• Journal of Ginseng Research
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• 제8권2호
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• pp.172-177
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• 1984

Saponins in leaf and stem of Gynostemma pentaphyllum that was collected from Jeju Island were extracted by the method for ginseng saponin. Comparison by overlapping chromatogram(HPLC) of pentaphyllum on that of ginseng and cochromatogram and ginseng although ginsenoside Rg2, Rg1 and Rf might be in common with rare possibility. It seems to be little difference in the kind of saponin glycosides between leaf and stem of pentaphyllum. Saponin content in leaf of pentaphyllum was higher than in stem, and much higher than those in ginseng. The kind of saponin glycoside in pentaphyllum appeared to be less than 22 and greater than those in ginseng. There was almost no change in saponins of pentaphyllum in methanol for 3 years at room temperature.

• Journal of Ginseng Research
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• 제7권2호
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• pp.108-114
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• 1983

1. To know the site of saponin synthesis in this plant, 4-years old Panax ginseng C.A. Meyer was administered with 1, 2-l4C-acetate (Na salt, 10 ucilplant) by stem injection and was continued to grow for 3 weeks and the distribution of the radioactivity in leaf, stem and root part was identified. The percentage of radioactivity recovered was about 3.99%. 2. The sliced roots or leaf discs (2g) were bathed in the reaction mixture containing sugar, ATP, NADPH, and the distribution of the radioactivity of the fractions (sugar, saponin, sapogenin) was identified. 3. It seemed that major synthesized saponins in roots and leaves are dial and triol-type, respectively. Although both types of saponins are synthesized in roots, the main saponins seemed to be dial saponins and a significant portion of triol saponins are supplied from leaves through stem.

• 한국약용작물학회지
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• 제22권1호
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• pp.1-7
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• 2014

Codonopsis lanceolata (Campanulaceae) has been used in traditional medicines, as its roots contain several kinds of 3,28-bidesmosidic triterpenoid saponin with high medicinal values. In this study, we induced hairy root-derived transgenic plants of C. lanceolata and analyzed triterpenoid saponins from the leaf, stem and root. Transgenic plants were regenerated from the hairy roots via somatic embryogenesis. The saponins are lancemaside A, B and E, foetidissimoside A, and aster saponin Hb. Transgenic plants contained richer triterpenoids saponin than wild-type plants. Major saponin lancemaside A was the most abundant saponin in the stem from transgenic-plant, $4.76mg{\cdot}1^{-1}dry$ stem. These results suggest that transgenic plants of C. lanceolata could be used as medicinal materials for the production of triterpene saponins.

• Applied Biological Chemistry
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• 제30권4호
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• pp.335-339
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• 1987

인삼(人蔘)의 근(根) 엽(葉) 및 경(莖)에서 사포닌 추출과정중(抽出過程中) 지용성(脂溶性) 용매류(溶媒類)에 따른 콜로르필 및 색소류(色素類) 등 가시부(加視部) 흡수물질(吸收物質)의 정제효과와 사포닌의 수율(收率)에 미치는 영향을 조사(調査)하였다. 근(根)사포닌의 정제(精製)는 여러 지용성(脂溶性) 용매류(溶媒類)가 효과적이었고, 엽(葉)과 경(莖)사포닌의 정제(精製)는 chloroform과 benzene이 효과적이었다. 또한 지상부(地上部)사포닌의 경우는 ethyl acetate, ethyl ether, chloroform 및 benzene으로 1회씩 순차적(順次的)으로 정제(精製)할 경우가 단일용매만으로 4회 추출하는 편보다는 효과적이었으며 지용성(脂溶性) 용매류(溶媒類)에 따른 사포닌 수율(收率)은 거의 차이가 없었다. 한편 조사포닌 분획물 및 ginsenoside 함량을 볼때 엽(葉)에 있어서는 $18.5{\sim}19.5%$ 및 $10.8{\sim}11.4%$로서 근(根)의 $4.6{\sim}5.1%$ 및 $2.0{\sim}2.6%$나 경(莖)의 $2.2{\sim}2.5%$및 $0.63{\sim}0.67%$에 비하여 현저하게 높았다 따라서 인삼엽(人蔘葉)은 사포닌 화합물(化合物)이나 $ginsenoside-Rg_1,\;-Re,\;-Rd,\;-Rc,\;-Rb_2,\;-Rf$ 등의 분리용(分離用) 원료(原料)로 매우 적합하였다.

