Extreme Effects of Extreme Disturbances: A Simulation Approach to Assess Population Specific Responses

Reed, Joshua; Harcourt, Robert; New, Leslie; Bilgmann, Kerstin

doi:10.3389/fmars.2020.519845

Cited by 8 publications

(6 citation statements)

References 104 publications

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“…The most widespread use of dynamic bioenergetic models in the past decade has been in the context (either implicit or explicit) of assessing the long-term consequences of sublethal anthropogenic disturbance on individuals or populations under the PCoD framework, which has included applications to pinnipeds ( Goedegebuure et al, 2018 ; McHuron et al, 2017a , 2018 ), harbour porpoises Phocoena phocoena ( Gallagher et al, 2021a ; Harwood et al, 2020 ; Nabe-Nielsen et al, 2014 ; Nabe-Nielsen et al, 2018 ), delphinids ( Hin et al, 2019 ; New et al, 2013b ; Pirotta et al, 2014 ; Pirotta et al, 2015 , 2020 ; Reed et al, 2020 ; Williams et al, 2006 ), beaked whales ( New et al, 2013a ), baleen whales ( Braithwaite et al, 2015 ; Christiansen and Lusseau, 2015 ; Dunlop et al, 2021 ; Guilpin et al, 2020 ; McHuron et al, 2021 ; Pirotta et al, 2018a , 2019 , 2021 ; Riekkola et al, 2020 ; van der Hoop et al, 2017 ; Villegas-Amtmann et al, 2015 ; Villegas-Amtmann et al, 2017 ), small- to medium-sized odontocetes ( Noren et al, 2017 ) and sperm whales ( Farmer et al, 2018b , 2018a ).…”

Section: Marine Mammal Dynamic Bioenergetic Modellingmentioning

confidence: 99%

A review of bioenergetic modelling for marine mammal populations

Pirotta

2022

Conservation Physiology

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Bioenergetic models describe the processes through which animals acquire energy from resources in the environment and allocate it to different life history functions. They capture some of the fundamental mechanisms regulating individuals, populations and ecosystems and have thus been used in a wide variety of theoretical and applied contexts. Here, I review the development of bioenergetic models for marine mammals and their application to management and conservation. For these long-lived, wide-ranging species, bioenergetic approaches were initially used to assess the energy requirements and prey consumption of individuals and populations. Increasingly, models are developed to describe the dynamics of energy intake and allocation and predict how resulting body reserves, vital rates and population dynamics might change as external conditions vary. The building blocks required to develop such models include estimates of intake rate, maintenance costs, growth patterns, energy storage and the dynamics of gestation and lactation, as well as rules for prioritizing allocation. I describe how these components have been parameterized for marine mammals and highlight critical research gaps. Large variation exists among available analytical approaches, reflecting the large range of life histories, management needs and data availability across studies. Flexibility in modelling strategy has supported tailored applications to specific case studies but has resulted in limited generality. Despite the many empirical and theoretical uncertainties that remain, bioenergetic models can be used to predict individual and population responses to environmental change and other anthropogenic impacts, thus providing powerful tools to inform effective management and conservation.

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Section: Marine Mammal Dynamic Bioenergetic Modellingmentioning

confidence: 99%

A review of bioenergetic modelling for marine mammal populations

Pirotta

2022

Conservation Physiology

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“…Understanding how disturbance may affect vital rates such as fecundity and survival can provide valuable insights into a population's response to a disturbance event [ 74 , 92 ] and guide mitigation and management strategies that target important life-history stages (e.g. mating and reproduction) or specific age classes (e.g.…”

Section: Life-history Traitsmentioning

confidence: 99%

“…Future models could be developed for representative populations or species exposed to common disturbance scenarios to investigate broad patterns in population responses to disturbance (e.g. see [ 31 , 92 ]). By identifying population characteristics and other contextual factors that could lead to population-level effects, model findings could be used to further guide decision-making and develop mitigations that target populations most at risk or sensitive to a proposed activity.…”

