TS Green Transport Info

TRUETRU

Volumetric investigation of the frontal-subcortical circuitry in patients with obsessive-compulsive disorder

Thesis (master`s)--서울대학교 대학원 :의학과 정신과학,2003.Maste

사건관련 기능적 자기공명영상을 이용한 강박장애 환자의 반응억제 이상과 관련된 뇌신경 회로망 연구

Thesis(doctors) --서울대학교 대학원 :의학과(정신과학 전공),2009.2.Docto

Development of Korea ocean renewable bioenergy using algae

한국해양과학기술원의 연구사업인 조류를 이용한 바이오에너지 자원화 기술개발 소개 및 행 후 방향 논의22othe

Mesoflavibacter zeaxanthinifaciens genome and its potential enzymes

Mesoflavibacter zeaxanthinifaciens strain S86 was isolated from coastal area of Chuuk State in Micronesia. The genome sequence of strain S86 was determined using 454 GS-FLX titanium sequencing. Also, we predicted useful genes from the genome such as saccharification enzymes (glucanase, xylanase and amylase etc.), bioactive enzymes (L-asparaginase and catalase etc.) and carotenoid synthesis enzymes. Here, we focused with beta-glucanase and L-asparaginase of M. zeaxanthinifaciens. Glucanases are involved in degradation of glucans. Recombinant beta-glucanase of M. zeaxanthinifaciens showed high active to several substrates such as laminarin, beta-glucan and lichenan which is a potential candidate for use in agriculture, drug, chemical and bioethanol industries. L-asparagianse is an enzyme that catalyzes the hydrolysis of asparagine to aspartic acid. The enzyme has potential effect to leukemic cell and some other suspected tumor cells. Recombinant L-asparagianse of M. zeaxanthinifaciens had strong active to asparagine which was highly increased activity and thermostablilty by manganese.e such as saccharification enzymes (glucanase, xylanase and amylase etc.), bioactive enzymes (L-asparaginase and catalase etc.) and carotenoid synthesis enzymes. Here, we focused with beta-glucanase and L-asparaginase of M. zeaxanthinifaciens. Glucanases are involved in degradation of glucans. Recombinant beta-glucanase of M. zeaxanthinifaciens showed high active to several substrates such as laminarin, beta-glucan and lichenan which is a potential candidate for use in agriculture, drug, chemical and bioethanol industries. L-asparagianse is an enzyme that catalyzes the hydrolysis of asparagine to aspartic acid. The enzyme has potential effect to leukemic cell and some other suspected tumor cells. Recombinant L-asparagianse of M. zeaxanthinifaciens had strong active to asparagine which was highly increased activity and thermostablilty by manganese.1

Marine Bio-energy Development Strategy for Sustainable Growth

Through this study on the navigation of current status and future prospects of the leading marine bio-energy industry, we derive the implications of the essential elements needed to execute strategy for the future development of green energy. The aim of this study was to estimate future prospects through the domestic and international markets of the marine bio-energy industry. Based on this, we can discuss the policy direction of R&D strategies for the marine bio-energy industries that will play a part in the future of our country’s green growth engines. A brief summary of the results of this study are as follows :First, marine bio-energy is almost the only alternative that can solve the energy crisis facing humanity from pollution and food shortages. Second, within the industrial market, the marine bio-diesel industry is expected to continue to grow for the foreseeable future. Third, when associated with power plants or industrial facilities, the marine bio-energy industry has achieved and can continue to achieve a level of greenhouse gas reduction for climate change. Finally, due to the public sector, marine bio-based technologies are expected to fail without government intervention in the market. This emphasizes the importance of active involvement from the government for the future growth of marine the biotechnology industries.y. The aim of this study was to estimate future prospects through the domestic and international markets of the marine bio-energy industry. Based on this, we can discuss the policy direction of R&D strategies for the marine bio-energy industries that will play a part in the future of our country’s green growth engines. A brief summary of the results of this study are as follows :First, marine bio-energy is almost the only alternative that can solve the energy crisis facing humanity from pollution and food shortages. Second, within the industrial market, the marine bio-diesel industry is expected to continue to grow for the foreseeable future. Third, when associated with power plants or industrial facilities, the marine bio-energy industry has achieved and can continue to achieve a level of greenhouse gas reduction for climate change. Finally, due to the public sector, marine bio-based technologies are expected to fail without government intervention in the market. This emphasizes the importance of active involvement from the government for the future growth of marine the biotechnology industries.22othe