• Applied Biological Chemistry
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• 제30권4호
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• pp.340-344
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• 1987

인삼(人蔘)의 근(根) 및 지상부(地上部) 사포닌을 얇은 막 크로마토그래피로 동정(同定)한 결과(結果) 인삼근(人蔘根)에 함유된 사포닌 중 $ginsenoside-Re,\;-Rg_1,\;-Rc,\;-Rf,\;-Rb_2$ 및 $-Rb_1$ 은 각각 엽(葉)과 경(莖)에서도 동정(同定)되었으며 이외에도 엽(葉)에서 10개과 경(莖)에서 9개의 unknown spot를 동정(同定)할 수 있었다. 또한 부위별(部位別) 총(總)사포닌을 50% 초산으로 온화한 조건에서 산(酸) 가수분해(加水分解)하여 생성(生成)된 prosapogenin의 조사결과(調査結果), panaxadiol계 사포닌 및 ginsenoside-Re의 산(酸) 가수분해물(加水分解物)인 $ginsenoside-Rg_3$ 및 $ginsenoside-Rg_2$가 각각 동정(同定)되었다. 한편 근(根), 엽(葉) 및 경(莖)의 총사포닌을 황산 가수분해(加水分解)하여 sapogenin 조사결과, 근(根)에서는 panaxadiol, panax atriol 및 oleanolic acid가 검출되었고, 엽(葉)과 경(莖)에서는 panaxatriol 및 panaxadiol만이 동정(同定)되었다.

• Journal of Ginseng Research
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• 제45권1호
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• pp.163-175
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• 2021

Background: Ginsenosides, which have strong biological activities, can be divided into polar or less-polar ginsenosides. Methods: This study evaluated the phytochemical diversity of the saponins in Panax ginseng (PG) root, American ginseng (AG) root, and Panax notoginseng (NG) root; the stem-leaves from Panax ginseng (SPG) root, American ginseng (SAG) root, and Panax notoginseng (SNG) root as well as the saponins obtained following heating and acidification [transformed Panax ginseng (TPG), transformed American ginseng (TAG), transformed Panax notoginseng (TNG), transformed stem-leaves from Panax ginseng (TSPG), transformed stem-leaves from American ginseng (TSAG), and transformed stem-leaves from Panax notoginseng (TSNG)]. The diversity was determined through the simultaneous quantification of the 16 major ginsenosides. Results: The content of ginsenosides in NG was found to be higher than those in AG and PG, and the content in SPG was greater than those in SNG and SAG. After transformation, the contents of polar ginsenosides in the raw saponins decreased, and contents of less-polar compounds increased. TNG had the highest levels of ginsenosides, which is consistent with the transformation of ginseng root. The contents of saponins in the stem-leaves were higher than those in the roots. The transformation rate of SNG was higher than those of the other samples, and the loss ratios of total ginsenosides from NG (6%) and SNG (4%) were the lowest among the tested materials. In addition to the conversion temperature, time, and pH, the crude protein content also affects the conversion to rare saponins. The proteins in Panax notoginseng allowed the highest conversion rate. Conclusion: Thus, the industrial preparation of less-polar ginsenosides from SNG is more efficient and cheaper.

• Journal of Ginseng Research
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• 제11권2호
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• pp.118-122
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• 1987

인삼의 재배과정중에 부산물로 산출되는 지상부위의 활용방안을 모색하기 위하여 엽과 경의 반성분, 용매별 엑기스 및 사포닌함량을 근의 함량과 대비 검토하여 다음과 같은 결과를 얻었다. 1. 엽은 총당의 함량이 21.5%로 근보다 낮았으나 조직유질, 조지방질 및 회분은 각각 9.41%, 3.43% 및 6.83%로 높았다. 경은 조직유질이 39.2%로 현저하게 많았고 총당과 조단백질은 22.7% 및 8.54%로 근보다 낮았다. 2. 용매별 추출물의 수율은 추출용매의 극성이 클수록 높았으며 근과 경에 비하여 엽은 methanol 및 ehanol 추출물의 수율이 35.9% 및 27.3%로 현저하게 많았고, acetone 및 ethyl acetate추출물도 5.64% 및 3.52%로 높았으며 그 외의 비극성 용매의 추출물의 수율도 대체로 높았다. 3. 총 조saponin의 수율은 근과 경은 4.78% 및 2.22%였으나 엽은 19.58%로 현저하게 높았다. HPLC에 의한 분석결과 엽에는 ginsenoside-Rg1(3.32%), -Re(3.24%), -Rd(2.32 %), -Rc(0.65%), -Rb2(0.92%), -Rbl(0.29%), and -Rf(0.11%)가 함유되었고, 경에는 ginsenoside-Rgl(0.28%), -Re(0.3%), -Rd(0.05%), -Rf(0.11%)외에 미량의 -Rbl, -Rb2, -Rc가 검출되었다. 특히 엽은 총 saponin과 ginsenoside-Rg1, -Re 및 -Rd외에도 -Rc와 -Rb2의 함량이 높아서 이들 성분의 분리용 시료로 적합함을 알 수 있었다.

