• 한국약용작물학회지
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• 제2권1호
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• pp.86-94
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• 1994

인삼(人蔘)의 광합성(光合成)이 콩보다 낮은 원인(原因)을 밝혀 인삼(人蔘)의 수량증대(收量增大)와 육종(育種)을 위한 기초자료(基礎資料)로 삼고저 자경종(紫莖種) 2년생(年生) 인삼식물(人蔘植物)에서 분리(分離)한 잎을 재료(材料)로 광합성(光合成)과 수분함량(水分含量), 기공식도도(氣孔植導度), 그리고 수분(水分) potential을 조사(調査)하고 콩과 비교(比較)하였다. 1. 동일(同一)한 광도(光度)에서 광합성(光合成)은 인삼(人蔘)이 콩보다 작았으며 광합성(光合成)에 대한 포화광도(飽和光度)도 약 $30{\mu}E\;/\;m^2\;/\;s$로 콩의 약 $800{\mu}E\;/\;m^2\;/\;s$보다 낮았다. 2. 분리(分離)한 잎에서 광합성(光合成)은 인삼(人蔘)이 콩보다 빠르게 감소(減少)하였으며 $20^{\circ}C$에서보다 $30^{\circ}C$에서 더 빨랐다. 또한 광합성(光合成)이 정지(停止)하는 시간(時間)도 인삼(人蔘)잎이 콩잎보다, $20^{\circ}C$에서보다 $30^{\circ}C$에서 더 짧았다. 3. 잎의 수분감소(水分減少速度)는 인삼(人蔘)이 콩보다 느렸고 광합성(光合成)이 정지(停止)되는 수분함량(水分含量)은 인삼(人蔘)잎(약$70{\sim}71%$)이 콩잎$(50{\sim}63%)$보다 높았다. 4. 수분함량(水分含量)파 광합성(光合成)과는 인삼(人蔘)과 콩 모두 온도(溫度)에 무관(無關)하게 각각(各各) 고도(高度)의 정(正)의 상관(相關)이 있었는데, 광합성(光合成)은 동일(同一)한 수분함량(水分含量)에서 인삼(人蔘)이 콩보다작았다. 5. 기공식도도(氣孔傳導度)와 광합성(光合成)과는 인삼(人蔘)과 콩 모두 두 온도(溫度)$(20^{\circ}C,\;30^{\circ}C)$에서 무관(無關)하게 고도(高度)의 정(正)의 상관(相關)이 있었으며, $20^{\circ}C$에서는 인삼(人蔘)의 기공식도도(氣孔傳導度) 범위(範圍)$(40mmo1\;/\;m^2\;이하)$에서 인삼(人蔘)과 콩의 광합성양(光合成量)은 비슷하였다. 6. 수분(水分) potential 엽수분함량(葉水分含量)이 동일(同一)한 조건(條件)에서 콩보다 인삼(人蔘)이 낮았으며, 수분(水分) potential과 광합성(光合成) 및 기공식도도(氣孔傳導度)와는 고도(高度)의 정(正)의 상관(相關)이있었다. 7. 이상(以上)의 결과(結果)를 종합(綜合)해 볼 때, 인삼(人蔘)의 광합성(光合成)이 타식물(他植物)보다 낮은 것은 기공식도도(氣孔傳導度)와 수분(水分) potential이 낮은 것과도 밀접(密接)한 관계(關係)가 있을 것으로 생각된다.

• Journal of Ginseng Research
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• 제8권1호
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• pp.57-64
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• 1984

In order to clarify an effect of seedling weight on the growth pattern of ginseng, seedlings ranged from 0.4g plant to 1.8g plant were transplanted, and then the characters of 5- and 6-year-old ginseng were investigated. The characters of root and leaf, such as length and diameter of main root, root weight, leaf area, and leaf dry weight of 5- and 6-year-old ginseng originated from large seedlings were superior as compared with those from small seedlings, and percentage of missing plant was increased with the increase of seedling weight. There were, however, no significant difference in stem length, stem dry weight, number of seeds per plant and number of palmate leaves and leaflets per plant in 5- and 6-year-old ginseng and these characters were not affected by the weight of seedings transplanted. Root field per unit area was higher in seedings of above 0.6g/plant than in small seedlings.

