Your search keyword '"aquaponics"' showing total 1,757 results

1. Growth, Ecophysiological Responses, and Leaf Mineral Composition of Lettuce and Curly Endive in Hydroponic and Aquaponic Systems.

Author

Vanacore, Lucia, El-Nakhel, Christophe, Modarelli, Giuseppe Carlo, Rouphael, Youssef, Pannico, Antonio, Langellotti, Antonio Luca, Masi, Paolo, Cirillo, Chiara, and De Pascale, Stefania

Subjects

SUSTAINABILITY, AGRICULTURE, SYNTHETIC fertilizers, CHLOROPHYLL spectra, NITRATE minerals, HYDROPONICS, AQUAPONICS

Abstract

Against the backdrop of climate change, soil loss, and water scarcity, sustainable food production is a pivotal challenge for humanity. As the global population grows and urbanization intensifies, innovative agricultural methods are crucial to meet rising food demand, while mitigating environmental degradation. Hydroponic and aquaponic systems, has emerged as one of these solutions by minimizing land use, reducing water consumption, and enabling year-round crop production in urban areas. This study aimed at assessing the yield, ecophysiological performance, and nutritional content of Lactuca sativa L. and Cichorium endivia L. var. crispum grown in hydroponic and aquaponic floating raft systems, with Oreochromis niloticus L. integrated into the aquaponic system. Both species exhibited higher fresh biomass and canopy/root ratios in hydroponics compared to aquaponics. Additionally, hydroponics increased the leaf number in curly endive by 18%. Ecophysiological parameters, such as the leaf net photosynthesis rate, actual yield of PSII, and linear electron transport rate, were also higher in hydroponics for both species. However, the nutritional profiles varied between the two cultivation systems and between the two species. Given that standard fish feed often lacks sufficient potassium levels for optimal plant growth, potassium supplementation could be a viable strategy to enhance plant development in aquaponic systems. In conclusion, although aquaponic systems may demonstrate lower productivity compared to hydroponics, they offer a more sustainable and potentially healthier product with fewer harmful compounds due to the reduced use of synthetic fertilizers, pesticides, and the absence of chemical residue accumulation. However, careful system management and monitoring are crucial to minimize potential contaminants. [ABSTRACT FROM AUTHOR]

Published

2024

2. Connection between the gut microbiota of largemouth bass (Micropterus salmoides) and microbiota of the aquaponics system environment.

Author

Yang, Guiqiang, Li, Wentong, Ma, Junfeng, Wang, Zhanquan, and He, Jie

Subjects

GUT microbiome, FISH ponds, LARGEMOUTH bass, FISH growth, AQUAPONICS

Abstract

The significant role played by the gut microbiota in fish growth, development, immunity, and overall health has been widely established. Nevertheless, there remains a lack of clarity regarding the interaction and origin between the environmental microbiota and the gut microbiota of aquaculture species within the aquaponics coupling system. Thus, we conducted an analysis of the gut microbiota of largemouth bass (Micropterus salmoides) obtained from an indoor enclosed circulating water aquaponics coupling system located in greenhouses in northern China. Additionally, we examined the microbiota of the fish pond water and tomato rhizosphere soil using high-throughput sequencing of the 16S rRNA gene. Our results demonstrated significant differences in the compositions of fish pond water, rhizosphere soil, and the gut microbiota of largemouth bass. Moreover, these compositions changed throughout the culture period. Approximately 11.99% of the bacterial composition in the gut microbiota of largemouth bass could be attributable to the rhizosphere soil microbiota, while 62.01% of the bacterial composition could be attributable to the fish pond water microbiota. However, the proportion of bacteria in the gut microbiota from the fish pond water microbiota remained respectively 40.90% and 56.15% in May and September, which increased markedly to 88.97% in July. Similarly, the proportion of bacteria in the pond water microbiota from the tomato rhizosphere soil microbiota were respectively 0% and 8.95% in samples collected in May and September, which increased markedly to 69.26% in July, and the proportion of bacteria in the gut microbiota from the tomato rhizosphere soil microbiota were respectively 0.07% and 0% in samples collected in May and September, which increased to 0.45% in July. The research results offer essential insights into the interactions and origins of environmental microbiota and gut microbiota in the aquaponics system of cultured fish. This knowledge could enhance green aquaponics practices for largemouth bass. [ABSTRACT FROM AUTHOR]

Published

2024

3. Deep Learning-Enabled Dynamic Model for Nutrient Status Detection of Aquaponically Grown Plants.

Author

Taha, Mohamed Farag, Mao, Hanping, Mousa, Samar, Zhou, Lei, Wang, Yafei, Elmasry, Gamal, Al-Rejaie, Salim, Elwakeel, Abdallah Elshawadfy, Wei, Yazhou, and Qiu, Zhengjun

Subjects

*CONVOLUTIONAL neural networks, *PLANT life cycles, *LETTUCE growing, *REFLECTANCE measurement, *SUPPORT vector machines

Abstract

Developing models to assess the nutrient status of plants at various growth stages is challenging due to the dynamic nature of plant development. Hence, this study encoded spatiotemporal information of plants within a single time-series model to precisely assess the nutrient status of aquaponically cultivated lettuce. In particular, the long short-term memory (LSTM) and deep autoencoder (DAE) approaches were combined to classify aquaponically grown lettuce plants according to their nutrient status. The proposed approach was validated using extensive sequential hyperspectral reflectance measurements acquired from lettuce leaves at different growth stages across the growing season. A DAE was used to extract distinct features from each sequential spectral dataset time step. These features were used as input to an LSTM model to classify lettuce grown across a gradient of nutrient levels. The results demonstrated that the LSTM outperformed the convolutional neural network (CNN) and multi-class support vector machine (MCSVM) approaches. Also, features selected by the DAE showed better performance compared to features extracted using both genetic algorithms (GAs) and sequential forward selection (SFS). The hybridization of deep autoencoder and long short-term memory (DAE-LSTM) obtained the highest overall classification accuracy of 94%. The suggested methodology presents a pathway to automating the process of nutrient status diagnosis throughout the entire plant life cycle, with the LSTM technique poised to assume a pivotal role in forthcoming time-series analyses for precision agriculture. [ABSTRACT FROM AUTHOR]

Published

2024

4. A Literature Review of Tilapia/Lettuce Aquaponics—Production Status, Varieties, and Research Gaps.

Author

Hussain, Aya S., Brown, Paul B., and Abdelrahman, Hisham

Subjects

*LITERATURE reviews, *NILE tilapia, *DIETARY proteins, *EVIDENCE gaps, *FISH feeds, *AQUAPONICS

Abstract

Tilapia and lettuce are the most frequently used combination among aquaponics producers, hobbyists, and educators. Therefore, this literature review aims to aggregate the knowledge on the current status of tilapia/lettuce production and identify research gaps. Among the 40 reviewed publications, 72.5% used Nile tilapia, 17.5% used red, 2.5% used red Mozambique, 5% used rocky mountain strain, and 5% of the articles stated that they used tilapia without reporting the species. Tilapia initial density used ranged from 0.34 to 28.4 kg/m3, which depended on the purpose of the study, experimental size, and design. For the hydroponic unit, 55% of the publications utilized deep water culture (DWC), 35% utilized nutrient film technique (NFT), and 10% utilized media bed (MB). The optimum ratio between fish feeding rate and plant growing area (60 g of feed/day/m2) was originally calculated at the University of Virgin Island and published in 1988 using Bibb lettuce. This recommended ratio has been used by farmers and researchers as a rule of thumb for years. However, this recommended ratio did not take into account other factors such as fish species, protein content of the diet, plant species/variety, plant density, biological filtration, and airflow in the grow bed. Hence, the current review suggests that the fish‐to‐plant ratio, fish density, and flow rate in the aquaponic systems needs to be reevaluated. As there is a thermal preference mismatch between tilapia and lettuce, there is a need to evaluate the optimum temperature for both to obtain the highest growth performance. Nowadays, it is believed that the farmed stocks' genetic quality needs to be regularly enhanced and protected. Consequently, feeding frequency, feeding amount, and stocking densities in aquaponic systems should be continuously reevaluated with the improved strains of tilapia as well as heat‐tolerant varieties of lettuce. [ABSTRACT FROM AUTHOR]

Published

2024

5. Making Aquaponics More Sustainable Using Worms and Water Replenishment Combined with a Sensing- and IoT-Based Monitoring System.

Author

Chandramenon, Praveen, Gascoyne, Andrew, Naughton, Liam, and Tchuenbou-Magaia, Fideline

Subjects

FOOD security, ENVIRONMENTAL quality, WATER quality, AQUAPONICS, INTERNET of things, VERMICOMPOSTING

Abstract

Aquaponics offers a simple conclusive solution to the food and environmental crisis around the world. This paper presents a comparative analysis of standard aquaponics with vermiponics (aquaponics with earthworms) before and after applying an optimal freshwater replenishment. Fish and plants were grown on a standard aquaponics testbed and a vermiponics testbed for 3 months each, initially without water replenishment, and then with 19% replenishment based on the fishtank volume. Water quality and environmental data were monitored, collected and processed using sensors and internet of things (IoT) devices. Daily growth analysis, the mean productivity of both testbeds before and after replenishment, the percentage of productivity difference and the general productivity comparison between standard and vermiponics testbeds were determined. Results showed an enhanced productivity of 2.83% and 5.54% for the standard testbed and the vermiponics testbed, respectively, when replenishment was applied. The yield improvement after replenishment was proven to be statistically significant, with p < 0.05 reassuring the impact of water replenishment. This research contributes to the understanding of the impact of water replenishment in aquaponics and vermiponics systems. Moreover, it provides insights into the effect of earthworms on both systems' yield productivity. [ABSTRACT FROM AUTHOR]

Published

2024

6. An Algorithm for Nutrient Mixing Optimization in Aquaponics.

Author

Kobelski, Alexander, Nestler, Patrick, Mauerer, Mareike, Rocksch, Thorsten, Schmidt, Uwe, and Streif, Stefan

Subjects

AQUAPONICS, SKILLED labor, PRODUCTION methods, WATER quality, PLANT development

Abstract

Featured Application: The algorithms provided in this work can be applied in most scenarios where fluids and water-soluble substances, e.g., salts, are mixed to meet certain requirements. Examples include hydroponics and aquaponics. Controlled environment agriculture is a promising alternative to conventional production methods, as it is less affected by climate change and is often more sustainable, especially in circular and recycling frameworks such as aquaponics. A major cost factor in such facilities, however, is the need for skilled labor. Depending on available resources, there are endless possibilities on how to choose ingredients to realize a desired nutrient solution. At the same time, the composition of the desired solution is subject to fluctuations in fish water quality, fertilizer availability, weather, and plant development. In high-evaporation scenarios, e.g., summer, nutrient solutions might be mixed multiple times per day. This results in a complex, multi-variable task that is time-consuming to solve manually, yet requires frequent resolution. This work aims to help solve this challenge by providing methods to automate the nutrient mixing procedure. A simple mass-balance-based model of a nutrient mixing tank with connections to different water sources, drains, and fertilizers is provided. Using methods of static optimization, a program was developed which, in consideration of various process constraints and optimization variables, is able to calculate the necessary steps to mix the desired solution. The program code is provided in an open-source repository. The flexibility of the method is demonstrated in simulation scenarios. The program is easy to use and to adapt, and all necessary steps are explained in this paper. This work contributes to a higher automation level in CEA. [ABSTRACT FROM AUTHOR]

Published

2024

7. Optimizing nutrient utilization, hydraulic loading rate, and feed conversion ratios through freshwater IMTA-aquaponic and hydroponic systems as an environmentally sustainable aquaculture concept.

