1.Study on growth law of Glycyrrhiza uralensis under different planting density.
Rui-Fang WANG ; Hai-Ming LIN ; Jian-Jun XIE ; Fa-Jiang LI ; Wen-Zhi AN ; Ling-Min ZHU
China Journal of Chinese Materia Medica 2008;33(10):1117-1120
OBJECTIVETo study the growth of Glycyrrhiza uralensis under different planting density for providing theoretic evidence for reasonable planting density.
METHODThe field experiment was designed by single factor randomized block.
RESULTThe plant height, root diameter, main root length and branches of main stem were all decreased with increasing planting density of G. uralensis. Meanwhile, dry matter accumulation on root, leaf, aerial part and rhizome were all decreased with increasing planting density.
CONCLUSIONTwo hundred and seventy thousand plants/hm2 was feasible planting density.
Forestry ; methods ; Glycyrrhiza uralensis ; growth & development
2.Preliminary study in glycyrrhizin content and its influencing factors of wild and cultivated in different region of China.
Shengli WEI ; Wenquan WANG ; Jiyong WANG ; Zhirong SUN ; Chunsheng LIU ; Hai WANG ; Zhigang YANG ; Baocai WU
China Journal of Chinese Materia Medica 2012;37(10):1341-1345
OBJECTIVEIn order to understand the glycyrrhizin content range in the wild and cultivated Glycyrrhiza uralensis in China and to find the related influencing factors of glycyrrhizin content.
METHODThe glycyrrhizin content of 165 wild and 1 013 cultivated G. uralensis samples from 37 countries in 9 provinces was determined by HPLC, and the effects of the producing region, medicinal parts, cultivation years, soil type and texture on the glycyrrhizin content were analyzed.
RESULT AND CONCLUSIONThe average glycyrrhizin content was (4.43 +/- 1.32)% in the wild G. uralensis population, and (1.51 +/- 0.49)% in the cultivated and the glycyrrhizin content in the cultivated was less than the minimum sandards in the Chinese Pharmacopoeia. The glycyrrhizin content was significant different in the wild and cultivated G. uralensis in different producing regions, respectively. The glycyrrhizin content in roots and rhizome of the wild G. uralensis had no significant difference, it had no significant difference in the cultivated G. uralensis from 1 to 4 years and it increased rapidly after 5 years, and the effects of the soil types and texture on it were significant.
China ; Glycyrrhiza uralensis ; chemistry ; growth & development ; Glycyrrhizic Acid ; analysis
3.Study on licorice resources and their sustainable utilization in center and western area of China.
Sheng-li WEI ; Wen-quan WANG ; Hai WANG
China Journal of Chinese Materia Medica 2003;28(3):202-206
OBJECTIVETo investigate the latest wild and cultivated licorice resource status; bring forward the licorice resource protection and sustainable utilization countermeasures in the center and western area of China.
METHODWith study both in interview survey and field survey.
RESULTAll samples investigated were the species of Glycyrrhiza uralensis. Human actions is concerned with the community status, reserves per unit and quality. Excessive exploitation made the licorice quality lower and reserves decrease.
CONCLUSIONEnforcing the wild licorice resource protection and improving licorice cultivated technique are brought forward to act as the sustaining countermeasures.
China ; Conservation of Natural Resources ; Ecosystem ; Glycyrrhiza uralensis ; growth & development ; Pharmacognosy ; Plants, Medicinal ; growth & development ; Quality Control
4.Analysis of broad-sense heritability and genetic correlation of production and content of glycyrrhizin of annual Glycyrrhiza uralensis.
Shengli WEI ; Wenquan WANG ; Changli LIU ; Jiyong WANG ; Ruifeng ZHANG ; Minbin SUN
China Journal of Chinese Materia Medica 2012;37(5):553-557
OBJECTIVETo estimate the broad-sense heritability of the production of Glycyrrhiza uralensis and the content of glycyrrhizin as well as the genetic relationship of various growth indexes and biomass indexes, and provide the scientific basis for establishment of high quality licorice cultivate technology system.
METHODThe randomized method was used to assign the provenance trial, the content of glycyrrhizin was determined by HPLC, and the method of classic genetics was applied to estimate the broad-sense heritability and genetic correlation coefficient.
RESULT AND CONCLUSIONThe content of glycyrrhizin is influenced by the growth environment and gene, but the growth environment is the dominant factor. The estimated result of single sites about broad-sense heritability (h2) showed that the production of G. uralensis (W(u)) and the content of glycyrrhizin was controlled by gene which the broad-sense heritability was 0.663 2, 0.751 1 respectively, they had some potential on genetic modification. The results of genetic analysis correlation showed that the plant height and the stem diameter was positive (P < 0.01) correlated significantly with the production (W(u)) either on phenotype or on genetic, it suggests that the plant height and the stem diameter could be the index above ground to assessment the production of the G. uralensis. The content of glycyrrhizin had a positive correlation with the number of lateral root (P < 0.05), but it had a negative correlation with the plant height, stem diameter, diameter of root top (D(r)), the total biomass (W(t)) and the biomass underground (W(u)) on inheritance. It is suggested that it was difficult to achieve both high content and high yield simultaneously in the genetic improvement, so we should have a deeply thought about the specific improvement target when making the reformed scheme.
