Aquaculture Inputs
-
T1B™ Acqua S
aquaculture probiotics for vannamei and Penaeus monodon farming
T1B™ Acqua S
-
T1B™ Acqua F
aquaculture probiotics for fish farming
T1B™ Acqua F
-
T1B™ Feed Pro
gut/feed probiotics for shrimp and fish
T1B™ Feed Pro
-
T1B™ Bio Floc
aquaculture probiotics for biofloc farming
T1B™ Bio Floc
“Let’s talk about how we can work together
to make a difference in our shared world.”
Aquaculture FAQs
Water Quality Management: The use of the right bacteria can help to reduce the levels of ammonia, nitrite, and other harmful compounds in the pond water, which can improve water quality and promote the growth of shrimp.
Disease Control: Many bacteria are capable of producing various antibiotics and other compounds that can help to suppress pathogens and diseases that can infect shrimp.
Nutrient cycling: Bacteria are important for breaking down organic matter and releasing nutrients that can be used by shrimp and other aquatic organisms.
Feed conversion: Bacteria helps in breconvertf feed and convert’s it into a form that can be easily utilized by shrimp, which can improve feed conversion and reduce costs.
It’s worth noting that the specific benefits will depend on the type of bacteria used and the application method. Also, the bacterial product should be selected carefully, as not all bacteria are suitable for use in shrimp aquaculture.
Competitive exclusion is an important concept in aquaculture as it can be used to promote the growth of beneficial microorganisms in the aquatic environment while suppressing the growth of harmful microorganisms. This can help to improve water quality, animal health, and the overall sustainability of the aquaculture system.
Seaweed extract is a product that can be derived from certain types of seaweed and has a wide range of uses in aquaculture.
Feeding: Seaweed gel is a rich source of essential nutrients, such as amino acids, minerals, and vitamins, that can be used to feed a variety of aquatic organisms, including shrimps, fish, shellfish, and phytoplankton.
Fertilization: Seaweed gel can be used as a natural fertilizer to promote the growth of aquatic plants and phytoplankton, which are important food sources.
Water Quality Management: Seaweed gel can be used to improve water quality by removing excess nutrients and other pollutants from the water. This can help to reduce the risk of algal blooms and other water quality issues that can affect the health of the aquatic organisms.
Inducing spawning: Seaweed gel can be used to induce the spawning of aquatic organisms, such as shrimps, fish and shellfish, by adding it to the water.
Health and immunity: Seaweed gel contains compounds that can improve the health and immunity of aquatic organisms by supporting their growth, reproduction, and disease resistance.
Environmental friendly: Seaweed gel can be used as an alternative to chemical fertilizers and pesticides, and can help to reduce the environmental impact of aquaculture by promoting sustainable and natural methods of production.
It’s important to note that the effectiveness of using seaweed gel in aquaculture can vary depending
on the species of seaweed used, the conditions in which it is produced, and the concentration and
quality of the extract used.
Biofloc farming is an innovative method of aquaculture that utilizes beneficial microorganisms to create a sustainable and closed-loop system for raising fish and other aquatic animals. The system is based on the concept of creating a “biofloc” – a dense, microbial ecosystem that develops within the water column of the pond or tank.
In biofloc systems, fish/shrimp are raised in water that is rich in dissolved organic matter, which serves as a food source for the microorganisms that make up the biofloc. These microorganisms, which include bacteria, protozoa, and algae, are able to convert the dissolved organic matter into biomass, which can then be consumed by the fish/shrimp.
The biofloc also serves as a natural filtration system, helping to remove excess nutrients and pollutants from the water. The biofloc also helps to maintain water quality by providing a natural source of oxygen and by reducing the levels of harmful ammonia and nitrite. Biofloc farming is particularly suited to intensive aquaculture systems, such as indoor recirculating systems and pond-based systems, where it can be used to improve water quality, increase animal growth and survival, and reduce dependence on external inputs such as feed and chemical treatments.
Aquaculture that is sustainable focuses on supplying both the demands of the industry and the environment while responsibly and ethically raising aquatic creatures for food and other uses. This entails methods that enhance the development and productivity of aquatic species while reducing adverse environmental effects such water pollution, habitat damage, and overfishing.
Molting in shrimp farming refers to the process of shedding the exoskeleton, or outer shell, of a shrimp. This is a normal and natural process that occurs periodically throughout the life of the shrimp. During molting, the shrimp secretes enzymes to dissolve the old exoskeleton, then crawls out of it and forms a new one.
In shrimp farming, molting is an important event because it affects the growth and overall health of the shrimp. The frequency and timing of molting can impact the growth rate, feed conversion efficiency, and disease resistance of the shrimp. Proper management of molting can help to optimize the growth and productivity of the shrimp.
Molting can also have a significant impact on water quality in the culture system. Shed exoskeletons can release a large amount of organic matter into the water, leading to changes in water chemistry and an increased risk of disease. To manage these effects, farmers may adjust the feeding regime or water quality to support the molting process.
