Abstract: Objective To investigate the influence of cryopreservation on cellular viability of latepregnancy fetal valved allografts in human. Methods The fetal valved allografts with gestational ages ranged from 24 to 40 weeks were sterilely procured within 6 hours after brain death. Each sample was bisected into control group and experiment group. The cellular viability of control group was directly tested and that of experiment group was examined after being storaged in liquid nitrogen for a week through a programmed frozen procedure. The light microscopy, tissue culture and Methylthiazol tetrazolium assay (MTT assay) were used to determine the cellular viability. Results Twelve latepregnancy fetal valved aortic allografts were procured. Light microscopy showed the integrity of the basic structure of the thawed aorta, the normal structure of the collagen and elastic fibers, with part of vascular endothelium lost. There were lots of cells deriving from both groups,but the cellular growing rate of the experiment group was relatively slower. At 490 nm, MTT assay valve of control group was 0.442±0.046, and that of experiment group was 0.424±0.041. The difference between two groups failed to statistically significance(t=1.617, P=0.328). Conclusion There were viable cells in latepregnancy fetal valved allografts after cryopreservation.
Objective To observe the configuration and viability of full thickness human fetal retina after short-, mid- and long-term preservation. Methods Twenty-two full thickness human fetal retinae of gestational age of 12-24 weeks were coated by glutin and cut into 88 pieces, and then preserved in Ames' solution, DX solution, -80℃ refrigerator or under cryopreservation condition. The cell viability of retinal neuroepithelial layer was determined by trypan blue staining, retinal configuration was determined by light microscope and electromicroscope. Results The viability of neuroepithelial layer was (94.79plusmn;2.85) % in fresh fetal retina, gt;80% in Ames' solution within 4 hours, and gt;77% in DX solution within 2 days. There was no significant difference between those solution-preservations and the fresh fetal. In -80℃ refrigerator, the viability was (65.83plusmn;5.06)% after 7 days, and then dropped to (57.54plusmn;16.18)% at the end of the first month. Under the cryopreservation condition, the viability was (69.46plusmn;9.31)% at the end of first month. Light and transmission electron microscopy had not deteced any abnormals in the full thickness human fetal retina preserved in Ames' solution within 2 hours, but showed clear retinal layers with bigger intercellular space after preserved in DX solution for 2 days, in -80℃ refrigerator for 7 days and under cryopreservation condition for 1 month. Conclusion Ames' solution and DX solution can preserve good viability and configuration of full thickness human fetal retina in a certain time period.
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: To investigate a cryophylactic agent (CPA) to protect tissue engineered tendon (TET) in deep low temperature. METHODS: Sixty-four BALB/C inbred nude mice were chosen, which included 4 as blank control group, left sides of 60 as experimental group and their right sides as control group. Transformed human embryonic tendon cells of the 54th passage and artificial materials of carbon fiber (CF) and polyglycolic acid (PGA) were co-cultured in vitro to construct TET. TET was frozen in liquid nitrogen with four kinds of CPA (groups A, B, C, and D) for 2 months. They were thawed quickly and transplanted into hind limbs of nude mice to repair the defects of Achilles tendon, which was 5 mm in length and 65.7% of total Achilles tendon. In control group, no cryopreservation treatment was taken. The morphological, histological, ultrastructure, and immunohistochemistry examinations were made and short tandem repeat loci were detected 2, 4, 6, 8, and 12 weeks later. RESULTS: In the experimental group, the morphological properties of tendon cells resumed gradually and the capability of synthesizing collagen enhanced by degrees. Tendon cells survived and could secret type I collagen and there was less difference between experimental and control groups 12 weeks after transplantation. In group A, vacuole in mitochondrion of tendon cell decreased, tendon cell arranged in order and abundant collagen fibers were found and linked. CONCLUSION: The cryopreservation agent in group A can protect TET in deep low temperature.
Objective To observe the effects of cryopreservation and resuscitation on the biological characteristics of mesenchymal stem cells (MSCs) derived f rom human umbilical cord blood. Methods MSCs were isolated and cultured f rom human umbilical cord blood in vitro. The cells were passaged , and the third generation of MSCs were cryopreserved in-196 ℃ liquid nitrogen for 4 weeks with cryopreservation medium , which contained 10 % dimethyl sulfoxide (DMSO) and 90 % fetal calf serum ( FCS) . The morphology , proliferation and differentiation of MSCs were investigated and compared with those of MSCs before cryopreservation. Results There was no significant difference of morphology between pre-cryopreserved MSCs and the ones af ter resuscitation. It was observed that all MSCs were spindle-shaped and showed adherence growth characteristic before and af ter cryopreservation. The cell growth curves of MSCs were also similar before and af ter cryopreservation. Even though the curve of resuscitated MSCs descended a little as compared with that of pre-cryopreserved MSCs , there was no significant difference ( Pgt; 0. 05) . After 2-week adipocytic differentiation induction , fat drops could be found in the kytoplasm of MSCs and they were red when stained with oil-red O staining , which suggested that MSCs could be induced and differentiated into adipocytes. Af ter 4-week osteoblastic differentiation induction , MSCs could be induced and differentiated into osteoblasts , and calcium node showed black when stained with Von Kossa staining. There were no significant changes of the differentiating ability of MSCs into adipocyte and osteoblast before and after cryopreservation. Conclusion MSCs derived from human umbilical cord blood maintains their biological characteristics af ter cryopreservation and resuscitation.