Biomass ; Glycyrrhiza uralensis ; chemistry ; genetics ; growth & development ; Glycyrrhizic Acid ; analysis ; metabolism
5.Wild-tending techniques study on Glycyrrhiza uralensis--effect of irrigation and rhizome length on survival ratio, yield and quality.
Li LI ; Sheng-Li WEI ; Wen-Quan WANG ; Hua SHI ; Sogumeyi TODA ; Zheng-Zheng GUO ; Guang-Xi REN
China Journal of Chinese Materia Medica 2014;39(15):2863-2867
This research aimed at studying the effects of irrigation and rhizome length on the survival of ratio, yield and quality of Glycyrrhiza uralensis in wild tending condition. Employed the split-block design to carry out the field experiment, sampled with the quadrat method to measured the relative growth indexes and to estimate the yield, used the HPLC (high performance liquid chromatog- raphy ) method to measure the glycyrrhizin in the rhizome and adventitious root of the G. uralensis in this study. The quantity of the adventitious roots and the survival ratio were increased significantly as the length of the rhizome increased (P < 0.01), but the length of the rhizome had no remarkable effect on the content of glycyrrhizin. The average content of the glycyrrhizin in the adventitious root and rhizome could reach 3.03% and 2.12% after 3-year wild tending, respectively, and this results indicated that the quality of the glycyrrhiza using this method was much better than that from cultured glycyrrhiza with the reproducing method of seeding. so using the rhizome as reproductive material to produce the glycyrrhiza under the wild tending condition could get the high quality glycyrrhiza quick- ly and steadily, this phenomenon could be explained by the Hypothesis of synthetic inertia of the medicinal components from the wild material of G. uralensis. But the maximum yield with this method was just more than 945 kg x hm(-2) in this study. So the further work of how to increase the yield in the practical application with the method found in this study need to be done in the next research.
Agricultural Irrigation
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Culture Techniques
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methods
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Glycyrrhiza uralensis
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growth & development
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metabolism
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Glycyrrhizic Acid
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metabolism
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Rhizome
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growth & development
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Survival Analysis
6.Study on geographical variation of morphologic and germination characteristic of different Glycyrrhiza uralensis provenance seeds.
Sheng-Li WEI ; Wen-Quan WANG ; Shu-Ying QIN ; Chang-Li LIU ; Zhao-Ying ZHANG ; Ming DI
China Journal of Chinese Materia Medica 2008;33(8):869-873
OBJECTIVETo study the geographical variation of morphologic and germination characteristic of different Glycyrrhiza uralensis provenance seeds, approach the geographical variation mode and ecology mechanism, and laid theoretical foundation for districting and allocating of G. uralensis seeds.
METHODField investigation and laboratory analysis were applied. Seed shape and kilosseed weight were sampled randomly, germination rate germination force by general methods.
RESULTThe morphologic characteristic of G. uralensis seeds showed roughly longitude variation tendency that the seeds increased gradually from west to east. While the germination characteristic showed roughly altitude variation tendency that the seeds germination rate and germination force increased with the increase of the altitude, and the average germination rate was the same with the seeds morphologic characteristic. The results of analysis correlated with the climatic factors show that the morphologic characteristic of G. uralensis was positive correlated with annual rain-fall of the habitat, and the germination rate was quickened by drought, high temperature and strong sunshine.
CONCLUSIONThe morphologic and germination characteristic and of G. uralensis seeds present distinguished geographical variation, and the formation of the variation was related to the ecological environment in which the seed provenance adapted.
Altitude ; Drugs, Chinese Herbal ; Geography ; Germination ; Glycyrrhiza uralensis ; anatomy & histology ; classification ; growth & development ; Rain ; Seeds ; anatomy & histology ; growth & development
7.The Indigenization of Licorice and Its Meaning During the Early Days of the Joseon Dynasty.
Korean Journal of Medical History 2015;24(2):423-455
This article explores the indigenization of licorice(Glycyrrhiza uralensis Fisch.) which was the most important medicine of the Oriental Medicine. There are a lot of records on licorice even before the Joseon Dynasty. The licorice had been used mainly in stomach related diseases such as food poisoning or indigestion. But the licorice was an imported medicine until the early days of the Joseon Dynasty. As the Joseon Dynasty began, the licorice production became necessary with the investigation and obtaining the herbs. And a large amount of licorice was needed when the epidemics outbroke under the reign of King Sejong. In particular, the licorice had been essential in treating the diseases of the Cold Damage which was focused in the Joseon Dynasty. That was why King Sejong ordered to plant the licorice in the Chollado province and Hamgildo province in 1448. But the licorice cultivation was not easy for two reasons. First, it was difficult to find the proper soil for proper soil for planting. Second, the people didn't actively grow the licorice, because they had to devote the licorice as the tax when the indigenization of licorice was succeeded. King Sejo and King Seongjong encouraged the people to plant the licorice. The recognition that the licorice is essential in pediatric diseases such as smallpox got stronger then before. Finally the indigenization of licorice was completed under the reign of King Seongjong. According to the Dongguknyeojiseungnam, edited in 1481, and Shinjeungdongguknyeojiseungnam, edited in 1530, the licorice was planted in seven districts. With the success of the indigenization of licorice, the approach of the people to the Oriental Medicine treatment had became much easier.
