scholarly journals A Solution for Sustainable Utilization of Aquaculture Waste: A Comprehensive Review of Biofloc Technology and Aquamimicry

2022 ◽  
Vol 8 ◽  
Author(s):  
Ubair Nisar ◽  
Daomin Peng ◽  
Yongtong Mu ◽  
Yu Sun
Keyword(s):  
Water Exchange ◽  
Inorganic Nitrogen ◽  
Stocking Density ◽  
Microbial Interactions ◽  
Shrimp Culture ◽  
Formulated Diets ◽  
Biofloc Technology ◽  
Efficient Alternative ◽  
Wastewater Recycling ◽  
Supplementary Nutrition

Biofloc technology (BFT) is gaining traction as a strategic aquaculture tool for boosting feed conversions, biosecurity, and wastewater recycling. The significant aspect of BFT is aquaculture with highest stocking density and minimal water exchange. It not only improves the water quality of a system by removing inorganic nitrogen from wastewater but also serves as a suitable feed supplement and probiotic source for cultured species. This technology is commonly used for shrimp and tilapia culture and can be used for both semi-intensive and intensive culture systems. Biofloc, when combined with formulated diets, forms a balanced food chain that improves growth performance. Nutrients in this system are continuously recycled and reused and form an efficient alternative system in aquaculture. In addition to the reduction in water exchange, it is also considered as a bio-security measure, since it prevents entry of disease from outside sources. Aquamimicry is an innovative concept that simulates natural estuarine conditions by developing copepods that act as supplementary nutrition especially for shrimp culture. The review highlights the process, significance, and development of BFT, its microbial interactions, nutritional value, transition from biofloc to copefloc, and concept of aquamimicry to sustainably improve aquaculture production.

scholarly journals APPLICATION OF BIOFLOC TECHNOLOGY IN INTENSIVE FARMING AFFECTED PRODUCTION AND BLOOD PERFORMANCES OF THE CATFISH [Clarias gariepinus (Burchell, 1822)]

2016 ◽  
Vol 78 (4-2) ◽  
Author(s):  
Sri Hastuti ◽  
Subandiyono Subandiyono
Keyword(s):  
Water Quality ◽  
Growth Rate ◽  
Water Exchange ◽  
Heterotrophic Bacteria ◽  
Clarias Gariepinus ◽  
Stocking Density ◽  
Relative Growth ◽  
Intensive Farming ◽  
Biofloc Technology ◽  
Control Water

The biofloc technology can control water quality under negligible water exchange. The aim of this study was to evaluate the  effects of stocking density on production and blood performance of catfish (Clarias gariepinus [Burchell, 1822]). The catfish were reared in biofloc system (heterotrophic bacteria and addition of sugar for a period of 10 wk and used three levels of density i.e. (500, 1 000, and 1 500) fish per m2. The production increased with the increasing of stocking density, relative growth rate decreased with the increasing of that. The stocking density of 1 500 fish per m2 on the biofloc technology can support maximum catfish production, health and proper water quality.

Effect of stocking density on soil, water quality and nitrogen budget inPenaeus monodon(Fabricius, 1798) culture under zero water exchange system

2012 ◽  
Vol 44 (10) ◽  
pp. 1578-1588 ◽  
Author(s):  
Ramamoorthy Saraswathy ◽  
Moturi Muralidhar ◽  
Muniyandi Kailasam ◽  
Pitchaiyappan Ravichandran ◽  
Baijnatha Prasad Gupta ◽  
...  
Keyword(s):  
Water Quality ◽  
Soil Water ◽  
Water Exchange ◽  
Stocking Density ◽  
Nitrogen Budget ◽  
Exchange System

Seed production and grow-out of sand goby (Oxyeleotris marmoratus) in Vietnam.

