Variation in True Metabolizable Energy Among Aquatic Vegetation and Ducks

Gross, Margaret C.; McClain, Sarah E.; Lancaster, Joseph D.; Jacques, Christopher N.; Davis, J. Brian; Simpson, John; Yetter, Aaron P.; Hagy, Heath M.

doi:10.1002/jwmg.21832

Cited by 11 publications

(7 citation statements)

References 67 publications

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“…Our fifth and sixth wetland categories were derived from a regional waterfowl‐focused land cover layer of unharvested flooded agriculture and intensively managed emergent wetlands, which were hand‐digitized and combined with our CDL base layer (Highway, 2022; Masto, 2023; Palumbo et al, 2019). Final wetland classifications included six wetland types that were presumed to generally increase in energetic quality based on extensive published literature (i.e., open water < woody wetlands < emergent wetlands < managed emergent wetlands < harvested agriculture < unharvested agriculture; Foster et al, 2010; Gross et al, 2020; Hagy et al, 2011; Hagy & Kaminski, 2012; Kaminski et al, 2003; Osborn et al, 2017; Tapp et al, 2018; Table 1; Appendix S1). However, we did not assign energy values to our categorical wetland variables explicitly; instead, we assumed their energetic quality, in a similar fashion to North American conservation planning initiatives and their partners (Edwards et al, 2012; Hagy et al, 2021; Hagy, Wirwa, Hitchcock, 2021; Soulliere et al, 2017).…”

Section: Methodsmentioning

confidence: 99%

Human access constrains optimal foraging and habitat availability in an avian generalist

Masto,

Blake‐Bradshaw,

Highway

et al. 2024

Ecological Applications

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Animals balance costs of antipredator behaviors with resource acquisition to minimize hunting and other mortality risks and maximize their physiological condition. This inherent trade‐off between forage abundance, its quality, and mortality risk is intensified in human‐dominated landscapes because fragmentation, habitat loss, and degradation of natural vegetation communities is often coupled with artificially enhanced vegetation (i.e., food plots), creating high‐risk, high‐reward resource selection decisions. Our goal was to evaluate autumn–winter resource selection trade‐offs for an intensively hunted avian generalist. We hypothesized human access was a reliable cue for hunting predation risk. Therefore, we predicted resource selection patterns would be spatiotemporally dependent upon levels of access and associated perceived risk. Specifically, we evaluated resource selection of local‐scale flights between diel periods for 426 mallards (Anas platyrhynchos) relative to wetland type, forage quality, and differing levels of human access across hunting and nonhunting seasons. Mallards selected areas that prohibited human access and generally avoided areas that allowed access diurnally, especially during the hunting season. Mallards compensated by selecting for high‐energy and greater quality foraging patches on allowable human access areas nocturnally when they were devoid of hunters. Postseason selection across human access gradients did not return to prehunting levels immediately, perhaps suggesting a delayed response to reacclimate to nonhunted activities and thus agreeing with the assessment mismatch hypothesis. Last, wetland availability and human access constrained selection for optimal natural forage quality (i.e., seed biomass and forage productivity) diurnally during preseason and hunting season, respectively; however, mallards were freed from these constraints nocturnally during hunting season and postseason periods. Our results suggest risk‐avoidance of human accessible (i.e., hunted) areas is a primary driver of resource selection behaviors by mallards and could be a local to landscape‐level process influencing distributions, instead of forage abundance and quality, which has long‐been assumed by waterfowl conservation planners in North America. Broadly, even an avian generalist, well adapted to anthropogenic landscapes, avoids areas where hunting and human access are allowed. Future conservation planning and implementation must consider management for recreational access (i.e., people) equally important as foraging habitat management for wintering waterfowl.