Author

Goda, Ashraf M. A.-S., Aboseif, Ahmed M., Taha, Mostafa K. S., Mohammady, Eman Y., Aboushabana, Nevine M., Nazmi, Hani M., Zaher, Marwa M., Aly, Hadir A., El-Okaby, Mohamed A. S., Otazua, Nora Ibáñez, and Ashour, Mohamed

Subjects

*AQUAPONICS, *SUSTAINABLE aquaculture, *HYDROPONICS, *GRAY mullets, *FISH farming, *NILE tilapia, *AQUATIC animals, *PONDS

Abstract

Water quality in land-based fish production can be controlled through either instantaneous water exchange or costly wastewater treatment followed by recirculation. Agricultural-aquaculture integration is an excellent alternative technique for reducing nutrient discharge levels, boosting profitability, and converting fish culture wastewater into valuable products. The current study employed a solar energy system to power two separate IMTA-aquaponics systems (Nutrient Film Technique, NFT, and Floating Raft Systems, FRS) for the cultivation of Nile tilapia, African catfish, thin-lipped grey mullet, freshwater crayfish, freshwater mussels, and a variety of vegetables. Tilapia and catfish were fed exclusively on diets under the IMTA system. All wastewater from tilapia and catfish ponds, both dissolved and solid, flows sequentially to ponds containing other cultivated species. The water then flows through the IMTA system's terminal point to the NFT and FRS systems before returning to the tilapia and catfish ponds, allowing complete control of the nutrient flow throughout this entire circular system. Two 147-day production cycles were concluded. The results from the second production cycle are reported. Total biomass gain for aquatic species in the IMTA system was 736.46 kg, compared to 145.49 kg in the tilapia and 271.01 kg in the catfish monoculture systems. The current IMTA system had a cumulative feed conversion ratio (FCR) of 0.90, while the FCRs for tilapia and catfish were 1.28 and 1.42, respectively. Nile tilapia and catfish consumed 571.90 kg of feed containing 25.70 kg of nitrogen (N) and 9.70 kg of phosphorus (P), reflecting, and gaining 11.41 and 3.93 kg of dietary N and P, representing 44.40 and 40.46% dietary N and P retention, respectively. In the IMTA system, the addition of mullet and prawn as detrivores aquatic animals improves dietary N and P utilization efficiency to 59.06 and 51.19%, respectively, while the addition of mussels as herbivore animals improves dietary N and P utilization efficiency to 65.61 and 54.67%, respectively. Finally, using FRS and NFT as hydroponic systems increased dietary N and P efficiency to 83.51% N and 96.82% P, respectively. This study shows that the IMTA-Aquaponic system, as a bio-integrated food production system, can convert the majority of fish-fed residues into valuable products suitable for desert, rural, and urban areas in impoverished and developing countries. [ABSTRACT FROM AUTHOR]

Published

2024

8. A Systematic Literature Review on Parameters Optimization for Smart Hydroponic Systems.

Author

Shareef, Umar, Rehman, Ateeq Ur, and Ahmad, Rafiq

Subjects

*FRUIT growing, *AGRICULTURE, *VEGETABLE farming, *AQUAPONICS, *ARTIFICIAL intelligence, *HYDROPONICS, *EDIBLE greens

Abstract

Hydroponics is a soilless farming technique that has emerged as a sustainable alternative. However, new technologies such as Industry 4.0, the internet of things (IoT), and artificial intelligence are needed to keep up with issues related to economics, automation, and social challenges in hydroponics farming. One significant issue is optimizing growth parameters to identify the best conditions for growing fruits and vegetables. These parameters include pH, total dissolved solids (TDS), electrical conductivity (EC), light intensity, daily light integral (DLI), and nutrient solution/ambient temperature and humidity. To address these challenges, a systematic literature review was conducted aiming to answer research questions regarding the optimal growth parameters for leafy green vegetables and herbs and spices grown in hydroponic systems. The review selected a total of 131 papers related to indoor farming, hydroponics, and aquaponics. The review selected a total of 123 papers related to indoor farming, hydroponics, and aquaponics. The majority of the articles focused on technology description (38.5%), artificial illumination (26.2%), and nutrient solution composition/parameters (13.8%). Additionally, remaining 10.7% articles focused on the application of sensors, slope, environment and economy. This comprehensive review provides valuable information on optimized growth parameters for smart hydroponic systems and explores future prospects and the application of digital technologies in this field. [ABSTRACT FROM AUTHOR]

Published

2024

9. MALAMA: Cultivating Food Sovereignty through Backyard Aquaponics with Native Hawaiian Families.

Author

Chung-Do, Jane J., Hwang, Phoebe W., Ho-Lastimosa, Ilima, Rogerson, Ikaika, Ho Jr., Kenneth, DeMello, Kauʻi, Kauahikaua, Dwight, and Ahn, Hyeong Jun

Subjects

*FOOD sovereignty, *HEALTH of minorities, *HAWAIIANS, *PUBLIC health, *FOOD security

Abstract

Native Hawaiians were a healthy and robust population who developed a sophisticated food system that was dismantled by colonization. Currently, Native Hawaiians face pervasive health disparities due to the limited access to healthy foods and lifestyles. This study pilot tested a family-based community-driven intervention called MALAMA, which teaches families to build and use a backyard aquaponics system to grow their own food. A total of 21 participants from 10 families completed a three-month curriculum that included a series of hands-on workshops. Participant attendance was recorded and participants completed a behavioral health questionnaire as well as provided clinical indicators at three time points. They also attended a focus group at the end of the curriculum. There was a high level of engagement and no participant attrition. Fruit consumption among all participants significantly increased and there were favorable trends in blood pressure and fish and vegetable consumption. No significant differences were found in the other clinical indicators. Participants found MALAMA to be highly culturally acceptable and identified multiple benefits. Community-driven solutions, such as MALAMA, may be a promising approach to addressing pervasive health disparities and promoting health equity in minority and Indigenous communities. [ABSTRACT FROM AUTHOR]

Published

2024

10. Integration of IoT in Small-Scale Aquaponics to Enhance Efficiency and Profitability: A Systematic Review.

Author

Zamnuri, Muhammad Aiman Hakim bin, Qiu, Shuting, Rizalmy, Muhammad Akmal Arif bin, He, Weiyi, Yusoff, Sumiani, Roeroe, Kakaskasen Andreas, Du, Jianguo, and Loh, Kar-Hoe

Subjects

*SUSTAINABLE agriculture, *WATER quality monitoring, *FOOD supply, *SUSTAINABILITY, *FISH farming, *AQUAPONICS, *FISH stocking

Abstract

Simple Summary: The Internet of Things (IoT) can improve small-scale aquaponics, a sustainable farming method that combines fish farming with plant growing in water without soil, by making the process more efficient and profitable by optimizing resource use, closely monitoring water quality, and ensuring the best conditions for both fish and plants to thrive. Aquaponics is beneficial for the environment and can help ensure a steady food supply but presents challenges for small-scale farmers due to a lack of expertise in water chemistry and system upkeep, as well as high operational costs. Identified challenges in aquaponics operation include high water and energy costs, maintaining the right balance of fish and plants, and the risk of mosquitoes breeding in the water. This systematic review offers a comprehensive guide to setting up and maintaining an aquaponics system, including choosing the right fish and plants, designing the system, monitoring water quality, and feeding the fish. The importance of knowledge sharing among farmers is also highlighted to improve aquaponics practices. The integration of IoT into these systems can reduce the need for manual work and improve the availability of information related to system control, which could facilitate further adoption and optimization of aquaponics farming practices. Aquaponics combines aquaculture and hydroponics to offer a sustainable approach to agriculture, addressing food security issues with minimal environmental harm. However, small-scale practitioners face challenges due to a lack of professional knowledge in water chemistry and system maintenance. Economic hurdles, such as operational costs and energy-intensive components, hinder the viability of small-scale aquaponics. Selecting suitable fish and plant species, along with appropriate stocking densities, is crucial. Media Bed (MB), Deep Water Culture (DWC), and the Nutrient Film Technique (NFT) are commonly used hydroponic techniques. This study outlines optimal conditions, including water quality, temperature, pH, and nutrient concentrations, essential for symbiotic fish and plant cultivation. Integrating IoT technology enhances efficiency and profitability by optimizing resource utilization, monitoring water quality, and ensuring optimal growth conditions. Knowledge sharing among practitioners fosters innovation and sustainability through collaborative learning and best practices exchange. Establishing a community for knowledge sharing is vital for continuous improvement, advancing small-scale aquaponics towards a more efficient and sustainable future. [ABSTRACT FROM AUTHOR]

Published

2024

11. Mitigating the Accumulation of Mercury (Hg) and Lead (Pb) through Humic Acid Application under Aquaponic Conditions Using Watercress (Nasturtium officinale R. Br.) as a Model Plant.

Author

Lelesz, Judit Éva, Csajbók, József, Molnár, Péter István, Virág, István Csaba, and Kutasy, Erika Tünde

Subjects

LEAD, HEAVY elements, WATER quality management, COPPER, HUMIC acid, HEAVY metals, MERCURY

Abstract

In aquaponic farming, there is a potential risk that heavy metals will contaminate the water, which can lead to heavy metal accumulation in the plants. Our research investigated the accumulation of mercury (Hg) and lead (Pb) under aquaponic conditions and the effect of their increased presence on the uptake of other macro- and micronutrients using watercress (Nasturtium officinale) as a model plant. The potential modifying effect of humic acid on heavy metal accumulation was also investigated. Adding Hg and Pb increased the mercury and lead levels of the watercress plants to over 300 µg kg−1, while the addition of humic acid significantly reduced the concentration of both mercury and lead in the plants compared to plants treated with heavy metals alone, from 310.647 µg kg−1 to 196.320 µg kg−1 for Hg and from 313.962 µg kg−1 to 203.508 µg kg−1 for Pb. For Fe and Mn, higher values were obtained for the Hg + humic acid treatments (188.13 mg kg−1 and 6423.92 µg kg−1, respectively) and for the Pb + humic acid treatments (198.26 mg kg−1 and 6454.31 µg kg−1, respectively). Conversely, the Na, K, Cu levels were lower compared to those in plants treated with heavy metals alone. Our results demonstrated that watercress can accumulate mercury, leading to high levels, even above food safety standards, highlighting the importance of water quality control in aquaponic systems. Furthermore, these results suggest that watercress could be used as a natural filter in recirculation systems. The addition of humic acid significantly reduced the accumulation of heavy metals and altered the element content in the plant. [ABSTRACT FROM AUTHOR]

Published

2024

12. PV energy penetration in Saudi Arabia: current status, residential, and commercial users, local investment, use in modern agriculture

Author

Muhammad Zubair

Subjects

Energy policy, PV energy, aquaponics, energy economics, Engineering (General). Civil engineering (General), TA1-2040

Abstract

ABSTRACTSaudi Arabia is the largest country in the Middle East with huge solar energy resources but has achieved minimal adoption of photovoltaic energy systems (PV). This study investigates the potential of PV systems to address pressing challenges, including water scarcity and agricultural unemployment. This study addresses the deployment of PV in contemporary agriculture such as aquaponics and hydroponics to promote sustainable water, energy, and agricultural practices. Scrutinising national goals for PV energy against ground realities. The buyback tariff, interest rates of loans, and potential future power price increases are simulated to find suitable rates to encourage PV adoption. The current government grid purchase price is 1.87 cents USD/kWh, while the national grid selling price is 4.8 cents USD/kWh. Small-scale PV plants offer local investors passive income streams if financial institutes can offer these projects at lower interest rates. Investigating the country’s educational sector reveals the need for an overhaul in technical education for solar energy systems. The simulation shows that PV use in agriculture is economically feasible for large loads even with buyback rates as low as 1.87 cents USD/kWh. This research contributes by emphasising local involvement and proposing financial mechanisms, government reforms, and sustainable agricultural development in the region.

