The fabric, 100% Silk, was dyed with Atractylodes japonica extract solution. The effects of concentration of extracts (colorant), temperature of dyeing, time of dyeing and pH of dye bath were studied. As the concentration of extracts increased, color strength (K/S value) increased progressively. The K/S values increased with raising temperature, time and proper conditions were 80℃ and 80 minutes. Maximum K/S value was obtained at pH 3. The K/S values of mordanted fabrics were increased with increasing mordant concentration up to specific values. Surface color of dyed and mordanted fabrics were yellowish. Light color fastness of fabric with mordanting was fairly good 3/4 rating. The mordanted silk fabrics showed excellent antibacterial activity. The silk fabric dyed with Atractylodes japonica extract showed a superior UV protective property.
삽주(.Atractylodes japonica Koidzumi)의 약명인 창출(蒼朮)과 백출(白朮)로 휘발성 향기성분을 조사하기 위하여 n-pentane/diethyl ether용매로 사용하여 SDE방법으로 정유성분을 분리한 다음 GC/MS를 이용하여 성분을 확인하였다. 백출에서 30종 그리고 창출에서 28종류의 휘발성 향기성분을 확인하였으며 백출의 향기성분을 관능기별로 보면 hydrocarbons 18종, carbonyls 2종, alcohols 5종, esters 5종이고, 창출은 hydrocarbons 14종, carbonyls 6종, alcohols 4종, esters 3종, acids 3종으로 각각 조사되었고, 백출 및 창출의 주요 향기성분으로서는 furanodiene 성분이 각각 27.9%, 15.7%, α-cyperone 성분이 8.1%, 22.5% alloaromadendrene 성분이 2.9%, 4.7% (1, 1-biphenyl)-4-carbox aldehyde 성분은 창출에서만 8.7%로 확인되었다. 백출에서 limonene. p-cymene, p-cymen-8-ol, (1, 1-biphenyl) -4-carbox aldehyde 등을 포함한 10종의 성분이 확인된 반면에 창출에서는 확인되지 않았고, 반면에 창출에서 α-copaene. isocaryophyllene, β-himachalene, germacrene B 등을 포함한 8종의 성분이 확인된 반면에 백출에서는 확인되지 않았다.
Background: Atractylodes radix is a well-known medicinal crop having many physiological effects. This study was conducted to select useful Atractylodes japonica × Atractylodes macrocephala (AJM) cultivars by comparing anti-oxidative and anti-inflammatory efficacies.
Methods and Results: Seven extracts from AJM cultivars were used to treat lipopolysacchride (LPS)-treated BV2 cells, and the effects on cell viability and inhibition on reactive oxygen species (ROS) and nitric oxide (NO) production were analyzed. In vitro scavenging activities of 2,2-diphenyl-1-picrylhydrazyl (DPPH) and peroxynitrite (NOO−) radicals were also investigated. Contents of total phenol, atractylenolide I, and atractylenolide III in the AJM extracts were measured using high performance liquid chromatography (HPLC) or spectrophotometry. The experiments show that none of the seven extracts was cytotoxic above 89.2% at 20 - 250㎍/㎖. Extracts of Gowon, Dawon, Sangchul, and Huchul inhibited ROS generation in a dose-dependent manner, and Sangchul extract showed the highest inhibition on ROS production. All the AJM extracts showed effective inhibitory activity after on NO release in the LPS-treated BV2 cells, and Sangchul extract showed the highest activity. Sangchul extract had the most potent scavenging activities for NOO− and had some DPPH radical scavenging effect. Sangchul extract also had the highest content at total phenol and atractylenolide I content. Atractylenolide III was not detected in the AJM extracts.
Conclusions: The results suggested that Sangchul was the most useful anti-oxidative and anti-inflammatory resource among the AJM cultivars.
Background : This study was carried out to introduce Atractylodes macrocephala as a new income element in Gangwon area and to develop the technology necessary for stable quality seedling production.
Methods and Results : For the production of high quality seedlings of Atractylodes macrocephala, seedling growth characteristics were investigated according to the types of plug cell size and seedling raising period. Atractylodes macrocephala seeds were sown on February 14, 2018 in 72, 105, 128, 162, and 200 plug trays. The emergence period after sowing was March 2, and the final occurrence rate was 76.6 - 79.5%. The number of days of emergence took 18 to 20 days from sowing date. Growth of seedlings tended to be better with less number of plug trays, such as seedling height, seedling width, leaf length, leaf width and leaf number. On the other hand, roots (net formation) increased rapidly as the number of plug trays increased. After 60 days, the matured seedling rate was good at 75.5 ± 8.4% for the 200 plug tray and 72.5 ± 4.1% for the 162 plug tray. The net formation ratio of matured seedling was the best in 60 days of seeding in 162 plug trays. The rooting rate was 98.0 ± 2.1 - 99.3 ± 1.2% when seeded for 60 days or more regardless of the type of plug tray.