2020 ◽  
Author(s):  
Van Khanh Pham
Keyword(s):  
Water Exchange ◽  
Feeding Rate ◽  
Stocking Density ◽  
Total Body Weight ◽  
Sand Goby ◽  
Fresh Food ◽  
Total Body ◽  
Marketable Size ◽  
Oxyeleotris Marmoratus ◽  
By Products

Abstract Pond area for broodfish ranges from 500 to 1,000 m2 with a depth of 1-1.2 m. Broodfish density ranges from 0.2 to 0.3 kg m-2. Fresh food such as snails, small prawns and fish are used to feed broodfish at a feeding rate of 3.5% of total body weight per day. Water exchange is done periodically at 20-30% of total volume per time. Sticky eggs of sand goby adhere to substrates. Hatching takes place 22-48 hours after fertilization. A suitable temperature is 28-29°C and pH at 6.5-7.5. Nursing fry to fingerlings is carried out in ponds at a stocking density of 300-500 fish m-2. After nursing for 50-60 days, they can reach the size of 3 cm. Large fingerlings of 15-30 g are obtained after at least 3 months of nursing. Continuing nursing up to 5-6 months gives larger fingerlings (60-80 g) for grow-out. Stocking density is 5-10 fish m-2 in grow-out ponds and 30-40 fish m-2 in cages. Fish, small prawns, snails and by-products from slaughterhouses are used to feed the fish. They can reach a marketable size of 500 g or more after 6-7 months of culture.

scholarly journals PENDUGAAN NUTRIENT BUDGET TAMBAK INTENSIF UDANG, Litopenaeus vannamei

2016 ◽  
Vol 1 (2) ◽  
pp. 181
Author(s):  
Rachmansyah Rachmansyah ◽  
Hidayat Suryanto Suwoyo ◽  
Muh. Chaidir Undu ◽  
Makmur Makmur
Keyword(s):  
Mass Balance ◽  
Litopenaeus Vannamei ◽  
Stocking Density ◽  
Nutrient Budget ◽  
Total Output ◽  
Shrimp Culture ◽  
Seed Supply ◽  
Total Input ◽  
Bottom Sampling ◽  
Assimilation Capacity

