Objective To locate sinoatrial node (SAN) in suckl ing pigs, to develop a rel iable method for isolation, purification and cultivation of SAN cells and to observe the compatibil ity of SAN cells and Col I fiber scaffold. Methods Five newborn purebred ChangBaiShan suckl ing pigs (male and female), aged less than 1-day-old and weighing 0.45-0.55 kg, wereused. Multi-channels electrophysiological recorder was appl ied to detect the original site of atrial waves. Primary SAN cells harvested from that area were cultured by the conventional culture method and the purification culture method including differential velocity adherent technique and 5-BrdU treatment, respectively. Atrial myocytes isolated from the left atrium underwent purified culture. Cell morphology, time of cell attachment, time of unicellular pulsation, and pulsation frequency were observed using inverted microscope. The purified cultured SAN cells (5 × 105 cells/mL) were co-cultured with prewetted Col I fiber scaffold for 5 days, and then the cells were observed by HE staining and scanning electron microscope (SEM). Results The atrial waves occurred firstly at the area of SAN. The purified cultured SAN cells were spindle, triangular, and irregular in morphology, and the spindle cells comprised the greatest proportion. Atrial myocytes were not spindle-shaped, but primarily triangular and irregular. The proportion of spindle cells in the conventional cultured SAN cells was decreased from 73.0% ± 2.9% in the purified cultured SAN cells, to 44.7% ± 2.3% (P lt; 0.01), and the proportion of irregular cells increased from 7.0% ± 1.7% in the purified cultrued SAN cells to 36.1% ± 2.6% (P lt; 0.01) . The proportion of the triangular cells in the purified and the conventional cultured SAN cells was 20.0% ± 2.1% and 19.2% ± 2.5%, respectively (P gt; 0.05). At 5 days after co-culture, HE staining displayed lots of SAN cells in Col I fiber scaffold, and SEM demonstrated conglobate adherence of the cells to the surface and lateral pore wall of scaffold, mutual connections of the cell processes, or attachment of cells to lateral pore wall of scaffold through pseudopodia. Conclusion With accurate SAN location, the purification culture method containing differential velocity adherent technique and 5-BrdU treatment can increase the proportion of spindle cells and is a rel iable method for the purification and cultivation of SAN cells. The SAN cells and Col I fiber scaffold have a good cellular compatibil ity.
Objective To investigate the effect of myoblast transplantation on duchenne muscular dystrophy (DMD) and to explore the method and feasibil ity of applying gene therapy to DMD. Methods Myoblast of C57/BL10 mice were cultured using multiple-step enzyme digestion method and differential velocity adherent technique. The morphology of the cells was observed with inverted phase contrast microscope. The cells at passage 4 were labeled with 5-BrdU. Twenty-four DMDmodel mice (mdx mice: aged 4-6 weeks, male, 13.8-24.6 g) were randomly divided into two groups (n=12 per group): group A, 1 × 106/mL labeled myoblast were injected via ven caudal is twice at an interval of 2 weeks; group B: 1 mL DMEM/F12 was injected in the same manner serving as a control group. The mice were killed 4 weeks after operation and the motor abil ity of the mice was detected by one-time exhaustive swimming before their death. HE staining and immunohistochemistry staining observation for 5-BrdU, desmin, and dystrophin (Dys) were preformed, and the imaging analysis was conducted. Results The primary myoblast could be sub-cultured 5-7 days after culture, providing stable passage and sufficient cells. The time of onetime exhaustive swimming was (60.72 ± 5.76) minutes in group A and (47.77 ± 5.40) minutes in group B, there was significant significance between two groups (P lt; 0.01). At 4 weeks after injection, HE staining showed that in group A, there were round and transparent-stained myocytes and the percentage of centrally nucleated fibers (CNF) was 67%; while in group B, there were uneven muscle fiber with such pathological changes as hypertrophia, atrophia, degeneration, and necrosis, and the percentage of CNF was above 80%. Immunohistochemistry staining revealed that the expression of 5-BrdU, desmin, and Dys was positive in group A; while in group B, those expressions were l ittle or negative. Image analysis result displayed that integral absorbency (IA) value of desmin was 489.70 ± 451.83 in group A and 71.15 ± 61.14 in group B (P lt; 0.05) and the ratio of positive area to thetotal vision area was 0.314 3 ± 0.197 3 in group A and 0.102 8 ± 0.062 8 in group B (P lt; 0.05); the Dys IA value was 5 424.64 ± 2 658.01 in group A and 902.12 ± 593.51 in group B (P gt; 0.05) and the ratio of positive area to the total vision area was 0.323 7 ± 0.117 7 in group A and 0.035 2 ± 0.032 9 in group B (P lt; 0.05). Conclusion Myoblast transplantation has certain therapeutic effect on DMD of mice.
