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OBJECTIVE To provide reference for quality control of Gentiana rhodantha. METHODS Taking 52 batches of G. rhodantha as subject, ultra-high performance liquid chromatography (UPLC) fingerprint was adopted. The similarity of 52 batches of medicinal materials samples was evaluated by the Similarity Evaluation System for Chromatographic Fingerprints of Traditional Chinese Medicine (2004A edition); the content of mangiferin was determined; chemometric analyses [cluster analysis, principal component analysis (PCA) and orthogonal partial least squares-discriminant analysis (OPLS-DA)] were performed. RESULTS UPLC fingerprints of 52 batches of G. rhodantha were established, 17 common peaks were identified, and 6 of them were identified, which were loganic acid (peak 1), neomangiferin (peak 3), swertiamarin (peak 5), dangyin (peak 6), mangiferin (peak 7) and isoorientin (peak 9). The similarities of 52 batches of medicinal materials samples were all greater than 0.9; cluster analysis showed that S1-S46, S48-S52 clustered into one class, and S47 alone; PCA results showed that the cumulative variance contribution rate of the first six principal components was 82.928%; OPLS-DA results showed that the corresponding components of swertiamarin, mangiferin and chemical composition represented by peak 4, 14, 15, 16 were the main iconic components affecting the quality differences of G. rhodantha medicinal materials. The contents of mangiferin in 52 batches of medicinal material samples ranged from 18.2 to 101.0 mg/g, mostly in accordance with 2020 edition of Chinese Pharmacopoeia. CONCLUSIONS The established UPLC fingerprint and chemometric analysis methods combined with content determination method of mangiferin can comprehensively evaluate the quality of G. rhodantha.
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Two sample pretreatment methods of pesticide residues in Panax notoginseng of Chinese traditional medicine were developed. For Method I, the residues were extracted from homogenized tissue with n-hexane-dichloromethane (6:4) by means of ultrasonication, the crude extract was purified by an Envi-carb/NH2 solid-phase extraction (SPE) column. For Method II, matrix solid-phase dispersion (MSPD) technique was used for extracting and cleaning up. The eluates were concentrated by rotary evaporation, and then were redissolved in dichloromethane prior to GC-MS determination. The determination was performed in selected ion monitoring (SIM) mode with the external calibration for quantitative analysis. Under the optimal conditions, the results indicated that the methods are easier and faster, the recoveries of method I for the spiked standards at concentration of 0.01, 0.5, and 2.0 mg x kg(-1) were 81.90%-102.10% with the relative standard deviations (RSDs) of 3.60%-7.10%. The recoveries of method II were 96.26%-104.20% with the RSDs of 3.52%-7.94%. The detection limits (S/N) for residues of pesticides were in the range of 0.48-1.34 ng x g(-1). The results indicated that these multiresidue analysis methods can meet the requirements for determination of residue pesticides and can be appropriate for trace analysis of residue pesticides in Panax notoginseng.
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Objective To study the repair function of united endothelial progenitor cells (EPC)transplantation on injured liver endothelium by bone marrow transplantation (BMT) conditioning.Methods C57BL/6 mice were divided into four groups randomly: normal control group, without any treatment; irradiation alone group, administered a total body irradiation(TBI) pretreatment, without BMT; (3) BMT alone group: C57BL/6 mice were infused with bone marrow mononuclearcells (MNC) 5 × 106/only through caudal vein not more than 4 h after the same TBI pretreatment as the irradiation alone group; united transplantation group: receiving the same way as the BMT alone group, but C57BL/6 mice were infused with EPC 5 × 105/only at the same time. Two, 4, 7, 14, and 21 days after the TBI, the changes of the liver weight were observed regularly. The histopathological examination of liver was done at the 4th, 7th, 14th, and 21st day after the TBI. Results In irradiation alone group, BMT alone group and united transplantation group the liver weight began to increase significantly on the day 2 and peaked at 14th day after the TBI, and the peaks were respectively (1.65±0. 15) times (P<0. 05), (1.61 ±0.06) times (P<0.05), and (1.11 ±0.40)times (P<0. 05) of those in normal control group. At the day 14, the liver weight in irradiation alone group, BMT alone group and united transplantation group began to decrease, and on the day 21 the liver weight in united transplantation group had been completely restored to normal level, however the liver weight in irradiation alone group and BMT alone group were still significantly heavier than that in normal control group (P<0. 05). Liver histopathological examination revealed that there were obvious sinusoidal endothelial cells (SEC) injury, hepatocyte edema and severe inflammatory cell infiltration in irradiation alone group, and on the day 7 the hepatocyte edema and necrosis were significantly worse than before, and almost no alive SEC were found. On the day 14 the injury of SEC in BMT alone group was lighter than before, but on the day 21 the injury had not returned to normal. On the day 7 the injury of SEC, hepatocyte edema and necrosis were alleviated in united transplantation group as compared with irradiation alone group and BMT alone group, and on the day 14 the injury had returned to normal basically. Conclusion The transplantation conditioning could damage recipient liver endothelium and the injury would persist, and united EPC infusion could repair the injured SEC following BMT.
