Objective To study the effect of platelet-rich plasma (PRP) on the survival and quality of fat grafts in the nude mice so as to provide a method and the experimental basis for clinical practice. Methods Fat tissue was harvested from the lateral thigh of a 25-year-old healthy woman and the fat was purified by using saline. The venous blood was taken from the same donor. PRP was prepared by centrifugation (200 × g for 10 minutes twice) and activated by 10% calcium chloride (10 : 1). Then 24 female nude mice [weighing (20 ± 3) g, 5-week-old] were allocated randomly to the experimental group and the control group (12 mice per group). Each subcutaneous layer of two sides of the back (experimental group) was infiltrated with 0.8 mL fat tissue-activated PRP mixtures (10 : 2); the control group was infiltrated with 0.8 mL fat tissue-saline mixtures (10 : 2); 0.14 mL activated PRP and 0.14 mL saline were injected into the experimental group and the control group respectively at 5 and 10 days after the first operation. At 15, 30, 90, and 180 days after the first operation, the samples were harvested for gross and histological observations. Results All nude mice survived to the end of the experiment. No inflammation and abscess formation of the graft were observed. Experimental group was better than control group in angiogenesis, liquefaction, and necrosis. The grafted fat weight and volume in the experimental group were significantly larger than those in the control group at 15, 30, and 90 days (P lt; 0.05); but there was no significant difference between the 2 groups at 180 days (P gt; 0.05). Histological observation showed good morphological and well-distributed adipocytes, increasing vacuoles, few necrosis and calcification in the experimental group; but disordered distribution, obvious necrosis, and calcification in the control group. The necrosis area ratio of the experimental group was significantly lower than that of the control group (P lt; 0.05), and the number of micro-vessels was significantly higher in the experimental group than in the control group at 15 and 180 days (P lt; 0.05). Conclusion The method of repeatedly using the PRP within 180 days in assisting fat grafts can obviously improve the survival and quality.
Objective To investigate the mechanism of vascular stromal fraction (SVF) at the early stage after aspirated fat transplantation. Methods Fat was harvested from 5 cases of women undergoing abdominal liposuction operation, and SVF was isolated. Aspirated fat with (group B) or without (group A) SVF was injected subcutaneously into the back of nude mice, and the grafts were harvested at 1, 3, 5, and 7 days. Graft wet weight was measured; and immunohistochemical method (CD31) was performed and the secretion of vascular endothelial growth factor (VEGF) and hepatocyte growth factor (HGF) were qnantified by Western blot assay. Results The wet weight of transplanted adipose tissue showed an increasing tendency in groups A and B with time, and no significant difference was found between groups A and B (P gt; 0.05). At 1 and 3 days after transplantation, no CD31 positive cells was seen in 2 groups; the CD31 positive cells of group B were significantly more than those of group A at 5 and 7 days (P lt; 0.05), and the CD31 positive cells at 7 days were significantly more than those at 5 days in 2 groups (P lt; 0.05). Western blot test showed that VEGF expression reached peak at 3 days , then decreased gradually; the expression of VEGF protein in group B was significantly higher than that in group A at 1, 3, and 5 days (P lt; 0.05). The expression of HGF protein in groups A and B remained at a high level within 5 days, but it tended to decrease at 7 days, which was significantly higher in group B than that in group A (P lt; 0.05). Conclusion SVF can enhance angiogenesis by secretion of growth factors at the early stage after aspirated fat transplantation.