By improving water quality and reducing stress, bio products can help to create a more favorable environment for molting to occur. This can lead to more frequent and successful molts, which can contribute to faster growth, improved feed conversion efficiency, and increased disease resistance in the shrimp.
High stocking density in shrimp farming can have negative impacts on shrimp production, health, and growth. Stocking density refers to the number of shrimp per unit of water, and high stocking density occurs when the number of shrimp is too high for the volume of water in the culture system.
Poor water quality: High stocking density can lead to a buildup of waste products, such as uneaten food and excrement, in the culture water. This can result in poor water quality, including high levels of ammonia, nitrite, and other toxic substances, which can harm the health of the shrimp.
Increased stress: Crowding can increase stress levels in the shrimp, which can suppress their growth, reduce feed conversion efficiency, and make them more susceptible to disease.
Spread of disease: High stocking density can also facilitate the spread of diseases and parasites, as infected shrimp can more easily transmit infections to other individuals in the culture system.
Poor feed conversion: Crowding can also reduce feed conversion efficiency, as the shrimp may have difficulty accessing food, or maybe competing for food with other individuals in the culture system.
Waste from the cultured species: Unconsumed food and excrement are just two examples of the waste products generated by the cultured species that can build up in ponds and lead to water pollution.
Feed usage: Feed used in aquaculture has the potential to pollute the environment. Unused feed and waste from feeding animals may sink to the bottom of a pond where they decompose and release nutrients and other toxins that can impair the quality of the water.
Insufficient water exchange: If water exchange is poorly managed, the pond may get stagnant and the water may become contaminated with trash and contaminants.
Runoff from surrounding areas: Runoff from surrounding areas, such as agricultural lands and urban areas, can also contribute to water pollution in the aquaculture pond. Runoff can contain pesticides, fertilizers, heavy metals, and other pollutants that can harm the water quality and the cultured species.
Use of chemicals: The use of chemicals in aquaculture, such as antibiotics, disinfectants, and algicides, can also contribute to water pollution. If these chemicals are not properly managed and disposed of, they can persist in the water and harm the environment and the cultured species.
Depending on the kind of shrimp being cultivated and the particular needs of the culture system, different types of soil can be ideal for shrimp aquaculture. However, some common traits of soils that are ideal for shrimp farming include:
- The soil should have sufficient permeability to permit appropriate water exchange and oxygenation.
- This aids in preserving good water quality and encouraging the farmed shrimp’s healthy growth.
Drainage: To avoid waterlogging, which can result in low oxygen levels and poor water quality, the soil should have sufficient drainage capabilities.
pH: For the majority of shrimp species, the soil should have a pH that is neutral to slightly alkaline, often between 7.0 and 8.5.
Nutrient Content: The soil should have adequate levels of nutrients to support the healthy growth of the shrimp
Salinity: The soil should be able to maintain the appropriate salinity levels for the species of shrimp being cultured.
In summary, the suitable soil type for shrimp aquaculture should have good permeability, drainage, a neutral to slightly alkaline pH, adequate nutrient content, and the ability to maintain the appropriate salinity levels for the species of shrimp being cultured.
Aquaculture places a high priority on seed selection because it significantly affects the system’s productivity and success. Here are some explanations for why aquaculture seed selection is crucial:
Genetics: Careful seed choice guarantees that the best genetic stock is applied in the culture system. The cultivated species may benefit from better growth, disease resistance, and general production as a result.
Size: Choosing the proper-sized seed can help promote uniform growth and appropriate stocking density. This may lessen competition for scarce resources like food and space and increase general production.
Health: Careful seed selection can reduce the likelihood that a disease will be introduced into the culture system. To provide a good culture environment, seeds should come from healthy, disease-free sources.
Seed Quality: In order to ensure that the cultured species are adapted to the circumstances of the culture system, it is important to choose quality seeds. As a result, the animals may live longer and grow faster while also experiencing less stress.
Cost: Carefully choosing seeds can lower costs for disease management, stocking and refilling, and other related expenses.
Like all aquatic species, shrimp have certain dietary needs for healthy growth and survival. The following are some essential nutrients for shrimp aquaculture:
Protein: As carnivorous aquatic creatures that consume other living things, shrimp need a lot of protein in their diet. Fishmeal is a high-quality protein source that can support healthy growth and survival. Shrimp rely on lipids as a significant source of energy and as a supply of critical fatty acids for healthy growth and reproduction.
Carbohydrates: While some species of shrimp can use them as a source of energy, they aren’t typically regarded as a necessary part of the diet.
Vitamins: Vitamins are crucial for the health and development of shrimp, particularly vitamins A, D, and E. The required vitamins may be provided by a well-balanced diet that uses a variety of feed items.
Minerals: Minerals including calcium, magnesium, and phosphorus are essential for the growth, development, and reproduction of shrimp shells.
Antioxidants: Antioxidants, including Vitamin C, can aid in immune system support and oxidative stress protection.