Objective To investigate the change law of the intracapsular pressure in vitro without outside force and the pressure of the expander upon the skin soft tissue in vivo during clinical routine expansion so as to provide some references for the safe application of the expander. Methods The rectangle expanders of 50, 80, 100, 150, 200, 250, 300, and 400 mL were used for in vitro expansion at room temperature to 400% volume of the expander capacity. The pressures before and after saline injection were recorded. Twelve patients who needed scar plastic surgery were enrolled; 17 rectangle expanders were implanted in 5 areas (cheek, trunk, forehead and temporal, limb, and head) and expanded routinely. The pressures before and after saline injection were recorded. The pressure of the expander upon the skin soft tissue was calculated and the values of the pressure at 50%, 100%, 150%, and 200% volume of 5 areas were chosen and analyzed statistically. Results The intracapsular pressure of the expanders at different volumes in vitro without outside force during routine expansion before and after saline injection was beyond 0 mm Hg (1 mm Hg=0.133 kPa) at around 100% volume, increased rapidly from 100% to 250% volume, and kept stable from 250% to 400% volume. In vivo, 16 expanders within 200% volume had the maximum pressure before saline injection, 15 had the maximum pressure after saline injection. Before saline injection, the pressure of the expander upon the skin soft tissue was lowest in the cheek, showing significant difference when compared with those of the forehead and temporal and head (P lt; 0.05); the pressure in the trunk was significantly lower than that in the head (P lt; 0.05); and there was no significant difference between the other body sites (P gt; 0.05). After saline injection, the pressure of the expander upon the skin soft tissue was lowest in the cheek, and showed an increasing trend in the trunk, the limb, the forehead and temporal, and the head; no significant difference was found between in the cheek and in the trunk, and between in the forehead and temporal and in the limb (P gt; 0.05), and significant differences were found between the other body sites (P lt; 0.05). Conclusion The pressure of expander upon skin soft tissue at early stage or middle stage is higher than that at late stage during expansion. The pressure is high in the head, and low in the cheek comparatively, and the pressures in the trunk, the forehead and temporal, and the limb are between them.
To study the effect of autogeneic PRP on prol iferation and osteogenetic differentiation of human adipose-derived stem cells (ADSCs) in vitro. Methods ADSCs were isolated from adipose tissue obtained from donor undergoing l iposuction and were cultured, and growth condition of the cells was observed by inverted microscope. ADSCs at passage 3 were cultured in adipogenic or chondrogenic medium and underwent identification, immunofluorescence staining observations for CD29 and CD44 were performed. ADSCs at passage 3 were divided into 2 groups: PRP group cultured by osteogenic induction culture medium containing 10 mL/L PRP, and control group cultured by osteogenic induction culture medium without PRP. Then growth condition of the cells was observed by inverted microscope. MTT method was used to observe cell prol iferation activity 1, 2, 3, 4 and 5 days after culture. ALP activity detection was conducted 7, 14, 21 and 28 days after culture. ALP staining was performed on PRP group 7 and 14 days after culture. Al izarin red staining was performed on PRP group 14 days after culture to detect the formation of calcium nodule. Results Under the inverted microscope, most ADSCs at passage 3 were spindle-shaped and the doubl ing time was about 35 hours. Adipogenic and chondrogenic differentiation were confirmed, and the cells were positive for CD29 and CD44 immunofluorescence staining. MTT method revealed the absorbance value of PRP group at 1, 2, 3, 4 and 5 days was 0.137 ± 0.015, 0.219 ± 0.023, 0.367 ± 0.031, 0.586 ± 0.039 and 0.948 ± 0.046, respectively, and in the control group, it was 0.081 ± 0.009, 0.115 ± 0.012, 0.162 ± 0.017, 0.242 ± 0.025 and 0.356 ± 0.032, respectively, suggesting there were significant differences between two groups (P lt; 0.01). At 7 days after osteogenic induction, PRP group was positive for ALP staining, grey-black cell plasm and black precipitate were evident; the positive cells increased