• Journal of Ginseng Research
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• 제20권1호
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• pp.78-82
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• 1996

In order to clarify effect of transplanting angle of seedling on shape and growth of ginseng root, ginseng of seedlings were transplanted with $60^{\circ}$ and $90^{\circ}$ respectively, and the root characters of 2-, 4- and 6-year-old ginseng were investigated. The length of main root with 45$^{\circ}$was above 7 cm (standard) but that of $60^{\circ}$ and $60^{\circ}$ was below 7 cm (standard). Number of good lateral root was above 2.3 ea for $45^{\circ}$, 0~$30^{\circ}$, but below 2.3 ea per plant for 60~$90^{\circ}$ respectively. Root fresh weight with $0^{\circ}$, $30^{\circ}$, $45^{\circ}$ was heavier than that with $60^{\circ}$ and $90^{\circ}$. Root disease infection rate was highest with $0^{\circ}$. There were, no significant difference in stem length, stem diameter, leaf area, comber of palmate leaves and leaflets per plant, ratio of missing plant, root diameter in 2-, 4- and 6-year-old ginseng.

• Bulletin of the Korean Chemical Society
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• 제31권7호
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• pp.2094-2096
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• 2010

• Journal of Ginseng Research
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• 제4권2호
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• pp.197-221
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• 1980

Habitat observation, cultural experience of old and present plantation, weather factors in relation to crop stand and water physiology of root and leaf were reviewed. According to habitat observation ginseng plants love water but plate wit talus well grow at drained place with high moisture content in air and soil while ginseng plants were not found in dry or wet place. According to cultivation experience ginseng plants require abundant water in nursery and main field but most old planters believe that ginseng plaints are draught-loving thus require little water. The experience that rain especially in summer i.e unfavorable might be due to mechanical damage of leaves arid leaf disease infection, or severe leaf fall which is caused by high air temperature and coinsided with rain. According to crop stand observation in relation to weather factors abunsant water increased each root weight but decreased total yield indicating tile increase of missing root rate. Rain in summer was unfavorable too. Though rain in June was favorable for high yield general experience that cloudy day and rain were unfavorable might be due to low light intensity under shade. Present leading planters also do loot consider the importance of water in main field. Water content is higher in top than in root and highest in central portion of root and in stem of top. For seedling the heavier the weight of root is tile higher the water content while it reveries from two years old. Water potential of intact root appeared to be -2.89 bar suggesting high sensitivity to water environment. Under water stress water content severly decreased only in leaf. Water content of leaf appeared to be 78% for optimum, below 72% for functional damage and 68% for perm anent wilting. Transpiration or curs Principally through stomata in lower side of leaf thus contribution of upper side transpiration decreased with the increase of intensity. Transpiration is greater in the leaves grown under high light intensity. Thus water content is lower with high light inte nsity under field condition indicating that light is probable cause of water stress in field. Transpiration reached maximum at 10K1ut The decrease of transpiration at higher temperature seems to be due to the decrease of stomata aperture caused by water stress. Severe decrease of photosynthesis under water stress seems to be principally due to functional damage which is not caused by high temperature and Partly due to poor CO2 supply. Water potential of leaf appeared to be -16.8 bar suggesting weakness in draught tolerance. Ginseng leaves absorb water under high humidity. Water free space of leaf disc is %mailer than that of soybean leaf and water uptake appears to be more than two steps.

• 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 $m{\mu}Ci/mg$).

• 한국약용작물학회지
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• 제23권4호
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• pp.292-297
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• 2015

This study was carried out to have the basic and applied informations relating to develop the cultivation methods and to increase the productivity and quality of ginseng. 1 to 6 year old ginsengs of Jakyung cultivar were cultivated and the content and synthetic amount of carbohydrates were investigated with different plant tissues, growth stages, and years old. The concentration of total carbohydrates at six year old ginseng including water soluble and water insoluble carbohydrates was about 18.9%, 42.9%, and 43,6% in leaves, tap roots, and lateral roots, respectively. Water soluble carbohydrate of tap and lateral roots was slightly decreased from August until September, and then increased on November, whereas its water insoluble carbohydrate was increased from August to September and then decreased on November. Comparing with the content of carbohydrates of 1 to 6 year old ginsengs, it was continuously increased from one year old ginseng until five year old ginseng, however it was not increased much in six year old ginseng. The highest content of carbohydrates was at five year-old in all tissues of ginseng. Water soluble and water insoluble carbohydrates were significantly shown different in leaves, stems, tap roots, and lateral root at different growth stages and with different years old. The content of water soluble carbohydrate in the leaves was remarkedly higher compared to that of water insoluble carbohydrate, while in the root the content of water insoluble carbohydrate was clearly higher compared to the water soluble carbohydrate. Comparing with the synthetic amount of carbohydrates, water soluble carbohydrates was higher in the shoot than that in the root, whereas water-insoluble carbohydrates higher in the root than that in the shoot. Carbohydrates which would be utilized in ginseng tissues for short and long-term periods as major energy were appeared differently in between shoot and root, with different growth stages, and years old.