Introduce of the Marine Global Earth Observatory (MarineGEO) project in Korea

Jeju Research Institute of Korea Institute of Ocean Science and Technology (KIOST) is participating in the Marine Global Earth Observatory (MarineGEO) project for the first time in Korea in cooperation with Smithsonian Institution from USA, Hong Kong University and Ryukyu University. The MarineGEO, directed by the Smithsonian Institutions Tennenbaum Marine Observatories Network (TMON), is the first long-term, worldwide research program to focus on understanding coastal marine life and its role in maintaining resilient ecosystems around the world. This project is a growing global partnership committed to 1) cataloguing nearshore marine biodiversity, 2) documenting how and why its changing, and 3) understanding the consequences of that change for ecosystem functioning and resilience using the Autonomous Reef Monitoring Structures (ARMS). The ARMS were developed during the Census of Marine Life (CoML) international initiative. Since the CoML, the ARMS project has expanded on a global scale and the ARMS have been adopted as a key biodiversity assessment tool by NOAAs National Coral Reef Monitoring Program (NCRMP) and Ocean Acidification Programs climate monitoring stations in the Pacific. KIOST installed ARMS in Jeju and Ulleungdo Island in August and September 2018, respectively. We will also be installed in areas where environmental problems such as flatfish farms and sewage treatment plants are caused in Jeju Hong Kong University and Ryukyu University. The MarineGEO, directed by the Smithsonian Institutions Tennenbaum Marine Observatories Network (TMON), is the first long-term, worldwide research program to focus on understanding coastal marine life and its role in maintaining resilient ecosystems around the world. This project is a growing global partnership committed to 1) cataloguing nearshore marine biodiversity, 2) documenting how and why its changing, and 3) understanding the consequences of that change for ecosystem functioning and resilience using the Autonomous Reef Monitoring Structures (ARMS). The ARMS were developed during the Census of Marine Life (CoML) international initiative. Since the CoML, the ARMS project has expanded on a global scale and the ARMS have been adopted as a key biodiversity assessment tool by NOAAs National Coral Reef Monitoring Program (NCRMP) and Ocean Acidification Programs climate monitoring stations in the Pacific. KIOST installed ARMS in Jeju and Ulleungdo Island in August and September 2018, respectively. We will also be installed in areas where environmental problems such as flatfish farms and sewage treatment plants are caused in Jeju1

Marine Bio-energy Development Strategy for Sustainable Growth

Through this study on the navigation of current status and future prospects of the leading marine bio-energy industry, we derive the implications of the essential elements needed to execute strategy for the future development of green energy. The aim of this study was to estimate future prospects through the domestic and international markets of the marine bio-energy industry. Based on this, we can discuss the policy direction of R&D strategies for the marine bio-energy industries that will play a part in the future of our country’s green growth engines. A brief summary of the results of this study are as follows :First, marine bio-energy is almost the only alternative that can solve the energy crisis facing humanity from pollution and food shortages. Second, within the industrial market, the marine bio-diesel industry is expected to continue to grow for the foreseeable future. Third, when associated with power plants or industrial facilities, the marine bio-energy industry has achieved and can continue to achieve a level of greenhouse gas reduction for climate change. Finally, due to the public sector, marine bio-based technologies are expected to fail without government intervention in the market. This emphasizes the importance of active involvement from the government for the future growth of marine the biotechnology industries.y. The aim of this study was to estimate future prospects through the domestic and international markets of the marine bio-energy industry. Based on this, we can discuss the policy direction of R&D strategies for the marine bio-energy industries that will play a part in the future of our country’s green growth engines. A brief summary of the results of this study are as follows :First, marine bio-energy is almost the only alternative that can solve the energy crisis facing humanity from pollution and food shortages. Second, within the industrial market, the marine bio-diesel industry is expected to continue to grow for the foreseeable future. Third, when associated with power plants or industrial facilities, the marine bio-energy industry has achieved and can continue to achieve a level of greenhouse gas reduction for climate change. Finally, due to the public sector, marine bio-based technologies are expected to fail without government intervention in the market. This emphasizes the importance of active involvement from the government for the future growth of marine the biotechnology industries.22othe