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        검색결과 40

        21.
        2001.06 KCI 등재 구독 인증기관 무료, 개인회원 유료
        A survey of consumers' awareness and attitudes about food biotechnology was conducted during May through August of 2001 with a random sample of 750 Korean consumers. More than 70% of the respondents was exposed to some informations related to genetically modified (GM) foods. The greatest benefit of the development of GM foods was thought to be the remedy for the food shortage in the future. More than 90% of Korean consumers wanted GM foods labeled. About 20% of the respondents would buy GM foods voluntarily, whereas over 50% would not until they found out more. More consumers responded that they would not buy herbicide-tolerant GM soybean but buy vitamin-enriched GM soybean. It seemed to be that many Korean consumers do not make decisions of acceptance or rejection of GM foods not on the basis of biotechnology but on the basis of the words) used to describe the products, such as herbicide and vitamin. Only 4% of Korean consumers responded that GM foods were the greatest safety-threatening factor of Korean foods and that the most interested information on food labels was whether the food was produced by biotechnology.
        4,000원
        24.
        1998.06 KCI 등재 구독 인증기관 무료, 개인회원 유료
        막분리기술은 다른 분리기술에 비해 에너지절약형이며 또 비교적 대량으로 분리를 수행할 수 있다는 장점이 있어 근래 산업 현장에서 많이 이용되고 있다. 특히 mass separating agent를 사용하지 않고, 상변화를 수반하지 않는 순조건에서 실시할 수 있다는 특성으로 인하여 생물물질의 생산 및 회수에 있어서 막분리의 사용이 크게 증가하고 있다. 근래에 들어 막의 재지라 분리 module의 개발 등에 의해 fouling, 농도분극현상 등, 막분리의 근본적 문제점들이 많이 해결되고 있을 뿐 아니라, 기존의 조분리의 영역을 넘어서 정밀분리에로의 발전이 가시화되고 있다. 또한 생물분리기술의 추세인 복합분리와 동시분리의 측면에 있어서도 막분리의 응용성은 우수하여, 향후 생물공학 제품의 생산에 있어 막분리 기술의 역할은 막대할 것으로 사료된다.
        4,000원
        25.
        1995.05 KCI 등재 구독 인증기관 무료, 개인회원 유료
        In conclusion, tremendous potential exists for the application of animal biotechnology to the beef industry, especially with the utilization of embryo cloning to produce genetically identical animals and genetic engineering to modify animal genomes to improve and /or create new phenotypes for many economically important traits. Research involving embryo cloning and genetic engineering of animals has been continuous now for over a decade, however inefficiencies in techniques have prevented large scale application. large numbers of identical cattle will some day be produced and producers will be utilizing transgenic cattle in their beef production programs.
        4,500원
        27.
        1992.12 KCI 등재 구독 인증기관 무료, 개인회원 유료
        Synthetic membrane processes are being increasingly integrated into existing reaction, isolation, and recovery schemes for the production of valuable biological molecules. In many cases they are replacing traditional unit processes. The properties of membrane systems which are most often exploited for both upstream and downstream processing and their permselectivity, high surface area per unit volume, are their potential for controlling the level of contact and/or mixing between two separate phases. Advances in both membrane materials and module design and operation have led to better control of concentration polarization and membrane fouling. After presenting some recent advances in membrane materials and fluid mechanics, we demonstrate how membranes have been integrated into cellular and enzymatic reaction schemes. This is followed by a review of established and emerging synergism between biological processes and synthetic membranes.
        4,000원
        28.
        2020.10 KCI 등재 서비스 종료(열람 제한)
        콩은 전세계적으로 재배되는 중요한 작물 중에 하나로 최근, 표준유전체 해독과 함께 유전적, 표현형적으로 다양성을 가진 한국핵심집단이 구축됨에 따라 유전체 기반 분자 육종 연구, 유전자 교정 기술을 활용한 새로운 육종 소재 개발 연구가 가속화 될 것으로 예상된다. 유전체 정보 기반 작물의 분자 육종 및 생명공학 연구를 통한 성공적인 작물의 개량을 위해서는 식물의 효율적인 조직배양 기술이 수반되어야 할 것이다. 그러나 반수체 생산, 원형질체 배양 및 형질전환 기술과 같은 콩의 조직배양 효율은 아직까지 높지 않고 일부 계통에 한정되어 이루어지고 있다. 본 논문에서는 콩의 분자육종 및 생명공학 기술의 적용을 위하여 다양한 콩 조직배양 기술에 관한 연구 동향을 분석하고 조직배양 효율에 영향을 미치는 요인들에 대한 정보를 제공하고자 하였다.
        29.
        2013.07 서비스 종료(열람 제한)
        Current agriculture encounters several challenges including increase in human population, increased meat consumption from income growth, climate change, and demand for healthier foods. Together this puts a tremendous strain on limited natural resources and on an increasingly fragile ecosystem. Today, 55% percent of habitable land is used for agriculture. Two-thirds (66%) of all annual fresh water withdrawals are used for irrigation. Energy is another vital input for agriculture productivity and experts are predicting increasing global competition for supply sources. Monsanto Company uses biotechnology, plant breeding, and agronomic solution to meet the increased food demand. In June 2008, we issued a three-fold commitment (produce more, conserve more and improve farmer’s lives for agriculture to be sustainable) that we call our Commitment to Sustainable Yield. Here, we present Monsanto pipeline to fulfill our commitment for sustainable agriculture.
        30.