【Abstract】 Objective To explore the optimal dosage, timing and cytotoxicity of bromodeoxyuridine (BrdU) labelling for rabbit adipose-derived stromal stem cells (ADSCs) in vitro so as to confirm its feasibil ity for stem cells labell ing and tracer means. Methods Six rabbits were used in this experiment, aged 8-12 weeks, weighing 1.5-2.0 kg and neglecting their gender. 1-2 mL fat was removed, the ADSCs were isolated and cultured using the adherence method in vitro . The 3rd passage of ADSCs was incubated with BrdU at 5, 10, 15 and 20 μg/mL (groups A, B, C and D)for 12, 24, 48 and 72 hours to identify the optimal BrdU concentration and incubating time for cell labell ing. Immunohistochemistry and trypanblau strain were performed respectively to calculate the labell ing index (positive rate) and the cells’ activity for different time after BrdU labell ing. The ADSCs without BrdU labell ing were used as control (Group E). Results The main appearance of primary ADSCs was short fusiform shape, and of the 3rd passage ADSCs long fusiform shape. The 3rd passage of ADSCs could differentiate into osteoblastsand adipocytes under corresponding inductive medium. The ADSCs’ nucleus show green fluor under fluorescence microscope after labeled by the BrdU. The labell ing ratio increased in groups A, B, C and D after incubating 12 hours, the mean labell ing ratio were 30.6% ±2.3%,32.4% ±1.9%,45.8% ±1.8%,50.8% ±3.1% , respectively, and the labell ing ratio of Group E was 0. There were significant differences between groups C, D and Group A (P lt; 0.01). The labell ing ratio of groups A, B, C and D were 45.9% ±2.0%,87.9% ±3.3%,90.6% ±2.9%,91.7% ±3.2%,respectively after 24 hours and the labell ing ratio of Group E was 0. There were significant differences between groups B, C, D and Group A (P lt; 0.01). The results of all groups after incubating48 hours and 72 h ours were similar to that after incubating 24 hours. The cell counting of groups A, B, C and D were better than that of Group E, but showing no siginificant differences(P gt; 0.05). Conclusion The most appropriate time for BrdU labell ing ADSCs is 48 hours, the most appropriate concentration is 10 μg/mL. The labell ing rate is high and cytotoxicity is l ittle.
Objective To compare two kinds of myofascial flap encapsulating adi pose-derived stromal cells (ADSCs) in adi pogenic efficacy in vivo, and to provide experimental basis for the efficient transplantation of free adi pose tissue. Methods ADSCs were isolated from the subcutaneous adipose tissue in the neck of 10 New Zealand rabbits (aged 3-4 months old, male and female, weighing 2.0-2.5 kg), and primary culture and subculture of ADSCs were conducted. When the cells at passage 3 covered 70%-80% of the bottom of the culture flask, BrdU (10 μg/mL) was appl ied to label the cells for 48 hours before performing immunofluorescence staining. Oil red O staining observation was conducted to thosecells 2 weeks after being induced towards adi pocyte, al izarin red staining observation was performed 3 weeks after being induced towards osteoblast, and alcian blue staining was conducted 2 weeks after being induced towards chondrocyte. Besides, after being induced towards adipocyte for 2 weeks, 1 × 107 ADSCs/piece at passage 3 labeled by BrdU was seeded into Col I (10 mm × 10 mm × 5 mm/piece) to prepare cell carrier complex. The experiment was divided into two groups: group A in which vascular pedicled dextral latissimus dorsi fascial flap was adopted to encapsulate the complex; group B in which dextral gluteus maximus fascial flap with no specific vessel pedicle was appl ied to encapsulate the complex. Rabbits in each group went through autogenous ADSCs transplant and self control. The implants were dislodged 8 weeks after operation, HE staining and immunohistochemistry staining were performed to testify cambium, the