• 고려인삼학회:학술대회논문집
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• 고려인삼학회 1974년도 학술대회지
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• pp.101-113
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• 1974

The radioactive compound sodium $acetate-U-C^{14}$ (C-14 acetate) was administered to two- and four-year-old July and September American ginseng (Panax quinquefolium L.) plants and cuttings. The C-14 acetate uptake was approximately $99\%.$ The autoradiochromatograms suggest that the saponins(panaquilins) isolated by preparative thin-layer chromatography contained impurities, especially those isolated from the leaf and stem extracts. The root and fruit methanol extracts yielded relatively pure saponins. The large amounts of panaquilin B and its proximity to panaquilin C on preparative thin-layer plates resulted in some admixing. The average concentration $(\%$ plant dry weight) of semipurified saponins were high in the leaves $(13.8\%),$ compared to fruits $(9.8\%),\;stems\;(7.9\%)\;and\;roots\;(6.3\%).$ The average percentage of C-14 acetate incorporation into panaquilins was $4.8\%.$ The average percentage of C-14 acetate incorporation into panaquilins B and C was higher $(1.40\%\;and\;1.13\%,$ respectively) than that into panaquilin C, (d), G-1 and G-2 $(0.75\%,\;0.65\%,\;0.13\%\;and\;0.53\%,$ respectively). Panaquilin synthesis may be depending upon the part collection period and age of the plant. The average percentage of C-14 acetate incorporation into panaquilin B is high in roots $(0.58\%)\;and\;stems\;(0.48\%);$ that into panaquilins C and (d) high in leaves $(0.40\%\;and\;0.45\%,$ respectively); and that into panaquilin E high in roots and leaves $(0.55\%\and\;0.50\%,$ respectively). Panaquilin G-2 was synthesized in all parts of plants. The panaquilins appear to be biosynthesized more actively in July than September (exception-panaquilin G-l). Panaquilins B, C and G-1 may be biosynthesized more actively in four-year-old plants and panaquilins (d) and E more actively in two-year-old plants. The results from expectance with cuttings suggest that the panaquilins are synthesized de novo in the above-ground parts of ginseng plants, and that panaquilin G-l may be synthesized de novo in the leaf. It is known from the tissue culture studies that panaquilins are produced by leaf, stem and root callus tissues and callus-root cultures of American and Korean ginseng plants. Panaquilins may actively be synthesized de novo in most any cell or organ of the ginseng plants. It was verified that C-14 acetate was incorporated into the panaxadiol portions of the panaquilins of two-year-old plants (sp. act., 0.56 $m{\mu}Ci/mg$) and four-year-old plants (sp. act., 0.54 $m{\mu}Ci/mg$).

• 대한수의학회지
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• 제55권1호
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• pp.1-7
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• 2015

Ginseng has been widely used in Korea as a natural medicine due to its saponin contents. Although the total amount of ginseng stem and leaf saponins (GSLS) is 4~5 times higher than that of saponin in the root, the root is mainly used. This is due to two reasons: nervous system-stimulant activity of GSLS and pesticide residues in GSLS. In this study, residual agricultural pesticides were removed from GSLS using two types of bacterial treatments. Two GSLS treatment groups of chickens (GSLS-1 and GSLS-2) were established. The chickens were fed 0.4% GSLS-1 or GSLS-2 mixed with crop. We then evaluated the effects of GSLS on bodyweight and several immune parameters. At the end of the experiments, chickens fed GSLS-1 and red ginseng saponin had significantly higher growth rates (16.6% and 8.0%, respectively) compared to the vaccine control group treated with Noblis Salenvac-T. The group fed GSLS-1 also had the highest IgG titer that was significantly different at the end of experiments compared to the other groups. These findings imply that GSLS-1 is a good candidate feed additive for the chicken industry.

• Journal of Ginseng Research
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• 제44권3호
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• pp.442-452
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• 2020

Backgroud: Sleep deprivation (SD) impairs learning and memory by inhibiting hippocampal functioning at molecular and cellular levels. Abnormal autophagy and apoptosis are closely associated with neurodegeneration in the central nervous system. This study is aimed to explore the alleviative effect and the underlying molecular mechanism of stem-leaf saponins of Panax notoginseng (SLSP) on the abnormal neuronal autophagy and apoptosis in hippocampus of mice with impaired learning and memory induced by SD. Methods: Mouse spatial learning and memory were assessed by Morris water maze test. Neuronal morphological changes were observed by Nissl staining. Autophagosome formation was examined by transmission electron microscopy, immunofluorescent staining, acridine orange staining, and transient transfection of the tf-LC3 plasmid. Apoptotic event was analyzed by flow cytometry after PI/annexin V staining. The expression or activation of autophagy and apoptosis-related proteins were detected by Western blotting assay. Results: SLSP was shown to improve the spatial learning and memory of mice after SD for 48 h, accomanied with restrained excessive autophage and apoptosis, whereas enhanced activation of phosphoinositide 3-kinase/protein kinase B/mammalian target of rapamycin signaling pathway in hippocampal neurons. Meanwhile, it improved the aberrant autophagy and apoptosis induced by rapamycin and re-activated phosphoinositide 3-kinase/Akt/mammalian target of rapamycin signaling transduction in HT-22 cells, a hippocampal neuronal cell line. Conclusion: SLSP could alleviate cognitive impairment induced by SD, which was achieved probably through suppressing the abnormal autophagy and apoptosis of hippocampal neurons. The findings may contribute to the clinical application of SLSP in the prevention or therapy of neurological disorders associated with SD.