Published

2024

13. Insect pests and natural enemies associated with lettuce Lactuca sativa L. (Asteraceae) in an aquaponics system

Author

Tamara Machado da Silva, Francisco Jorge Cividanes, Fernando André Salles, Amanda Liz Pacífico Manfrim Perticarrari, Suzan Beatriz Zambon da Cunha, and Terezinha Monteiro dos Santos-Cividanes

Subjects

Aquaponics, Vegetable, Thrips, Aphid, Predator, Ladybug, Medicine, Science

Abstract

Abstract Although food is produced in aquaponics systems worldwide, no information is available on the occurrence of insect pests and natural enemies in aquaponic lettuce, Lactuca sativa L. In this study, a survey was carried out in an aquaponic system combining lettuce with lambari, Astyanax altiparanae (Garutti & Briski), aiming to determine the insect pests and natural enemies associated with this system. We also determined the predominant insect species and the effect of meteorological factors on their populations. Insect abundance was estimated by visual sampling during 13 cultivation cycles, totaling 27 sampling dates. The meteorological factors considered were air temperature and relative humidity, and their effects were determined using the Pearson correlation. The thrips Frankliniella schultzei (Trybom) and Caliothrips phaseoli (Hood) and the aphid Aphis spiraecola (Patch) predominated. Ambient temperature and relative humidity were essential factors affecting C. phaseoli and F. schultzei. The natural enemies found on the lettuce plants were the thrips Franklinothrips vespiformis (Crawford) and Stomatothrips angustipennis (Hood) and the ladybugs Cycloneda sanguinea L., Eriopis connexa (Germar), and Hippodamia convergens (Guérin-Méneville). These results constitute the first step for a lettuce-integrated pest-management program in aquaponics systems.

Published

2024

14. Nutrient‐efficient catfish‐based aquaponics for producing lamb's lettuce at two light intensities.

Author

Sebastião, Fernando, Vaz, Daniela C, Pires, Cristiana L, Cruz, Pedro F, Moreno, Maria João, Brito, Rui M M, Cotrim, Luis, Oliveira, Nelson, Costa, Ana, Fonseca, André, Rodrigues, Maria, Ispolnov, Kirill, Bernardino, Raul, and Vieira, Judite

Subjects

*LIGHT intensity, *LETTUCE, *CLARIAS gariepinus, *EDIBLE greens, *BOTANICAL specimens, *LAMBS, *AQUAPONICS

Abstract

BACKGROUND: Aquaponic systems are sustainable processes of managing water and nutrients for food production. An innovate nutrient‐efficient catfish‐based (Clarias gariepinus) aquaponics system was implemented for producing two cultivars of two leafy vegetables largely consumed worldwide: lamb's lettuce (Valerianella locusta var. Favor and Valerianella locusta var. de Hollande) and arugula (Eruca vesicaria var. sativa and Eruca sativa). Different growing treatments (4 × 2 factorial design) were applied to plants of each cultivar, grown at two light intensities (120 and 400 μmol m−2 s−1). During growth, several morphological characteristics (root length, plant height, leaf number, foliage diameter and biggest leaf length) were measured. At harvest, plants were weighed and examined qualitatively in terms of greenness and health status. Additionally, leaf extracts were obtained and used to determine total phenolic contents, antioxidant capacities, and levels of cytotoxicity to Caco‐2 intestinal model cells. RESULTS: After a 5‐week growth period, both lamb's lettuce cultivars presented high levels of greenness and health status, at both light intensities, particularly the var. de Hollande that also showed higher average performance in terms of plant morphology. In turn, arugula cultivars showed lower levels of greenness and health status, especially the cultivar E. vesicaria var. sativa submitted to direct sunlight during growth. In addition, plant specimens submitted to higher levels of light intensity showed higher contents in antioxidants/polyphenols. Cultivars with a higher content in antioxidants/polyphenols led to higher Caco‐2 cell viability. CONCLUSION: For successful industrial implementation of the aquaponics technology, different and optimized acclimatizing conditions must be applied to different plant species and cultivars. © 2024 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2024

15. A New Approach to Vertical Plant Cultivation Maximises Crop Efficiency.

Author

Ptak, Mariusz, Wasieńko, Sebastian, and Makuła, Piotr

Abstract

This publication presents an innovative tower cultivation device designed to significantly increase vertical farming's efficiency. The device divides the cultivation system into separate chambers. One division corresponds to the different growth phases of the plants, while another reflects the daily variation in conditions. Each chamber presents slightly different conditions and cultivation patterns from the others. For the early stages, crops are grown horizontally in trays; once they mature, they are transplanted into mobile cultivation towers. The closed circulation of ventilation and irrigation reduces water consumption by up to 95%. A unique separate day–night division optimises light, temperature, and humidity conditions, mimicking natural growth patterns. This approach not only saves water and energy but also improves cultivation in a three-dimensional space. The presented solution focuses on the often-overlooked aspects of cultivating in vertical farms and makes this method of growing much more cost-effective and feasible to implement on a large scale. Our comparative analysis with other vertical farming solutions is based on publicly available data and provides valuable insights, while acknowledging the potential limitations at play. [ABSTRACT FROM AUTHOR]

Published

2024

16. Life cycle assessment of a high-tech vertical decoupled aquaponic system for sustainable greenhouse production.

Author

Ravani, Maria, Chatzigeorgiou, Ioanna, Monokrousos, Nikolaos, Giantsis, Ioannis A., and Ntinas, Georgios K.

Subjects

SUSTAINABILITY, PRODUCT life cycle assessment, GREENHOUSE gases, SUSTAINABLE agriculture, ELECTRIC power consumption, ENVIRONMENTAL impact analysis, SUSTAINABLE architecture, IDENTIFICATION

Abstract

Introduction: Aquaponics provide multiple benefits due to the simultaneous yield of vegetables and fish, however they are characterized by increased greenhouse gas emissions owing to intensive production system. The most appropriate method for quantifying the environmental effects of these systems is Life Cycle Assessment with which the identification of hotspots and the suggestion of improved production plans can be achieved. The purpose of the present study was to evaluate the environmental impact of a pilot high-tech aquaponic system utilized for the simultaneous production of baby lettuce and rocket as well as rainbow trout, in indicators such as Global Warming Potential. Materials and methods: To achieve this goal, data on inputs and outputs were collected from 12 case studies that were implemented, combining different fertilizer treatments, substrate choices, plant species cultivated and water source provision. Life Cycle Assessment was performed using SimaPro v.9.4.0.2 software. Results: The results showcase that the optimal case studies include the cultivation of baby lettuce and rocket in perlite substrate using wastewater from fish and partial use of synthetic fertilizers. Indicatively, Global Warming Potential of these cases was calculated at 21.18 and 40.59 kg CO2-eq/kg of vegetable respectively. The parameter with the greatest impact on most of the environmental indicators was electricity consumption for the operation of the oxygen supply pump for the fish tanks, while greenhouse infrastructure had the greatest impact in Abiotic Depletion and Human Toxicity impact categories. In an alternative production scenario tested where renewable energy sources were used, system impacts were reduced by up to 50% for Global Warming Potential and 86% for Eutrophication impact. The results of this study aspire to constitute a significant milestone in environmental impact assessments of aquaponic production systems and the adoption of more sustainable farming practices. [ABSTRACT FROM AUTHOR]

Published

2024

17. Effects of Zn-EDTA on the health and welfare of the African catfish, Clarias gariepinus (Burchell, 1822), in a recirculating aquaculture system.

Author

Hildebrand, Marc-Christopher, Rebl, Alexander, Goldammer, Tom, Palm, Harry Wilhelm, and Baßmann, Björn

Subjects

CATFISHES, AQUACULTURE, CLARIAS gariepinus, AQUAPONICS, ETHYLENEDIAMINETETRAACETIC acid, ZINC

Abstract

As nutrient-rich water in aquaponic systems cannot supply growing plants with all the required trace elements, supplementation with specific fertilizers is performed to make up for this deficit. While chelated fertilizers such as ethylenediaminetetraacetic acid-zinc disodium complex (Zn-EDTA) are becoming more popular in this context for improving plant growth in aquaponic systems, little is known about their effects on fish. During two experiments, a total of 576 individuals of catfish fry (0.19 g) and fingerlings (220.01 g) of the African catfish (Clarias gariepinus; Burchell, 1822) were kept separately for 32 days under experimental aquarium conditions. The fry was exposed to 0.125 and 0.5 mg/L, while the fingerlings were exposed to 0.5 and 2.0 mg/L Zn-EDTA in a plantless aquaponic system. The third treatment group consisted of a control group without Zn-EDTA. The growth, mortality, and ethological indicators were assessed for all growth stages, while the leukocyte distribution and histopathological changes were additionally determined for the fingerlings. As the feed intake in the experiment was limited, the investigations were focused on the effects of Zn-EDTA and not on the growth process of a respective fish growth stage. While the growth, mortality, and behavior were not significantly different in both growing stages, the number of mature neutrophils changed significantly in all treatments in fingerlings. Zn was not detected in the histologically investigated organs at the tested concentrations using the staining method. However, morphological alterations of the gill epithelium were found on the secondary lamellae. Quantitative multiplex PCR was used to simultaneously evaluate the expression of 17 genes related to Zn metabolism and stress physiology in head kidney samples. The transcripts of several selected genes changed by up to 70-fold. Due to high individual variances, only the copy numbers of the KMT2A (lysinespecific methyltransferase 2a) gene were significantly different across treatment groups and sampling points. However, the present results indicate that the addition of Zn-EDTA at the tested concentrations can be considered relatively benign for the health and welfare of C. gariepinus, as no toxic effects of Zn-EDTAwere observed in moderately hard to hard water. [ABSTRACT FROM AUTHOR]

Published

2024

18. Evaluating crop growth between hydroponics and aquaponics with different light inputs.

Author

Jeongwook Heo, Jeonghyun Baek, Subah, Zarin, and Jae Hyeon Ryu

Subjects

AGRICULTURAL technology, SUSTAINABLE agriculture, AGRICULTURE, LEMON balm, SPEARMINT, BASIL

Abstract

Indoor farming technologies, such as aquaponics and hydroponics, are crucial for advancing sustainable agriculture, especially in urban areas with limited land for conventional agriculture. As studies comparing these two systems are limited, this study explored the cultivation of five leafy vegetables--white leaf beets (Beta vulgaris var. cicla), hooker chives (Allium hookeri), basil (Ocimum basilicum), lemon balm (Melissa officinalis), and spearmint (Mentha spicata)--in an indoor greenhouse facility using two different food production platforms: an aquaponic system (AS) with catfish (Silurus asotus) and a conventional hydroponic system (HS). The results showed that the plant growth in AS outperformed that in HS, while the general growth patterns in AS were significantly affected by the different light sources. In addition, the leaf yield of the herbal plants (basil and lemon balm) in AS was 60%-70% more than that in HS. The leaf growth of hooker chives in AS also showed significant improvement (200%) compared with that in HS. It appears that the nutrient sources provided by fish were remarkable, as the average concentration of NO3-N (64 mg/L) was easily achieved in AS. The proposed AS, therefore, would be a promising alternative to the production and supply of supplement organic food, ultimately contributing to promoting sustainable agriculture in a changing climate. [ABSTRACT FROM AUTHOR]

Published

2024

19. Starvation and re-feeding of Gilthead seabream (Sparus aurata) and European seabass (Dicentrarchus labrax) co-cultured with glasswort (Salicornia europaea) in a polyculture aquaponic system.