Objective To investigate the effect of tissue engineered bone with cryopreservation on healing of bone defects and to explore feasibility of cryopreservation for tissue engineered bone. Methods Tissue engineeredbones were constructed with osteoblasts being seeded onto bio-derived materials made from freshhuman bones,and they were preserved at 4℃ and -196℃ for 3 months and 6 monthsrespectively.They were applied to repair segmental bone defects of rabbit’s radius while the tissue engineered bone without cryopreservation and bio-derived materials were brought into control groups.The experiment was divided into groups A3,A6,B3,B6,C and D(group A3:tissue engineered bones were preserved at 4℃ for 3 months; group A6:tissue engineered bones were preserved at 4℃ for 6 months;group B3:tissue engineered bones were preserved at -196℃ for 3 months; group B6:tissue engineered bones were preserved at -196℃ for 6 months; group C: tissueengineered bones without cryopreservation; group D: bio-derived materials). Macroscopical and histologial examination were done at the 2nd,4th,6th,12th weeks, X-ray examination was done at the 6th,12th weeks and biomechanics were determined at 12th weeks after operation respectively. Results Macroscopical observation showed no significant differences among group A3, A6, B3, B6 and C, but less new bone formation and more obvious boundary in group D were observed. Histological observation showed more collagen and new bone around the edge of implant of group A3, A6, B3, B6 and C than group D, and histological evaluation showed significant differences between group D and other groups(P<0.05). Radiographic observation showed no absorbability of the implant cortex and less new bone formation in group D, but the unity between implant and host bone, medullary cavity reopened, disappearance of fracture line and fine bone modelling were observed in other groups at 12 weeks after operation. Biomechanics between group D and other groups showed significant differences(P<0.05). Conclusion Cryopreservation (4℃ and -196℃) were capable of preserving tissue engineered bone for long time, and tissue engineered bone withcryopreservation has significant effect on healing of bone defects. The methods f it clinical application.
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.
【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.
ObjectiveTo explore the effects of cryopreservation on the cell survival rate, cell viability, early apoptosis, migration ability, and tendon-related marker expression of tendon-derived stem cells (TDSCs) in rat patellar tendons.MethodsThe patellar tendon tissues were harvested from 12 4-month-old male Sprague Dawley rats; 12 patellar tendon tissues from 6 rats were cryopreserved (the experimental group), and the other 12 patellar tendon tissues were not treated (the control group). The patellar tendons were digested with 0.3% type I collagenase to obtain nucleated cells. The survival rate of nucleated cells was detected by trypan blue exclusion assay, and colony-forming ability by crystal violet staining. TDSCs were isolated and cultured to passage 3 (P3). The cell viability of TDSCs was detected by Alamar Blue method, the early apoptosis by Annexin V-FITC/PI assay, the cell migration ability by Transwell method, and the mRNA expressions of tendon-related markers [collagen type I (Col1α1), scleraxis (Scx), and tenomodulin (Tnmd)] by real-time quantitative PCR.ResultsThe survival rate of nucleated cells was 91.00%±3.63% in the control group, and was 61.65%±4.76% in the experimental group, showing significant difference (t=12.010, P=0.000). The formation of the primary nucleated cell clones was observed in 2 groups. At 12 days, the number of colonies forming of the experimental group [(8.41±0.33)/1 000 nucleated cells] was significantly lower than that of the control group [(15.19±0.47)/1 000 nucleated cells] (t=28.910, P=0.000). The percentage of TDSCs in the active nucleated cells in the experimental group (1.37%±0.09%) was significantly lower than that in the control group (1.67%±0.10%) (t=5.508, P=0.003). The growth trend of TDSCs (P3) in the 2 groups was consistent within 14 days. There was no significant difference in absorbance (A) value between 2 groups at each time point (P>0.05). The early apoptotic rate of TDSCs was 1.67%±0.06% in the experimental group and was 1.63%±0.06% in the control group, showing no significant difference (t=0.707, P=0.519). Under microscope, TDSCs adhered to the lower chamber of the Transwell chamber; the number of cells was 445.00±9.70 in the experimental group and was 451.50±12.66 in the control group, showing no significant difference (t=0.998, P=0.342). The relative mRNA expressions of Col1α1, Scx, and Tnmd were 3.498±0.065, 0.062±0.002, and (4.211±0.211)×10–5 in the experimental group and were 3.499±0.113, 0.062±0.001, and (4.341±0.274)×10–5 in the con-trol group, showing no significant difference (t=0.013, P=0.991; t=0.042, P=0.969; t=0.653, P=0.549).ConclusionThe survival rate of nucleated cells in cryopreserved rat tendon tissues is lower, but a large number of active TDSCs, and its cell viability, early apoptosis rate, migration ability in vitro, and cell tenogenic differentiation ability are remained.
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 ℃.