산양삼은 산림청 특별관리 임산물로 지정되어 관리되고 있지만 체계적인 연구 나 표준 재배지침이 현장의 재배 현실과는 상이한 부분이 많은 실정이다. 이에 본 연구에서는 평창지역의 산양삼 재배지 환경조건에 따른 진세노사이드 함량이 어 떠한가를 알아보기 위하여 산양삼 시료를 각각 10본씩 채취하여 실험을 통해 확 인하였다. 산양삼 입지환경은 경사, 사면 방향, 해발고, 나무 종류, 흉고 직경과 수 고 등 모두 6가지를 조사하여 국립산림과학원의 분류기준을 참고하여 침엽과 활 엽으로 구분하였다. 산양삼 재배지의 토양산도를 포함한 9가지 토양이화학성 분석 에서는 전체적으로 침엽지역보다 활엽지역에서 높은 함량을 보였다. 통계분석 결 과에서는 A, B, C, 재배지에서 침엽과 활엽지역 간 통계적 유의성이 있는 것으로 나타났으며, D 재배지는 침엽과 활엽지역의 유의차가 거의 없는 것으로 나타났다. 진세노사이드 함유량 분석 결과에서는 Re, Rb1, Rg1의 순서로 높은 함량을 나타 내고 있어서 평창 산양삼의 주성분을 확인할 수 있었다. 연구 결과로 산양삼은 산 삼이 잘 생육할 수 있는 환경과 비슷한 곳을 재배지로 선정하여야 고품질의 제품 을 생산할 수 있다고 예상할 수 있다. 향후 본 연구 결과가 임업인 소득증대에 도 움을 줄 수 있는 자료로도 활용될 수 있기를 기대한다.

This study conducts a comparative analysis on the difference in profitability between organically cultivated ginseng and conventionally cultivated ginseng, based on their cultivation characteristics, in order to promote the production and consumption of organic ginseng. The production quantity of organically cultivated ginseng per 10 a was 40% less than that of conventionally cultivated ginseng for both four- and six-year-old roots. In the case of four-year-old roots, although the production cost of organically cultivated ginseng was 60% higher than that of conventionally cultivated ginseng, the net profit was higher by 70%, owing to its higher selling price. In the case of six-year-old roots, the production cost of organically cultivated ginseng was 10% higher than that of conventionally cultivated ginseng, but the net profit was lower by 10%, owing to a low selling price. The reduction in production costs must be supported by a reduction in land lease and labor costs by expanding the cultivation area, a reduction of pest control costs through the self-production of environmentally friendly materials, and an improvement in the certification of perennial crops that can reduce certification costs. A reduction in production costs can lead to a decrease in consumer prices, which, in turn, would promote an increase in consumption among general consumers. Moreover, as a measure to increase the production yield per unit area, the soil nutrient content must be increased by selecting high-quality planned sites and implementing planned site management in order to increase the proportion of organic fertilizers. Furthermore, these must be supported by improved cultivation methods, which suppress early defoliation, and enhanced cultivation technology. In addition to these methods, establishing producer cooperatives in order to expand production can stabilize supply, which can increase sales through export and processing companies. Moreover, uniformity in product quality through producer cooperatives can contribute to building consumer confidence.

본 연구는 인삼의 재배단계에서의 생물학적 위해요소를 조사하고 그 결과를 인삼 GAP 실천 모델의 개발을 위한 기초자료로 제공하기 위해 수행하였다. 충남 금산에 소재 한 인삼 경작지 3곳에서 재배환경, 작물, 개인위생 항목에 대해 총 96점의 시료를 수집하여 위생지표세균, 병원성미생물, 그리고 곰팡이에 대해 분석하였다. 일반세균과 대장균군, 곰팡이의 오염도는 각각 1.3~6.0, 0.1~5.0 및 0.4~4.9 log CFU/g (or mL, hand, and 100 cm2)으로 확인되었고, 대장균의 경우 C 농장의 농업용수에서 검출되었다. 병원성 미생물은 모든 시료에서 B. cereus만 0.1~4.9 log/g (or mL, hand, and 100 cm2)범위로 검출되었으며, L. monocytogenes, E. coli O157:H7, Salmonella spp. 및 S. aureus는 검출되지 않았다. 이상의 결과 인삼 경작지 3곳은 미생물학적 위해요소에 대해서는 안전한 것으로 나타났으나, 주변 환경이나 작업자들에 의해 교차오염이 발생할 가능성은 항상 존재하므로 보다 안전성이 확보된 인삼을 재배하기 위해서 미생물학적 위해요소의 관리과 포함된 GAP 모델의 적용이 필요하다.