Author

Mitsopoulos, Ioannis, Kontou, Iliana Gesthimani, Babouklis, Konstantinos, Vlahos, Nikolaos, Berillis, Panagiotis, Levizou, Efi, and Mente, Eleni

Subjects

EUROPEAN seabass, SPARUS aurata, SEA basses, FISH growth, FOOD consumption

Abstract

The aim of this study was to evaluate the effect of starvation and refeeding on the growth and food intake of gilthead seabream (Sparus aurata) and seabass (Dicentrarchus labrax) and on the growth and nitrogen uptake of glasswort (Salicornia europaea) in a polyculture aquaponic system under 12 ppt salinity for 75 days. Nine small-scale autonomous aquaponic systems were used, each containing 10 gilthead seabreams (average weight of 6.33 ± 0.73 g and average length of 5.73 ± 0.72 cm) and 10 seabasses (5.82 ± 0.77 g and 6.35 ± 0.45 cm), as well as five glasswort plants. Three fish feeding treatments were performed, a control (A), in which fish were fed daily until satiation, and two fasting treatments for 4 (B) and 7 days (C). Fish growth performance was significantly lower (p < 0.05) in the C treatment for both species compared to treatments A and B. Food consumption (FC) and feed conversion ratio (FCR) were significantly higher (p < 0.05) in treatment C. Glasswort growth performance was significantly higher in treatment C (p < 0.05). The results showed that the 4-day food-deprived fish were similar to the control fish by achieving partial compensatory growth. The more extended fasting period (7 days) resulted in significantly lower growth performance. The lipid and nitrogen retention levels in both species were significantly lower in food-deprived fish than in the control fish both before and during compensatory growth. The results suggest that a feeding schedule involving starvation–refeeding cycles is a promising feed management option for these species in polyculture aquaponic systems. The effect of food deprivation was also significantly beneficial (p < 0.05) for the growth performance of glasswort compared to the control treatment. [ABSTRACT FROM AUTHOR]

Published

2024

20. Integrated Nutrient Management of Fruits, Vegetables, and Crops through the Use of Biostimulants, Soilless Cultivation, and Traditional and Modern Approaches—A Mini Review.

Author

Ali, Awais, Niu, Genhua, Masabni, Joseph, Ferrante, Antonio, and Cocetta, Giacomo

Subjects

SUSTAINABLE agriculture, SUSTAINABILITY, FIELD crops, AGRICULTURAL productivity, PLANT propagation

Abstract

The increasing population, its requirements for food, and the environmental impact of the excessive use of inputs make crop production a pressing challenge. Integrated nutrient management (INM) has emerged as a critical solution by maximizing nutrient availability and utilization for crops and vegetables. This review paper highlights the potential benefits of INM for various vegetables and field crops and explores the conceptual strategies, components, and principles underlying this approach. Studies have shown that a wide range of vegetables and field crops benefit from INM, in terms of increased yield and improvements in yield attributes, nutrient contents and uptake, growth parameters, and various physiological and biochemical characteristics. This paper discusses biostimulants, their categories, and their impact on plant propagation, growth, photosynthesis, seed germination, fruit set, and quality. Additionally, this review explores modern sustainable soilless production techniques such as hydroponics, aeroponics, and aquaponics. These cultivation methods highlight the advancements of controlled-environment agriculture (CEA) and its contribution to nutrient management, food security and minimizing the environmental footprint. The review concludes by proposing methods and fostering discussions on INM's future development, while acknowledging the challenges associated with its adoption. Finally, this review emphasizes the substantial evidence supporting INM as a novel and ecologically sound strategy for achieving sustainable agricultural production worldwide. [ABSTRACT FROM AUTHOR]

Published

2024

21. Aquaponic growth of basil (Ocimum basilicum) with African catfish (Clarias gariepinus) in standard substrate combined with a Humicacid Fiber-Substrate (HFS).

Author

Knaus, Ulrich, Hübner, Dirk Hyo-Dschung, Küchenmeister, Christian, Appelbaum, Samuel, Iten, Walter, and Palm, Harry W.

Subjects

*CLARIAS gariepinus, *AGRICULTURE, *SUBSTRATES (Materials science), *AQUAPONICS, *PLANT containers, *BASIL

Abstract

A major challenge in agriculture, horticulture and aquaponics practices is the reduction of mineral fertilisers and peat to reduce CO2 emissions and increase sustainability. This study used a three-phase-natural fertiliser, the Humicacid Fiber-Substrate (HFS), made from natural regenerative organic and mineral-fractions (Humus-Mineral-Complex), to reduce the peat content in plant pots for aquaponics farming. Basil (Ocimum basilicum) growth was compared with i) 100% standard media substrate ("Einheitserde", white peat 80%, clay 20%), and ii) 85% "Einheitserde" and 15% of HFS under irrigation with aquaculture process waters from an extensive and intensive production of African catfish (Clarias gariepinus) under coupled aquaponic conditions. The substitution with 15% HFS and use of intensive fish water resulted in comparable plant growth to a fertiliser solution as control, and in higher leaf width and leaf green weight and lower root dry weight compared with the standard media substrate "Einheitserde". Basil leaf chlorophyll content from the aquaponics was higher compared with local market plants. This suggests the possible substitution of the peat substrate "Einheitserde" with at least 15% HFS to reduce the natural peat fraction. Further studies on crop-specific substrates are needed to reduce peat in aquaponics farming plant cultivation. [ABSTRACT FROM AUTHOR]

Published

2024

22. Comparing lettuce and cucumber production using hydroponics and aquaponic (tilapia) systems.

Author

Estrada-Pérez, Nallely, Zavala-Leal, Iram, González-Hermoso, Juan P., and Ruiz-Velazco, Javier M. J.

Subjects

*AQUAPONICS, *CUCUMBERS, *HYDROPONICS, *FISH farming, *TILAPIA, *LETTUCE, *ENVIRONMENTAL quality

Abstract

Aquaponics is the cultivation technique that integrates aquaculture with hydroponics. The present work compared two plant production cycles of a hydroponic component of an aquaponic system (tilapia-lettucecucumbers) vs. a hydroponic system. The tilapia growth trial lasted 22 weeks in the aquaponic system, during which two plant production cycles -lettuce-cucumber- (seven weeks) were performed. Water quality and environmental variables were recorded, evaluating weight growth and biomass produced in fish rearing. Leaf number, height, and weight were determined in lettuce plants. Stem length and fresh weight were measured in cucumber plants; length, fresh weight, and diameter were determined in cucumber fruit. The results showed that the average tilapia biomass per tank was 33.76 kg m-3 with an average final weight of 592.26 ± 25.45 g fish-1. Lettuce production (plants ha-1 ) was higher in aquaponics than hydroponics during the first cycle, while in the second one, it was greater in hydroponics. Significant differences (ANOVA, P < 0.05) resulted between treatments in both cucumber production cycles with larger biomass growth in hydroponics than in aquaponics. Cucumber fruit showed larger weight (212.52 ± 18.89 g) and length (14.15 ± 1.75 cm) in hydroponics, thus greater yield (4.97 t ha-1 ); hydroponics-grown cucumber plants had longer stem lengths (292.51 ± 8.73 cm). In conclusion, the hydroponic system had higher plant production. However, aquaponics provided a double benefit since it produced fish and plants, and the plants used waste from fish rearing without contaminating the environment. [ABSTRACT FROM AUTHOR]

Published

2024

23. Case of Vibrio vulnificus Infection in Orechromis niloticus during Suspension of Recirculating Aquaculture System.

Author

Cai, Yan, Jiang, Liu, Wang, Shaoqun, Zhao, Zhangding, Zhou, Yongcan, and Wang, Shifeng

Subjects

VIBRIO vulnificus, VIBRIO infections, NILE tilapia, FISH mortality, TILAPIA, AQUAPONICS, AQUACULTURE

Abstract

During a suspension of a GIFT tilapia broodstock recirculating aquaculture system (RAS), a significant fish mortality event occurred. To determine the cause, four bacterial strains were isolated from affected fish and identified as Vibrio vulnificus through 16S rDNA sequencing. Virulence assays confirmed the pathogenicity of these strains, with the most virulent, CS-4, selected for a further analysis. Antimicrobial testing revealed CS-4's sensitivity to 19 antibiotics, including meloxicillin and Gentamicin. Challenge tests indicated varied 7-day Lethal Dose 50 (LD50) values for CS-4 depending on the infection route, with immersion after skin injury being the most lethal. Additionally, the effects of salinity, crowding with air exposure, and nitrite on tilapia mortality were evaluated. The results showed that salinity stress increased the mortality rate of tilapia infected with V. vulnificus through immersion, and that salinity stress and V. vulnificus infection had a synergistic effect. A 20 min crowding with air exposure stress reduced the mortality rate of Nile tilapia infected with V. vulnificus. Nitrite stress had little effect on the mortality rate of tilapia infected with V. vulnificus. The results of the risk factor analysis indicated that salinity was the main factor affecting tilapia mortality caused by V. vulnificus infection. This study will serve as a valuable reference for the future management of similar RAS. [ABSTRACT FROM AUTHOR]

Published

2024

24. Agroecology principles in aquaculture: a case study of East Africa.

Author

POKUPEC, David, LEŠNIK, Tina, and BOREC, Andreja

Subjects

FARMERS, AQUAPONICS, AQUACULTURE, FOOD security, CATCH crops, POULTRY manure

Abstract

Copyright of Journal of Central European Agriculture is the property of Journal of Central European Agriculture and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

25. Aquaponics Revolution: Reinforcing performance by means of Apache Spark and Apache Kafka.

Author

Ibtissame, EZZAHOUI, Rachida, AIT ABDELOUAHID, and Abdelaziz, MARZAK

Subjects

AGRICULTURE, BIG data, AQUAPONICS, INTERNET of things, AQUACULTURE, MICROBIAL inoculants

Abstract

Many studies provide ways to monitor and manage the aquaponics system, a closed-loop ecosystem that combines hydroponics—growing plants without soil—and aquaculture—raising fish—using cloud computing, the Internet of Things (IoT), and smart sensing technologies. A system operating at peak efficiency yields organic, healthful food with little water and no chemical fertilizer usage, therefore contributing to food security and sustainability. In order to develop our proposed aquaponic system based on Internet of Things technologies, this paper will centralize our endeavor to integrate big data tools, namely Apache Spark and Kafka, into the previous architecture for data collection and processing, as well as for the prediction of any anomalies in the system. [ABSTRACT FROM AUTHOR]

Published

2024

26. Enhancing energy recovery from aquaculture residual materials: a focus on anaerobic digestion of African catfish (Clarias gariepinus) sediment sludge.

Author

Klein, Jan, Schüch, Andrea, Foth, Sebastian, Sprafke, Jan, Bischoff, Adrian, Nelles, Michael, and Palm, Harry W.