wet weight and micro vessel count of the cambium in each group were tested, immunofluorescence staining was performed to determine the origin of cambium and microvascular endothel ium. Results The nucleus of ADSCs positive for BrdU label ing showed green fluorescence under fluorescence microscope, with the positive label ing ratio of ADSCs above 90%. For ADSCs at passage 3, the formation of red l ipid droplets within cells was observed 2 weeks after being induced towards adipocyte, red calcium nodules were evident 3 weeks after being induced towards osteoblast, and highly congregated cell mass positive for alcian blue staining appeared 2 weeks after being induced towards chondrocyte. Eight weeks after operation, neogenetic blood vessel grew into scaffolds and no obvious fibreencapsulation was observed in group A, while few blood vessel grew into scaffolds in group B. The wet weight of cambium in group A and B was (0.149 5 ± 0.017 3) g and (0.095 3 ± 0.012 7) g, respectively, indicating there was a significant difference between two groups (P lt; 0.01). HE staining showed the formation of neogenetic adipose tissue and the growth of micrangium in the implant, and the degradation and absorption of scaffold. The micro vessel count of group A and B was 31.2 ± 4.5 and 19.3 ± 2.6, respectively, indicating there was a significant difference between two groups (P lt; 0.01). Eight weeks after operation, the immunofluorescence staining of cambium showed that the cell nucleus of regenerated adi pocytes and partial capillary endothel ium in groups A and B presented green fluorescence. Conclusion ADSCs encapsulated by vascular pedicled latissimus dorsi fascial flap and collagen protein scaffold complex has a higher adi pogenic efficacy in vivo than the gluteus maximus fascial flap with no specific vessel pedicle.
ObjectiveTo explored the effect of stromal cell-derived factor 1α (SDF-1α) on promoting the migration ability of rat adipose derived stem cells (rADSCs) by constructed the rADSCs overexpression SDF-1α via adenovirus transfection.MethodsrADSCs were isolated from adipose tissue of 6-week-old SPF Sprague Dawley rats. Morphological observation, multi-directional differentiations (osteogenic, adipogenic, and chondrogenic inductions), and flow cytometry identification were performed. Transwell cell migration experiment was used to observe and screen the optimal concentration of exogenous SDF-1α to optimize the migration ability of rADSCs; the optimal multiplicity of infection (MOI) of rADSCs was screened by observing the cell status and fluorescence expression after transfection. Then the third generation of rADSCs were divided into 4 groups: group A was pure rADSCs; group B was rADSCs co-cultured with SDF-1α at the best concentration; group C was rADSCs infected with recombinant adenovirus-mediated green fluorescent protein (Adv-GFP) with the best MOI; group D was rADSCs infected with Adv-GFP-SDF-1α overexpression adenovirus with the best MOI. Cell counting kit 8 (CCK-8) and Transwell cell migration experiment were preformed to detect and compare the effect of exogenous SDF-1α and SDF-1α overexpression on the proliferation and migration ability of rADSCs.ResultsThe cell morphology, multi-directional differentiations, and flow cytometry identification showed that the cultured cells were rADSCs. After screening, the optimal stimulating concentration of exogenous SDF-1α was 12.5 nmol/L; the optimal MOI of Adv-GFP adenovirus was 200; the optimal MOI of Adv-GFP-SDF-1α overexpression adenovirus was 400. CCK-8 method and Transwell cell migration experiment showed that compared with groups A and C, groups B and D could significantly improve the proliferation and migration of rADSCs (P<0.05); the effect of group D on enhancing the migration of rADSCs was weaker than that of group B, but the effect of promoting the proliferation of rADSCs was stronger than that of group D (P<0.05).ConclusionSDF-1α overexpression modification on rADSCs can significantly promote the proliferation and migration ability, which may be a potential method to optimize the application of ADSCs in tissue regeneration and wound repair.