Performance of Channel Catfish and Hybrid Catfish in Single‐Batch, Intensively Aerated Ponds

Kumar, Ganesh; Li, Menghe H.; Wise, David J.; Mischke, Charles C.; Rutland, Billy; Tiwari, Ambika; Aarattuthodiyil, Suja; Griffin, Matt J.; Khoo, Lester H.; Ott, Brian D.; Torrans, Les; Tucker, Craig S.

doi:10.1002/naaq.10109

Cited by 21 publications

(17 citation statements)

References 54 publications

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“…This single‐batch production strategy for hybrid catfish grow out is being increasingly adopted by U.S. catfish producers, as greater production from these ponds, typically 12,000–18,000 lb/acre (Bott et al 2015; Kumar and Engle 2017a; Torrans and Ott 2018), spreads the fixed costs over greater volumes of fish production, thus achieving cost efficiencies. Compared with multiple‐batch systems, the breakeven yields that are required to cover the total costs of production in intensively aerated systems are higher (Kumar et al 2018, 2019, 2020; Engle et al 2020), causing predation losses to be a greater source of economic risk.…”

Section: Discussionmentioning

confidence: 99%

“…The fish were immediately released back into the ponds, and the study continued through the remainder of the production season. The fish were fed once daily and managed according to standard industry protocols (Kumar and Engle 2017a; Kumar et al 2019).…”

Section: Methodsmentioning

confidence: 99%

“…For the intensively aerated pond scenarios, the enterprise budgets were developed for a 5‐acre pond (implied to be part of a 330‐acre farm) using the average production variables from Table 2. The additional investments that were required (Kumar et al 2017a, 2019) for the construction and renovation of small 5‐acre intensively aerated ponds were spread over the useful life of the investment (10 years). The annual depreciation costs were calculated by using a straight‐line depreciation method.…”

Section: Methodsmentioning

confidence: 99%

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Economic Losses of Catfish to Avian Predation: A Case Report

et al. 2021

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Avian predation in catfish aquaculture has been a persistent issue throughout the history of the industry, and as production has expanded predation from piscivorous birds has intensified. Catfish ponds in the Mississippi River delta (in the Mississippi migratory flyway) provide a constant and readily accessible supply of forage for birds. Intensive foraging by fish‐eating birds has led to a specific regulatory policy and numerous on‐farm and regional management efforts. However, in 2016, legal challenges lead to recision of some federal policies and uncertainty as to allowable management, resulting in limitations on bird depredation. Estimating the extent of fish losses to avian predators is difficult, as loss estimates from farms are often confounded with disease‐ and management‐related mortalities. This study details the reported losses to birds that were observed in commercial‐scale catfish ponds at the Thad Cochran National Warmwater Aquaculture Center, Stoneville, Mississippi, during periods of limited bird management. The observed fish losses attributed to birds ranged from 33% to 95% loss in survival and potential yield losses of 4,396 to 8,889 lb/acre, increasing production costs and decreasing net returns. Net economic losses when accounting for negative net returns and lost profits ranged from US$3,518 to $4,060/acre. Losses of this magnitude on commercial fish farms are economically detrimental, especially because catfish farms lack the compensatory economic relief programs that are available in other agriculture sectors. Roost dispersal activities that are organized by federal agencies and avoiding delays in issuing bird depredation permits are vital for mitigating this persistent and growing regulatory problem in the U.S. catfish industry.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Economic Losses of Catfish to Avian Predation: A Case Report

et al. 2021

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“…Given the unique body shape (smaller head and wider trunk) and unique behavioral characteristics, hybrid catfish do not grade well in conventional sock graders (Torrans & Ott, 2018). As such, hybrid catfish are generally raised in single‐batch systems (Bott, Roy, Hanson, Chappell, & Whitis, 2015; Dunham et al, 2000; Hanson et al, 2020; Kumar et al, 2019; Kumar & Engle, 2010). Channel catfish remain the preferred fish in multiple‐batch systems.…”

