Monitoring and Managing Fishes that Are Invisible and Keep Moving Around: Influences of an Invasive Species and Environmental Factors on Capture Probability

Healy, Brian D.; Moore, J. F.; Pine, William E.

doi:10.1002/nafm.10755

Cited by 5 publications

(12 citation statements)

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“…2018; Healy et al. 2022)—for example, a nocturnal activity pattern is hypothesized to be an adaptation to reduce predation risk in several temperate fish species (Emery 1973; Hanych et al. 1983; Culp 1989).…”

Section: Discussionmentioning

confidence: 99%

Improving Salmonid Monitoring by Nocturnal Counting in Rivers

Kambestad

Hellen²,

Jensen

et al. 2022

N American J Fish Manag

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Accurate abundance estimates are crucial for evidence-based fisheries management. In rivers, drift dive counting and electrofishing are commonly used for quantifying fish abundance. However, the likelihood that fish are detected by these counting methods is affected by a range of factors, with substantial potential implications for the outcomes. Fish behavior and distribution also differs with light intensity, yet diel variation in abundance estimates produced by common enumeration methods has received little attention. Here, we present a comparison of diurnal and nocturnal counts of the landlocked population of Atlantic Salmon Salmo salar, known as "småblank," and Brown Trout Salmo trutta in a Norwegian river. Six drift dive transects and 12 electrofishing sites were surveyed at day and night in early autumn. During drift dives, småblank were exclusively observed at night. Brown Trout were observed by snorkelers both day and night but in significantly higher numbers at night (six times more Brown Trout per 100 m at night versus in the day). Catch per unit effort of backpack electrofishing was significantly higher at night than at daytime for both småblank and Brown Trout older than age 0 (202% and 108% higher, respectively). We argue that differences in drift dive counts were mainly caused by fish hiding in the substrate during the day and being more active at night, resulting in diel differences in detection rate. Further studies are needed to determine whether differences in electrofishing catches were caused by diel fish migrations or higher catchability at night.Quantifying abundance is fundamental in fisheries research and management. The most straightforward way of estimating population size is counting all individuals within their spatial distribution as is attempted for adults of some migratory fish populations (e.g., Orell and Erkinaro 2007;Skoglund et al. 2021). This is impractical for most species, and population monitoring is therefore often conducted by local abundance estimation in selected areas (for discussions on different approaches, see Otis et al. 1978;Royle and Nichols 2003;Brashares and Sam

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Section: Discussionmentioning

confidence: 99%

Improving Salmonid Monitoring by Nocturnal Counting in Rivers

Kambestad

Hellen²,

Jensen

et al. 2022

N American J Fish Manag

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“…Bright Angel Creek subpopulation suppression included life stage and electrofishing pass‐specific

\hat{p}

for each subpopulation (MR) (Table 1) estimated from 3‐pass electrofishing (Healy, Moore, et al., 2022). We also included a scenario with eradication of the BACU subpopulation via chemical piscicides and interception of migrants at weir operations (Healy et al., 2020).…”

Section: Methodsmentioning

confidence: 99%

“…We focused perturbation analysis on the CR because different techniques may be available to target different life stages (e.g., dam operations to target incubating eggs [Korman et al., 2011] vs. electrofishing for older life stages). All life stages are susceptible to electrofishing in BAC (Healy, Moore, et al., 2022). Although the DyHDER accounts for some environmental and demographic stochasticity (i.e., vital rate temporal variance) (Murphy et al., 2020) (Appendix S1; Figures 4, 5, & 7), we acknowledge our use of mean values for other parameters (e.g.,

\hat{p}

for electrofishing suppression) causes underrepresentation of error in our results; thus, scenario outcomes should be interpreted relative to each other (Morris & Doak, 2002).…”

Section: Methodsmentioning

confidence: 99%

“…For example, invasive amphibians have complex life cycles that may include aquatic egg or larval stages, metamorphosis to a juvenile stage, and sometimes a transition to upland adult habitats, all of which vary in vulnerability to removal techniques (Govindarajulu et al., 2005 ). Fishing gears used to control invasive fishes, such as electro‐fishing or netting, also select for larger (and thus older) individuals (Healy, Moore, et al., 2022 ; Koel et al., 2020 ). Species with complex life histories, including a partial or fully migratory stage, may also require a landscape‐scale approach that controls explicitly for dispersal between populations (Day et al., 2018 ; Milt et al., 2018 ).…”

Section: Introductionmentioning

confidence: 99%

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Exploring metapopulation‐scale suppression alternatives for a global invader in a river network experiencing climate change

Healy

Budy

Yackulic

et al. 2022

Conservation Biology

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“…We assumed that capture probability, p, for electrofishing in the Colorado River was constant at the site scale and scaled p to the state scale based on this effort calculation. Sampling of brown trout in Bright Angel Creek occurred during a trout suppression project (Healy et al 2020), involved three-passes of depletion backpack electrofishing, and has previously been shown to include substantial interannual variation in capture probability (Healy et al 2022c). We summarized the catch of adult brown trout per pass via this effort and fit depletion models to estimate the year-specific p-star (i.e., cumulative p across three passes; eight parameters) for brown trout that were in Bright Angel Creek during the winter of years with removals within the model.…”

Section: Basic Structure Of Our Multistate Mark-recapture Modelmentioning

confidence: 99%

Impeding access to tributary spawning habitat and releasing experimental fall-timed floods increase brown trout immigration into a dam’s tailwater

Healy

Yackulic

Schelly

2023

Can. J. Fish. Aquat. Sci.

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River ecosystems have been altered by flow regulation and species introductions. Regulated flow regimes often include releases designed to benefit certain species or restore ecosystem processes, and invasive species suppression programs may include efforts to restrict access to spawning habitat. The impacts of these management interventions are often uncertain. Here, we assess hypotheses regarding introduced brown trout (Salmo trutta) movement in a regulated river. We model mark-recapture data in a multistate framework to assess whether movement was affected by the operation of a tributary weir (restricting access to spawning habitat), experimental releases of fall-timed High Flow Experiments (Fall HFEs), or simply increased during the fall, spawning season. Our results suggest that the presence of the weir led to reduced tributary homing and the release of Fall HFEs stimulated upstream movement and straying. Both effects are of a similar magnitude, however the fall HFE effect is more certain. Our results suggest the expansion of an invasive species was stimulated by management interventions, and demonstrate the potential for unanticipated outcomes of restoration in highly altered river ecosystems.

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Monitoring and Managing Fishes that Are Invisible and Keep Moving Around: Influences of an Invasive Species and Environmental Factors on Capture Probability

Cited by 5 publications

References 65 publications

Improving Salmonid Monitoring by Nocturnal Counting in Rivers

Improving Salmonid Monitoring by Nocturnal Counting in Rivers

Exploring metapopulation‐scale suppression alternatives for a global invader in a river network experiencing climate change

Impeding access to tributary spawning habitat and releasing experimental fall-timed floods increase brown trout immigration into a dam’s tailwater

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