Animals ; Cellular Reprogramming ; Dentate Gyrus ; cytology ; Fibroblasts ; cytology ; Mice ; Neural Stem Cells ; cytology ; transplantation ; Swine

OBJECTIVETo acquire lots of cell to culture during the primary cell culture.

METHODWe take the split-thickness skin slide technique to acquire the dissociated fibroblast cell in two big-ear rats.

RESULTSThe cell number is above 10(6) from 1 cm x 2 cm split-thickness skin slide and the technique is simple, economic, effectve.

CONCLUSIONWe think this way is better than other methods, and should be adopted in the primary cell culture, especially in fibroblast transplantation by injection.

Animals ; Cell Culture Techniques ; methods ; Fibroblasts ; cytology ; transplantation ; Rabbits

A line of fibroblast-type cells derived from embryos of a domestic rabbit has been cultivated continuously for over 3 years by serial passages up to the level of the moth passage. The cell line was tentatively named rabbit embryo fibroblast (REF). The establishment of primary culture, serial passages, growth rate and cytology are described in this communication. In addition some of the results of experiments on the detection of Mycoplasma contamination, on storage of the frozen cells and on its susceptibility to vaccinia virus infection are included.
Animal ; Cell Line ; Embryo/cytology* ; Fibroblasts* ; Rabbits ; Tissue Culture*

OBJECTIVETo explore the feasibility of constructing tissue-engineered cartilage with human dermal fibroblasts (HDFs) in vitro.

METHODSPorcine articular chondrocytes and HDFs were isolated and in vitro expanded respectively. Then they were mixed at the ratio of 1:1 (chondrocytes: fibroblasts) . The mixed cells were seeded onto polyglycolic acid (PGA) scaffold at the ultimate concentration of 5.0 x 10(7)/ml as co-culture group. Chondrocytes and HDFs at the same ultimate concentration were seeded respectively onto the scaffold as chondrocyte group ( positive control group) and fibroblast group ( negative control group). The specimens were collected after in vitro culture for 8 weeks. Gross observation, histology and immunohistochemistry were used to evaluate the results.

RESULTSIn chondrocyte group, the cell-scaffold constructs could maintain the original size and shape during in vitro culture. The new formed cartilage-like tissue had typical histological structure and extracellular matrix staining similar to normal cartilage. In co-culture group the constructs shrunk slightly at 8 weeks, cartilage-like tissue formed and GAG could be detected for strong expression by Safranin O staining. Furthermore, using the specific identification, a few HDFs derived cells were found to form lacuna structure at the peripheral area of cartilage-like tissue. In fibroblast group, the constructs deformed and shrunk gradually without mature cartilage lacuna in histology.

CONCLUSIONThe 3D-co-culture system can effectively induce the differentiation of HDFs to chondrocytes. The tissue-engineered cartilage can be constructed in vitro with the 3D-co-culture system.

Animals ; Cartilage ; cytology ; Cells, Cultured ; Chondrocytes ; cytology ; Coculture Techniques ; Dermis ; cytology ; Fibroblasts ; cytology ; Humans ; Swine ; Tissue Engineering ; methods ; Tissue Scaffolds

OBJECTIVETo investigate the methods and conditions for the isolation, purification and culture of human spermatogonial stem cells (SSCs) on the feeder layer cells of human embryonic fibroblasts (hEFs).

METHODSSSCs isolated and purified from normal human fetal testicular tissues by sequential two-step enzyme digestion and Percoll uncontinuous density gradient centrifugation were cultured on the feeder layer cells of hEFs isolated from 5-9 weeks old human embryos. The surface markers SSEA-1 and OCT4 of the SSCs were detected by immunohistochemistry; the alkaline phosphatase (AKP) activity of the SSC clones measured; and the expressions of the SSC-related genes determined by RT-PCR.

RESULTSSSCs survived, proliferated and formed colonies on the feeder layers, and the colonies were highly positive for SSEA-1 and OCT4, with strong AKP activity and high expressions of the SSC-related genes.

CONCLUSIONThe feeder layer of hEFs supports the growth of human spermatogonial stem cells.

Cell Culture Techniques ; methods ; Cell Differentiation ; Cells, Cultured ; Embryo, Mammalian ; cytology ; Fibroblasts ; cytology ; Humans ; Male ; Spermatogonia ; cytology ; Stem Cells ; cytology

OBJECTIVETo explore the way of stably inducing canine bone marrow mesenchymal stem cells (BMSCs) to differentiate into fibroblasts and myofibroblasts in vitro, and provide seed cells for fabricating tissue engineering heart valves (TEHV).

METHODSAdult canine BMSCs were separated by a gradient centrifugation on Percoll (density 1.073 g/ml), then the cells were incubated in low-glucose Dulbecco Eagle's minimum essential medium (LG-DMEM) with 10% bovine calf serum. Cell phenotype were identified by immunohistochemistry staining. The second and third generation of BMSCs were committedly induced by conditioning culture medium, which were detected by immunohistochemistry staining. The induced-BMSCs were freezed, preserved and resuscitated after 7 d to observe the cell growth, proliferation and function.

