosphate between the experimental and control sides at 4, 8 and 12 weeks after transplantation (P lt; 0.05). With time passing by, the contents of calcium and phosphate have the increasing trends. In the experimental group, lamella bone was seen and medullary canal recanalized at 8 weeks postoperatively. The histological section showed the bone lacuna and lamella bone were formed. CONCLUSION: It suggests that allogeneic fetal bone in combination with a covering cryopreserved periosteal allograft can promote bone repair, and allogeneic fetal bone is excellent bone substitute.
In order to repair cartilage defect in joint with transplantation of cryopreserved homologous embryonic periosteum, 30 rabbits were used and divided into two groups. A 4 mm x 7 mm whole thickness cartilage defect was made in the patellar groove of femur of each rabbit. The homologous embryonic rabbit skull periosteum (ERSP), preserved in two-step freezing schedule, was transplanted onto the cartilage defect of joints of one group and autogenous periosteal graft was done in the joint defect of the other group. The knees were not immobilized, following operation and 16 weeks later, the newly formed tissue in the defects were assessed by gross observation, histochemical examination and biochemical analysis. The results showed that new hyaline-like cartilage was formed in the cryopreserved ERSP grafted knee, and had no significant difference from that of the knee receiving autogenous periosteal graft, but had significant difference from that of the fresh ERSP grafted knee and the non-grafted knee. Furthermore, the new hyaline-like cartilage had the biochemical characteristics of a fibrous cartilage. The conclusion was that this method might be feasible to repair articular cartilage defects.
Objective To investigate the possibility of establishing the human bone marrow mesenchymal stem cells (hMSCs) bank as to provide an alternative source for the seed cells of tissue engineering. Methods The cell surface antigensof the purified, expanded hMSCs and the ones following cryopreservation were detected by flow cytometry, cultured in a special medium to induce the ostoegenic and chondrocytic- differentiation. Morphology was studied by light and electronic microscopes. The detection of alkaline phosphatase, collagen type Ⅰ, osteocalcin, and collagen type Ⅱ were also performed by immunochemistry and molecular biology.Results The phenotype and expansion possibility of hMSCs after cryopreservation were remained. It could expand for 10 generations. The doubling time was 40 h.Conclusion The bank of hMSCs is inipiently established and can provide eligible seed cells for tissue engineering.
【Abstract】 Objective To isolate and culture human amniotic fluid-derived mesenchymal stem cells (HAFMSCs),to investigate a better cryopreservation protocol of HAFMSCs and to observe the biocharacteristics and the multi-potential of HAFMSCs after cryopreservation for the further fundamental researches and cl inical appl ications. Methods HAFMSCswere isolated from the amniotic fluid of pregnant women during the second trimester by the improved two-step method.HAFMSCs were cryopreserved with different cryopreservation protocols (containing different contents of FBS and DMSO atcryoprotectant) in l iquid nitrogen for 12 weeks. The biocharacteristics of the HAFMSCs after cryopreservation were analyzed. The growth characteristics were observed by MTT method and the growth curves were drawn. The surface antigens of HAFMSCs were detected using flow cytometry, including CD29, CD34, CD44, CD45, CD73, and CD90. The adi pogenic and osteogenic differentiation abil ities of HAFMSCs were observed. The mRNA levels of Oct-4 and Nanog of the HAFMSCs were compared between before and after cryopreservations. Results At 12 weeks after cryopreservation, different protocols had different effects on the cell viabil ity; the better formula of cryoprotectant was 50% DMEM, 40% FBS, and 10% DMSO. After cryopreservation, the cells proliferated rapidly and the growth curves showed “S” shape, which was the same as the cells before cryopreservation. Phenotype showed that HAFMSCs were positive for the surface markers CD29, CD44, CD73, and CD90, and negative for CD34 and CD45. After 21 days of adi pogenic differentiation, the l ipid droplets were observed by oil red O staining. After 21 days of osteogenic differentiation, the calcium mineralizations were verified by von Kossa staining. There was no significant difference (P gt; 0.05) in the mRNA levels of Oct-4 and Nanog between before and after cryopreservations. Conclusion HAFMSCs have rapid proliferation and multi-potential in vitro. The cells have high viabil ities and no changes of the biocharacteristics and differentiation potential ities after cryopreservation for 12 weeks. Cryoprotectant containing 50% DMEM, 40% FBS, and 10% DMSO is a better cryopreservation protocol.