Objective To explore heterotopic chondrogenesis of canine myoblasts induced by cartilage-derived morphogenetic protein 2 (CDMP-2) and transforming growth factor β1 (TGF-β1) which were seeded on poly (lactide-co-glycolide) (PLGA) scaffolds after implantation in a subcutaneous pocket of nude mice. Methods Myoblasts from rectus femoris of 1-year-old Beagle were seeded on PLGA scaffolds and cultured in medium containing CDMP-2 and TGF-β1 for 2 weeks in vitro. Then induced myoblasts-PLGA scaffold, uninduced myoblasts-PLGA scaffold, CDMP-2 and TGF-β1-PLGA scaffold, and simple PLGA scaffold were implanted into 4 zygomorphic back subcutaneous pockets of 24 nude mice in groups A, B, C, and D, respectively. At 8 and 12 weeks, the samples were harvested for general observation, HE staining and toluidine blue staining, immunohistochemical staining for collagen type I and collagen type II; the mRNA expressions of collagen type I, collagen type II, Aggrecan, and Sox9 were determined by RT-PCR, the glycosaminoglycans (GAG) content by Alician blue staining, and the compressive elastic modulus by biomechanics. Results In group A, cartilaginoid tissue was milky white with smooth surface and slight elasticity at 8 weeks, and had similar appearance and elasticity to normal cartilage tissue at 12 weeks. In group B, few residual tissue remained at 8 weeks, and was completely degraded at 12 weeks. In groups C and D, the implants disappeared at 8 weeks. HE staining showed that mature cartilage lacuna formed of group A at 8 and 12 weeks; no cartilage lacuna formed in group B at 8 weeks. Toluidine blue staining confirmed that new cartilage cells were oval and arranged in line, with lacuna and blue-staining positive cytoplasm and extracellular matrix in group A at 8 and 12 weeks; no blue metachromatic extracellular matrix was seen in group B at 8 weeks. Collagen type I and collagen type II expressed positively in group A, did not expressed in group B by immunohistochemical staining. At 8 weeks, the mRNA expressions of collagen type I, collagen type II, Aggrecan, and Sox9 were detected by RT-PCR in group A at 8 and 12 weeks, but negative results were shown in group B. The compressive elastic modulus and GAG content of group A were (90.79 ± 1.78) MPa and (10.20 ± 1.07) μg/mL respectively at 12 weeks, showing significant differences when compared with normal meniscus (P lt; 0.05). Conclusion Induced myoblasts-PLGA scaffolds can stably express chondrogenic phenotype in a heterotopic model of cartilage transplantation and represent a suitable tool for tissue engineering of menisci.
Objective Col I A1 antisense oligodeoxyneucleotide (ASODN) has inhibitory effect on collagen synthesis in cultured human hypertrophic scar fibroblasts. To investigate the effects of intralesional injection of Col I A1 ASODN on collagen synthesis in human hypertrophic scar transplanted nude mouse model. Methods The animal model of humanhypertrophic scar transplantation was established in the 60 BALB/c-nunu nude mice (specific pathogen free grade, weighing about 20 g, and aged 6-8 weeks) by transplanting hypertrophic scar without epidermis donated by the patients into the interscapular subcutaneous region on the back, with 1 piece each mouse. Fifty-eight succeed models mice were randomly divided into 3 groups in accordance with the contents of injection. In group A (n=20): 5 μL Col I A1 ASODN (3 mmol/L), 3 μL l iposome, and 92 μL Opti-MEM I; in group B (n=20): 3 μL l iposome and 97 μL Opti-MEM I; in group C (n=18): only 100 μL Opti-MEM I. The injection was every day in the first 2 weeks and once every other day thereafter. The scar specimens were harvested at 2, 4, and 6 weeks after injection, respectively and the hardness of the scar tissue was measured. The collagens type I and III in the scar were observed under polarized l ight microscope after sirius red staining. The ultrastructures of the scar tissues were also observed under transmission electronic microscope (TEM). Additionally, the Col I A1 mRNAs expression was determined by RT-PCR and the concentrations of Col I A1 protein were measured with ELISA method. Results Seventeen mice died after intralesional injection. Totally 40 specimens out of 41 mice were suitable for nucleic acid and protein study, including 14 in group A, 13 in group B, and 14 in group C. The hardness of scars showed no significant difference (P gt; 0.05) among 3 groups at 2 weeks after injection, whereas the hardness of scars in group A was significantly lower than those in groups B and C at 4 and 6 weeks (P lt; 0.05), and there was no significant difference between groups B and C (P gt; 0.05). The collagen staining showed the increase of collagentype III in all groups, especially in group A with a regular arrangement of collagen type I fibers. TEM observation indicated that there was degeneration of fibroblasts and better organization of collagen fibers in group A, and the structures of collagen fibers in all groups became orderly with time. The relative expressions of Col I A1 mRNA and the concentrations of Col I A1 protein at 2 and 4 weeks after injection were significant difference among 3 groups (P lt; 0.05), and they were significantly lower in group A than in groups B and C (P lt; 0.05) at 6 weeks after injection, but no significant difference was found between groups B and C (P gt; 0.05). Conclusion Intralesional injection of Col I A1 ASODN in the nude mice model with human hypertrophic scars can inhibit the expression of Col I A1 mRNA and collagen type I, which enhances the mature and softening of the scar tissue. In this process, l iposome shows some assistant effect.
