Bioenergetic Habitat Suitability Curves for Instream Flow Modeling: Introducing User‐Friendly Software and its Potential Applications

Naman, Sean M.; Rosenfeld, Jordan S.; Neuswanger, Jason R.; Enders, Eva C.; Hayes, John W.; Goodwin, Eric; Jowett, Ian G.; Eaton, Brett C.

doi:10.1002/fsh.10489

Cited by 26 publications

(30 citation statements)

References 38 publications

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“…These models (like inSTREAM) predict a trout's net rate of energy intake (NREI, often treated as equivalent to growth potential) as a function of hydraulic conditions, food availability, temperature, and fish characteristics. NREI models are used as an alternative way to evaluate habitat in PHABSIM-like models, by treating NREI as a measure of "suitability" (e.g., Jowett, Hayes, & Neuswanger, 2021;Naman et al, 2020;Naman, Rosenfeld, Neuswanger, Enders, & Eaton, 2019) and, combined with models of drift transport, to predict the "carrying capacity" of stream reaches (e.g., Hayes, Hughes, & Kelly, 2007;Wall, Bouwes, Wheaton, Saunders, & Bennett, 2015). Here we identify important specific differences between InSTREAM 7 and traditional assessment methods, specifically the use of PHABSIM and NREI models and temperature criteria.…”

Section: How Instream Differs From Other Modelsmentioning

confidence: 99%

InSTREAM 7: Instream flow assessment and management model for stream trout

Railsback

Ayllón

Harvey

2021

River Research & Apps

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Mechanistic, individual-based simulation models have been used for >25 years to overcome well-known limitations of "habitat suitability" models. InSTREAM 7 is the latest of our individual-based models for predicting the effects of flow and temperature regimes on stream salmonid populations. Unlike PHABSIM (or other methods based on habitat "quality," e.g., as net rate of energy intake), inSTREAM mechanistically represents specific effects of flow and temperature on all life stages, and how those effects combine into testable predictions of population measures such as abundance, relative abundance of multiple trout species, and persistence. InSTREAM 7 is the first version to also represent the daily light cycle (dawn, day, dusk, and night) and how feeding, predation risk, and individual behavior vary among light phases. An example assessment illustrates the importance of inSTREAM's multiple mechanisms: predicted trout population response to flow and temperature regimes depended on the effects of sub-lethal temperatures on feeding behavior and effects of temperature on egg survival and development, as well as how depth and velocity affected growth and predation risk. While its input data requirements are comparable to PHABSIM's, inSTREAM provides a more comprehensive framework for thinking about and predicting specific, well-known effects of flow and temperature. It has also proven useful for designing and evaluating restoration projects and for prioritizing alternative management actions. InSTREAM 7 is free, open-source, completely updated with recent literature, and implemented in the popular NetLogo software platform that makes customization easy.

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Section: How Instream Differs From Other Modelsmentioning

confidence: 99%

InSTREAM 7: Instream flow assessment and management model for stream trout

Railsback

Ayllón

Harvey

2021

River Research & Apps

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“…This emphasizes that density may not be an accurate indicator of habitat quality for drift-feeding salmonids, particularly for juveniles at high densities or when rearing habitat is limited. This study also highlights a potential solution in the form of bioenergetic-based HSCs, which can provide an estimate of habitat quality across various depth and velocity combinations using modeled energy intake and swimming costs for drift-feeding fish based on the fundamental bioenergetics of central-placed foraging (Hughes & Dill, 1990;Naman et al, 2020a). Because net energy intake is estimated in the absence of competition, it represents a robust index of habitat quality that is independent of fish density (Naman, Rosenfeld, Neuswanger, Enders, & Eaton, 2020c;Rosenfeld et al, 2016;Rosenfeld, Bouwes, Wall, & Naman, 2014).…”

Section: Effects Of Territoriality On Habitat Suitability Curvesmentioning

confidence: 99%

“…Calculating bioenergetic-based HSCs is a complicated process that will deter most instream flow biologists. However, userfriendly software (BioenergeticHSC; Naman et al, 2020c, see Data S1) has recently been developed to automate the creation of bioenergetic-based HSCs, which can then be used as stand-alone curves or to serve as diagnostics to flag whether empirical frequency-based curves are likely to be biased (Naman et al, 2020a). For example, any HSC that shows very high habitat quality at low velocities for fish that are known to be drift-feeders…”

