Objective To study the effect of Fe 3+ -modified carborymethyl celluiose (Fe 3+ -CMC ) on preventing postoperative adhesion and inhibiting the expressions of tumor necrosis factor-α (TNF-α) and fibroblast growth factor (FGF) in the injured parts of postoperative peritoneum. Methods Fourty Wistar mice were divided into 2 groups randomly, and abdominal adhesion models were made, then 0.9% NaCl (control group) and Fe 3+ -CMC (experimental group) were sprayed into the wound surface of abdominal cavity. All mice were killed to observe the adhesion condition on day 14 after operation. Another 120 Wistar mice were divided into 2 groups randomly, and abdominal adhesion models were made as mentioned above. Ten mice were killed which were chosen randomly from 2 groups on day 1, 3, 5, 7, 14 and 60, respectively. The expressions of TNF-α and FGF in the peritoneal injured and adhesion tissues were observed by immunohistochemistry technique. Results The adhesion grade in experimental group was much lower than that in control group ( P < 0.01). The expression of TNF-α (day 3-7 after operation) and FGF (day 5-7 after operation) in experimental group were lower than those in control group ( P < 0.05).Conclusion Fe 3+ -CMC can decrease postoperative adhesion grade and prevent the expressions of TNF-α and FGF in injured parts of postoperative peritoneum.
Objective To observe the proapoptotic effect ofthe homogenate of different parts of pig’s full thickness dermal wounds on cultured fibroblasts. Methods The tissues were dissected from the wound center and subneoepithelium separately 15 days after homogenization and sterilization, the specimens stored at -70℃. The forth passage of the fibroblasts were cultured for 16 hours in different culture solutions and were grouped into 7 groups: DMEM containing 5% fetal bovine serum as Group Ⅰ, DMEM containing 5% homogenate of tissue from wound center as GroupⅡ, DMEM containing 5% homogenate of tissue from subneoepithelium as Group Ⅲ, the culture solution of Group Ⅱmixed with 10 μg/ml GM6001 in Group Ⅳ, with the culturing medium of Group Ⅲplus 10 μg/ml GM6001 as Group Ⅴ, the culture solution of Group Ⅱ mixed with 10 ng/ml aFGF as Group Ⅵ, and the culture solution of Group Ⅲ mixed with 10 ng/ml aFGF as Group Ⅶ. In all groups except Group Ⅰ, the fibroblasts of the 6 pigs were treated with the homogenate derived from the same animal respectively. After being incubated in Annexin Ⅴ-FITC and PI, cells were analyzed by Flow Cytometry and the rate of apoptotic cells was acquired. The data were analyzed by SPSS 11.0 using Leastsignificant Difference test(LSD). Results The apoptotic rate of the 7 groups were as follows:4.39%±0.41% in Group Ⅰ,10.98%±1.42% in Group Ⅱ,13.47%±1.44% in Group Ⅲ,7.2%±0.46% in Group Ⅳ,12.1%±0.85% in Group Ⅴ,3.9%±0.63% in Group Ⅵ,9.8%±0.50% in Group Ⅶ; there were significant differences between every two groups except Group Ⅰand Group Ⅵ. Conclusion Homogenate of the tissue derived from the subneoepithelium has greater proapoptotic effect than that from the wound center; the proapoptotic effect of homogenate of the tissue both under neoepithelium and in wound center can be significantly alleviated by acid fibroblast growth factor, partly because of MMPs.
Objective To establish an effective way to cryopreserveprecartilaginous stem cells(PSCs) of neonate rat. Methods PSCs [fibroblast growth factor-3(FGFR-3) positive cells] were isolated and purified by magnetic cell sorting method. PSCs were cultured and amplified to the third generation. PSCs were preserved in liquid nitrogen. The biological properties of cryopreserved PSCs were investigated by reverse transcriptase polymerase chain reaction(RT-PCR), immunohistochemistry, and immunofluorescence. Results Immunohistochemical and immunofluorescent analysis showed widespread expression of FGFR-3 in cryopreserved PSCs. FGFR-3 could be dectected by RT-PCR in cryopreserved PSCs.Cryopreserved PSCs kept high cell viability, and phenotypic and proliferation characteristics of PSCs in vivo.Conclusion Cryopreservation of PSCs can supply adequate qualified cells for repairing the defects of epiphyseal growth plate by tissue engineering technique.
OBJECTIVE: To study the stimulating effects of basic fibroblast growth factor(bFGF) on fibroblast function and its ability to expression of c-fos gene. Furthermore, to explore the possible network action between bFGF and oncogene in modulating wound healing. METHODS: Cultured rat fibroblasts were divided into bFGF stimulating group and control group. Fibroblasts in bFGF stimulating group were treated with bFGF in a dosage of 40 ng/culture hole, while the control fibroblasts were treated with the same vehicle without bFGF. The morphology, cell vitality and their ability to express c-fos gene in the fibroblasts in both groups were studied with MTT and immunohistochemical methods. RESULTS: All fibroblasts in bFGF treated groups were enlarged and showed increased vitality with MTT method. C-fos gene expression in bFGF stimulating group was increased, especially in nucleus when compared with those in control group. CONCLUSION: The results show that the function and the ability to express c-fos gene in bFGF treated fibroblasts are enhanced. Combined with our previous studies, it may make a conclusion that there is a network regulation mechanism between growth factors and some oncogenes.