Subjects

CLARIAS gariepinus, UPFLOW anaerobic sludge blanket reactors, ANAEROBIC digestion, AQUACULTURE, PLANT identification, PLANT residues

Abstract

In Germany, warm water Recirculating Aquaculture Systems (RAS) are generally integrated with biogas plants. The process sludge produced in aquaculture could be utilized to generate energy. This study investigates the potential of process sludge from commercial African catfish (Clarias gariepinus) warm water RAS, alongside associated plant production residues (whole plants and pruning residues) for energy generation through anaerobic digestion. Biogas tests, including batch, semi-Continuous Stirred Tank Reactor (CSTR), and Upflow Anaerobic Sludge Blanket Reactor (UASB) were conducted. In batch, methane yields were 229 L(N) / kg VS from the sludge and 173-184 L(N) / kg VS from the various plant substrates (cucumber, paprika, and tomato plants). During CSTR operation, mono-fermentation of sludge produced a methane yield of 265 L(N) / kg VS. Co-fermentation with 25% cucumber residues, based on VS, increased this value to 381 L(N) / kg VS. Mono-fermentation of sludge in the UASB reactor yielded a maximum of 329 L(N)/kg VS. The relatively low TS content and unfavorable C/N ratio in C. gariepinus sludge, along with the low energy density and occasional high sulfur content in the investigated plant substrates, present challenges for CSTR biogas production. These challenges can be partially mitigated through substrate combination. For mono-fermentation of African catfish RAS sludge, the UASB reactor is recommended. Improved solids separation, extraction, and concentration techniques at aquaculture operations are essential for the efficient utilization of aquaculture sludge, especially from African catfish, in biogas plants. [ABSTRACT FROM AUTHOR]

Published

2024

27. Integration of down-flow hanging sponge reactor to oreochromis niloticus − Brassica oleracea aquaponics system.

Author

Kotcharoen, Wilasinee, Nagai, Zen, Watari, Takahiro, Adlin, Nur, Hatamoto, Masashi, Murakami, Yuki, Maharjan, Namita, Takeuchi, Yutaka, Yamazaki, Shinichi, and Yamaguchi, Takashi

Subjects

*TRICKLING filters, *NILE tilapia, *NITRIFYING bacteria, *WATER quality, *AQUACULTURE industry, *AQUAPONICS, *HYDROPONICS

Abstract

Aquaponics is a promising solution for addressing food security concerns. Nonetheless, an effective water-purification system is necessary to achieve high and stable yields of fish and vegetables. This study aimed to evaluate the nitrification and oxygen transfer performance of a laboratory-scale down-flow hanging sponge (DHS) reactor with a Brassica oleracea aquaponics system to treat water in an Oreochromis niloticus closed-aquaculture system. The DHS reactor showed a higher oxygen transfer coefficient (KLa) than the conventional aerator and provided an adequate dissolved oxygen (DO) concentration of approximately 5.5 mg/L essential for O. niloticus growth throughout the experimental period. The evaluated DHS-based aquaponic system maintained high water quality in an aquaculture tank, with a survival rate of 97%. The O. niloticusgrew at a low feed conversion ratio of 1.5–2.1 and a low feeding rate of 0.5% at high stocking densities of 17.5–22.2 kg-fish-weight/m3. 16S rRNA gene sequencing indicated that the DHS sponge carrier effectively retained nitrifying bacteria such as Nitrosomonas and Nitrospira. This study demonstrated that the DHS reactor provided a high DO concentration and that a simultaneous DHS reactor with a hydroponic tank provided a low-cost aquaponic system that could be applied for food production in the aquaculture industry. [ABSTRACT FROM AUTHOR]

Published

2024

28. Comparative seasonal analysis of IC50, total antioxidant capacity, phenolics, and flavonoids of some vegetable plants from the aquaponics system.

Author

IBRAHIM, Labaran

Subjects

*ANTIOXIDANT analysis, *PLANT phenols, *AQUAPONICS, *VEGETATION & climate, *SEASONAL physiological variations

Abstract

Seasonal factors such as temperature, solar UV-light intensity, and daylight length can induce changes in the water quality properties and, hence, the nutritional compositions of plants. This comparative study was carried out for the consecutive four (4) seasons (winter, spring, summer, and autumn) to determine the influence of seasonal variations on the 50% inhibitory concentration (IC50), total antioxidant capacity (TAC), total phenolics content (TPC), and total flavonoids content (TPC) of the red chili fruit (RCF), red tomato fruit (RTF), green leafy spinach (GLS), and green leafy lettuce (GLL) collected from a coupled commercial aquaponics system. The IC50, TAC, TPC, and TFC concentration levels indicated a significant (P<0.05) difference in the summer compared with the winter, spring, and autumn. The RCF extract indicated the lowest IC50, thus greater scavenging power in comparison to RTF, GLS, and GLL extracts. Similarly, the RCF showed the highest TAC and TPC, while the GLL showed the highest TFC. In this study, variations in seasons have induced changes in the IC50, TAC, TPC, and TFC concentration levels of the RCF, RTF, GLS, and GLL extracts. [ABSTRACT FROM AUTHOR]

Published

2024

29. Production of Flathead Grey Mullet (Mugil cephalus) and Lettuce (Lactuca sativa) in a Coupled Aquaponic System under Suboptimal Water Temperatures.

Author

Gisbert, Enric, Molas, Sandra, Hernández, Esteban, Carbó, Ricard, and Ruiz, Alberto

Subjects

*STRIPED mullet, *GRAY mullets, *LETTUCE, *AQUAPONICS, *WATER temperature, *FISH growth, *ANIMAL products

Abstract

The combined production of three varieties of lettuce (romaine, iceberg, and red leaf) with flathead grey mullet (Mugil cephalus) was tested in triplicate in three independent coupled aquaponic units with no thermal control. For this purpose, a total of 114 fish (2.5 kg/m3) were stocked in each fish tank (2 m3), and 92 lettuces were planted in the hydroponic unit (6 m2). As no thermal control was included in the design of the aquaponic system, water temperatures declined from maximum values of 20.4 °C to minimum values of 5.0 °C, which directly affected fish growth. However, the conditions imposed by the aquaponic system were suitable for promoting lettuce's growth and external appearance, as no pests or leaf discoloration were noticed. Lettuce survival was similar among the three tested varieties (98.5 ± 1.7%). The yields for the romaine and iceberg varieties were 384 ± 100 g/lettuce and 316 ± 70 g/lettuce, respectively, and that for the red leaf variety was lower, at 176 ± 75 g/lettuce. Yield values ranged between 3.6 and 4.4 kg/m2 depending on the replicate considered (4.0 ± 0.4 kg/m2). According to present results, each aquaponic unit required ca. 2.6–2.7 L of water per unit of lettuce produced. [ABSTRACT FROM AUTHOR]

Published

2024

30. It Runs in the Family: The Importance of the Lamiaceae Family Species.

Author

Chrysargyris, Antonios

Subjects

*LAMIACEAE, *BASIL, *SPECIES, *HYDROPONICS, *CULTIVATED plants, *SUSTAINABLE agriculture, *AQUAPONICS, *OREGANO, *PLANT germplasm

Abstract

The article discusses the importance of the Lamiaceae family of plants, which includes species like thyme, mint, oregano, basil, and sage. These plants are known for their aromatic properties and are widely used in various industries such as food, cosmetics, and pharmaceuticals. The article also highlights recent research on topics such as plant cultivation methods, extraction techniques for essential oils, and the preservation of fresh produce using natural compounds. The collection of scientific papers aims to explore the potential of these plants and their extracts in various applications while optimizing growth conditions and extraction methods. [Extracted from the article]

Published

2024

31. 鱼菜共生系统中乳酸菌的筛选及其发酵矿化应用.

Author

蒋金辰, 徐琰斐, 单建军, 张宇雷, and 高霞婷

Abstract

Lactic acid bacteria have been widely used as feed additives in aquaculture to improve the absorption of nutrients, as well as the immunity and growth performance of fish. According to the lactic acid bacteria to decompose organic matter, this study aims to improve the utilization efficiency of solid waste resources with high nutrients in aquaponics systems. Fishderived bacteria were screened with strong resistance and better mineralization function, in order to enhance the fermentation and mineralization of fish waste. The experiments were conducted to take the biofilter media and fish from the aquaponics system as the source of lactic acid bacteria. A series of tests were then performed on the high-temperature tolerance, acid and alkali tolerance, high salt tolerance, and the mineralization performance of various nutrients in fish waste. Two strains were obtained with mineralization function and application potential, which were identified as Lactococcus lactis L1 and Lactobacillus dextrinicus L2, respectively. A comparison was also made on the growth performance of the strains at 10, 20, 30 and 40 °C. The results revealed that the growth of L1 and L2 was inhibited at 10 and 20 °C, while they proliferated normally at 30 and 40 °C. The survival rate of L1 and L2 after 30 min of heating at 50, 60, and 70 °C was examined to verify the high-temperature tolerance of the strains. It was found that the L1 was achieved the better high-temperature tolerance. The survival rate of L1 was 96.60% at 50 °C, which was significantly higher than that of L2 (80.35%). According to the range of water acidity and alkalinity in the environment of aquaculture, the tolerance of the two strains was examined at pH 5.0-9.0. The results showed that the survival rates of L1 (65.43% and 71.25%) were higher than those of L2 (31.10% and 52.22%) at both pH 5.0 and 9.0 (P<0.05). The tolerance of the strains was examined at 15, 30, and 60 g/L salinity, where the mariculture and salinity were considered after the thickening of mariculture sludge. The survival rate of the strains gradually decreased with the increase of salinity. Once the salt concentration was 60 g/L, the survival rate of L1 was 37.33%, while there was no L2 survival. In terms of tolerance to temperature, acid, and alkali, L1 was selected as the subsequent experimental object for the fish waste fermentation mineralization experiment. The control group (no lactic acid bacteria added) and the L group (with Lactococcus lactis added) were divided to last for seven days. A comparison was made on the contents of nitrogen, phosphorus and various mineral elements in the fermentation broth at days 0, 1, 3, 5 and 7. The results showed that better degradation and mineralization of organic matter were achieved in the L group. The highest concentrations of total ammonia nitrogen (TAN) and total nitrogen (TN) in the fermentation broth of the L group were 192.82 and 342.00 mg/L, respectively, which were much higher than the control group (30.29 and 79.00 mg/L, respectively). Potassium (K), calcium (Ca), magnesium (Mg), iron (Fe), manganese (Mn), and zinc (Zn) in the fermentation broth of the L group were significantly higher than those of the control group, except for sulfur (S) and all reached the highest values (27.59%-94.67%) in the 3d. In conclusion, Lactococcus lactis presented the better resistance to heat, salt, acid, and alkali, indicating better fermentation and mineralization of fish waste. Furthermore, 3 d was the optimal cycle of fermentation and mineralization. The finding can provide a strong reference to apply the lactic acid bacteria to the mineralization of solid wastes, in order to improve the nutrient utilization efficiency in aquaponics systems. [ABSTRACT FROM AUTHOR]

Published

2024

32. Horticultural Irrigation Systems and Aquacultural Water Usage: A Perspective for the Use of Aquaponics to Generate a Sustainable Water Footprint.

