• 한국수산과학회지
• /
• 제43권3호
• /
• pp.217-222
• /
• 2010

Two 15-week feeding trials were conducted to investigate how the rate and frequency of feeding affected the winter growth of olive flounder ($13^{\circ}C$). In the first experiment, triplicate groups of fish (initial mean weight $117{\pm}6.0$ g) were fed extruded pellets twice a day at feeding rates of 0.1, 0.25, 0.4, 0.55, and 0.57% (satiation) body weight per day (BW/d). The weight gain, specific growth rate, and feed efficiency increased significantly (P<0.05) with the feeding rates from 0.1 to 0.55% BW/d, but no significant differences in these parameters were found for fish fed diets of 0.55% BW/d and satiation. The moisture and ash contents of whole body of fish tended to decrease as the feeding rate increased, but the opposite trend was found for crude lipid content. In the second experiment, triplicate groups of fish (initial mean weight $117{\pm}6.3$ g) were fed extruded pellets to apparent satiation at the three different feeding frequencies: one meal 2 days, one meal a day and two meals a day. The weight gain and specific growth rate of fish fed one meal 2 days were significantly (P<0.05) lower than those of fish fed one or two meals a day, whereas no significant differences in the weight gain and specific growth rate were found between fish fed one and those fed two meals a day. Feed efficiency and condition factor were not significantly affected by feeding frequency. Based on these results, a feeding rate of 0.3% BW/d is recommended as maintenance feeding level, and the optimum feeding frequency is one meal a day with satiation feeding for the growth of olive flounder (117-147 g) during winter ($13^{\circ}C$).

• 청정기술
• /
• 제21권4호
• /
• pp.241-247
• /
• 2015

굴 패각은 한국 남쪽의 해안의 바다 양식 폐기물로써 처리문제로 대두되고 있다. 폐기물인 굴 패각을 실용화하기 위해서, 현지 회사에서 구입한 소성된 굴 패각(COS)에 AITC (allyl isothiocyanate)를 흡착시킨 후 식품 감염 질병을 일으키는 박테리아에 대해 성장억제능력을 시험하였다. COS 분말은 Escherichia coli, Staphylococcus aureus, Salmonella thyphimurium 균에 대해 1% 정도의 농도에서 세균 발육 억제 효과를 3에서 5 log 10 CFU/mL로 나타냄으로써 세균 발육 억제 효과를 보였으며, 순수 AITC의 MIC 결과는 Escherichia coli, Staphylococcus aureus, Salmonella thyphimurium에 대해 각각 1 mg/mL, 0.8 mg/mL 0.7 mg/mL을 나타내었다. 소성된 굴 패각은 소성과정에서 기공이 생성되어 225 mg/g의 AITC를 흡착하였고, FTIR 결과로 COS에 AITC가 흡착이 되었음을 확인하였다. 입자의 특성은 매우 미세한 입자 크기 및 높은 선상 표면을 나타내었다. AITC가 흡착된 소성된 굴 패각(ACOS)은 1% 농도에서 완전히 세균 세포를 억제함에 따라, ACOS는 COS보다 더 나은 항균활성을 나타냄을 확인하였으며, 이는 박테리아에 대해 AITC와 소성된 굴 패각의 상승효과가 있음을 나타내었다.