산양삼 재배를 위한 기초자료를 제공할 목적으로 9개도 18 재배지를 대상으로 입지환경, 토양환경, 생육과정, 재배방법과 시기를 조사·분석하였다. 산양삼 재배 입지환경은 활엽수림, Ⅳ영급 기준 ha당 잔존본수 500∼1,000본, 해발 500 m 미만, 경사 25˚이하, 재배사면은 북, 북동, 동, 북서방향에서 주로 재배되는 것으로 나타났다. 토양은 유기물함량 3.43∼24.07%, pH 3.8∼5.7, 토성은 사토∼사양 토로 재배지 간에 많은 차이를 나타내었다. 생육과정은 발순, 개엽, 개화, 결실, 홍숙, 낙과, 낙엽까지 조사되어 평균 98일의 생육기간이 소요되었다. 재배방법은 파종과 이식 형태로 증식되고 있었으며, 파종은 개갑처리(발아촉진처리)와 직파형태로 파종하고 있으며 각각 70%, 30%로 처리되는 것으로 나타났다.

농생태계 인삼 경작 재배지에서 서식하고 있는 토양 생물상을 확인하기 위하여 전라북도 진안 6개 조사구의 인삼 재배 농가에서 조사하였다. 2008년 4월 부터 11월까지 채집하여 분류된 미소절지동물은 총 3,101개체였다. 이중 응애류 44.9%, 톡토기 50.1%, 기타 5.0%로 가장 많은 개체수가 출현한 장소는 분변토를 시용한 대조구, 4년근 순으로 나타났으며 월별 밀도소장은 4월, 5월 6월 순이었으며 7월, 8월은 낮은 밀도를 보였다. A/C 비

The aim of this study was to investigate the comparative growth characteristics and ginenoside contents of wild-simulated ginseng on different years (7 and 13-year-old) by monitoring soil properties of cultivation regions. Plant and soil samples were collected from 6 different cultivation regions. Soil organic matter (OM), total nitrogen (TN) and cation exchangeable capacity (CEC) were significantly higher in 13-year-old wild-simulated ginseng cultivation regions compared to 7-year-old wild-simulated ginseng cultivation regions. Growth characteristics of wild-simulated ginseng had shown significantly higher in 13-year-old wild-simulated ginseng compared to 7-year-old wild-simulated ginseng. Ginsenoside G-Rb1, Rb2, Rc, Rd, Re, Rf, Rg1 were significantly higher in 13-year-old wild-simulated ginseng than 7-year-old wild-simulated ginseng. According to the results of correlation analysis, soil OM, TN and CEC of the cultivated regions were positively correlated with the growth of wild-simulated ginseng. In addition, the root length of wild-simulated ginseng showed positive correlation with ginsenoside content. Hence, this study was able to investigate the correlation between growth and ginsenoside content of wild-simulated ginseng based on soil characteristics of the cultivation regions.

Ginseng (Pnanx ginseng C. A. Meyer) is famous worldwide, and is very important cash crop and medicinal herb in Korea. It takes four to five years to produce harvestable ginseng roots, and ginseng is attacked by several pathogens during cultivation. We investigated the disease rate caused by ginseng root rot from 6 years old ginseng cultivation fields (Chungnam; 9 fields, Chungbuk; 11 fields, Gangwon 5 fields). The highest disease severity was Dangjin D (2.9) and the lowest one was Gaesan C (0.6). Of the 625 isolations, 340 isolations were classified as Ilyonectria radicicola and Fusarium solani. Finally, genetic diversity of I. radicicola and F. solani was confirmed by sequence analysis. Among the I. radicicola group, I. mors-panacis, which is known as highly virulent pathogen, and I. liriodendri, I. robusta and I. cyclamicicola, which are weakly virulent pathogens, were identified. In the case of F. solani, it is divided into two groups, but it is necessary to conduct diversity research through genetic analysis and pathogenetic studies using various markers. Based on these results, it could be used as a basic data for control of ginseng root rot pathogens.