Conclusion : In order to produce efficient and stable seedlings in the cultivation of Atractylodes macrocephala in Gangwon area, it was considered to be advantageous for 60 days of seedling settling in the plug trays of more than 162 and less than 200.
Background : Atractylodes macrocephala is a perennial herbaceous plant belonging to the family Asteraceae and should be cultivated in field soils with good water dripping due to plant characteristics. However, cultivating farmers mainly have recently been cultivated in paddy soil due to their regional characteristics, which causes the decrease in yield due to poor drainage. Therefore, this study was carried out to investigate the cultivation in high ridge and subsoil breaking effect for stable paddy soils cultivation technology of A. macrocephala.
Methods and Results : Soil was paddy soils in the fall of 2017, and the pH (1 : 5) was 6.61 ± 0.15 as a result of chemical and physical properties. EC was 0.49 ± 0.05 dS/m, and organic matter content was 28.69 ± 69 g/㎏ and effective phosphoric acid was 306 ± 17.8 ㎎/㎏. As a result of the soil layering survey, the surface layer was 0 - 26 ㎝ deep as paddy soil mounded with sandy loam in the past. In the surface layer, there was a light layer after 17 ㎝ depth, and volume density was 1.71 ± 1.3 g/㎤. The porosity of the plow pan was 33.41 ± 2.34%. The cultivation methods were cultivation in high ridge (30 ㎝ or more) and level row (10 ㎝ or less) at 2 levels and 3 repetitions. In subsoil breaking, the depth of the plow pan was increased from 17.1 ± 0.5 ㎝ before treatment to 31.1 ± 3.6 ㎝ after treatment and the hardness was 24.8 ± 1.5 ㎜. In the case of rotary plowing, the depth of the plow pan was 17.1 ± 1.9 ㎝ before treatment and 26 ± 2.4 ㎝ after treatment and the hardness was 25.8 ± 2.9 ㎜. The medium growth characteristics of A. macrocephala per treatment showed the tendency of increase in plant length, culm length, number of nodes, number of leaves, and fresh weight in level row cultivation after subsoil breaking. Root growth of cultivation in high ridge after subsoil breaking tended to be good with rhizome weight of 11.6 g per hill. The survival percentages were 98.8 - 100% and the bolting rate was 93.4 - 96.2%
Conclusion : In cultivation in high ridge after subsoil breaking in the paddy field of Gangwon area, the decrease of yield of A. macrocephala due to drainage was expected to be alleviated, but final conclusion should be drawn after analyzing soil temperature and soil moisture data.
Background: Atractylodes japonica Koidz. and Atractylodes macrocephala Koidz. belong to the family (Asteraceae). Their rhizomes, called white Atractylodes rhizomes, are used in traditional medicine. To address some issues with their cultivation, we recently developed eight hybrid cultivars by interspecific hybridization of A. japonica and A. macrocephala. This study was conducted to screen the hybrid cultivars that have high amounts of active ingredients and yield ability.
Methods and Results: Experiments were conducted using the eight hybrid cultivars and A. macrocephala (control cultivar) in the experimental field of the department of Herbal Crop Research located in Eumseong, South Korea. We investigated the growth characteristics of the aerial and underground parts. Among the cultivars, ‘Sanwon’ had the highest rhizome dry weight (53.8 g/plant), followed by ‘Dachul’ (50.0 g/plant). In addition, the content of atractylenolide I, II, III and total active ingredients were investigated using high-performance liquid chromatography. Compared with A. macrocephala, most of the inter-specific hybrid cultivars had a higher content of active ingredients and yield ability.
Conclusions: Through study, we established the superior quality of Atractylodes inter-specific hybrid cultivars. In particularly, it was found that ‘Dachul’ may be grown as a superior cultivar, with high amount of active ingredients as well as yield ability.
Background : During 2016 to 2017, Bacterial Rot symptom has been observed on Atractylodes macrocephala Koidz. in Yeongju-si, Mungyeong-si, Jecheon-si and Eumseong-gun. This experiment was carried out to identify pathogenic bacteria that has not been reported up to now from A. macrocephala and to test pathogenicity of isolated bacteria against A. macrocephala.