• 대한수의학회지
• /
• 제45권2호
• /
• pp.303-309
• /
• 2005

Olive flounder (Paralichthys olivaceus) is the major mariculture fish in Korea. The annual aquaculture production of olive flounder in Korea during the period of 2003 was 300,000 ton (2002 Statistics, Ministry of Maritime Affairs & Fisheries, Korea Government). Anesthetics is very necessary in aquaculture to minimize stress and damage during harvesting, grading, transportation, spawning induction and handling to fish. In the present study, isoeugenol as new anesthetic in marine fish, especially olive flounder, was examined to know the efficacy and proper concentration. As a result, olive flounder adult was exhibited sedation at 5 ppm at 10 and $15^{\circ}C$, and 7.5 ppm at $20^{\circ}C$, respectively. Anesthesia was required at least 10, 7.5 and 10 ppm at $10^{\circ}C$, $15^{\circ}C$ and at $20^{\circ}C$, respectively. In case of fry, the effect of sedation was observed from 2.5 ppm at $10^{\circ}C$ and 5 ppm at 15 and $20^{\circ}C$, respectively. Anesthesia was observed from 2.5 ppm at $10^{\circ}C$, 5 ppm at 15 and $20^{\circ}C$, respectively. In acute toxicity test, it was impossible to explore $LD_{50}$ with the concentration of isoeugenol adult at $15^{\circ}C$ used, but over immersion volume of 15 ppm at $15^{\circ}C$ was observed mortality in fry. Based on the present study, isoeugenol was identified as a safe and active anesthetic to olive flounder.

• 한국양식학회지
• /
• 제22권1호
• /
• pp.1-4
• /
• 2009

본 연구는 사료급이율이 여름철에 사육된 넙치 성어의 성장 및 체조성에 미치는 영향을 조사하고자 수행되었다. 최초 평균체중 535g의 실험어를 12개 수조(1.8톤)에 15마리씩 사료급이율 별 3반복으로 수용하여, 1일 2회 실험사료를 급이하며 10주간 사육하였다. 사료급이율은 만복(100%), 만복의 90%, 80%, 70%(어체중에 대한 일일 사료섭취율 기준)로 설정하였다. 사육기간 동안의 평균수온은 $19.2{\pm}2.8^{\circ}C$였다. 사육실험 후, 증체율, 일일사료섭취율 및 비만도는 사료급이율에 따라 유의한 차이를 보였으나, 생존률 및 사료효율은 모든 실험구간에 차이가 없었다. 증체율과 어체의 비만도는 일일 사료급이율이 증가함에 따라 증가하였으며, 만복의 90% 급이구는 만복 급이구와 유의한 차이가 없었으나, 80% 및 70% 급이구는 만복 급이구에 비하여 낮은 결과를 보였다. 실험 종료시, 실험어의 등근육과 간의 일반성분은 실험구간에 특별한 변화경향을 보이지 않았다. 본 연구의 증체율 및 비만도 결과로 볼 때, 여름철에 넙치 성어(535-928 g)의 적정 성장 및 비만도 유지를 위해서는 만복의 90%로 사료를 급이 하여도 좋을 것으로 판단된다.

• 환경생물
• /
• 제27권3호
• /
• pp.285-291
• /
• 2009

본 연구는 밀폐식 순환여과 시스템의 호흡측정실내에서 해수 및 담수사육 강도다리의 산소소비에 미치는 수온 영향을 조사하였다. 실험에 사용한 어류는 해수 및 담수에 각각 순화시킨 해수사육 강도다리(9마리, 평균체중 $263.0{\pm}40.4$ g)와 담수사육 강도다리(9마리, 평균체중 $265.8{\pm}34.8$ g)를 사용하였다. 수온 15, 20, $25^{\circ}C$에서 해수사육 강도다리의 산소소비량은 각각 $74.4{\pm}17.0,\;85.9{\pm}15.8,\;98.3{\pm}11.4\;mg\;O_2\;kg^{-1}hr^{-1}$, 담수사육 강도다리는 $46.7{\pm}12.0,\;63.3{\pm}7.5,\;82.6{\pm}5.3\;mg\;O_2\;kg^{-1}hr^{-1}$로 수온 상승 비례하여 증가하였다. 또한 수온 $15^{\circ}C$와 $20^{\circ}C$에서는 명기(09:00~21:00 hr)와 암기(21:00~09:00 hr)로 나누어진 광주기(12L : 12D)의 조건에서 해수 및 담수사육 강도다리 모두 명기에는 산소소비가 적고, 암기에는 산소소비가 많은 뚜렷한 일주리듬을 보였다. 하지만 수온 $25^{\circ}C$에서는 해수 및 담수사육 강도다리 모두 명기와 암기의 뚜렷하지 않은 산소소비 일주리듬을 보였으며, 수온 $20^{\circ}C$ 이상에서는 대사리듬이 흐트러지는 것으로 판단된다. 해수 및 담수사육 강도다리의 호흡률을 비교했을 때 담수사육 강도다리가 해수사육 강도다리보다 높았으나, 산소소비량은 해수사육 강도다리가 많았다.