Author

Schoor, Mark, Arenas-Salazar, Ana Patricia, Parra-Pacheco, Benito, García-Trejo, Juan Fernando, Torres-Pacheco, Irineo, Guevara-González, Ramón Gerardo, and Rico-García, Enrique

Subjects

RESOURCE exploitation, AQUAPONICS, WATER pollution, MANAGEMENT information systems, IRRIGATION, WATER shortages

Abstract

The expansion of food production is becoming more important due to a rising world population, which is relying on food security on regional and local scales. Intensive food production systems exert a negative impact on the regional ecosystem because of agrochemical pollution and nutrient-rich water discharging into nearby rivers. Furthermore, these systems highly depend on regional water resources, causing water scarcity and soil erosion due to the overexploitation of natural resources in general. The objective of this article is to review the water usage in the two most water-intensive food production systems, agriculture and aquaculture, showing lacking areas like system management and climate change, which must be considered in the implementation of a sustainable water footprint. In addition, the review includes an analysis of the combination of both production systems in aquaponic food production and the possibilities of water saving. There are a variety of analyses related to water usage for crop and aquatic animal production, but in these analyses, there is a lack of information about system management in general, which includes cleaning processes, water substitution, pond removal, water evaporation, and, especially in aquaculture, the water usage required for industrially elaborated fish feed. [ABSTRACT FROM AUTHOR]

Published

2024

33. Aquaponics system for sustainable water, energy, and food nexus: A review

Author

Mohamed Gabr, Nawaf Alhajeri, Fahad Al-Fadhli, and Salem Al Jabri

Subjects

aquaponics, sustainability, wetland treatment system, water quality, wastewater integrated system, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Climate change, population expansion, water shortages, soil erosion, and food security are some of the primary concerns facing the world today. Hydroponic, aquaponic, and aquaculture systems may help to address these difficulties. Hydroponics is a closed-loop system for growing plants in nutrient-rich water rather than soil. Aquaponic systems combine hydroponics and the growing of fish or other aquaculture species in addition to plants. This review aims to evaluate the challenges encountered by aquaponic and aquaculture farming operations and identify which issues still need to be addressed. The review is organized as follows: recent previous studies on hydroponics, aquaponics, and aquaculture were collected and investigated; water quality and energy issues were addressed; technologies to improve water quality in these systems were discussed; and challenges to the implementation of large-scale aquaponics were discussed. The study found that a commercial reverse osmosis filtering system that provides excellent water quality control is a good method for removing harmful contaminants from water in small-scale aquaponics and aquaculture. Recirculation systems are more sustainable and effective in managing the volume of effluent in aquaculture units because only 10% of the total volume of water is refilled daily. Constructed wetland systems are a low-cost, high-efficiency treatment solution for nitrogen-containing wastewater, with removal efficiencies of up to 98% for NH4-N and above 98% for NO2-N. The use of aquaponics in desert settings with water constraints constraint is viewed as a possible sustainable food production approach.

Published

2024

34. Plant nutritional value of aquaculture water produced by feeding Nile tilapia (Oreochromis niloticus) alternative protein diets: A lettuce and basil case study

Author

Jeffrey J. Jones, Christopher Shaw, Tsu‐Wei Chen, Christopher Martin Staß, Christian Ulrichs, David Riewe, Werner Kloas, and Christoph‐Martin Geilfus

Subjects

aquaponics, minerals, multitrophic food production systems, nutrient use efficiencies, phenylpropanoids, zero waste, Environmental sciences, GE1-350, Botany, QK1-989

Abstract

Societal Impact Statement Refining circular multitrophic food production methods, which integrate plant, fish, and insect outputs, is imperative for environmental sustainability. Our findings suggest that the right protein choices in fish feed, like black soldier fly meal and poultry meal, can notably enhance the nutrient profile of fish waste water. This, in turn, is conducive for hydroponic cultivation, enhancing the nutritional attributes of plants like basil and lettuce. As we reduce environmental impact and optimize resource use, it is evident that our food ecosystems are deeply intertwined. Harnessing these synergies could redefine our approach to food production, paving the way for a more sustainable global future. Summary Optimization of nutrient use efficiencies in circular multitrophic food production systems (i.e., plant, fish, and insect production) is crucial for sustainability. This study tested how protein ingredient choice in fish feed influences the plant nutritional value of the fish waste water when used for hydroponic crop production. Waste water samples were obtained from recirculating aquaculture systems (RAS) in which Nile tilapia (Oreochromis niloticus) were fed different single protein source diets—black soldier fly meal (BSFM), poultry by‐product meal (PM), poultry blood meal (PBM), and fish meal. Water was analyzed for plant nutrients and used for lettuce and basil cultivation to evaluate their suitability for hydroponic crop production—viz. yield, mineral nutrient, and selected secondary metabolite levels. BSFM RAS water had the highest concentrations of K, Mg, and micronutrients (Cu, Mn, Mo, Zn) of the RAS waters, whereas PM RAS water contained the highest P concentration and had a mean pH of 6.5 closer to the optimum pH for hydroponic plants. These RAS waters consequently lead to the highest yields in basil and lettuce indicating the importance of the aforementioned factors. From a plant production perspective, BSFM appears promising as a protein source in fish feeds for aquaponics. Usage of RAS waters for plant production helps reduce (i) environmental impact of RAS water and (ii) resource input in plant production. Longer term RAS trials should be conducted to determine the maximum nutrient concentrations achievable during fish production with diets including BSFM as the main protein source.

Published

2024

35. Bacterial communities in aquaponic systems: Insights from red onion hydroponics and koi biological filters

Author

Bambang Widyo Prastowo, Indarti Puji Lestari, Ni Wayan Sri Agustini, Dody Priadi, Yati Haryati, Akhmad Jufri, Puspita Deswina, Eko Binnaryo Mei Adi, and Iskandar Zulkarnaen

Subjects

Red onion, Koi, Aquaponics, Bacterial communities, Bioremediation, Environmental engineering, TA170-171, Chemical engineering, TP155-156

Abstract

Aquaponics is a sustainable food production technology combining the tripartite relationship between fish, plants, and microorganisms. This study discusses the diversity and characteristics of bacteria communities in different aquaponic system compartments. Samples from red onion hydroponic compartment and koi biological filters were collected and analyzed for their bacterial community structure. Gene sequencing with high throughput 16S rRNA is used to analyze bacterial communities. Hydroponic compartments had significantly more bacterial communities than koi biological filters. The most dominant phylum in the hydroponic compartment is Proteobacteria (α, β, γ), Bacteroidota, Firmicutes, Planctomycetota, Cyanobacteria, and Actinobacteria. While in the biological filter are Bacteroidota, β-Proteobacteria, and Actinobacteria. The bacterial community in the hydroponic compartment showed significant specificity compared to the bacterial community in the biological filter. We also systematically describe bacterial communities in hydroponic compartments and biological filters and estimate their relevant functions in biological filtration of water. These results provide new insights into bacterial communities’ role in the hydroponic compartment for red onion growth as well as bacterial communities in the biofilter that act as bioremediation agents on water quality that affect the growth and survival of koi. However, it would be required a deeper analysis to identify its specific roles in aquaponics.

Published

2024

36. IoT and machine learning approach for the determination of optimal freshwater replenishment rate in aquaponics system.

Author

Chandramenon, Praveen, Gascoyne, Andrew, and Tchuenbou-Magaia, Fideline

Subjects

MACHINE learning, AQUAPONICS, STANDARD deviations, REGRESSION analysis, WATER quality, SUICIDE statistics

Abstract

Conventional aquaponics conserve water used in aquaponics whereas the literature suggests a certain level of freshwater replenishment or freshwater exchange for good water quality, fish and plant wellbeing, and the overall productivity of the system. This paper deals with the determination of an optimal freshwater replenishment rate for a standard aquaponics system. IoT devices and sensors were used for this project data collection. This paper used linear regressions and ensemble methods to determine the optimal rate of periodic water replenishment to maintain the water quality parameters that determine the yield and productivity of aquaponics systems. Cubic spline and Lagrange interpolation were applied to raw and simulated data. Results were evaluated and compared using statistical error estimation approaches. The bestmodel amongst the investigated machine learning models was gradient boost with an optimal replenishment rate of 19L per week and a water quality of 4.86 for an aquaponic tank of 100 L capacity. The error estimations were a Mean Squared Error of 0.0224, Mean Absolute Error of 0.1137, Root Mean Squared Error of 0.1499, and R2 of 0.7208. This was within 1% of the value obtained fromraw and interpolated data using a polynomial regression. These findings suggest that the water quality of an aquaponics system can be maintained at the desired optimal level with a weekly 19% water replenishment, thereby contributing to the improvement of productivity and resource efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

37. Evaluation of Alternative Sources of Proteins and Other Nutrients with Potential Applications in Fish Nutrition.

Author

Muntean, George-Cătălin, Simedru, Dorina, Uiuiu, Paul, Tanaselia, Claudiu, Cadar, Oana, Becze, Anca, and Coroian, Aurelia

Subjects

*GREENHOUSE gases, *COFFEE grounds, *PLANT proteins, *POLYCYCLIC aromatic hydrocarbons, *SUNFLOWER seeds, *PUMPKIN seeds, *SUNFLOWERS, *AQUAPONICS

Abstract

The European Union's (EU) agricultural self-sufficiency is challenged by its reliance on imported plant proteins, particularly soy from the Americas, contributing to deforestation and greenhouse gas emissions. Addressing the EU's protein deficit, this study evaluates alternative protein sources for aquaculture, focusing on their nutritional value, elemental content, and polycyclic aromatic hydrocarbons (PAHs). Protein flours from gastropods (Helix pomatia, Arion lusitanicus, Arion vulgaris) and their hepatopancreas, along with plant-based proteins from food industry by-products (oilcakes, coffee grounds, spent brewer's yeast), were analyzed. Results revealed that snail flour contained the highest protein content at 59.09%, significantly outperforming hepatopancreas flour at 42.26%. Plant-based proteins demonstrated substantial nutritional value, with coffee grounds flour exhibiting a remarkable protein content of 71.8% and spent brewer's yeast flour at 57.9%. Elemental analysis indicated high levels of essential minerals such as magnesium in hepatopancreas flour (5719.10 mg/kg) and calcium in slug flour (48,640.11 mg/kg). However, cadmium levels in hepatopancreas flour (11.45 mg/kg) necessitate caution due to potential health risks. PAH concentrations were low across all samples, with the highest total PAH content observed in hepatopancreas flour at 0.0353 µg/kg, suggesting minimal risk of PAH-related toxicity. The analysis of plant-based protein sources, particularly oilcakes derived from sunflower, hemp, flax, and pumpkin seeds, revealed that these by-products not only exhibit high protein contents but present a promising avenue for enhancing the nutritional quality of feed. This study underscores the potential of utilizing gastropod and plant-based by-products as sustainable and nutritionally adequate alternatives to conventional feeds in aquaculture, contributing to the EU's environmental sustainability goals. [ABSTRACT FROM AUTHOR]

Published

2024

38. Comparative Evaluation of Water Quality Properties: A Case Study of Coupled Commercial Aquaponics System.

Author

IBRAHIM, Labaran

Subjects

*WATER quality, *AQUAPONICS, *PHOSPHATES, *WATER temperature, *DISSOLVED oxygen in water

Abstract

The current study intends to evaluate the influence of seasonal changes on the water quality parameters of a coupled commercial aquaponics system. The determined water quality parameters for the comparative study were total ammoniumnitrogen (TAN), nitrate-nitrogen (NO3-N) and phosphate (PO43-), water temperature (WT), water pH, dissolved oxygen (DO), electrical conductivity (EC), and total dissolved solids (TDS). The WT and DO analysis were carried out using a portable dissolved oxygen meter (Model: PDO-520, Taiwan). A portable electrode pH meter (Model: PH-220, Taiwan) was utilized for the pH measurement. The TDS and EC readings were obtained using a multi-parameter water quality meter (PHT-27, China). The TAN, NO3-N, and PO43- determinations were done using their individual Merck Spectro-quant® test kits. The research results indicated a significant (p<0.05) difference in the NO3-N, PO43-, WT, pH, EC, and TDS values among the comparative four seasons (winter, spring, summer, and autumn). However, the TAN and DO levels revealed no significant (p>0.05) difference. The observed significant increase of NO3-N, PO43-, EC, and TDS in the summer and autumn periods could be associated to the increased fish feeding rate (which increases waste production) as well as relative increase in microbial waste conversion/mineralization. The investigated water quality makers were within the recommended amounts in the aquaponics system. Thus, in this study, seasonal differences have induced variation in the NO3-N, PO43-, WT, pH, EC, and TDS amounts. However, these differences do not affect the TAN and DO levels. [ABSTRACT FROM AUTHOR]

Published

2024

39. Enhancing Indoor Culture of Weather Loach (Misgurnus anguillicaudatus) and Caipira Lettuce (Lactuca sativa) in a Decoupled FLOCponics System.