Section: Introductionmentioning

confidence: 99%

“…This is also reflected in multiple‐batch production strategies in which channel catfish are raised at higher stocking densities in relatively smaller (1.6–3.2 ha) intensively aerated ponds equipped with >9 kW/ha fixed paddlewheel aeration rate (Engle, Kumar, & van Senten, 2020; Kumar et al, 2020). Such intensification incurs higher upfront investment and greater operating costs to purchase additional fingerlings, feed, and aerators; however, cost efficiencies can be achieved by spreading the fixed costs over greater volumes of fish production (Kumar et al, 2019; Kumar et al, 2020). Although technological advances such as the increased adoption of fixed‐paddlewheel aeration (Kumar & Engle, 2017a; Torrans, 2005, 2008) allow for the accommodation of increased catfish biomass in single‐batch systems, its effect in multiple‐batch systems raising channel catfish has not been ascertained.…”

Section: Introductionmentioning

confidence: 99%

Effect of understocking density of channel catfish fingerlings in intensively aerated multiple‐batch production

Kumar

Wise

et al. 2020

J World Aquaculture Soc

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Multiple‐batch production is the most widely practiced method of raising channel catfish. Producers are increasingly adopting intensified production practices in multiple‐batch systems by increasing stocking density and aeration rates as a means to improve cost efficiencies. Proven stocking recommendations are required for the efficient implementation of recent developments in multiple‐batch production. Twelve 0.4‐ha ponds were understocked with 17,484, 20,612, and 26,124 fingerlings/ha (mean weight = 40 g/fish) over equal weights of carryover fish (0.46 kg/fish @ 4,589 kg/ha). Fish were fed once daily to apparent satiation with a 28% protein floating feed and aerated with a single 7.4‐kW electric paddlewheel aerator. Density‐dependent significant differences were absent for gross, net, daily net yields, marketable yields (≥0.54 kg), growth (g/day), and survival. Sub‐marketable yield (<0.54 kg) and feeding rate increased significantly with increased understocking density. Economic analysis revealed increased breakeven prices and diminished net returns with increased stocking density when sub‐marketable fish were not considered as revenue. These differences in production costs and profits among the three treatments became minimal when sub‐marketable fish were included as revenue. All three density treatments attained positive annual net cash flows. This study validates channel catfish understocking densities of 17,000–26,000 fish/ha to improve cost efficiency in intensively aerated, multiple‐batch production systems.

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Effect of Brooder Age and Size on Fry Size Variation in Channel Catfish

et al. 2023

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Variation in harvest size of ictalurid catfishes can be problematic for both catfish producers and processors, ultimately reducing profitability for both. Although harvesting and grading techniques can reduce this variation, the biological underpinnings of these size discrepancies remain unknown. Fry from Channel Catfish Ictalurus punctatus brooders that were 2–5 years old were measured to determine the amount of naturally occurring variation in body mass among sac fry and swim‐up fry. Over two spawning seasons, older brooders consistently produced larger sac fry (38–54% larger) and swim‐up fry (42–51% larger) than their younger counterparts. However, within‐spawn fry size variation was similar among all brooder ages measured. Regression modeling indicated that broodstock body mass did not influence fry body mass, whereas broodstock age was a significant predictor. These data reveal that brooder age is an important determinant of fry size and that initial fry body mass variation could be relevant to understanding fingerling size variation and may play a role in improving the production of ictalurid catfishes.

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Performance of Channel Catfish and Hybrid Catfish in Single‐Batch, Intensively Aerated Ponds

Cited by 21 publications

References 54 publications

Economic Losses of Catfish to Avian Predation: A Case Report

Economic Losses of Catfish to Avian Predation: A Case Report

Effect of understocking density of channel catfish fingerlings in intensively aerated multiple‐batch production

Effect of Brooder Age and Size on Fry Size Variation in Channel Catfish

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