Section: Effects Of Territoriality On Habitat Suitability Curvesmentioning

confidence: 99%

“…The first source of bias relates to the assumption that the frequency of habitat use accurately reflects habitat quality; however, territoriality generates strong potential for systematic biases in velocity HSCs when dominant individuals displace subordinate fish to lower velocity micro-habitats at high densities, thereby inflating the fitness value of low-velocity habitats (Beecher, Caldwell, DeMond, Seiler, & Boessow, 2010). Second, habitat simulation models assume that fish abundance is limited by the availability of physical habitat (Orth, 1987), and ignore flow effects on prey flux and consumption (Naman et al, 2020a), which may decrease more quickly with reduced flow than available habitat (Hayes, Goodwin, Shearer, Hay, & Kelly, 2015;Rosenfeld et al, 2016;Rosenfeld & Ptolemy, 2012). Finally, the use of focal velocities to construct traditional habitat suitability curves may systematically underestimate velocity preference within the broader foraging arena of a drift-feeding fish, thereby underestimating the flows that maximize overall energy intake (Naman, Rosenfeld, Jordison, Kuzyk, & Eaton, 2020b).…”

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confidence: 99%

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Identifying and mitigating systematic biases in fish habitat simulation modeling: Implications for estimating minimum instream flows

Rosenfeld

Naman

2021

River Research & Apps

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Habitat simulation approaches (e.g., PHABSIM) have been used to model instream flows in thousands of streams and rivers and remain the most widely implemented detailed instream flow methodology. However, recent studies suggest that conventional habitat simulation models incorporate assumptions that may systematically underestimate instream flow needs, particularly for drift-feeding fish. These include:(i) systematic biases in velocity habitat suitability curves (HSCs) caused by territorial-

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“…To quantify microhabitat use, snout velocity and depth were measured at the location from which foraging attempts originated with a handheld flowmeter (FH950) after the behavioral observation was terminated. The software bioen-ergeticHSC (v1.0, Naman et al 2020) was then used to estimate the NREI. Given our low sample size for behavioral observations, NREI was estimated once per density treatment (n = 4) using the average fork length, foraging velocity, temperature, and depth for that treatment, and the size-frequency distribution of invertebrates from all drift net samples pooled together.…”

Section: Behavioral Observations and Microhabitat Usementioning

confidence: 99%

Mechanisms of density dependence in juvenile salmonids: prey depletion, interference competition, or energy expenditure?

Matte¹,

Fraser²,

Grant³

2021

Ecosphere

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Density dependence is a strong regulator of animal populations, operating primarily through intraspecific competition for a limiting resource. Because food is generally limited in natural environments, it is typically assumed that increasing animal density leads to reduced individual fitness through food depletion or monopolization. However, recent work demonstrates that density dependence can occur without apparent food depletion, or with virtually unlimited resources, suggesting that other mechanisms must also be important. Alternatively, density-dependent regulation could be achieved through increasing energy costs rather than decreasing food abundance. The relative importance of these two processes (food depletion and energy costs) and their underlying mechanisms remains unclear. Here, we manipulated the density of juvenile stream-dwelling brook trout (Salvelinus fontinalis) in three neighboring populations over two consecutive summers to relate food availability and consumption to density-dependent growth, survival, and their trade-off. Despite strong patterns of density dependence and evidence of food limitation, increasing fish density did not lead to detectable prey depletion in the environment. Instead, behavioral observations suggested that increasing densities resulted in higher energetic costs, primarily via increasing interference competition and the use of less suitable foraging microhabitats. These results highlight that animal populations may be regulated by density dependence without necessarily impacting prey communities.

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Bioenergetic Habitat Suitability Curves for Instream Flow Modeling: Introducing User‐Friendly Software and its Potential Applications

Cited by 26 publications

References 38 publications

InSTREAM 7: Instream flow assessment and management model for stream trout

InSTREAM 7: Instream flow assessment and management model for stream trout

Identifying and mitigating systematic biases in fish habitat simulation modeling: Implications for estimating minimum instream flows

Mechanisms of density dependence in juvenile salmonids: prey depletion, interference competition, or energy expenditure?

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