특정 선박의 조종성능이 실질적으로 제한되어 있는지 여부는, 특정한 선박을 기준으로 해당 선박의 기능적 특성과 운항 당시의 환경을 종합적으로 고려하여 판단하여야 하는 상대적 개념이다. 어로에 종사하고 있음으로 인해 조종성능이 실질적으로 제한되어 있는지 여부를 다른 선박이 명확히 판단하는 것은 용이하 지 않다. 따라서 해상교통안전법 제83조의 적용에 있어서는 특정 선박이 자신 의 항법상 지위를 정확히 판단한 후 이에 부합하는 등화 및 형상물을 표시하는 것이 무엇보다 중요하다. 다수의 재결에서 해양안전심판원은 통발조업 어선의 법적 지위를 어로에 종사하고 있는 선박으로 인정한 사례가 있지만, 일부 재결에서는 이에 반대되는 사례도 있다. 그러나 위와 같은 해양안전심판원의 재결 은 개별 사안에서 구체적 타당성을 고려한 심판원의 고민의 결과라고 해석하는 것이 타당하다. 어업실무상 통발조업에 사용되는 통발의 종류는 다양할 뿐만 아니라 규격화되어 있지 않다는 점과 통발을 사용하여 어획하는 어류도 다양하 다는 점을 고려하면, 유사한 성능을 가진 선박이 유사한 환경에서 통발조업을 하더라도 해당 선박의 항법상 지위에 관해 항상 동일한 결론이 도출된다고 보 기는 어렵다. 해양안전심판원은 일부 재결을 통해, 어로에 종사하고 있는 선박 의 판단기준으로서 사고 당시 선박의 침로나 속력의 변경 가능성 외에 적극적 인 피항동작으로 인한 어구 등의 손상 가능성을 고려하고 있다. 그렇다면 통발 조업 어선의 어로에 종사하고 있는 선박으로서의 지위에 관해서는 향후 심판원 의 재결을 통해 해당 문제에 대한 명확한 입장 표명이 요구된다.

This study analyzed the catch data of Chionoecetes japonicus in the offshore trap fishery from 2009 to 2022 to investigate the spatial distribution changes of fishing grounds in the East Sea. The results showed that the center of the fishing grounds consistently shifted offshore and northward from 2009 to 2020, but moved back towards the coastal areas since 2020. When comparing the catch of C. japonicus from the offshore trap fishery between 2009-2015 and 2016-2022, statistically significant differences were found (p<0.01). Analysis of the center of the fishing grounds revealed that they gradually shifted offshore while the fishing grounds were initially concentrated in the coastal areas of the East Sea. This suggests that the center of the fishing grounds moved offshore and northward as the C. japonicus in the coastal fishing grounds decreased. The shift of the fishing grounds back towards the coastal areas since 2020 is attributed to the increased operational costs due to the soaring fuel prices and the impact of the COVID-19 pandemic, which led to a decline in consumer demand for live seafood consumed in restaurants. Consequently, the offshore trap fishery for C. japonicus shifted their focus from offshore areas, which required higher operational costs due to increased fuel consumption and longer fishing times, to coastal areas, that were relatively less costly. This study is the first scientific results of its kind to investigate the formation of fishing grounds and annual changes in the fishing grounds of C. japonicus caught in offshore trap fishery in the East Sea from 2009 to 2022.

Extracellular traps (ETs), primarily composed of DNA and antibacterial peptides, are mainly secreted by neutrophils to inhibit pathogen spread and eliminate microorganisms. Recent reports suggest that microglia can also secrete ETs, and these microglial ETs are associated with various neurological conditions, including nerve injury, tumor microenvironment, and ischemic stroke. However, the components and functions of microglial ETs remain underexplored. Secretagogin (Scgn), a calcium-sensor protein, plays a crucial role in the release of peptide hormones, such as insulin, in endocrine cells; however, its function in immune cells, including microglia, is not well understood. Our study demonstrated that Scgn deficiency can lead to the formation of abnormal ETs. We hypothesized that this may involve the c-Jun N-terminal kinase-myeloperoxidase pathway and autophagy.

모기류는 흡혈을 통해 원충, 바이러스, 사상충 등 다양한 병원체를 보유하며 말라리아, 일본뇌염, 웨스트나일열, 뎅기열 등을 사람에게 매 개하는 위해성이 있는 위생해충이다. 이번 연구에서는 해외유입 모기류 감시를 위해 경상남도 고성군에 스마트 고공포집기를 설치하여 2022년 부터 2023년까지 모기류들을 모니터링하였다. 조사기간 동안, 총 3속 5종 43개체가 채집되었으며, 이중 삼일열말라리아를 매개하는 벨렌얼룩날 개모기(Anopheles belenrae)를 경남 지역에서 처음으로 발생함을 확인하였다. 본 연구에서는 스마트 고공포집기를 통해 해외에서 유입가능한 모 기류에 대한 실시간 모니터링이 가능함을 확인하였다.