Penelitian ini bertujuan untuk mendapatkan nutrient budget tambak intensif udang Litopenaeus vannamei sebagai acuan alokasi input produksi pada tingkat kapasitas asimilasi lingkungan perairan. Pendugaan nutrient budget tambak udang intensif menggunakan pendekatan mass balance, dihitung berdasarkan input nutrien nitrogen - N dan fosfor – P yang berasal dari pakan, benih, pupuk, media probiotik, inflow, dan output nutrien yang ada pada produksi udang, outflow, dan endapan lumpur di dasar tambak. Sampel air, tanah, sedimen, plankton diambil sebelum penebaran dan setiap dua minggu selama pemeliharaan dari tiga petak tambak, masing-masing 5 titik sampel per petak tambak contoh. Analisis nitrogen dan fosfor dilakukan untuk sampel pakan, karkas udang awal dan akhir. Data managemen budi daya meliputi padat penebaran benur 50 ekor m-2, produksi 1.188—1.489 kg/0,25 ha, dan FCR 1,69—2,14; maka total input nutrien tambak udang Litopenaeus vannamei antara 171,9155—179,3778 (176 ± 3,9586) kgN dan 95,2533—99,4180(97,8340 ± 2,3348) kg P. Pakan mendominasi input N sebesar 61,96% ± 0,66%; disusul inflow 30,93% ± 0,70%; pupuk 6,52% ± 0,15%, serta media probiotik dan benur masing-masing <1%. Pola yang sama terjadi pada input phosphorous dengan komposisi 87,75% ± 0,24% dari pakan; 7,73% ± 0,19% pupuk; 4,05% ± 0,25% inflow dan media probiotik < 1%. Total output nitrogen tambak udang vannamei antara 107,1279-110,1438 (108,4957 ± 1,5274) kg N dan 51,6362—63,6576 (56,1292 ± 6,5604) kg P. Komposisi output nitrogen adalah outflow sebanyak 29,82% ± 3,20%; kemudian udang yang dipanen 21,32% ± 1,33%, lumpur atau sludge 10,40% ± 0,81%. Sedangkan komposisi output phosphorous didominasi oleh lumpur 39,03% ± 6,59%; kemudian udang yang dipanen 15,22% ± 0,85% dan outflow 3,09% ± 0,26%. Efisiensi pakan dan air melalui managemen budi daya yang benar menjadi peubah dominan penentu beban limbah tambak udang.This research was aimed to find out nutrient budget on L. vannamei intensive ponds as input allocation reference produce at environmental assimilation capacity level. Nutrient budget assessment was used mass balance approach, calculate based on nutrient input of nitrogen (N) and phosphor (P) from feed, seed, fertilizer, probiotic media, and inflow and nutrient output within pond yield, outflow, and sludge sedimentation at pond bottom. Sampling for water quality, sediment, and plankton was carried out at three ponds and five stations within each pond before stocking and continued fortnightly as long as culture periods. Nitrogen and phosphor analyzed for feed, and shrimp carcass of both of initial stocking and harvest. The data of culture management consist of shrimp yield reached 1,188—1,489 kg/0.25 ha with stocking density of 50 ind/m2 and FCR 1.69—2.14. Total input nutrients within L. vannamei ponds are 171.9155—179.3778 (176 ± 3.9586) kg N and 95.2533—99.4180 (97.8340 ± 2.3348) kg P. Food given domination on N input N with 61.96% ± 0.66% followed by inflow by 30.93% ± 0.70%, fertilizer 6.52% ± 0.15%, and both of probiotic media and seed supply less than1% respectively. There are the same pattern with phosphorous input with following composition 87.75% ± 0.24% from food, 7.73% ± 0.19% fertilizer, 4.05% ± 0.25% inflow and probiotic media less than 1%. Total output nitrogen from L vannamei ponds between 107.1279—110.1438 (108.4957 ± 1.5274) kg N and 51.6362—63.6576 (56.1292 ± 6.5604) kg P. Composition of nitrogen output is dominated by outflow 29.82% ± 3.20%, followed by shrimp harvest 21.32% ±1.33%, and sludge 10.40 ± 0.81%. Meanwhile, composition of phosphorous output dominated by sludge 39.03% ± 6.59%, shrimp harvest 15.22% ± 0.85% and outflow 3.09% ± 0.26%. Both food and water efficiency under good culture management are the mainfactors of waste load from shrimp culture ponds.

scholarly journals Influence of stocking density on water quality and growth performance of white leg shrimp (Litopenaeus vannamei) reared in fiberglass tanks, without water exchange

2019 ◽  
Vol 18 (06) ◽  
pp. 14-22
Author(s):  
Tu P. C. Nguyen
Keyword(s):  
Water Quality ◽  
Survival Rate ◽  
Growth Performance ◽  
Linear Relationship ◽  
Litopenaeus Vannamei ◽  
Water Exchange ◽  
Stocking Density ◽  
Quality Parameters ◽  
Final Weight ◽  
Ad Libitum

The present study evaluated the effects of stocking density on water quality parameters, growth performance and survival rate of white leg shrimp Litopenaeus vannamei, reared in fiberglass tanks, without water exchange. Three stocking densities (50, 100 and 200 shrimp/m2) were tested. Each treatment consisted of three replicates fiberglass tanks (500 L). The shrimp were fed ad libitum four times per day with a commercial pellet (40-42% protein). After an 8-week trial, concentrations of nutrients in the culture tanks showed an increasing linear relationship with increasing stocking density. The growth performance of shrimp in low stocking densities was significantly greater than that in high stocking densities. The results from this study demonstrate that with increasing the stocking density the production of shrimp increased but in a low final weight and survival compared to low stocking density.

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