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Section: Methodsmentioning

confidence: 99%

Human access constrains optimal foraging and habitat availability in an avian generalist

Masto,

Blake‐Bradshaw,

Highway

et al. 2024

Ecological Applications

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“…As proof, Lancaster et al, (2018) showed that bioavailable energy particularly total metabolizable energy (TME) of submersed aquatic vegetation, was highly variable among duck species, favoring mallard ducks compared with gadwall (Mareca Strepera). A recent study demonstrated a similar result that mallards had slightly greater nitrogen-corrected total metabolizable energy (TME N ) than gadwall (Mareca Strepera) for submersed aquatic vegetation species such as Canadian waterweed (Elodea canadensis; 1.66 ± 0.26), followed by coontail (Ceratophyllum demersum; 1.51 ± 0.28), southern naiad (Najas guadalupensis; 1.37 ± 0.39), sago pondweed (Stuckenia pectinata; 0.50 ± 0.22), wild celery (Vallisneria americana; 0.05 ± 0.42), and Eurasian watermilfoil (Myriophyllum spicatum; -0.13 ± 0.42) (Gross et al, 2020). Likewise, the degree of growth is also a factor that influences energy metabolism and consequent utilization.…”

Section: A Feed Energy Utilization With Emphasis On Ducksmentioning

confidence: 99%

Energy Values of Corn and Rice Bran and Energy Levels for Ducks – Basis in Establishing Energy Requirement for Improved Philippine Mallard Duck

Vidad

Hufana-Durán²

2022

CLSU-IJST

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New breeds of Philippine Mallard Ducks (PMD) were developed to ensure the availability of outstanding stocks for egg production. Maximizing the potentials of these new breeds can be achieved with sound nutrition. Energy is considered the most important and occupy big fraction in the diet of duck as it influences feed intake and proportion of other nutrients in the diet. Optimaldietary energy levels for the new breeds of PMD is yet to be established.. Determining the energy values of common and locally abundant basal feeds such as corn and rice bran for PMDwill serve as a basis in the inclusion of these feeds to duck’s diet. Ducks are considered more efficient in maximizing the energy values of corn (CO) and rice bran (RB) despite of the large proportion of non-starch polysaccharides of RB compared to chickens. Dietary energy levels have not been established for PMD unlike in Pekin ducks (PD) and some indigenous or country ducks. Fast growing PD tend to require a denser energy ranging from 3008 to 3284 kcal/kg compared to 2700 to 2950 kcal/kg for indigenous breeds and khaki Campbell (KC) for optimal performance. It has been found out that the PMD is closely more related to KC than PD. Hence, the possibility of requiring a lower dietary energy than PD. The determination of energy values of CO and RB for PMD and establishment of optimal dietary energy level will facilitate the formulation of PMD specific diet. Thus, this condensed information will serve as concrete viewpoints in understanding bioenergetic dynamics of PMD.

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“…In addressing the unexpected tendency of certain guilds to decrease despite more abundant SAV, many interviewees noted the importance of vegetative community composition and its relationship to waterfowl foraging behaviour. For instance, assimilable energy may provide insight into the vegetation valued by waterfowl species within each guild (Dugger et al, 2007;Fredrickson & Reid, 1988;Gross et al, 2020). Southern naiad (Najas guadalupensis), wild celery (Vallisneria americana), coontail (Ceratophyllum demersum), sago pondweed (Potamogeton pectinatus), and Eurasian watermilfoil (Myriophyllum spicatum) are all important waterfowl resources found in Back Bay with varying degrees of tolerance to turbidity and salinity (Carter et al, 1983;Carter & Rybicki, 1991;Chamberlain, 1948;Tiner & Rorer, 1993) and varying degrees of true metabolizable energy for waterfowl (Gross et al, 2020).…”

Section: Informant Speculation Of Observed Trendsmentioning

confidence: 99%

“…For instance, assimilable energy may provide insight into the vegetation valued by waterfowl species within each guild (Dugger et al, 2007;Fredrickson & Reid, 1988;Gross et al, 2020). Southern naiad (Najas guadalupensis), wild celery (Vallisneria americana), coontail (Ceratophyllum demersum), sago pondweed (Potamogeton pectinatus), and Eurasian watermilfoil (Myriophyllum spicatum) are all important waterfowl resources found in Back Bay with varying degrees of tolerance to turbidity and salinity (Carter et al, 1983;Carter & Rybicki, 1991;Chamberlain, 1948;Tiner & Rorer, 1993) and varying degrees of true metabolizable energy for waterfowl (Gross et al, 2020). Moreover, diving ducks such as bufflehead (B. albeola) and mergansers (hooded [L. cucullatus] and red-breasted [Mergus serrator]) may be more tolerant of higher salinity conditions due to their ability to dive for marine crustaceans and molluscs (Perry et al, 2007).…”

