A Simulation Study to Evaluate Biases in Population Characteristics Estimation Associated with Varying Bin Numbers in Size‐Based Age Subsampling

Hilling, Corbin D.; Jiao, Yan; Bunch, Aaron J.; Phelps, Quinton E.

doi:10.1002/nafm.10429

Cited by 6 publications

(22 citation statements)

References 21 publications

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“…For age‐classes in which the number of fish was fewer than 1,000 individuals, all data were used. Age‐based subsampling was recently demonstrated to be unbiased (Goodyear 2019), but neither that study nor the present study evaluated this assumption relative to gear selectivity, although this can be an important consideration (Hilling et al 2020). Therefore, we also ran models with subsamples of 10 and 100 fish per system per year to confirm that this choice did not arbitrarily influence model selection or statistical inference.…”

Section: Methodsmentioning

confidence: 83%

“…First, we assumed that the wide range of gears and methods used for fish collection were representative of these populations through time. Importantly, it has been demonstrated that gear selectivity can influence estimated VBGF parameters (Gwinn et al 2010) and in some instances can even override attempts to correct this through size-based subsampling within gears (Hilling et al 2020). Through inclusion of multiple gears and collection, our intention was to minimize the potential for bias from any given gear.…”

Section: Discussionmentioning

confidence: 99%

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Climate Change May Cause Shifts in Growth and Instantaneous Natural Mortality of American Shad Throughout Their Native Range

et al. 2021

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American Shad Alosa sapidissima is an anadromous species with populations ranging along the U.S. Atlantic coast. Past American Shad stock assessments have been data limited and estimating system-specific growth parameters or instantaneous natural mortality (M) was not possible. This precluded system-specific stock assessment and management due to reliance on these parameters for estimating other population dynamics (such as yield per recruit). Furthermore, climate-informed biological reference points remain a largely unaddressed need in American Shad stock assessment. Population abundance estimates of American Shad and other species often rely heavily on M derived from von Bertalanffy growth function (VBGF) parameters. Therefore, we developed Bayesian hierarchical models to estimate coastwide, regional, and system-specific VBGF parameters and M using data collected from 1982 to 2017. We tested predictive performance of models that included effects of various climate variables on VBGF parameters within these models. System-specific models were better supported than regional or coast-wide models. Mean asymptotic length (L ∞ ) decreased with increasing mean annual sea surface temperature (SST) and degree days (DD) experienced by fish during their lifetime. Although uncertain, K (Brody growth coefficient) decreased over the same range of lifetime SST and DD. Assuming no adaptation, we projected changes in VBGF parameters and M through 2099 using modeled SST from two climate projection scenarios (Representative Concentration Pathways 4.5 and 8.5). We predicted reduced growth under both scenarios, and M was projected to increase by about 0.10. It is unclear how reduced growth and increased mortality may influence population productivity or life history adaptation in the future, but our results may inform stock assessment models to assess those trade-offs.

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Section: Methodsmentioning

confidence: 83%

Section: Discussionmentioning

confidence: 99%

Climate Change May Cause Shifts in Growth and Instantaneous Natural Mortality of American Shad Throughout Their Native Range

et al. 2021

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“…Importantly, the aged subsample is not a random sample of either the entire sample or the population, as these data are collected according to a fixed number of individuals per length‐group. Using a length‐stratified aged subsample without incorporating information from the entire sample has the potential to drastically bias growth estimates and should not be used to directly evaluate growth (Chang et al 2019; Goodyear 2019; Hilling et al 2020; Perreault et al 2020). Evaluating growth with length‐stratified subsampled age data should employ a method to “expand” those data to the entire sample such that estimation uses information from all fish collected (i.e., account for the length‐stratified sampling design).…”

mentioning

confidence: 99%

“…The reweighting method of Chih (2009) estimates growth parameters by fitting the VBGM to length–age data in the aged subsample, where each observation is weighted by the ratio of the proportion of fish from the entire sample that belong to the fish’s length‐bin to the proportion of fish from the aged subsample that belong to the fish’s length‐bin. Hilling et al (2020) found that the reweighting method accurately estimated growth parameters for the population in some cases but performed poorly in other cases (e.g., with dome‐shaped selectivity when extracting the entire sample from the population). Perreault et al (2020), expanding on the work of Zhang and Cadigan (2019), described several methods for estimating growth that were based on the statistical theory of double sampling.…”

mentioning

confidence: 99%

“…Goodyear (2019) evaluated five experimental sampling designs and showed that some designs, such as increasing effort to increase the number of individuals in larger length‐bins, could exacerbate biases. Hilling et al (2020) examined the effects of varying length‐bin width and subsample size when evaluating growth and found that no combination of bin width or sample size was superior in reducing bias. These papers focused on how growth estimates derived from the aged subsample estimated the true growth parameters of the population.…”