Section: Data Gaps and Future Prioritiesmentioning

confidence: 99%

Emerging themes in Population Consequences of Disturbance models

et al. 2021

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Assessing the non-lethal effects of disturbance from human activities is necessary for wildlife conservation and management. However, linking short-term responses to long-term impacts on individuals and populations is a significant hurdle for evaluating the risks of a proposed activity. The Population Consequences of Disturbance (PCoD) framework conceptually describes how disturbance can lead to changes in population dynamics, and its real-world application has led to a suite of quantitative models that can inform risk assessments. Here, we review PCoD models that forecast the possible consequences of a range of disturbance scenarios for marine mammals. In so doing, we identify common themes and highlight general principles to consider when assessing risk. We find that, when considered holistically, these models provide valuable insights into which contextual factors influence a population's degree of exposure and sensitivity to disturbance. We also discuss model assumptions and limitations, identify data gaps and suggest future research directions to enable PCoD models to better inform risk assessments and conservation and management decisions. The general principles explored can help wildlife managers and practitioners identify and prioritize the populations most vulnerable to disturbance and guide industry in planning activities that avoid or mitigate population-level effects.

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“…Apart from fisheries interactions, anthropogenic threats to common dolphins in South Australian waters span a wide range of stressors, including over-exploitation of prey resources, water pollution, diseases, urban and industrial habitat degradation and climate change (Kemper et al, 2016;Robbins et al, 2017). For example, modeling has shown that extreme epizootic events and climate change disturbance scenarios with high frequency and intensity have the biggest influence on population trends of bottlenose dolphins in Spencer Gulf and Gulf St. Vincent (Reed et al, 2020), and these are likely to also pose a threat to common dolphins. Furthermore, there has been no assessment of the potential long-term impacts (e.g., enhanced stress levels, mothercalf separations) that fisheries interactions (e.g., encirclement and release operations in purse seine nets) may have on dolphins, and how this may impact reproductive success and survival rates in the affected populations (Archer et al, 2004;Edwards, 2006;Wade et al, 2007;Cramer et al, 2008).…”

Section: Discussionmentioning

confidence: 99%

Abundance and Potential Biological Removal of Common Dolphins Subject to Fishery Impacts in South Australian Waters

et al. 2021

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Conservation management of wildlife species should be underpinned by knowledge of their distribution and abundance, as well as impacts of human activities on their populations and habitats. Common dolphins (Delphinus delphis) are subject to incidental capture in a range of Australia’s commercial fisheries including gill netting, purse seining and mid-water trawling. The impact these fishery interactions have on common dolphin populations is uncertain, as estimates of abundance are lacking, particularly for the segments of the populations at risk of bycatch and in greater need of protection. Here we used double-observer platform aerial surveys and mark-recapture distance sampling methods to estimate the abundance of common dolphins in 2011 over an area of 42,438 km2 in central South Australia, where incidental mortality of common dolphins due to fisheries bycatch is the highest. We also used the potential biological removal (PBR) method to estimate sustainable levels of human-caused mortality for this segment of the population. The estimated abundance of common dolphins was 21,733 (CV = 0.25; 95% CI = 13,809–34,203) in austral summer/autumn and 26,504 in winter/spring (CV = 0.19; 95% CI = 19,488–36,046). Annual PBR estimates, assuming a conservative maximum population growth rate of Rmax = 0.02 and a recovery factor of Fr = 0.5 for species of unknown conservation status, ranged from 189 (summer/autumn) to 239 dolphins (winter/spring), and from 378 (summer/autumn) to 478 dolphins (winter/spring) with an Rmax = 0.04. Our results indicate that common dolphins are an abundant dolphin species in waters over the central South Australian continental shelf (up to 100 m deep). Based on the 2011 abundance estimates of this species, the highest estimated bycatch of common dolphins (423 mortalities in 2004/05) in the southern Australian region exceeded the precautionary PBR estimates for this population segment. Recent bycatch levels appear to be below PBR estimates, but low observer coverage and underreporting of dolphin mortalities by fishers means that estimates of dolphin bycatch rates are not robust. The effects of cumulative human impacts on common dolphins are not well understood, and thus we recommend a precautionary management approach to manage common dolphin bycatch based on local abundance estimates.

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Extreme Effects of Extreme Disturbances: A Simulation Approach to Assess Population Specific Responses

Cited by 8 publications

References 104 publications

A review of bioenergetic modelling for marine mammal populations

A review of bioenergetic modelling for marine mammal populations

Emerging themes in Population Consequences of Disturbance models

Abundance and Potential Biological Removal of Common Dolphins Subject to Fishery Impacts in South Australian Waters

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