Glycyrrhiza uralensis/*growth & development
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History, 15th Century
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History, 16th Century
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History, Medieval
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Korea
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Medicine, Korean Traditional/*history
8.Genotype, environment and their interactions of major bioactive components in 2-year licorice (Glycyrrhiza uralensis) population.
Fu-Lai YU ; Wen-Quan WANG ; Jun-Ling HOU ; Xiang-Zhen ZHOU ; Ya-Nan HAN ; Dan WANG
China Journal of Chinese Materia Medica 2013;38(10):1479-1483
OBJECTIVEThis study aimed at analyzing the effect of genotype (G), environment (E) and their interactions (G x E) on the major bioactive components of 2-year licorice (Glycyrrhiza uralensis) population, in order to provide a theoretical basis for the licorice breeding with high content of bioactive components and quality improvement.
METHODFour genotype licorice populations were transplanted under four different environments by using complete randomized block design with three replicates, and four major bioactive components, including glycyrrhizin (GL), total saponins (TS), liquiritin (LQ) and total flavonoids (TF) were determined by UV and by HPLC.
RESULTThe major bioactive components of licorice were influenced by genotype and environment, and the genotype had more effect on all of the bioactive components. The contents of GL and LQ were codetermined by genotype and environment factors.
CONCLUSIONThere exist different selective effects on different growth region for quality breeding in cultivated population of licorice.
Chromatography, High Pressure Liquid ; Ecosystem ; Gene-Environment Interaction ; Genotype ; Glycyrrhiza uralensis ; chemistry ; genetics ; growth & development ; metabolism ; Plant Extracts ; analysis ; metabolism
9.The underground part growth distribution pattern of Glycyrrhiza uralensis and its effects on glycyrrhizinic acid content.
Zhi-rong SUN ; Wen-quan WANG ; Chang-hua MA ; Min-bin SUN ; Yong-hong YAN ; Chang-li LIU
China Journal of Chinese Materia Medica 2004;29(4):305-309
OBJECTIVETo ascertain the relationship between glycyrrhizinic acid content and the underground part growth character of Glycyrrhiza uralensis and provide the theoretical evidence for wild resources protection and artificial cultivation method of G. uralensis.
METHODThrough the analytical investigation on the underground part of G. uralensis and analysis of glycyrrhizinic acid content in different organs, parts, ages, and diameter medicinal materials, the systematic study on the relationship between glycyrrhizinic acid content and the underground part growth character of glycyrrhiza uralensis was carried out.
RESULTThe underground part of a G. uralensis seedling consisted of seed root, random root, horizontal underground stem, vertical underground stem and assimilating root. The glycyrrhizinic acid content in horizontal underground stem with the age below two years old or in random root with the diameter below 0.5 cm was low. The difference of glycyrrhizinic acid content among horizontal underground stem, random root and vertical underground stem was obvious, but the difference between horizontal underground stem and random root was not obvious.
CONCLUSIONThe horizontal underground stem was of G. uralnesis acts as a link that can connect random root, vertical underground and stem assimilating root, so that the whole underground part constructs one huge underground net system. The glycyrrhizinic acid accumulation is a effected by organ type, growth age, root diameter and grow position, and the distribution pattern of random root and vertical underground stem has influence on glycyrrhizinic acid distribution in horizontal underground stem.
Glycyrrhiza uralensis ; chemistry ; growth & development ; Glycyrrhizic Acid ; analysis ; Plant Roots ; chemistry ; growth & development ; Plants, Medicinal ; chemistry ; growth & development ; Seedlings ; chemistry ; growth & development ; Time Factors
10.Effect of drought stress on growth of Glycyrrhiza uralensis.
Chang-li LIU ; Wen-quan WANG ; Shuai-ying LI ; Jun-ru CUI
China Journal of Chinese Materia Medica 2004;29(10):931-934
OBJECTIVETo study the effect of drought stress on the growth of Glycyrrhiza uralensis and its drought resistance characteristic.
METHODThe growth in dicators of G. uralensis including leaf, stem, root and biomass were measured when two-years-old G. uralensis had lived in drought stress soil for 60 days.
RESULTThe growth of all organs of G. uralensis was restrained because of drought stress, especially to up ground organs.
CONCLUSIONIt is obvious that the restraining effect of drought stress on G. uralensis possesses organ speciality. Both yield and quality of G. uralensis will be satisfied when it grows in the soil with relative water content of 50%.
Disasters ; Glycyrrhiza uralensis ; anatomy & histology ; growth & development ; Plant Components, Aerial ; anatomy & histology ; growth & development ; Plant Roots ; anatomy & histology ; growth & development ; Plants, Medicinal ; anatomy & histology ; growth & development