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confidence: 99%

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Evaluating the Performance of Methods Used to Estimate Growth Parameters from Subsampled Age Data

Lusk¹,

Middaugh²,

Ogle

2021

N American J Fish Manag

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Due to time and resource limitations, the growth of many fish species is evaluated with age and length data in a length‐stratified subsample of a sample from a population. Some fisheries professionals draw inferences about growth using age and length data from only those fish that were actually aged (aged‐only method). Alternatively, growth may be evaluated by employing a method of incorporating the length‐stratified aged subsample with information from the entire sample of fish collected, such as the weighted‐mean and assigned‐age methods, which are commonly used in inland fisheries management. More recently, two prominent alternatives to those methods have emerged: the reweighting and empirical proportion methods. In this study, we used observed data from three freshwater fish species with different life history traits (short‐ to long‐lived) to inform a simulation model comparing estimated von Bertalanffy growth model parameters and predicted mean lengths at age calculated using the five aforementioned methods across a range of sample sizes per length‐group and a range of CVs. As expected, our results demonstrated that the aged‐only method is unreliable and biased when estimating von Bertalanffy parameters and mean lengths at age. The weighted‐mean method performed better than the aged‐only method but was not among the top‐performing methods. The assigned‐age, reweighting, and empirical proportion methods all performed well and produced similar estimates, although the empirical proportion method generally resulted in slightly more precise and less biased estimates. We recommend that fisheries professionals discontinue their use of the aged‐only and weighted‐mean methods and instead use the assigned‐age, reweighting, or empirical proportion method.

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Comparing Channel Catfish Populations in the Fragmented Minnesota River

Sindt

2021

N American J Fish Manag

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Channel Catfish Ictalurus punctatus provide important fisheries in lotic systems throughout much of North America, but few studies have evaluated the influence of dams and habitat fragmentation on their populations. The Minnesota River is an important recreational catfish fishery in Minnesota that is fragmented by Granite Falls Dam, located 395 km upstream from the confluence with the Mississippi River. Granite Falls Dam is a significant barrier to upstream fish passage; consequently, the upstream fish community is less diverse than the downstream community and habitat availability differs between reaches. For this study, hoop‐net assessments conducted by the Minnesota Department of Natural Resources during 2014–2017 were used to compare Channel Catfish catch rates, size structure, growth, and annual survival between the upstream and downstream reaches. Hoop‐net catch rates upstream (mean ± SE = 45.1 ± 5.2 fish/net‐night) were significantly greater by an order of magnitude compared to catch rates downstream (3.9 ± 0.4 fish/net‐night). Size structure of Channel Catfish also significantly differed between reaches: the percentage of stock‐length (≥280‐mm) fish that were preferred length or larger (≥610 mm) was 28.4% downstream compared to 5.8% upstream. Annual survival estimates and growth indices were generally similar between reaches, but there was evidence of greater longevity downstream, where the oldest aged fish were 24 years compared to 19 years upstream. This study demonstrates population differences that may be influenced and exacerbated by habitat fragmentation and provides support for considering each population individually when making future management decisions.

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A Simulation Study to Evaluate Biases in Population Characteristics Estimation Associated with Varying Bin Numbers in Size‐Based Age Subsampling

Cited by 6 publications

References 21 publications

Climate Change May Cause Shifts in Growth and Instantaneous Natural Mortality of American Shad Throughout Their Native Range

Climate Change May Cause Shifts in Growth and Instantaneous Natural Mortality of American Shad Throughout Their Native Range

Evaluating the Performance of Methods Used to Estimate Growth Parameters from Subsampled Age Data

Comparing Channel Catfish Populations in the Fragmented Minnesota River

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