• 한국양식학회지
• /
• 제20권2호
• /
• pp.114-120
• /
• 2007

육성기 넙치 사육용으로 부상배합사료 및 생사료의 사육효과를 비교하기 위하여 2회에 걸친 사육실험을 실시하였다. 실험 1에서는 평균체중 115 g의 넙치를 5종류의 실험EP ($EP1{\sim}EP5$v와 생사료(MP)로 78일간 사육 실험하였으며, 실험 2는 양식현장에서 평균체중 137 g의 넙치를 실험 1에 사용한 5종류의 EP ($EP1{\sim}EP5$), 시판사료(EP6) 및 EP4와 EP6에 물과 각종 영양소를 흡착시킨 2종류 흡착-습사료(MEP4 및 MEP6)로 80일간 사육 실험하였다. 사육실험 결과, 실험 1에서 증중율은 모든 EP 실험구가 MP 실험구와 유의한 차이가 없었으며, EP4는 MP에 비하여 더 높은 값을 보였다. 사료효율은 EP4 실험구가 다른 실험구보다 유의적으로 높은 결과를 보였다(P<0.05). 등근육의 간과 수분함량 및 간의 지질함량은 실험구간에 유의한 차이를 보였다. 실험 2에서는 생존율은 $89{\sim}99%$의 범위로 양호한 결과를 보였다. 증중량은 EP4와 MEP4 실험구가 가장 높은 값을 보였으며, 그 다음으로 EP3과 MEP6 실험구가 양호한 결과를 보였다. 사료효율은 모든 실험구에서 108% 이상으로 양호하였으며, EP4, MEP4 및 MEP6에서 높은 값을 보였다. 이상의 결과들로부터, $114{\sim}350\;g$인 넙치에게 생사료를 기초로 제조된 MP를 공급하는 것 보다 영양소 균형이 잘 갖춰진 EP를 공급하여도 좋을 것으로 보이며, EP 공급시 물과 다른 영양소의 흡착과정은 불필요할 것으로 판단된다. 또한, MP와 상업용 EP 실험구에 비해 양호한 성장 결과를 보인 EP4는 MP 대체 실용사료로서 사용될 수 있을 것으로 기대된다.