Background: The ginsenosides Rb1 (G-Rb1) and Rg1 (G-Rg1) are used as marker compounds, and are the principal bioactive compounds assessed in the quality control of white ginseng. This study was conducted to analyze white ginseng samples of different and to obtain useful data for the quality control of white ginseng. Methods and Results: The variation in the content of G-Rb1 and G-Rg1 was evaluated among 35 samples of 4-, 5-, and 6-year-old white ginseng. The content of both G-Rb1 and G-Rg1 did not significantly differ among ages, and the relative ratio of the maximum to the minimum content of these within ginseng of the same ages was more than two. However, the ratio of G-Rb1 to G-Rg1 content in the 5- and 6-year-old ginseng was significantly higher than that in the 4-year-old one. According to the ‘Ginseng industrial act’, the standard (w/w, %) minimum G-Rg1 and G-Rb1 content is 0.10% and 0.20% or more, respectively. Among the 35 samples examined, the content of G-Rg1 was found to be 0.124 - 0.399% with none being less than the standard level, while that of G-Rb1, was 0.147 - 0.595%, with 4 samples (11.4%) failing to meet the standard levels. The content of G-Rg1 and G-Rb1 did not show a constant relationship with the size of ginseng. Conclusions: In our study, the content of both G-Rg1 and G-Rb1 varied widely, and there was no significant difference among cultivation ages. The results of the present study might provide useful information for the quality control of raw ginseng and processed white ginseng using marker compound.

Background : This study was conducted to develop sustainable and safe ginseng cultivation facilities to cope with climate change and to save labor due to the decrease of labor force in rural areas. Methods and Results : In 2017, we designed the wide-shading facility which was unmanned and labor saving to cope with climate warming and decreasing labor force in farming area for stable and sustainable production of ginseng. The developed model is called model Ⅰ(Slope-shading facility, Gyeongsangbuk-do ARES), model Ⅱ (Slope-shading facility, Gyeonggi-do ARES) and Model Ⅲ (Roof-type shading facility, RDA, NIHHS, Department of Herbal Crop Research). The tested varieties were stem-violet variant, and the transplanting was done by using the 2-years-old seedlings on April 3, 2017 and the planting density was 90 plant/1.62㎡. A thermometer, a light meter, and a rain gauge were installed in the center of the facility on April 13, 2017 to measure the micro-weather in the facility. Micro-weather observations were made from April 14 to October 10, measuring temperature, humidity, light intensity, soil moisture content, water leakage, and wind speed. Surveys were carried out on June 20 and September 29, respectively. The maximum temperature in the facility was 2 to 3℃ lower than the outside, but the relative humidity was 2 - 3% higher in the facility than in the outside. Soil moisture did not show a clear trend among the models. The light transmittance was 5 - 10% and it was the highest in model I, where the height of the shading facility was the highest. Rain leakage was 10 - 36%, the most in model Ⅱ. The amount of leaks increased with the amount of precipitation per hour. In all models, ginseng stem and leaf were damaged due to excessive water leakage. On July 10, stem and leaf were grown well only in wide-shading facility where leakage was adequately blocked with double-sided film. The average wind speed was less than 1.6 m/s during the survey period. The maximum wind speed was 8.8 m/s or less, which did not affect the deformation of the wide-shading facility. In all models, there was no difference in growth of aboveground part and root. Conclusion : As a result, in order to grow ginseng continuously and stably using wide-shading facilities, it is considered that the amount of leakage should be minimized by using material that can prevent leakage in cope with rainfall or heavy rain rather than wind-resistance.