This study employs Bayesian network analysis to quantitatively evaluate the risk of incidents in trap boats, utilizing accident compensation approval data spanning from 2018 to 2022. With a dataset comprising 1,635 incidents, the analysis reveals a mortality risk of approximately 0.011 across the entire trap boat. The study significantly identifies variations in incident risks contingent upon fishing area and fishing processes. Specifically, incidents are approximately 1.22 times more likely to occur in coastal compared to offshore, and the risk during fishing processes outweighs that during maintenance operations by a factor of approximately 23.20. Furthermore, a detailed examination of incident types reveals varying incidence rates. Trip/slip incidents, for instance, are approximately 1.36 times more prevalent than bump/hit incidents, 1.58 times more than stuck incidents, and a substantial 5.17 times more than fall incidents. The study concludes by providing inferred mortality risks for 16 distinct scenarios, incorporating fishing areas, processes, and incident types. This foundational data offers a tailored approach to risk mitigation, enabling proactive measures suited to specific circumstances and occurrence types in the trap boat industry.

코드린나방은 사과, 배, 복숭아 등 과실류를 비롯한 다양한 작물에 피해를 주는 해충으로써, 대한민국 식물방 역법상 금지해충에 속해있다. 검역실적으로는 2016년 6월에 1건, 2018년 6월에 2건이 모두 인천공항으로 수입된 우즈베키스탄산 양벚에서 검출되었다. 코드린나방은 국내 침입이 매우 우려되는 해충 중의 한 종으로써 한국, 일본, 대만을 제외한 거의 모든 온대지역에 분포하고 있다. 따라서 우리나라는 본 해충에 대한 정밀하고 지속적인 표적 예찰이 필수 불가결이다. 효과적인 예찰을 위한 페로몬 트랩 개발을 위해 다음 사항들을 고려할 수 있다. 우선 페로몬 성분비에 따른 유인력의 차이를 검정해 효과적인 성분비를 찾는 것이 중요한데, 그 방법으로는 GC-MS/MS 분석법을 통해 루어의 페로몬 구성비율을 분석한다. 이후 적합한 실험환경을 설정하고 페로몬 혼합 물을 적용한 여과지를 케이지에 달아 일정 시간 동안 여과지에 접촉한 횟수를 기록 후 통계분석을 통한 유의성 검정을 실시한다. 이어서 페로몬을 루어에 주입, 흡착시킨 후 페로몬 트랩을 현장에 설치해 포획된 수컷 성충 수를 조사해 효과적인 약량 및 루어형태 등을 선별하게 된다. 이를 통해 효과적인 코드린나방 트랩 개발을 위한 기초연구를 수행하고자 하며, 우리나라의 농업과 자연환경 보호에 기여하고자 한다.

Due to climate change and the rise in international transportation, there is an emerging potential for outbreaks of mosquito-borne diseases such as malaria, dengue, and chikungunya. Consequently, the rapid detection of vector mosquito species, including those in the Aedes, Anopheles, and Culex genera, is crucial for effective vector control. Currently, mosquito population monitoring is manually conducted by experts, consuming significant time and labor, especially during peak seasons where it can take at least seven days. To address this challenge, we introduce an automated mosquito monitoring system designed for wild environments. Our method is threefold: It includes an imaging trap device for the automatic collection of mosquito data, the training of deep-learning models for mosquito identification, and an integrated management system to oversee multiple trap devices situated in various locations. Using the well-known Faster-RCNN detector with a ResNet50 backbone, we’ve achieved mAP (@IoU=0.50) of up to 81.63% in detecting Aedes albopictus, Anopheles spp., and Culex pipiens. As we continue our research, our goal is to gather more data from diverse regions. This not only aims to improve our model’s ability to detect different species but also to enhance environmental monitoring capabilities by incorporating gas sensors.

The brown planthopper (BPH) and white-backed planthopper (WBPH), significant rice pests, cannot overwinter in Korea and primarily originate and migrate from Southeast Asia and China, where they cause considerable damage. These planthoppers, along with other pests, annually migrate to the Korean Peninsula. Monitoring their migration is essential for controlling their populations and maintaining agricultural productivity. Traditional monitoring methods often struggle with timeliness due to time and manpower constraints. To address this, we developed the Smart Aerial Net Traps (SANT) for immediate tracking of pests. The SANT system is installed in 43 locations across the country and has been used for over 10 years to track migrating insects. Our research shows that SANT is a more effective method for monitoring migratory pests compared to traditional methods. SANT enables real-time tracking of various migratory pests and can also be utilized in different areas, such as analyzing pest population changes and determining pest origins through the study of air currents.