RESULTSBMSCs deriving from the bone marrow mononuclear cells separated by a Percoll gradient were positive expression of alpha-smooth muscle antibody, vimentin and negative expression of CD34, laminin. About (50 +/- 3)% induced-BMSCs were positive expression of laminin. Approximately (85 +/- 3)% freezed induced-BMSCs could be resuscitated. And the growth, proliferation and function were well.

CONCLUSIONBMSCs could be committedly induced to differentiate into fibroblasts and myofibroblasts in vitro. It is suitable to be the seed cells.

Animals ; Cell Culture Techniques ; methods ; Cell Differentiation ; Dogs ; Fibroblasts ; cytology ; Mesenchymal Stromal Cells ; cytology ; Monocytes ; cytology ; Myoblasts ; cytology

Bone Marrow Cells ; cytology ; Fibroblasts ; cytology ; metabolism ; Fibrosis ; Humans ; Myocardium ; pathology

OBJECTIVETo explore the effects of direct current electric fields on directional migration and arrangement of dermal fibroblasts in neonatal BALB/c mice and the related mechanisms.

METHODSTwelve neonatal BALB/c mice were divided into 4 batches. The skin on the back of 3 neonatal mice in each batch was obtained to culture fibroblasts. Fibroblasts of the second passage were inoculated in 27 square cover slips with the concentration of 5 × 10(4) cells per mL. (1) Experiment 1. Six square cover slips inoculated with fibroblasts of the second passage were divided into electric field group (EF) and sham electric field group (SEF), with 3 cover slips in each group. The cover slips were put in live cell imaging workstation. The cells in group EF was treated with electric power with EF intensity of 200 mV/mm, while simulating process without actual power was given to SEF group (the same below) for 6 h. Cell proliferation rate was subsequently counted. (2) Experiment 2. Six cover slips were divided and underwent the same processes as in experiment 1. Cell movement locus within EF hour (EFH) 6, direction change of cell migration at EFH 0 (immediately), 1, 2, 3, 4, 5, and 6 which was denoted as cos(α), cell migration velocity within EFH 6, direction change of long axis of cell within EFH 6, and direction change of cell arrangement at EFH 0, 1, 2, 3, 4, 5, and 6 which was denoted as polarity value cos[2(θ-90)] were observed under live cell imaging workstation. After EFH 6, the morphological changes in microtubules and microfilaments were observed with immunofluorescent staining. (3) Experiment 3. Six cover slips were divided into cytochalasin D group (treated with 1 μmol/L cytochalasin D for 10 min) and colchicine group (treated with 5 μmol/L colchicine for 10 min), with 3 cover slips in each group. The morphological changes in microfilaments and microtubules were observed with the same method as in experiment 2. (4) Experiment 4. Nine cover slips were divided into control group (no reagent was added), cytochalasin D group and colchicine group (added with the same reagents as in experiment 3), with 3 cover slips in each group. Cells in the 3 groups were exposed to an EF of 200 mV/mm for 6 h. Cell movement locus within EFH 6, cell migration velocity within EFH 6, cell polarity values at EFH 0, 3, and 6, and morphological changes of cells at EFH 0 and 6 were observed. Data were processed with independent samples t-test, one-way analysis of variance, and LSD test.

RESULTS(1) There was no statistically significant difference in cell proliferation rate in group EF and group SEF (t=-0.24, P﹥0.05). (2) Within EFH 6, cells in group EF migrated towards the anode of EF, while cells in group SEF moved randomly. At EFH 0, the values of cos(α) of cells in the 2 groups were both 0. The absolute value of cos(α) of cells in group EF (-0.57 ± 0.06) was significantly higher than that in group SEF (0.13 ± 0.09, t=6.68, P<0.01) at EFH 1, and it was still higher than that in group SEF from EFH 2 to 6 (with t values from 5.33 to 6.83, P values below 0.01). Within EFH 6, migration velocity of cells in group EF was (0.308 ± 0.019) μm/min, which was significantly higher than that in group SEF [(0.228 ± 0.021) μm/min, t=-2.76, P<0.01]. Within EFH 6, long axis of cells in group EF was perpendicular to the direction of EF, while arrangement of cells in group SEF was irregular. Cell polarity values in group EF were significantly higher than that in group SEF from EFH 2 to 6 (with t values from -7.52 to -0.90, P values below 0.01). At EFH 6, the morphology of microfilaments and microtubules of cells in EF group was similar to that in SEF group. (3) The fluorescent intensity of microfilaments of cells in cytochalasin D group became weakened, and the filamentary structure became fuzzy. The microtubules of cells in colchicine group became fuzzy with low fluorescent intensity. (4) Within EFH 6, cells in control group migrated towards the anode of EF, while cells in cytochalasin D group and colchicine group moved randomly. Within EFH 6, there was statistically significant difference in migration velocity of cells in the 3 groups (F=6.36, P<0.01). Migration velocity of cells in cytochalasin D group and colchicine group was significantly slower than that in control group (P<0.05 or P<0.01). At EFH 0, 3, and 6, cell polarity values in the 3 groups were close (with F values from 0.99 to 1.51, P values above 0.05). At EFH 0, cells in control group were spindle; cells in cytochalasin D group were polygonal or in irregular shapes; cells in colchicine group were serrated circle or oval. At EFH 6, no morphological change was observed in cells in control group; cells in cytochalasin D group were spindle with split ends on both ends; cells in colchicine group were serrated oval.