Background : Recently, the shortage of first planted ginseng field has increased direct seeding cultivation in paddy. Therefore, the demand for the development of ginseng varieties suitable for direct seeding cultivation in paddy has increased. So the aim of this study was selection ginseng varieties and germplasms suitable for direct seeding cultivation in paddy. Methods and Results : We used 13 varieties and 191 lines of Korean ginseng (Panax ginseng C. A. Meyer) in this study. Ginseng Seeds were harvested at the end of July 2013, sown in mid-November, and were grown for four years in paddy. In 2017, the survey was conducted on 27 items of growth characteristics in accordance with the standards for survey of ginseng variety, and the degree of diseases and physiological disorders. Among ginseng varieties, the growth of Gopoong, Sunwon and Gwumjin were excellent. However, the incidence of physiological disorder was low in Gumpoong and Geumsun. Among the genetic sources, the growth of 7 ginseng lines, such as G04092, G04098, M05015, G07053, G10069 and G10093, were excellent. However, the incidence of physiological disorder was low in 10 lines of ginseng, such as G04020, G04061, G04081, G04092, G05054, G07052, G07053, G10069 and G10093. Conclusion : This result suggests that 5 varieties and 10 lines of ginseng showed outstanding growths in paddy. In the future, we will review the characteristics of root and the content of ginsenosides of ginseng variety and elite lines.

Background : This study was conducted to investigate the effect of soluble silicate and germanium on the characteristics of soil and growth in ginseng (Panax ginseng C. A. Meyer) cultivated in blue-white plastic houses. Methods and Results : Seedlings (n = 63 per 3.3 ㎡) of Korean ginseng cultivar were planted on April 10, 2015. Shading material of plastic house [8 m (W) × 3.5 m (H) × 50 m (L)] was blue-white vinyl. From May to September of each year, 1,000 times diluted sol. of germanium and silicate and these mixed solutions were drenched once a month. The chemical properties of the soil are as follows : pH, EC, organic content, and P2O5 of the soil were within the proper range, and the Mg content of the Ex-cations was lower than the standard value in 3 treatments except treatment of germanium 1,000 times. The total nitrogen content was 0.13 - 0.14%, which was higher than the optimum value. The number of soil microorganisms (Actinomycetes etc.) was higher in the treatment than in the non-treatment of inorganic components. The photosynthetic rate of ginseng leaves was 2.25 μmole CO2/㎡/s in the non-treatment and 2.91 to 3.17 μmole CO2/㎡/s in the inorganic treated. The growth characteristics of the aerial parts (leaf and stem) of the ginseng plants were generally better than that of non-treatment. Especially, in the treatment with silicate 1,000 times showed better growth, leaf area and leaf width growth. The growth of the underground part (root weight etc.) were also better than non-treatment. Specially, at 1,000 ppm treatment with soluble silicate, the root length and diameter were longer and the weight was was 72.2 g per plant. The ginsenoside content of each treatment is under analysis. The disease incidence (Alternaria panax etc.) rate was 20.1% in the untreated and 6.4% to 10.0% in the inorganic components treatment. Conclusion : By soil drench of inorganic compononts such as soluble silicate in ginseng blue-white plastic house cultivation, the growth of the aerial and root parts in ginseng were more improved than non-treatment. There are a lot of soil microorganism and less disease.

Background : The insufficient soil moisture due to spring drought causes the germination rate of ginseng seeds to be remarkably lowered and the low seeding depth causes the roots not to be settled but remain in the surface soil containing moisture, resulting in the ill-shaped ginseng. Especially, in the case of paddy soil, the soil environment is often over-humidified or over-dried, resulting in high rate of occurrence of physiological disorders such as rough skin, yellow-colored root and red-colored root, etc. compared to the upland soil, requiring more care in managing the soil. Therefore, this study was conducted with the aim to investigate the effects of stamping treatment on the direct seeding cultivation in the paddy soil and to investigate the survival and growth characteristics according to the seeding method. Methods and Results : We investigated the effects of stamping on the emergency rate and growth by using rollers (15, 20, 25, 30 ㎏), and also investigated the growth characteristics according to the direct sowing methods (broadcast planting, motorized seeder, semi-automatic seeder, manual seeder, hoop-type seeder). In the emergency rate of 1-year-old ginseng group directly sowing and treated with trampling, the group treated with 25 ㎏ & 30 ㎏ showed the highest emergency rate & growth, and above-ground & underground parts growth of 1-year-old ginseng by sowing method, there was no significant difference between sowing methods, the emergency rate of motorized seeder and semi-automatic seeder was high. Conclusion : In the paddy soils, the 25 – 30 ㎏ stamping after direct seeding showed superior above-ground growth and emergency rate, and there was no significant difference in growth, but motorized seeder and semi-automatic seeder had a higher rate of emergency in 1-year-old ginseng.