The United States enforces the seafood import regulations so-called the Marine Mammal Protection Act (MMPA), and by 2023, all exports of aquatic products and processed fish products by fisheries which have not obtained an “Comparability Finding” from the National Oceanic and Atmospheric Administration will be completely banned. Therefore, to respond to the US MMPA, it is critical to identify technologies and methods used in worldwide for reducing bycatch of marine mammals. In particular, marine mammals are frequently caught in five fisheries (trawl, gill net, trap, stow net and set net) in Korea, which is facing a great challenge. This study presented bycatch reduction methods by five fisheries, classified the methods by country, and suggested appropriate reduction methods which can be applied in Korea.

솔알락명나방(Dioryctria abietella)의 유충은 잣나무 구과를 가해 하는데, 피해를 심하게 받은 구과 종자의 손실량은 20.3%이며, 잣나무에서 구과피해율이 평균 25.7%에 달하여(이성찬, 2014), 잣 생산에 막대한 영향을 미치고 있다. 잣나무에서 페로몬 트랩의 설치 높이에 따른 솔알락명나방의 유인 효과 조사를 위하여 고가작업차 를 이용하여 잣나무림 지상부, 수관하부, 수관중부, 수관상부에 페로몬 트랩을 설치하였다. 페로몬은 케이아이 피에서 구입 하여 사용하였으며 트랩은 델타트랩을 설치하였다. 4월 26일에 최초 설치를 시작하여 기상상황에 맞게 10~15일 간격으로 수거하여 유인된 개체수를 조사하였다. 5월 초순에 4개 개체가 채집되기 시작하였으며, 6월 하순에 136개체가 채집되어 최대 밀도가 채집되었으며, 이후 점차 밀도가 감소하다가 8월 부터 밀도가 다시 증가하였다가 8월 중순 이후부터 다소 감소하기 시작하였다. 6월 초순에는 채집개체가 전혀 없었는데 이는 5월 하순부터 잣나무 송화가루가 날리면서 끈끈이트랩을 오염시켜 끈끈이트랩의 접착력이 떨어진 것에 기인한 것 으로 판단되었다. 수고별 솔알락명나방 페로몬 트랩 유인효과는 채집된 개체의 99.0%가 수관 상부에서 채집되 었으며, 2개체만이 수관중부에서 채집되었다. 수관하부와 지상에 설치된 트랩에서는 전혀 채집이 되지 않아 페로몬 트랩의 설치 높이에 따라 유인 효과가 매우 다른 것으로 나타났다.

Machilus thunbergii (Laurales: Lauraceae, 후박나무) is planted as a street tree in Jeollanamdo and Jeju Island. Orthaga olivacea (Lepidoprate: Pyralidae, 제주집명나방) is known as a major pest of M. thunbergii. For managing O. olivacea by eco-friendly control method, the mating disruption would be expected. The sex pheromone of O. olivacea was identified as a mixture of (Z)-11-hexadecenyl acetate (Z11-16Ac), (Z)-11-hexadecenal (Z11-16Ald), and (Z)-11-hexadecenol (Z11-16OH) at a ratio of 100: 0.1:0.1 by Chinese research group. Before applying mating disruption, confirmation of its attraction in Korea was essential. The pheromone traps composed of Z11-16Ac alone and the blend of three components (100:0.1:0.1) were installed in Haenam, Jeollanamdo in 2021, and Jeju and Seogwipo, Jeju in 2022. In field attraction test, no O. olivacea was attracted to any trap. However, Mamesastra brassicae (Lepidoptera: Noctuidae), which was not intended, was caught in both years in the trap. Total of 19 in Haenam between September 23 and 30, total of 11 in Jeju between September 30 and October 28, and total of 108 in Seogwipo between September 15 and November 11 were caught to the trap lured with Z11-16Ac. While in the trap lured with the blend, total 1 and 6 were captured in Haenam and Seogwipo, respectively.

As increasing number of stray cats, it recently has more chance for stray cats to invade people area. Inevitably, the number of cases of inconvenience and damage caused by street cats is also increasing proportionally. Therefore, we investigated and analyzed the current status and implementation of TNR in Korea and suggested the direction in which Korea's policy should go. Domestic TNR has been implemented for about 20 years, but the ratio of stray cats to which TNR is applied insufficient and post-management after TNR is also insufficient. In the case of other countries, a large percentage of TNR is conducted by selecting TNR target cats based on scientific grounds and adoption or additional observation is carried out after TNR. Based on this strategy, the conditions for successful TNR need to expand the decision-making authority of veterinarians involved in TNR and actively invigorate subsequent solutions such as adoption. In addition, the policy should be improved in the way of expanding management and supervision after TNR through food service centers and shelters.