CONCLUSIONSThe physiologic strength of exogenous direct current EF can induce directional migration and alignment of dermal fibroblasts in neonatal BALB/c mice. Microfilaments and microtubules are necessary skeleton structure for cell directional migration induced by EF, while they are not necessary for cell directional arrangement induced by EF.

Animals ; Cell Movement ; Cells, Cultured ; Electricity ; Fibroblasts ; cytology ; Mice ; Mice, Inbred BALB C ; Microtubules ; Skin ; cytology

The proliferation of cardiac fibroblasts (CFs) is a key pathological process in the cardiac remodeling. To establish an objective, quantitative method for the analysis of cell proliferation and cell cycle, we applied the high-content screening (HCS) and flow cytometry (FCM) techniques. CFs, isolated by enzyme digestion from newborn C57BL/6J mice, were serum starved for 12 h and then given 10% fetal bovine serum (FBS) for 24 h. Followed by BrdU and DAPI (or 7-AAD) staining, CFs proliferation and cell cycle were analyzed by HCS and FCM, respectively. Discoidin domain receptor 2 (DDR2) staining indicated that the purity of isolated CFs was over 95%. (1) HCS analysis showed that the ratio of BrdU-positive cells was significantly increased in 10% FBS treated group compared with that in serum-free control group [(12.96 ± 0.67)% vs (2.77 ± 0.33)%; P < 0.05]. Cell cycle analysis showed that CFs in G0/G1 phase were diploid, and CFs in S phase were companied with proliferation, DNA replication and enlarged nuclei; CFs in G2 phase were tetraploid, and CFs in M phase produced two identical cells (2N). (2) FCM analysis showed that the ratio of BrdU-positive cells was increased in 10% FBS treated group compared with that in the control group [(11.10 ± 0.42)% vs (2.22 ± 0.31)%; P < 0.05]; DNA content histogram of cell cycle analysis indicated that the platform of S phase elevated in 10% FBS group compared with control group. (3) There were no differences between the two methods in the results of proliferation and cell cycle analysis. In conclusion, HCS and FCM methods are reliable, stable and consistent in assessment of the proliferation and cell cycle in CFs.
Animals ; Cell Cycle ; Cell Proliferation ; Fibroblasts ; cytology ; Flow Cytometry ; Mice ; Mice, Inbred C57BL ; Mitosis ; Myocardium ; cytology

OBJECTIVETo investigate the influence of human telomerase reverse transcriptase (hTERT) gene transfection on the proliferation of human embryonic fibroblasts (hEF).

METHODShEFs were cultured in vitro. Sense recombinant eukaryotic plasmid (pIRES2-EGFP-hTERT) and pIRES2-EGFP vacant vector were transfected into hEF respectively with Lipofectin reagent, and were named as hEF-hTERT and hEF-EGFP. The hTERT, Id1, PCNA and I, III type collagen expression in these cells were detected by Western blot. Then the cell cycle and growth curve were measured and plotted with flow cytometry and MTT method, respectively.

RESULTS1. The expression of hTERT, Id1, PCNA, type I and III collagen in hEF-hTERT were much higher than that in hEF and hEF-EGFP. 2. As shown in the growth curve, the OD value of hEF-hTERT at 4 to 6 days after culture was obviously higher than that of hEF and hEF-EGFP (P < 0.05), while no difference existed between hEF and hEF-EGFP from 1 to 6 days after culture (P > 0.05). 3. The cell number in G0/G1 phase in hEF-hTERT was less than that in hEF and hEF-EGFP. The cell number of hEF-hTERT in S and G2/M phase and its proliferation index (57.47%) increased when compared with that in hEF-EGFP (13.13%) and hEF (17.38%), but there was no difference between hEF and hEF-EGFP.

CONCLUSIONExogenous hTERT gene transfection could promote the proliferative capacity of hEF.

Cell Proliferation ; Cells, Cultured ; Embryonic Stem Cells ; cytology ; Fibroblasts ; cytology ; Humans ; Telomerase ; genetics ; Transfection