Background: Dazomet are widely used as soil fumigant to solve soilborne problems, and the degradation intermediates are toxic to nematodes, fungi, bacteria, insects and weeds. Methods and Results: The effects of cultivation of green manure crop, maize before and after soil fumigation on the control of ginseng root rot disease were compared using soil where 6-years-old ginseng was harvested. Fumigant (dazomet) were used for soil fumigation in May and September, respectively. Maize was grown for soil management before and after soil fumigation. After May fumigation, the sowing date of maize was delayed by 15 days and thus its dry weight was decreased significantly. Maize cultivation after May fumigation increased pH but decreased EC, NO3, P2O5, and K significantly. Maize cultivation after May fumigation decreased fungi population and the ratio of fungi and bacteria. Growth of 2-years-old ginseng was improved and the incidence of ginseng root rot was significantly decreased by maize cultivation after May fumigation. After harvesting 2-years-old ginseng, the population of Cylindrocarpon destructans was not different between treatment of May and September, but Fusarium solani showed a significant increase in September fumigation after maize cultivation. Conclusions: Maize cultivation after soil fumigation was effective in inhibiting ginseng root rot by the amendment of mineral composition and microorganism in fumigated soil.

Background : This study was carried out to secure technology for stable production of ginseng by developing technology to reduce the high temperature in response to climate change. Methods and Results : Polyethylene film (PE film), scattering film and blue-white double-sided film (85% shading rate) were tested for ginseng rain-shielding materials. The shading materials used were a black shading net (90% shading rate) in the first, and an aluminum screen (40% shading rate) in the second. The first shading materials were installed on April 10 with PE film + black light shielding net, and scattering film + black light shielding net. As the treatment for high temperature injury relief, an aluminum screen was installed under a scattering film + black light shielding net and a blue-white double-sided film at a high temperature. The amount of transmitted light was 12.9% at scattered film, 14.5% at double sided film, and 12.5% at PE film when the primary rain-shielding material was covered. In secondary shading, scattering film + aluminum screen and blue-white double-sided film + aluminum showed 8.6% and 7.6% of light transmitting, respectively. In the case of temperature, the average temperature was lower than the outside temperature at the scattering film + aluminum screen, clear double sided film + aluminum screen and PE film recovery. The differences among the cultivars were significant in plant height, stem height, stem diameter, leaf length, leaf width and leaf area. There were significant differences in the plant height, stem height, leaf length, and leaf width between treatments, but there was no interaction effect between varieties and treatments. The interactions between treatments were found only in the number of brach root. Conclusion : High temperature damage was influenced by the amount of irradiation in the facility rather than the temperature, which was presumed to be due to the accelerated aging of the ginseng leaf as the light transmittance increased.