Author

Park, Junseong, Hwang, Ju-ae, Choe, Jongryeol, Lee, Donggil, and Kim, Hyeongsu

Subjects

*LETTUCE, *FISH farming, *WEATHER, *SURVIVAL rate, *AQUAPONICS, *HYDROPONICS

Abstract

Interest in aquaponics (AP) is increasing due to its ability to minimize sewage and maximize feed efficiency in fish farming. However, owing to limitations of intensive cultures and a lack of nutrients such as NO3 for growing crops, AP requires the use of artificial nutrients. Therefore, novel approaches are required to develop AP-intensive culturing methods. An AP system based on biofloc technology (BFT) called FLOCponics (FP) has been recommended. Here, the productivity of the weather loach (Misgurnus anguillicaudatus) in the FP system, BFT system, and flow-through systems (FTSs), as well as these systems' effect on Caipira lettuce (Lactuca sativa) growth, was analyzed. To compare crop productivity, a hydroponic (HP) bed was installed. The growth rate of M. anguillicaudatus showed significant differences, at 51.1 ± 3.69% in the FP system, followed by 24.0 ± 4.16% in the BFT system and −14.3 ± 1.4% in the FTS. Its survival rates were better in the FP system (91.1 ± 2.64%) than in the BFT system (82.1 ± 10.98%) or the FTS (66.8 ± 2.75%) (p < 0.05). Total ammonia nitrogen and NO2−-N concentrations were stabilized in every plot during the experimental period. However, the NO3−-N concentration continuously increased in the BFT system but decreased in the FP system and was maintained. The shoot weight of the Caipira lettuce was 163.6 ± 8.65 g in the FP system and 149.6 ± 9.05 g in the HP system. In conclusion, FP system can provide a large amount of nutrients and improve the growth performance of both fish and crops in the FP system. [ABSTRACT FROM AUTHOR]

Published

2024

40. The effect of swimming activity and feed restriction of rainbow trout (Oncorhynchus mykiss) on water quality and fish‐plant growth performance in aquaponics.

Author

Tunçelli, Gökhan and Memiş, Devrim

Subjects

*RAINBOW trout, *WATER quality, *SWIMMING, *FISH locomotion, *LETTUCE, *AQUAPONICS, *FISH development, *FISH growth

Abstract

In this study, we investigated the effects of swimming activity and feed restriction on juvenile rainbow trout (Oncorhynchus mykiss) in decoupled aquaponic systems. Our focus was on assessing their impact on water quality parameters within the aquaponic setup and evaluating the growth performance of the fish, including final weight (FW), condition factor (K), coefficient of variation (c.v.) in weight, specific growth rate (SGR), total feed intake (g/fish), feed conversion rate (FCR), hepatosomatic index (HSI), and viscerosomatic index (VSI), as well as the growth of lettuce (Lactuca sativa L. var. elmaria). The study involved 108 juvenile rainbow trout with an average initial weight of 26.54 ± 0.36 g and 60 ten‐day‐old lettuce seedlings, over a period of 42 days. We designed four treatment groups, each with three fish tanks: static ad libitum (SA), where fish were in static water conditions and fed to satiation; static restriction (SR), with fish in static water and a 25% feed restriction; current ad libitum (CA), where fish experienced forced swimming at 1 BL s−1; and current restriction (CR), with swimming exercise at 1 BL s−1 and a 25% feed restriction. Using a flow rate of 1 BL s−1 in the tanks for rainbow trout yielded several benefits. Notably, the fish in the CA group exhibited increased feed intake (60 ± 1.78 g fish−1) and enhanced fish growth with an FW of 91.72 ± 0.91 g, compared to the SA group (55.88 ± 0.88 g fish−1 for feed intake and 89.26 ± 0.81 g for FW). In contrast, the CR group showed a reduced feed intake (39.02 ± 2.78 g fish−1) and a lower FW (67.85 ± 1.49 g) compared to the CA group. In addition, the CA group demonstrated positive contributions to fish development with a reduced HSI (1.26 ± 0.02) in comparison to the SA group (1.56 ± 0.14). Inadequate nutrient provisioning in the SR and CR groups negatively impacted fish growth and system efficiency. Our findings suggest that optimizing water flow and feed benefits fish and plants and enhances system sustainability. [ABSTRACT FROM AUTHOR]

Published

2024

41. Количествен анализ на хранителните разтвори на три аквапонични системи.

Author

Кръстанова, Милена

Abstract

The effects of nutrient flows on tilapia fish (Oreochromis niloticus) and plant crops in three model aquaponic systems (deep water culture system, nutrient film technique and substrate beds) placed under identical conditions were evaluated. Quantitative analysis of ammonia, nitrite, nitrate concentrations and the factors on which they depend (air and fish water temperature, air humidity, pH and dissolved oxygen) was performed. The nutrient solutions affecting the yield and quality of the produce and the efficiency of the resources used were assessed. Monitoring and good management of aquaponics are necessary and mandatory requirements to ensure optimal conditions for the symbiosis between fish, beneficial bacteria and plants. [ABSTRACT FROM AUTHOR]

Published

2024

42. Exploring the Potential of Biostimulants to Optimize Lettuce Cultivation in Coupled and Decoupled Aquaponics Systems: Growth Performance, Functional Characteristics and Metabolomic Analysis.

Author

Chandrou, Eirini, Faliagka, Sofia, Mourantian, Anastasia, Kollaros, Marios Georgios, Karamanoli, Katerina, Pechlivani, Eleftheria-Maria, Katsoulas, Nikolaos, and Levizou, Efi

Subjects

AQUAPONICS, METABOLOMICS, LETTUCE, CIRCULAR economy, HYDROPONICS, PLANT performance, AGRICULTURAL productivity

Abstract

Zero-discharge and low-input aquaponics systems are a promising alternative to the intensive agricultural and aquacultural production systems currently used, ensuring high environmental sustainability. However, new approaches and management practices are needed to increase their productivity to reach the yields of classic production systems. In this context, the present study investigated for the first time the potential of two biostimulants to improve lettuce performance in aquaponics, whether coupled or decoupled, with hydroponics serving as a control. A comprehensive evaluation was conducted to assess the plant functional (focusing on the photosynthetic process evaluation) and growth responses at the whole-plant level. In addition, the nutritional state of the leaves was determined and metabolomic analysis was performed at the cellular level, the latter also for the first time in aquaponics research. The results demonstrated the limitations that coupled aquaponics poses in relation to lettuce growth, function and metabolism, which were already obvious from the 12th day of the experiment. Indicatively, the plants grown under coupled aquaponics exhibited a notable decrease in the leaf fresh weight, potassium content and nitrogen content, with reductions of 80%, 60%, and 30%, respectively, in comparison to the hydroponics control. However, the combined physiological and metabolomic data indicate that these plants down-regulate processes and metabolism to acclimate to low nutrient levels in lettuce leaves rather than experiencing damage. The application of biostimulants did not significantly optimize the plants' performance, though one of them appeared to be effective in improving some aspects of the photochemical efficiency. The decoupled and hydroponics systems resulted in similarly high yields and efficiency in terms of plant function, without any marked contribution from the biostimulants. We conclude that the decoupled aquaponics system has been successful in achieving yields comparable to those of hydroponics, with lower chemical inputs. Future studies should focus on examining other biostimulants in this system to further improve its performance while maintaining its environmental benefits within a circular economy framework. [ABSTRACT FROM AUTHOR]

Published

2024

43. Isolation and Identification of Lysinibacillus sp. and Its Effects on Solid Waste as a Phytate-Mineralizing Bacterium in an Aquaponics System.

Author

Riaño-Castillo, Edna Rocio, Rodríguez-Ortiz, Juan Carlos, Kim, Hye-Ji, Guerrero González, María de la Luz, Quintero-Castellanos, María Fernanda, and Delgado-Sánchez, Pablo

Subjects

SOLID waste, PHYTASES, PHYTIC acid, AQUAPONICS, ORGANIC wastes, BACTERIA, MINERALIZATION, PLANT nutrition

Abstract

Sedimentable solids generated in aquaponic systems are mainly composed of organic waste, presenting molecules such as phytate, which can be a potential source of inorganic nutrients through mineralization. This work aimed to isolate and identify phytase-producing bacteria and evaluate the inoculation effects of pure strains on mineralization and nutrient release from solid waste generated in aquaponic systems at different oxygen and temperature conditions. The bacteria were isolated from the settleable solids of a commercial aquaponic system and molecularly identified by amplifying the 16S rRNA gene. Subsequently, two tests were carried out: 1. Test for the biochemical identification of phytase-producing bacteria; 2. In vitro mineralization test, where the ability to mineralize phytate and release nutrients under different oxygen conditions [0 rpm (2.1 mg L−1) and 200 rpm (7.8 mg L−1)] and temperatures (24 and 37 °C) were evaluated. Our findings show that two pure strains of Lysinibacillus mangiferihumi can mineralize phytate under conditions of 200 rpm and 24 °C, mainly increasing the mineralization of PO4- and Ca, a property that has not yet been reported for this species. On the other hand, at 0 rpm and 24 °C, an increase in K was observed (control conditions), while the conditions of 200 rpm and 24 °C, regardless of bacterial inoculation, favored a rise in S, Mg, and Fe. The Lysinibacillus strains obtained in this investigation are of great importance due to their application in agriculture and the optimization of mineralization in aquaponic systems. A proper combination of oxygen and temperature will lead to a greater availability of nutrients for the growth and development of vegetables. [ABSTRACT FROM AUTHOR]

Published

2024

44. An Automated Fish-Feeding System Based on CNN and GRU Neural Networks.

Author

Son, Surak and Jeong, Yina

Abstract

AI plays a pivotal role in predicting plant growth in agricultural contexts and in creating optimized environments for cultivation. However, unlike agriculture, the application of AI in aquaculture is predominantly focused on diagnosing animal conditions and monitoring them for users. This paper introduces an Automated Fish-feeding System (AFS) based on Convolutional Neural Networks (CNNs) and Gated Recurrent Units (GRUs), aiming to establish an automated system akin to smart farming in the aquaculture sector. The AFS operates by precisely calculating feed rations through two main modules. The Fish Growth Measurement Module (FGMM) utilizes fish data to assess the current growth status of the fish and transmits this information to the Feed Ration Prediction Module (FRPM). The FRPM integrates sensor data from the fish farm, fish growth data, and current feed ration status as time-series data, calculating the increase or decrease rate of ration based on the present fish conditions. This paper automates feed distribution within fish farms through these two modules and verifies the efficiency of automated feed distribution. Simulation results indicate that the FGMM neural network model effectively identifies fish body length with a minor deviation of less than 0.1%, while the FRPM neural network model demonstrates proficiency in predicting ration using a GRU cell with a structured layout of 64 × 48. [ABSTRACT FROM AUTHOR]

Published

2024

45. Environmental impacts on algal–bacterial-based aquaponics system by different types of carbon source addition: water quality and greenhouse gas emission.