ObjectiveTo investigate the relationships between the expression of integrin β1 and activated cells in a partial-thickness articular cartilage injury model of adult rats. MethodForty-five male Sprague Dawley rats (aged 10 weeks and weighing 300-400 g) were randomly divided into operated group (n=15) , sham-operated group (n=15) , and control group (n=15) . Partial-thickness articular cartilage injury model was made by scarification in operated group, direct suture after opening of the knee joint was performed in sham-operated group, and no operation was done in control group. Five rats were sacrificed at 1, 7, and 14 days after operation respectively for macroscopic evaluation, HE staining, Safranin O staining, CD105, BrdU, CD105/integrin β1 immunofluorescence and double labeling staining. The histological score of HE staining, gray value of Safranin O staining and CD105-positive cells count were compared among groups at each time point. ResultsMacroscopic evaluation showed chondromalacia and cartilage fibrosis around the linear injury with aggravating tendency with time in operated group, but no chondromalacia and cartilage fibrosis in sham-operated and control groups. HE staining demonstrated a number of activated cells accumulating around the linear injury with nonuniform distribution in operated group, and uniform size and distribution in sham-operated and control groups. The histological scores at each time point in operated group were significantly higher than those in sham-operated group and control group (P<0.05) , but no significant difference was found between different time points in 3 groups (P>0.05) . Safranin O staining was nonuniform with hypochromasia around linear injury in operated group, but the staining was uniform in sham-operated group and control group. Gray value of Safranin O staining had no significant difference among groups and among different time points in the same group (P>0.05) . BrdU-positive and CD105-positive cells distributed unevenly around the linear injury in operated group, uniform distribution was observed in sham-operated group and control group. CD105-positive cells count in operated group was significantly higher than those in sham-operated group and control group at each time point (P<0.05) ; CD105-positive cells increased significantly with time in operated group (P<0.05) . CD105/integrinβ1-positive cells were observed around the linear injury in operated group, but was not observed in sham-operated group and control group. ConclusionsThe partial-thickness articular cartilage injury model is successfully established in rats, and cartilage injury could not be repaired completely in the model. The activated cells aggregation around the linear injury can be observed, but there is no obvious relationships between activated cells and cartilage matrix. These activated cells are in proliferation and could express both CD105 and integrin β1.
Objective To study the biological characteristic of rabbit bone marrow mesenchymal stem cells (BMSCs) double-labeled by PKH26 and BrdU in vitro, and to construct tissue engineered cardiac patch in vitro. Methods The BMSCs were harvested from 6-month-old New Zealand rabbits and labeled with PKH26 and BrdU. The growth and fluorescent intensitywere observed by inverted phase contrast microscope, fluorescent microscope, flow cytometry, and MTT detection. Thecharacteristics of double-labeled BMSCs differentiating into osteoblasts and adipocytes, respectively, in vitro were identified by alkal ine phosphatase (ALP) staining, Al izarin red staining, Oil red O staining, immunocytochemical technique of collagen type I, and osteocalcin expression. The labeled BMSCs were seeded on the small intestinal submucosa (SIS) and co-cultured for 5-7 days to construct tissue engineered cardiac patch. The patches were tested by inverted phase contrast microscope, fluorescent microscope, scanning electron microscope, and HE staining to observe the cell prol iferation. Results The double-labeled cells grew well and showed red fluorescence. There was no significant difference in the growth characteristic between the labeled and unlabeled cells. There was no significant difference in the expression of stem cell specific surface antigen between before lebel ing and after lebel ing. After osteogenic induction of labeled BMSCs, ALP staining and Al izarin red staining were positive, and the cells expressed collagen type I and osteocalcin. After adipocytes induction, l ipid droplets could be observed in cytoplasm by Oil red O staining. After the co-culture in vitro for 5-7 days, the double-labeled cells grew well, showing a multi-layer cellular structure on the surface of SIS. Conclusion Rabbit BMSCs can be double-labeled with PKH26 and BrdU stably. The labeled cells still have the potential of self-renewal abil ity and multipotent differentiation abil ity; tissue engineered cardiac patch can be constructed by co-culturing labeled BMSCs and SIS in vitro.