OBJECTIVE: To investigate the changes of fibroblast growth factor (FGF) in burn wounds. METHODS: The FGF expression in the center of wound granulation, the edge of wound, the healed part of wound, the normal skin of patients, and the heal course of second degree burn wounds were detected by immunohistochemical methods. RESULTS: The expression intensity of FGF was different in the different sites of third degree burn wounds. The highest contents of FGF was in the center granulation of burn wounds, the less was in the borderline of wound and healed skin, and the least was in the healed skin. FGF expression mainly concentrated in the middle layer of wound, and almost no FGF expression in normal skin. The most FGF expression was occurred at 14 days after injury in second degree of burn wound. CONCLUSION: The changes of FGF in wounds are closely related to the wound healing, and rational use of FGF can promote wound healing.
OBJECTIVE: To further explore the effects of fibroblast growth factor on soft tissue repair. METHODS: Based on the data from our experiments and clinical trial and data from other reports, a further reconsideration about fibroblast growth factor and soft tissue repair was demonstrated, including embryonic development, histology, animal experiments, clinical trial and prospect. RESULTS: Amounts of basic and clinical data showed that fibroblast growth factor was needed in embryonic development. Exogenous fibroblast growth factor could accelerate wound healing. CONCLUSION: Fibroblast growth factor is a bioactive protein which can obviously promote wound healing, it has broad prospects of clinical application.
To investigate the best way of using fibroblast growth factor (FGF) in wound healing, the following experiments were performed. Twelve Wistar rats were chosen. Four 1.5 cm x 1.5 cm middle-thick skin wounds were made in the back of each rat, 2 in each side, and labelled as number 1 to 4. Number 1 wound of each rat was used as control, only PBS was applied to the wound, 50 microliters per time, twice a day from the first day to 11th day. Number 2 wound was sustained medication group, 50 microliters 4 micrograms/ml FGF was applied twice a day from the first day to 11th day; Number 3 wound was early medication group, 50 microliters 8 micrograms/ml FGF was applied twice a day from the first day to 5th day; Number 4 wound was late medication group, 50 microliters 8 micrograms/ml FGF was added twice a day from the 5th day to 11th day. By day 4, 8, 12 and 16, the area of wounds were measured, and the healing time of each wound was recorded. The elastic fiber, collagen fiber and DNA content were measured by immunohistological method. The result showed that the elastic fiber, collagen fiber and DNA content in the groups of FGF used were more than those in the control group. The healing time of the control group was 14.4 days while that of the early meduation group was 13.4 days, late medation group was 13.5 days and sustained medication group was 12.2 days. It was suggested that FGF could accelerate the wound healing, and sustained use of FGF was the best way of giving the drug.
Taking Wistar rats and pigs as models, the basic fibroblast growth factor (bFGF) was studied on wound healing. Five rats and five pigs were used in the experiment. Each rat had 2 roundshapedwound (1.8cm in diameter) and each pig had 4 wounds of the same size as that ofthe rat. One wound of each rat and 2 wound of each pig were dressed with bFGF saline (60U/cm2). While the other wounds of the rats and pigs were dressed with normal saline as control. The wounds treated with bFGF were completely covered with granulation tissue on the 7th day after injury, and in 14 days the wounds were almost completely covered by epithelium. The bFGF would enhance the growth of theepithelial cells, reepithelization of the wound and the tensile strength of thetissue. It was concluded that the bFGF could promote skin regeneration, whichmight be the direct action of bFGF on the bFGF receptors in the basic cells of skin.
Abstract To observe the effect of fibroblast growth factor (FGF) on wound healing, 50 mice were divided into 5 groups. On the back of every mouse, 2 wounds were made by operative cuts, one for experiment and the other for control. The wounds of the experimental group were covered with 0.5ml FGF solution (contented FGF 300 μg/ml, heparin 100 μg/ml), whereas the wounds of the control group were covered with 0.5ml 0.9% NaCl solution. All of the wounds were dressed by sterilized gauze, and received the same treatment once a day. After 1,3,5,7,10 days, the mice in every group were sacrificed and the tissues of the wounds were collected and prepared for microscopic examination. The results showed that the capillaries and fibroblasts in the experimental group were markedly increased and reached the peak 2~3 days earlier than those in the control group. It was suggested that FGF promoted the formation of granulation tissue and the wound healing.
ObjectiveTo investigate the expression and relation of vascular endothelial growth factor (VEGF) and basic fibroblast growth factor (bFGF) in rats with diabetic retinopathy.MethodFifty-five Wistar rats were randomly divided into the control group (10 rats), and 1, 3, and 5-month-diabetes group (15 rats in each diabetes group), and the diabetic models were set up. The expressions of VEGF and bFGF were detected by situ hybridation and immunohistochemistry on retinal paraffin sections.ResultsThe results of situ hybridation showed that expression of bFGF was found in 3-month-deatbtes group with the percentage of 77.8%, and 88.9% in 5-month-deatbtes group; the positive expression of VEGF was not found in 3-month-deatbtes group but in 5-month-deatbtes group with the percentage of 66.7%. Immunohistochemistry indicated that the positive expression of bFGF started in 3-month-deatbtes group with the percentage of 55.6%, and 88.9% in 5-month-deatbtes group; the percentage of the expression of VEGF was 33.3% in 3-month-deatbtes group and 88.9% in 5-month-deatbtes group.ConclusionThe expression of VEGF occurs after the expression of bFGF in rats with DR.(Chin J Ocul Fundus Dis, 2005,21:37-40)