Objective To provide experimental evidence for the clinical application of ischemia therapy to treating pancreatic cancer. Methods After the model of pancreatic transplanted cancer was established in nude mice with orthotransplantation of human pancreatic cancer cell line into the pancreas, the ischemia of the right lobe of the pancreas was induced with ligation of the gastroduodenal, inferior pancreaticoduodenal and dorsal pancreatic arteries. Effects of regional ischemia on the growth of transplanted cancer and the pathomorphology of the transplanted cancer and pericancerous tissue were investigated. Results The transplanted cancer grew slower and its doubling time was longer in the ischemic group than in the control. On the 3rd, 7th and 14th day after operation, the size of transplanted cancer, the proliferative index and protein content of the cancer cells were significantly lower in the ischemic group than in the control (P<0.01). Optical microscopy revealed large areas of coagulation necrosis, necrobiotic cells and the infiltration of inflammatory cells. The atrophy of acini, fibrosis and the infiltration of lymphocyte cells were found in pericancerous tissue. Conclusion Regional ischemia can destroy and inhibit the pancreatic transplanted cancer in nude mice effectively. The ischemia changes of pericancerous tissue may be unfavourable for the growth of the pancreatic transplanted cancer.
ObjectiveTo investigate the co-transplantation of C57-green fluorescent protein (GFP) mouse epidermis and dermis cells subcutaneously to induce the hair follicle regeneration. MethodC57-GFP mouse epidermis and dermis were harvested for isolation the mouse epidermis and dermis cells. The morphology of epidermis and dermis mixed cells at ratio of 1:1 of adult mouse, dermis cells of adult mouse, cultured 3rd generation dermis cells were observed by fluorescence microscope. Immunocytochemistry staining was used to detect hair follicle stem cells markers in cultured 3rd generation dermis cells from new born C57-GFP mouse. And then the epidermis and dermis mixed cells of adult mouse (group A), dermis cells of adult mouse (group B), cultured 3rd generation dermis cells of new born mouse (group C), and saline (group D) were transplanted subcutaneously into Balb/c nude mice. The skin surface of nude mice were observed at 4, 5, 6 weeks of transplantation and hair follicle formation were detected at 6 weeks by immunohistochemistry staining. ResultsThe isolated C57-GFP mouse epidermis and dermis cells strongly expressed the GFP under the fluorescence microscope. Immunocytochemistry staining for hair follicle stem cells markers in cultured 3rd generation dermis cells showed strong expression of Vimentin and α-smooth muscle actin, indicating that the cells were dermal sheath cells; some cells expressed CD133, Versican, and cytokeratin 15. After transplanted for 4-6 weeks, the skin became black at the injection site in group A, indicating new hair follicle formation. However, no color change was observed in groups B, C, and D. Immunohistochemical staining showed that new complete hair follicles structures formed in group A. GFP expression could be only observed in the hair follicle dermal sheath and outer root sheath in group B, and it could also be observed in the hair follicle dermal sheath, outer root sheath, dermal papilla cells, and sweat gland in group C. The expression of GFP was negative in group D. ConclusionsCo-transplantation of mouse epidermis and dermis cells can induce the hair follicle regeneration by means of interaction of each other. And transplantation of isolated dermis cells or cultured dermis cells individually only partly involved in the hair follicles formation.