• 수산경영론집
• /
• 제34권2호
• /
• pp.75-90
• /
• 2003

When we think of fundamental problems of the aquaculture industry, there are several strict conditions, and consequently the aquaculture industry is forced to change. Fish aquaculture has a structural supply surplus in production, aggravation of fishing grounds, stagnant low price due to recent recession, and drastic change of distribution circumstances. It is requested for us to initiate discussion on such issue as “how fish aquaculture establishes its status in the coastal fishery\ulcorner, will fish aquaculture grow in the future\ulcorner, and if so “how it will be restructured\ulcorner” The above issues can be observed in the mariculture of yellow tail, sea scallop and eel. But there have not been studied concerning seabream even though the production is over 30% of the total production of fish aquaculture in resent and it occupied an important status in the fish aquaculture. The objectives of this study is to forecast the future movement of sea bream aquaculture. The first goal of the study is to contribute to managerial and economic studies on the aquaculture industry. The second goal is to identify the factors influencing the competition between production areas and to identify the mechanisms involved. This study will examine the competitive power in individual producing area, its behavior, and its compulsory factors based on case study. Producing areas will be categorized according to following parameters : distance to market and availability of transportation, natural environment, the time of formation of producing areas (leaderㆍfollower), major production items, scale of business and producing areas, degree of organization in production and sales. As a factor in shaping the production area of sea bream aquaculture, natural conditions especially the water temperature is very important. Sea bream shows more active feeding and faster growth in areas located where the water temperature does not go below 13∼14$^{\circ}C$ during the winter. Also fish aquaculture is constrained by the transporting distance. Aquacultured yellowtail is a mass-produced and a mass-distributed item. It is sold a unit of cage and transported by ship. On the other hand, sea bream is sold in small amount in markets and transported by truck; so, the transportation cost is higher than yellow tail. Aquacultured sea bream has different product characteristics due to transport distance. We need to study live fish and fresh fish markets separately. Live fish was the original product form of aquacultured sea bream. Transportation of live fish has more constraints than the transportation of fresh fish. Death rate and distance are highly correlated. In addition, loading capacity of live fish is less than fresh fish. In the case of a 10 ton truck, live fish can only be loaded up to 1.5 tons. But, fresh fish which can be placed in a box can be loaded up to 5 to 6 tons. Because of this characteristics, live fish requires closer location to consumption area than fresh fish. In the consumption markets, the size of fresh fish is mainly 0.8 to 2kg.Live fish usually goes through auction, and quality is graded. Main purchaser comes from many small-sized restaurants, so a relatively small farmer and distributer can sell it. Aquacultured sea bream has been transacted as a fresh fish in GMS ,since 1993 when the price plummeted. Economies of scale works in case of fresh fish. The characteristics of fresh fish is as follows : As a large scale demander, General Merchandise Stores are the main purchasers of sea bream and the size of the fish is around 1.3kg. It mainly goes through negotiation. Aquacultured sea bream has been established as a representative food in General Merchandise Stores. GMS require stable and mass supply, consistent size, and low price. And Distribution of fresh fish is undertook by the large scale distributers, which can satisfy requirements of GMS. The market share in Tokyo Central Wholesale Market shows Mie Pref. is dominating in live fish. And Ehime Pref. is dominating in fresh fish. Ehime Pref. showed remarkable growth in 1990s. At present, the dealings of live fish is decreasing. However, the dealings of fresh fish is increasing in Tokyo Central Wholesale Market. The price of live fish is decreasing more than one of fresh fish. Even though Ehime Pref. has an ideal natural environment for sea bream aquaculture, its entry into sea bream aquaculture was late, because it was located at a further distance to consumers than the competing producing areas. However, Ehime Pref. became the number one producing areas through the sales of fresh fish in the 1990s. The production volume is almost 3 times the production volume of Mie Pref. which is the number two production area. More conversion from yellow tail aquaculture to sea bream aquaculture is taking place in Ehime Pref., because Kagosima Pref. has a better natural environment for yellow tail aquaculture. Transportation is worse than Mie Pref., but this region as a far-flung producing area makes up by increasing the business scale. Ehime Pref. increases the market share for fresh fish by creating demand from GMS. Ehime Pref. has developed market strategies such as a quick return at a small profit, a stable and mass supply and standardization in size. Ehime Pref. increases the market power by the capital of a large scale commission agent. Secondly Mie Pref. is close to markets and composed of small scale farmers. Mie Pref. switched to sea bream aquaculture early, because of the price decrease in aquacultured yellou tail and natural environmental problems. Mie Pref. had not changed until 1993 when the price of the sea bream plummeted. Because it had better natural environment and transportation. Mie Pref. has a suitable water temperature range required for sea bream aquaculture. However, the price of live sea bream continued to decline due to excessive production and economic recession. As a consequence, small scale farmers are faced with a market price below the average production cost in 1993. In such kind of situation, the small-sized and inefficient manager in Mie Pref. was obliged to withdraw from sea bream aquaculture. Kumamoto Pref. is located further from market sites and has an unsuitable nature environmental condition required for sea bream aquaculture. Although Kumamoto Pref. is trying to convert to the puffer fish aquaculture which requires different rearing techniques, aquaculture technique for puffer fish is not established yet.