• 한국작물학회지
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• 제32권2호
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• pp.157-162
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• 1987

인삼의 종 및 품종간 생리적 특성을 알기 위하여 볏짚 해가림하의 동일한 환경조건하에서 재배된 Panax ginseng C. A. Meyer 인 자경종, 황숙종, 미마끼, 소련재배인삼 그리고 Panax quinque folium L.인 미국삼을 광도, 온도, 시기별 광합성능력과 기공, 엽록소, 비엽중 및 지상하부 형질들을 조사하였던 바 그 결과를 요약하면 다음과 같다. 1. 광포화점은 자경종, 황숙종, 미마끼 및 미국삼이 15,000 lux 내외였고 소련재배인삼은 10,000 lux 내외였 다. 2. 광합성 최적 온도는 자경종, 황숙종, 미국삼 및 미마끼가 20 $^{\circ}C$ 내외였으나 소련재배인삼은 15$^{\circ}C$ 내외였다. 3. 광합성속도(생육기)는 미국삼이 7.8 mg($CO_2$/dm$^2$/h) 정도로 가장 높았고, 자엽종. 황숙종, 미마끼가 약 6~7mg($CO_2$/dm$^2$/h)였으며 소련재배인삼은 5mg($CO_2$/dm$^2$/h) 정도로 가장 낮았다. 4. 암호흡속도는 온도가 높아짐에 따라 달라지는 영향이었으나 종 및 품종간에는 비슷하였다. 5. 단위 엽면적당 기공수는 미국삼이 가장 많았고 소련재배인삼이 가장 적었으며 기공의 길이는 그 반대였다. 6. 엽록소함량은 미국삼이 가장 많았으며, 비엽중은 미마끼가 가장 높았다. 7. 2년근시 근중은 미국삼이 가장 무거웠고 소련재단인삼이 가장 가벼웠으나, 엽수는 자엽종, 황숙종, 미마끼가 많았고, 미국삼, 소련재배인삼 순으로 적었다. 8. 6년근주 근중은 자엽종, 황숙종, 미마끼가 가장 무거웠고. 미국삼 소련재배인삼 순으로 가벼웠으며, 엽수도 같은 경향이었다.

• 한국작물학회지
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• 제34권1호
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• pp.92-97
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• 1989

2년생 인삼에서 화경출현 개체와 비화경출현 개체를 구분 선정하여 이들 개체간의 년생별 생육 및 개화특성 그리고 형질간 상관관계를 비교 조사하여 화경출현 개체의 육종소재로서 활용성을 모색하고자 시험하였던 바 결과는 다음과 같다. 1. 2년생에서 화경출현 개체는 비화경출현 개체에 비하여 경장, 엽장이 크고 장엽수가 많으 개체군에서 화경출현률이 높았다. 2. 2년생 시 화경출현 개체는 3,4년생에서도 2년생과 같은 경향으로 비화경 개체에 비하여 지상부 생육이 양호하였고 염실률, 근량도 증가되었다. 3. 착과수 및 근종과 상관이 높은 지상부 형질은 경직경, 경장, 엽장, 장엽수 등이었다. 4. 2년생 화경출현 개체의 3년생 지상부 형질 상관은 2년생 비화경 출현 개체의 4년생 지상부 형질상관과 진상을 보였다.

• 고려인삼학회:학술대회논문집
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• 고려인삼학회 1984년도 학술대회지
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• pp.57-62
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• 1984

4년근 미국 인삼을 재료로 미국 North Carolina 소재 인삼포에서 대조군과 부초처리군으로 나누어 재배 시험을 수행하였다. 토양 산도(pH 4.4, 5.5, 6.5) 토양 인산(19, 89.232 ppm) 및 부초처리 (밀짚, 솔잎, 포프라나무 껍질 소나무 껍질 등을 상면에 피복) 재배가 개별 진세노사이드 함량에 미치는 영향을 조사했다. 각 시험구에서 재배한 인삼옆과 인삼근 조직을 H-PLC를 이용하여 5가지 진세노사이드($Rg_{1}$, Rd. Re, $Rb_{2},\;A_{1}$) 함량을 분석하였다. 각 피복재료중에서 떡갈나무 껍질로 피복 재배한 시험구가 인삼 생육 및 진세노사이드 함량이 전반적으로 좋은 경향을 보였다.