Methods and Results : Nine types of representative bacteria strains depending on colony size and color were isolated from surface disinfested symptomatic tissue that was macerated and streaked onto lysogeny broth (LB) medium with agar. Fungi were not recovered from any tissue that was surface disinfested and placed into acidified potato dextrose agar. Only one strain cause dark brown leaf rot symptom on A. macrocephala leaves soaked in bacterial suspensions. Potted A. macrocephala plants were used to test for pathogenicity. Inoculum was prepared by suspending the bacteria in sterile distilled water (SDW) for a final concentration of approximately 105 CFU/㎖. Suspensions were sprayed until runoff onto three replicate plants. Control plants were sprayed with SDW until runoff. Plants maintained in a dew chamber with 100% relative humidity at 30℃. After 3 days, leaf rot lesions developed on all inoculated plants; lesions later turned dark brown and appeared similar to symptoms observed in the field. Plants treated with water developed no symptoms. Same bacteria re-isolated onto LB from symptomatic tissues.
Conclusion : On the basis of 16S rRNA sequence analysis, the strain isolated from A. macrocephala was identified as Pseudomonas viridiflava. Biological assay method using Potted plants confirmed the pathogenicity of Pseudomonas viridiflava. This is the first report of bacterial rot caused by Pseudomonas viridiflava on A. macrocephala.
Background : Atractylodes japonica koidz (AJ) is a perennial herb that belongs to Atractylodes genus. The dried rhizome of AJ is known as ‘Baek-chul’. The ‘Baek-chul’ is used as important traditional medicine in north-east Asia. It is considered to be effective for the treatment of stomach disorder, virus, diuresis, inflammation, arthritis. AJ is heavily depend on import from china and only few studies have been carried out. In this study, we develop SSR marker to build a foundation of breeding, to analyze genetic diversity and to construct core collection.
Methods and Results : AJ resources was collected from each different place. To find simple sequence repeat (SSR) marker, we sequenced genomic DNA of AJ resources using Illumina HiSeq 2000 System. As a result of next generation sequencing (NGS), we obtained putative SSR loci. From these SSR primers, 553 SSR primer sets were designed successfully and confirmed polymorphism by in silico analysis. Nucleotide motifs ranged from tri- to penta-. Among these, 48 primer were tested in 4 individuals by capillary electrophoresis. Finally, selected 28 SSR marker were showed clear band and polymorphism by Electrophoresis.
Conclusion : In this study, we developed 28 polymorphic SSR marker using NGS, and it could be used for analyzing genetic diversity of A. japonica. These marker would be useful for breeding of new cultivar in the future.
Background : Bai Zhu (Atractylodes macrocephala Koidz.) has been generally harvested in 1-2 years after seedstock planting. Recently, seed is used increasingly for planting in spring and rhizome is harvested in 1 year. In 1 year open field culture, seed harvesting rate is low below 30% and supply and demand of seed is so hard. This study was carried out to improve seed harvesting for stable seed supply and demand in Atractylodes macrocephala Methods and Results : Seed of Atractylodes macrocephala Koidzumi was directly sown in open field, under tunnel and rain shielding condition in mid-April. Tunnel was installed from prebloom, mid-september to seed harvesting time, November using 240 ㎝ wires for 120 ㎝ by interval and 20 ㎝ by height in furrow to assure insect pollination and wind fertilization. In rain shielding condition, plant height was highest as 38.2 ㎝ and number of branches, number of nodes, and content of chlorophyll were higher as 7.8 ea/plant, 8.7 ea/plant, and 65.4 respectively compared to open field and under tunnel. Flowering time was earliest as 23rd September in rain shielding condition and in open field and under tunnel was 26th September. There is no blossom rot in rain shielding condition while blossom rot occurrence was highest in open field by 5 in degree. Seed setting rate was highest as 42.0% in tunnel cultivation and seed weight per plant and 1,000 seed weight were highest as 3.7 g/plant and 22.3 g respectively. Total seed yield was higher as 58% and 65% in tunnel and rain shield condition respectively compared to 29 ㎏/10 a of open field. Tunnel cultivation for seed production of Atractylodes macrocephala is more beneficial for lower installation cost. Conclusion : Tunnel cultivation for seed production of Atractylodes macrocephala is more beneficial due to low blossom rot degree by 1, higher 1,000 seed weight and seed setting rate as 19.0 g and 42%, increased seed yield, and lower installation cost.