Author

Ji, Mingde, Gao, Hang, Zhang, Jian, Hu, Zhen, and Liang, Shuang

Subjects

GREENHOUSE gases, ELECTRON donors, WATER quality, AQUAPONICS, GREENHOUSE effect, BIOMASS production

Abstract

Carbon source addition is an important way improving the carbon and nitrogen transformation in aquaculture system; however, its effectiveness of algal–bacterial-based aquaponics (AA) through carbon source addition is still vague. In this study, the influences of organic carbon (OC-AA system) and inorganic carbon (IC-AA system) addition and without carbon source addition (C-AA system) on the operational performance of AA system were investigated. Results showed that 10.1–19.5% increase of algal–bacterial biomass enhanced the purifying effect of ammonia nitrogen in OC-AA system and IC-AA system relative to C-AA system. Moreover, extra electron donor supply in the OC-AA system obtained the lowest NO3−-N concentration. However, that was at the cost of aggravated N2O conversion ratio, which increased by more than 2.0-folds than other systems, attributing to 2.9-folds increase of nirS gene abundance. In addition, carbon source addition increased the pH and then decreased the fish biomass production of AA system. The results of this study would provide theoretical supports of carbon source addition on the performance of nutrient transformation and greenhouse gas effect in AA system. [ABSTRACT FROM AUTHOR]

Published

2024

46. Integration of probiotics in aquaponic systems: an emerging alternative approach.

Author

Kasozi, Nasser, Iwe, Gerald Degu, Walakira, John, and Langi, Sandra

Subjects

*PROBIOTICS, *TRADITIONAL farming, *SUSTAINABLE agriculture, *SUSTAINABILITY, *AQUAPONICS, *LITERATURE reviews

Abstract

The increasing demand on water resources, reduced land for agriculture, and concerns over food and nutrition security have prompted the evolution of innovative and complex food production systems. In this context, efficient and sustainable food production systems such as aquaponics are viewed as an important and environmentally friendly technology for adaptation under resource-limited environments. Producing food in soilless systems is a promising strategy, as this method utilizes significantly less water than traditional agriculture. However, optimizing growing conditions to enhance crop and fish yields in aquaponics is frequently ambiguous and is often not economically feasible. One of the strategies to improve plant yields and supply of nutrients in aquaponics is the application of probiotics. With this strategy, the crop yields in aquaponics are improved via a variety of mechanisms, including nitrogen fixation, solubilization of mineral nutrients, organic matter mineralization, plant hormone modulation, and biocontrol. As a result, incorporating probiotics in aquaponic systems is a strategy for mitigating environmental effects and advancing sustainable agriculture. This review paper provides the current knowledge of the use of probiotics in aquaponics. Suggestions for further studies on the effects of probiotics in aquaponic systems are proposed. Through literature review, integrating probiotics into aquaponic systems has the potential to improve nutrient supply, modulation of water quality parameters, and microbial communities, which are key processes in enhancing the productivity of aquaponic systems. [ABSTRACT FROM AUTHOR]

Published

2024

47. Development of a bio-green floating system (BFAS) for the improvement of water quality, fish health, and aquaculture production.

Author

Sopawong, Arissara, Yusoff, Fatimah Md, Zakaria, Muta Harah, Khaw, Yam Sim, Monir, Md Shirajum, and Hashim, Amalia Mohd.

Subjects

*WATER quality, *ENVIRONMENTAL degradation, *FISH farming, *AQUACULTURE, *WASTEWATER treatment, *MICROBIAL inoculants

Abstract

Aquaculture activities often lead to environmental deterioration due to discharges of nutrient-rich wastewater without treatments. The present study aimed to develop a bio-green floating system (BFAS) to utilize excess nutrients, improve water quality, enhance plant and fish production, and minimize threats of aquaculture effluents. The floating raft system was constructed using water spinach integrated with a substrate (lava rock) to allow the development of biofilm communities, which together with the plants, improved the water quality by nutrient sequestration. Three treatments were employed for 105 days: (1) zero water exchange without BFAS (T1-NCT); (2) water exchange at 5-day intervals without BFAS (T2-PCT); (3) zero water exchange with BFAS (T3-BFAS). Total ammonia removal was significantly (p < 0.05) higher (92.4 ± 1.2%) in T3-BFAS compared to T2-PCT (89.2 ± 0.5%). The percent removal of other nutrients such as unionized ammonia, nitrite, and soluble reactive phosphorus was significantly (p < 0.05) higher in T3-BFAS compared to T2-PCT and the control. The T3-BFAS showed a significantly (p < 0.05) lower feed conversion ratio (FCR, 1.16 ± 0.05), higher (p < 0.05) specific growth rate (SGR, 3.58 ± 0.03), and better health indicators (hemato-biochemistry characteristics) compared to the other treatments. Heavy metals in T3-BFAS were significantly lower (p < 0.05) than the control and were significantly higher in roots than in the water. The findings suggested that the simple newly developed energy-free BFAS could enhance water quality, improve fish health, and optimize fish production in an aquaculture system without water exchange. [ABSTRACT FROM AUTHOR]

Published

2024

48. Aquaponics as a climate‐smart technology for sustainable food production: A comparison with conventional production system in United Arab Emirates.

Author

Nishanth, Drishya, Alshamsi, Mariam H. S., Alkaabi, Alreem M. K. A., AlKaabi, Aysha H. A., Alnuaimi, Shamma H. K., Nair, Chythra Somanathan, and Jaleel, Abdul

Subjects

SUSTAINABILITY, AQUAPONICS, BASIL, FOOD production, WATER efficiency, HERBS, FOOD science

Abstract

This research aimed to standardize the growth of two commonly cultivated herbs in the United Arab Emirates, basil (Ocimum basilicum L.) and coriander (Coriandrum sativum L.), within an aquaponic system. The study compared a recirculatory aquaponic system (RAS) with static aquaculture systems (for fish performance) and irrigated greenhouse cultivation systems (for herb performance). The project assessed growth, element composition, and aquaponic efficacy to determine the viability of aquaponics for these herbs. In the soilless (aquaponic) system, both herbs exhibited significantly enhanced growth parameters, including plant height, root length, leaf count, and fresh and dry weights, compared to conventional soil‐based cultivation. This growth enhancement was attributed to the additional nutrients derived from fish waste in the aquaponic system. Furthermore, plants displayed significantly higher element levels, highlighting the effectiveness of aquaponics in nutrient delivery. Notably, the aquaponic system demonstrated superior antioxidant activity in both herbs. The study also revealed remarkable water use efficiency in the aquaponic system, with water savings exceeding 90% compared to conventional methods. These findings establish the efficiency and sustainability of aquaponic systems over traditional food production approaches, particularly in arid regions such as the United Arab Emirates. Utilizing an aquaponic system for these commonly cultivated herbs resulted in improved growth and resource efficiency, affirming its viability as an environmentally sustainable and efficient method of food production in desert climates. [ABSTRACT FROM AUTHOR]

Published

2024

49. Optimisation of Small-Scale Aquaponics Systems Using Artificial Intelligence and the IoT: Current Status, Challenges, and Opportunities.

Author

Channa, Abdul Aziz, Munir, Kamran, Hansen, Mark, and Tariq, Muhammad Fahim

Subjects

*ARTIFICIAL intelligence, *AQUAPONICS, *SUSTAINABILITY, *INTERNET of things, *EVIDENCE gaps, *URBANIZATION

Abstract

Environment changes, water scarcity, soil depletion, and urbanisation are making it harder to produce food using traditional methods in various regions and countries. Aquaponics is emerging as a sustainable food production system that produces fish and plants in a closed-loop system. Aquaponics is not dependent on soil or external environmental factors. It uses fish waste to fertilise plants and can save up to 90–95% water. Aquaponics is an innovative system for growing food and is expected to be very promising, but it has its challenges. It is a complex ecosystem that requires multidisciplinary knowledge, proper monitoring of all crucial parameters, and high maintenance and initial investment costs to build the system. Artificial intelligence (AI) and the Internet of Things (IoT) are key technologies that can overcome these challenges. Numerous recent studies focus on the use of AI and the IoT to automate the process, improve efficiency and reliability, provide better management, and reduce operating costs. However, these studies often focus on limited aspects of the system, each considering different domains and parameters of the aquaponics system. This paper aims to consolidate the existing work, identify the state-of-the-art use of the IoT and AI, explore the key parameters affecting growth, analyse the sensing and communication technologies employed, highlight the research gaps in this field, and suggest future research directions. Based on the reviewed research, energy efficiency and economic viability were found to be a major bottleneck of current systems. Moreover, inconsistencies in sensor selection, lack of publicly available data, and the reproducibility of existing work were common issues among the studies. [ABSTRACT FROM AUTHOR]

Published

2024

50. Effect of Aquaponically Grown Duckweed as a Sustainable Feed on Growth Indices, Water Quality, and Digestive Activities, for the Nile Tilapia Reared in Aquaponic Culture.

Author

Alkhamis, Yousef Ahmed

Subjects

*NILE tilapia, *WATER quality, *PORTULACA oleracea, *AQUATIC plants, *WEIGHT gain, *DIGESTIVE enzymes

Abstract

One of the challenges facing aquaculture is finding a high-value, sustainable, and low-cost alternative feedstuff. Duckweed, a small aquatic plant, has a high-quality protein value. This study was conducted to evaluate the impact of aquaponically produced duckweed L. minor as a substitute feedstuff and its effect of different levels (0, 10, 20, and 30%) on water quality, growth indices, digestive activities, and profitability of the Nile tilapia Oreochromis niloticus fingerlings (15.27± 0.19g) using aquaponics system for 8 weeks. With a completely randomized design, fish were stocked (6kg/m3) in 12 experimental aquaponic units (250L). Results showed that duckweed inclusion had a significant impact on water quality measures (P< 0.05), leading to a drop in nitrogen and phosphorus levels in fish tanks. Duckweed improved growth indexes, digestive enzyme activities, and profitability (P< 0.05). At a substitution rate of 20% of duckweed in the diet, the feeding impact was at its peak, resulting in a weight gain rate of 63.2g in 56 days, which was 32.7% greater than the control group (P< 0.05). Compared to the control group, the fish showed significantly higher body weight, specific growth rate, feed conversion ratio, condition factor, and hepatosomatic index (P< 0.05). Duckweed stimulated the digestive system's amylase, protease, and lipase activity (P< 0.05). Based on the findings, it can be reported that, the Nile tilapia fingerlings reared in an aquaponics system can include duckweed at a rate of 20% in diet to show better growth indices and profitability. [ABSTRACT FROM AUTHOR]

Published

2024