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Objective To explore a proper dose of endothelial progenitor cells (EPCs)administration that can achieve optimal hematopoietic improving effectiveness in a murine allogeneic hernatopoietic stem cell transplantation (allo-HSCT) model.Methods Female Balb/c mice were lethally irradiated with 60Co source,and then were injected intravenously with 5 106 bone marrow cells from C57BL/6 mice (bone marrow transplantation group).In co-transfer experiments,5 × 104,1 ×105,5 × 105 or 1 × 106 donor EPCs (EPCs treated groups) were injected simultaneously with bone marrow cells.The recipients were monitored for survival,peripheral white blood cells,hematopoietic stem cells (HSCs) and bone marrow histology.Results Compared with bone marrow transplantation group,all EPCs treated groups had accelerated recovery of peripheral white blood cells (P<0.05),platelets (P<0.05) and HSCs (P<0.05).When infused with less than 5 × 105 EPCs,these effective hernatopoietic improving phenomena showed a positive correlation with the administrated doses of EPCs.However,when infused with 1 × 106 EPCs,the mice showed lower survival rate (P<0.05)and slower recovery of peripheral white blood cells (P<0.05),platelets (P<0.05) and HSCs (P<0.05) than 5 × 105 EPCs treated grpup.Bone marrow histopathology analysis confirmed the above findings.Conclusion Co-transfer with donor EPCs can improve survival rate and hematopoietic reconstitution of recipient mice in allo-HSCT,and 5 × 105 EPCs should be a proper dose to achieve the best effectiveness.
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Objective To study the relationship between graft-versus-host disease (GVHD) and endothelium injury following hematopoietic stem cells transplantation in mice. Methods C57BL/6 mice as donors and Balb/c mice as recipients were randomly divided into 4 groups: control group, bone marrow transplantation group, GVHD group, GVHD mitigation group. The clinical manifestations,circulating endothelial cells and tissue pathological changes were observed at different time points after transplantation. Results No manifestations of GVHD were found in each group at the day 5, while those were found in GVHD group at the day 9 and all died within 15 days. The counts of endothelial cells in peripheral blood showed no significant difference at the day 5 between GVHD group (7. 34 ±1.26 cells/μl) and bone marrow transplantation group (11.51 ± 7. 40 cells/μl) or GVHD mitigation group (7. 36 ± 0. 16 cells/μl), while among three groups there was statistically significant difference at the day 9 (GVHD group: 153. 64 ± 35. 35 cells/μl vs bone marrow transplantation group: 10. 49 ±5. 61 cells/μl and GVHD mitigation group: 47. 82 ± 4. 69 cells/μl). The scores of pathological aGVHD had no significant difference at the day 5 between GVHD group (4. 33± 1. 53) and bone marrow transplantation group (3. 33 ± 0. 58) or GVHD mitigation group (4. 00 ± 1.73), while among three groups there was statistically significant difference at the day 9 (GVHD group: 10. 0 vs bone marrow transplantation group: 3. 33 ± 1.15 or GVHD mitigation group: 4. 33 ± 0. 58) and at the day 14 (GVHD group: 10. 33 ± 2. 58 vs bone marrow transplantation group: 2. 33 ± 1.25 or GVHD mitigation group 3. 33 ± 1.15). Conclusion Occurrence of GVHD causes endothelial damage again and injured endothelium worsens the GVHD.