Background: The roots of Atractylodes macrocephala Koidzumi contain atractylone, which is used to suppress appetite and indigestion caused by gastrointestinal disturbance. The present study was conducted to investigate the effect of several organic compost on the growth and root yield of A. macrocephala with organic fertilizer.Methods and Results:When organic fertilizer was applied basally, the average yield of 10 a was 184.6 ㎏ in the HA (Hwanggeumjidae, organic material mix), 171.3 ㎏ in the GG (Gyunbaeyangchegreen, bacterial cuture filtrate) and 175.0 ㎏ in the CF (Customary fertilization, control) each other in practice of CF had no statistical significance. Atractylenolide I was significantly greater in the HA (0.036%) than the GG (0.034%) or CF (0.023%). With regard to the amount of organic fertilzer, 10 a yield ws the most common of 203.0 ㎏ at 2.0 times of the organic 1 (HA), conventional fertilization of 134.0 ㎏ and 173.0 ㎏ of no application was a statistically significant. Organic fertilizer 1 was 1.5 to 2.0 times, organic fertilizer was 2 to 1.5 times that were most suitable.Conclusions:The results of the present study indicated that HA and GG are the most suitable for the organic cultivation of A. macrocephala. The content of atractylone I was highest under the HA treatment and lowest under the CU (Chamjoa, oil cake), TG (Totogreen, plant oil cake) and HG (Heuksalgreen, Castor oil cake) treatment.
Background : According to medicinal plant standard culture, flower organ should be removed but there is no detail information on flower organ removal in Atractylodes macrocephala Koidzumi. This study was carried out to examine effect of flower organ removal on the increase of roots yield in Atractylodes macrocephala Koidzumi. Methods and Results : ○ Experiment variety : Atractylodes macrocephala Koidzumi. ○ Treatment : ① Flower organ non-cutting ② Flower organ cutting ○ Planting date : April, 2015/ April 25, 2016 ○ Planting distance : 30×20cm/ 30×15cm ○ Experiment place : Ginseng & Medicinal Plant Research Institute(Geumsan-gun, Chungcheongnam-do) Conclusion : The fresh rhizome yield of F. O. C. at a bud treatments were increased 21.0% ∼50.0% compare to F. O. N. C. treatments. The fresh rhizome yield of F. O. C. at a flower treatments were increased 17.4%∼34.6% compare to F. O. N. C. treatments. The fresh weight of above-ground parts of F. O. C. treatments were decreased 77.2%∼65.7% compare to F. O. N. C. treatments. F. O. C.(=Flower organ cutting) / F. O. N. C.(=Flower organ non-cutting).
Background : Bai Zhu is generally harvested in 1-2 years after seedstock planting. Recently mainly in Guemsan, Bai Zhu is harvested in just 1 year after planting in spring . According to medicinal plant standard culture, Bai Zhu should be directly sown by 20cm distance in April. This study was carried out to find out proper planting date. Materials and Methods ○ Experiment variety : Bai Zhu (Atractylodes macrocephala Koidz.) ○ Treatment : Planting Date ① Late march ② Early april ③ Middle of april(control) ④ Late april Plantind density : ① 30×10cm ② ① 30×20cm ○ Planting type : Direct Seeding ○ Experiment place : Ginseng and Medicinal Plant Research Institute (Geumsan-gun, Chungcheongnam-do) Conclusion : Number of lateral branches in 30×10cm was more in late march than late April and aerial part growth was superior as planting date was earlier. Emergence rate was higher in middle of April and late April and aerial part weight, fresh root weight, dry root weight rate, and dry root weight were superior as planting date was earlier. Dry weight yield increased as 38.3% in late March compared to middle of April. Dry weight was havier as 36.2% in planting time of late March and early April than planting time of middle of April and late April. Total income was higher in planting time of late March and early April than planting time of middle of April and late April.
This study was carried out to determine the effects of light controls and leaf mold on root growth and physiological responses of Atractylodes japonica growing in forest farming. The experiment was performed by light controls (100%, 62.5%, 40.3% and 19.7% of full sunlight) and application of leaf mold to soil. Height, stem diameter, number of flower buds and root collar diameter were the highest in leaf mold within 62.5% of full sunlight (relative light intensity 62.5%). And these were the higher in leaf mold within each light level. As the shading level increased, light saturation point and maximum photosynthesis rate decreased. As the light level decreased, SPAD value increased in control and leaf mold. As a result of surveying the whole experiment, A. japonica was judged worse root growth under the lower light level. It was concluded that the light level was one of the most important factors to produce A. japonica. Also, producing high-quality of A. japonica with the price competitiveness by using leaf mold like the experiment can be an effective way to increase incomes for farmers.