        2013.07 서비스 종료(열람 제한)
        In 2012, the world population exceeded 7 billion and the need to address food security has never been greater. Achieving food security won’t be easy considering the megatrends of growing population, greater affluence, and increasing urbanization. Not only are more people demanding more food, but they want greater variety, including meat, dairy, fruits and vegetables. While demand for food is growing, farmers’ ability to increase productivity is facing unprecedented challenges. Scarcity of water, energy, and land is expected to define food production in the coming decades. Agricultural practices will also need to protect biodiversity through increasing productivity without expanding into natural ecosystems. Further exacerbating the situation is a changing climate that has led to higher temperatures and erratic weather patterns in some areas. Each day farmers face the challenge of growing more from less - increasing yields while protecting the environment by using less water, land, and energy. Global Agricultural Biotechnology companies like Syngenta have addressed these challenges through innovation in research and development by looking at the grower’s challenges holistically, including land, technology, and the community. The presentation will cover general R&D activities in an agricultural biotechnology company, which may differ from those in academic research institutes. Product safety and environmental considerations are integral to industry’s R&D work. To make earlier and better-informed decisions on which active ingredients or traits to move forward, normally companies begin safety trials early in the development process, facilitating timely engagement with regulators and other key stakeholders. Also to complement in-house expertise and bring in novel technologies which may or may not be used in agribusiness, companies are actively seeking value-adding partnerships and collaborations to bring exciting new offers to the grower. Development of a GM crop through all those activities mentioned above is quite a costly and lengthy process. My presentation will describe a typical process required for developing a GM crop in an agricultural biotechnology company from early discovery to commercialization to the market, which may give you a different perspective from academic point of view.
        31.
        2013.07 서비스 종료(열람 제한)
        During pathogen attack, the host plant induces genes to ward off the pathogen while the pathogen often induces host genes that increase susceptibility to the pathogen. Gene expression studies identified many soybean genes altered in expression in resistant and susceptible plant roots over time during infection by soybean cyst nematode (Heterodera glycines; SCN). However, it is difficult to assess the role and impact of these genes on resistance and susceptibility by using gene expression patterns alone, because the nematode injects proteins into the host. These nematode effector proteins interfere with and subvert the normal molecular mechanisms of the host cell. Therefore, we cloned >110 soybean genes from gene expression experiments using microarrays and RNA-Seq deep sequencing. The genes were overexpressed in soybean roots of composite plants to determine their impact on SCN development. Several overexpressed genes decreased the number of mature SCN females more than 50% at 32-35 days after inoculation; numerous other genes increased the number of mature females by more than 150%. Genes that reduced the number of mature females per plant by more than 50% when overexpressed, included genes encoding a β-glucanase, two lipases, calmodulin, a possible transcription factor, as well as proteins of unknown function. Four genes increased the number of mature SCN females more than 200%, while eleven more genes increased the number of mature SCN females more than 150%. Genes enhancing susceptibility included several transporters, pectate lyase, a Ca-dependent kinase and ACC oxidase. Our data support a role for auxin and ethylene in susceptibility of soybean to SCN. These studies highlight the contrasting gene sets induced by host and nematode during infection and provide new insights into the interactions between host and pathogen at the molecular level. Some genes that conferred resistance to SCN were also tested against the root-knot nematode (RKN), Meloidogyne incognita. Many of the genes that conferred resistance to SCN also conferred resistance to RKN. This demonstrated that the genes conferred resistance across genera and provides new strategies for developing broad resistance in plants to parasitic nematodes.
        32.
        2007.11 KCI 등재 서비스 종료(열람 제한)
        Plant germplasm resources are the plant materials containing useful inheritable characters of actual or potential value. Generally speaking, plant resources include cultivated and wild plants. China is a megadiversity country. A great lot of different complex climate environments in China such as dryness, wetness, clearness, clouding, shade, plain, hill, mountain, and so on, have gestated many Chinese endemic special plants. Some of them have special genes, such as resistance to drought, chilliness, disease, pests, and saltness etc, elite quality, high yield characteristics and so on. There are 470 families、about 3 7000 genus、more than 30 000 species of lichen, fern、seed plants in China. Special species in China involve 200 genus and about 10 000 species. Plant resources in China are conservated in situ and ex situ, by means of reforestation, regrassing, natural protection zones, arboreta, campus, parks, and institutes, etc. National Crop Gene Bank in Beijing, built in 1986, has 3200m2, two long-term rooms (T=-18℃±1℃, RH<50%) with the capability 400,000. There are more than 340,000 accessions in long-term banks of the National Crop Gene Bank of China, involving 35 families, 192 genus, 725 species. Among them, 80% are native to China. Up to now, there have been more than 210 main tree species for artificial forestation in China. Among them, there are more than 120 species for reforestation of barren slopes, deserts, and stony mountains. There are about 800-1000 Chinese traditional medicine plants, which were mainly conservated in situ and ex situ. The application of plant germplasm in China in plant biotechnology were reviewed on the following aspects: (1)Core germplasm construction by molecular marker technology (2)Plant germplasm preservation by biotechnology (3) Plant germplasm reproduction and industrialization by biotechnology (4) Elite gene discoverfrom plant germplasm by biotechnology (5) Plant germplasm in China and gene engineering technology. At last, some problems of plant resources in China were put forward.
        40.
        1990.03 KCI 등재 서비스 종료(열람 제한)
        The traditional plant imprownent methods consisted of pure line selection, cross breeding, heterosis breeding, polyploid breeding, mutati-onbreeding, ect.Biotechmoiogy is divided into gene spliclng , monocle-nal antibodies , protein engineering , agricultural research, and microbiological engineering. Of these , high plants deal with agricultural research, and the importent part of which is tissue culture and celLculture , Tissue .culture and cell culture are again divided into embryoculture, test tube fertilization, anther and pollen culture, somatichybridization , transformation, recombination, recombinant DNA moleculehybrid plasmid, ect For these haploid production, protoplast culture,protoplast fusion, selection and propagation, ect. , the technical sett-lement is needed.
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