Background : This experiment was conducted to study the characteristics of Korean ginseng (Panax ginseng C. A. Meyer) growth by LED artificial light source in the plastic house using multi-stage cultivation facility and artificial soil. Methods and Results : Seedlings of Korean ginseng cultivar cultivated from 6:00 am to 6:00 pm by adjusting the ratio of 1 : 1, 2 : 1 and 3 : 1 for red light and blue light for the LED light quality test. Controls were tested by treating the white light (fluorescent lamps) for the same time. The average temperature inside the plastic house remained above 25℃, then below 25℃ after mid-August and below 20℃ after mid-September. The temperature near the roots of the artificial soils was higher than 26℃ in late July and early August and lowered to 20℃ or lower in all treatments in September. The pH of the soil was in the standard range, but the EC value was 2.89 in the soil before the test and 5.83 in the white light treatment, higher than the standard range of 1.0. The light intensities were 95.3 μmol and 94.9 μmol in the 3 : 1 and 2 : 1 ratios of red and blue light, respectively. The photosynthetic rate was 1.72 μmole CO2/㎡/s in 3 : 1 treatment and 1.9 times higher than white light treatment. As the red light ratio increased, the light amount and photosynthetic rate increased. Growth characteristics of aerial parts (plant height, leaf length etc.) by LED irradiation were longer than that of white light treatment in the 2 : 1 or 3 : 1 treatment of red light and blue light. The root length was the longest at 13.7 ㎝ in the 3 : 1 treatment of red and blue light, taproot length were 6.9 ㎝ and 6.6 ㎝ in the 2 : 1 treatment and 3 : 1 treatment, respectively, longer than 4.3 ㎝ in white light. Root fresh weight was the heaviest (3.6 g/plant) in 3 : 1 treatment for red and green lights. Conclusion : It was confirmed that the rate of photosynthesis of Korean ginseng was higher than that of white light treatment and the growth characteristics of aerial and root parts were excellent at the ratio of 3 : 1 of LED red light and blue light in plastic house using multi-stage cultivation facility and artificial soil.

Background : This study was conducted to investigate the effect of inorganic compounds (germanium etc) on the characteristics of growth and ginsenoside contents in Korean ginseng (Panax ginseng C. A. Meyer) cultivated in plastic houses. Methods and Results : The experiments were performed in the Jinan (elevation: 300 meters above sea level). Seedlings (n = 72 per 3.3㎡) of Korean ginseng cultivar were planted on March 23, 2015. Shading material of plastic house was blue-white vinyl. From May to September of each year, 500 and 1,000 times diluted solution of germanium and silicate and these mixed solutions were drenched once a month. The chemical properties of the soil are as follows : pH, EC, organic content, and P2O5 of the soil were within the proper range, and the Mg content of the Ex-cations was lower than the standard value in 3 treatments, including 500 times solution of silicate. The rate of photosynthesis in Korean ginseng leaves were 2.2 - 2.5 μmole CO2/㎡/s in germanium and silicate treatment than in the non-treatment (1.5 μmole CO2/㎡/s). In the mixed treatment of silicate and germanium, the growth characteristics of the aerial parts (leaf and stem) of the Korean ginseng plants tended to be higher and longer than the other treatments. In a mixed germanium and silicate treatment, the root length was 33.3 ㎝, diameter was 23.5 ㎜, and the weight was the best at 53.8 g. The ginsenoside content was 16.8 ㎎/g in germanium treatment, 16.3 ㎎/g in germanium + silicate treatment. These were 37% and 33% higher than the control, respectively. The incidence of disease such as Alternaria panax was less in the inorganic treatment than in the non-treatment, and the incidence of disease was significantly decreased in the treatment with germanium + silicate. Conclusion : By soil drench of inorganic ingredients in Korean ginseng plastic house cultivation, the growth of the aerial and root parts in ginseng were more improved than non-treatment and ginsenoside content was increased and decreased the incidence of disease.

Background : Currently sprout ginsengs are produced in extensive variations of cultivation times, methods and specifications that are different in each farm in Korea. Also, regardless the effective ingredient content of ginseng, overgrown sprout ginseng are distributed so that the quality standardization of sprout ginseng is urgently required. The sprout ginseng market is only a segment of the Korean ginseng market still. However, If development of processed products utilizing the functionalities is connected, the market may exponentially grow. Also, if the use of sprout ginseng is extended to productions of drinks, cosmetics, facial masks and others in the cosmetics and health functional food industries, the export competitiveness to the global market is expected to increase. Therefore, this study aims the quality standardization of sprout ginseng to secure the market competitiveness in Korea and overseas by examining the property change following the cultivation phases. Methods and Results : For the overground growing in green houses, the sprout ginsengs planted in early April and early June show to be better in growing than the ones planted in early August. For the underground growing, while no significance is found among the cultivation periods, the sprout ginsengs planted in early June are excellent in terms of the root length and the weight of overground portion. Also, according to the examination on the stem properties of 2-year grown sprout ginsengs in each cultivation time, a trend that, as the growing period is longer from 25 days to 35 days, 45 days and 95 days, the hardness, gumminess, chewingness and springiness of stem are higher. And, on the hardness, gumminess, chewingness and springiness of leaf, while no statistically significance is found in the growing periods from 25 days to 45 days, the 95-day sprout ginsengs show high figures referring that the leaves becomes tougher. Conclusion : In case of cultivating sprout ginsengs in a green house, cultivating in April - June is advantageous for the overground and underground growing. And, it is determined that cultivating sprout ginsengs for 35 - 45 days produces leaves and stems with the most excellent chewing textures felt by consumers when chewing.