Section: Informant Speculation Of Observed Trendsmentioning

confidence: 99%

“…As a vital primary producer in both aquatic and adjoining upland habitats, SAV provides a range of ecosystem services including water column filtration, sediment stabilization, and biodiversity support through habitat and food resource provision (de Boer, 2007; Hestir et al., 2016; Madsen et al., 2001; Munro & Perry, 1983; Stevenson & Confer, 1978). In Back Bay, Virginia, SAV has historically supported large populations of waterfowl, including dabbling ducks, like the American black duck ( Anas rubripes ), gadwall ( Mareca strepera ), and mallard ( Anas platyrhynchos ); diving ducks, such as bufflehead ( Bucephala albeola ) and hooded merganser ( Lophodytes cucullatus ); and swans and geese, including Canada goose ( Branta canadensis ), snow goose ( Anser caerulescens ), and tundra swan ( Cygnus columbianus ) (Gross et al., 2020; Morton & Kane, 1994; Perry et al., 2007; Settle & Schwab, 1991; Waterfield, 1951). Throughout the twentieth century, however, fluctuations in the percent frequency of aquatic vegetation in Back Bay (from 87% in 1974 to less than 1% in 1991), and the seemingly associated decline in waterfowl abundance (over 90 thousand in 1977 to less than 10 thousand in 1990) has prompted concern from natural resource managers throughout the region (Orth & Moore, 1983; Schwab et al., 1991; Morton & Kane, 1994; Moorman et al., 2017; Figure S1 in the Supporting Information).…”

Section: Introductionmentioning

confidence: 99%

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Effects of submerged aquatic vegetation and water quality on waterfowl abundance by foraging guild

Sibilia

Aguirre‐Gutiérrez

Mowbray³

et al. 2022

Ecol Sol and Evidence

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Back Bay, Virginia, has been documented as an important foraging area for waterfowl since at least the mid‐1800s. Expansive submerged plant beds historically supported diverse assemblages of non‐breeding waterfowl; however, coastal development and other anthropogenic influences have since led to fluctuations in submerged aquatic vegetation (SAV) and an associated decline in waterfowl abundance in the bay. To gain insight into the effects of environmental drivers on waterfowl foraging guilds, our study explores the effects of SAV frequency and water quality on the abundance of dabbling ducks, diving ducks and swans and geese in Back Bay. We use 8 years of SAV, water quality, and waterfowl monitoring data collected by state and federal agencies to model the effects of salinity, turbidity, pH and percent frequency of SAV on the relative abundance of waterfowl by foraging guild in Back Bay. The appropriateness of the data and reasonability of the preliminary results were then evaluated through semi‐structured interviews with 11 local informants representing state, federal and non‐governmental organizations. Quantitative results indicated that dabbling ducks are affected differently than other guilds by water quality and percent frequency of SAV. Thematic analysis of the interview data revealed a number of potential explanations for the model results, as well as highlighted areas of uncertainty in need of further research. In a test of face validity, participants demonstrated a significant degree of belief in turbidity, salinity and SAV as drivers of waterfowl abundance, but were not convinced by the potential effects of pH as demonstrated by the model. This mixed methods study provides insights that could potentially influence the management and conservation of non‐breeding waterfowl populations by challenging the assumption that particular environmental conditions serve all foraging groups equally.

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Variation in True Metabolizable Energy Among Aquatic Vegetation and Ducks

Cited by 11 publications

References 67 publications

Human access constrains optimal foraging and habitat availability in an avian generalist

Human access constrains optimal foraging and habitat availability in an avian generalist

Energy Values of Corn and Rice Bran and Energy Levels for Ducks – Basis in Establishing Energy Requirement for Improved Philippine Mallard Duck

Effects of submerged aquatic vegetation and water quality on waterfowl abundance by foraging guild

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