Background : Panax ginseng C.A. Meyer belong to Panax species Araliaceae and a perennial plants. It grows in Far East Asia such as the Maritime province in Russia, the Manchuria reg ion of China, and the Korean peninsula. Panax ginseng C.A. Meyer is cultivated by seed sow ing or transplanting-culture, but seedling standing rate is as low as 50%. Therefore, it is impo rtant to increase seedling standing rate. This study was performed to research of plug-seedling cultivation techniques of Panax ginseng C.A. Meyer for increase of seedling standing rate. Methods and Results : Testing material, Panax ginseng C.A. Meyer seed, was sown on 5 kin ds of seedling trays (72, 105, 128, 162, 200 cells) in the middle of February 2016. It was gr own in the seedling green house in medicinal plant resources research department of Gyeongs angnam-do Agricultural Research and Extension Services. Four months after sowing, the seedli ng growth characteristics such as seedling standing rate and seedling withering rate were inves tigated. After transplanting in the mountain area of Hamyang-gun, growth characteristics of the root length, root weight, and other factors were investigated at the beginning of November. A s a result, seedling standing rates were 50.1% to 56.2% and seedling withering rates were 25. 2% to 35.9%. Among the five ports, the seedling standing rate of 105 cells and 72 cells was 56.2% and 55.7%, which were higher than others. In the case of 105 cells, however, seedling withering rate was 35.1% higher than that of 72 cells. Seedling leaf length and width were lo nger at 72, 105, 128 cells than at 162, 200 cells and seedling root length, root fresh weight and shoot fresh weight were the highest at 72 cells. Roughly, the more tray cells, the less se edling growth. After harvesting, among the five ports, root fresh weight and root dry weight per 1 hill of 128 cells were 0.36 g and 0.11 g, respectively, which were higher than those of other cells. Conclusion : The growth characteristics of Panax ginseng C.A. Meyer considering the seedling standing rate and seedling withering rate, among the five ports, 72 cells was most suitable. A mong the five ports, considering root fresh weight and root dry weight after harvesting, 128 c ells was most suitable.

Background : Replant failure of ginseng is caused by soil-born pathogens causing root rot such as Cylindrocarpon destructans and Fusarium solani. Dazomet are widely used as soil fumigant to solve soilborne problems, and the degradation intermediates are toxic to nematodes, fungi, bacteria, insects and weeds. Methods and Results : The effects of cultivation of green manure crop, maize before and after soil fumigation on the control of ginseng root rot disease were compared using soil of field where 6-years-old ginseng was harvested. Fumigant (dazomet) were used for soil fumigation in May and September, respectively. Maize was grown for soil management before and after soil fumigation. Maize cultivation after May fumigation was delayed the sowing day by 15 days, and the fresh and dry weight decreased significantly. Maize cultivation after May fumigation increased pH but decreased EC, NO3, P2O5, and K significantly. Maize cultivation after May fumigation decreased fungi population and ratio of fungi and bacteria. Growth of 2-years-old ginseng was improved and the incidence of ginseng root rot was significantly decreased by maize cultivation after May fumigation. After harvesting 2-years-old ginseng, the population of Cylindrocarpon destructans was not different among treatments, but Fusarium solani showed a significant increase in September fumigation after maize cultivation. Conclusion : Maize cultivation after soil fumigation was effective in inhibiting ginseng root rot by improvement of mineral composition and microorganism in soils.