Researcher perspectives on challenges and opportunities in conservation physiology revealed from an online survey

Conservation physiology represents a recently emerging arm of conservation science that applies physiological tools and techniques to understand and solve conservation issues. While a multi-disciplinary toolbox can only help to address the global biodiversity crisis, any field can face challenges while becoming established, particularly highly applied disciplines that require multi-stakeholder involvement. Gaining first-hand knowledge of the challenges that conservation physiologists are facing can help characterize the current state of the field and build a better foundation for determining how it can grow. Through an online survey of 468 scientists working at the intersection of physiology and conservation, we aimed to identify characteristics of those engaging in conservation physiology research (e.g. demographics, primary taxa of study), gauge conservation physiology’s role in contributing to on-the-ground conservation action, identify the perceived barriers to achieving success and determine how difficult any identified barriers are to overcome. Despite all participants having experience combining physiology and conservation, only one-third considered themselves to be ‘conservation physiologists’. Moreover, there was a general perception that conservation physiology does not yet regularly lead to tangible conservation success. Respondents identified the recent conceptualization of the field and the broader issue of adequately translating science into management action as the primary reasons for these deficits. Other significant barriers that respondents have faced when integrating physiology and conservation science included a lack of funding, logistical constraints (e.g. sample sizes, obtaining permits) and a lack of physiological baseline data (i.e. reference ranges of a physiological metric’s ‘normal’ or pre-environmental change levels). We identified 12 actions based on suggestions of survey participants that we anticipate will help deconstruct the barriers and continue to develop a narrative of physiology that is relevant to conservation science, policy and practice.

Optimism and opportunities for conservation physiology in the Anthropocene

We discuss 12 themes that emerged from the set of case studies comprising the text, namely: (1) mechanisms matter for conservation; (2) physiology is just one source of knowledge; (3) physiology and behaviour are intertwined; (4) new tools and technologies should be embraced; (5) physiology can be valuable in captive settings; (6) conservation physiology extends across scales; (7) physiology can be incorporated into long-term monitoring programmes; (8) conservation physiology is applicable to invertebrates; (9) non-imperilled species deserve attention; (10) successful application is increased by co-production; (11) sharing success stories is important; and (12) findings should be communicated across a variety of platforms. We end the chapter with a discussion of some of the challenges currently being faced in the discipline, and with a message of optimism for the future.

On conducting management-relevant mechanistic science for upriver migrating adult Pacific salmon

Pacific salmon undertake iconic homeward migrations where they move from ocean feeding grounds to coastal rivers where they return to natal spawning sites. However, this migration is physiologically challenging as fish have to navigate past predators, nets, hooks, and dams while dealing with variable flows, warm water temperatures, and pathogens. These challenges often interact in synergistic ways that can sometimes lead to migration failure. The conservation physiology toolbox has led to new understanding of how salmon deal with different challenges with a goal of generating management-relevant science. Given the sensitivity of Pacific salmon to warm temperatures, much research has focused on identifying thermal thresholds. In addition, physiology has informed the development of methods for recovering fish that are exhausted from fisheries interactions and for enhancing passage success at fishways. These successes have arisen in part due to the extent to which we partnered with fisheries managers and other stakeholders to ensure that we were conducting relevant research.

The history, goals, and application of conservation physiology

Conservation physiology is a rapidly expanding, multi-disciplinary field that utilizes physiological tools, knowledge, and concepts to understand and solve conservation problems. Here we provide a consolidated overview of the scope and goals of conservation physiology, with a focus on animals. We outline the major avenues by which conservation physiology is contributing to the monitoring, management, and restoration of animal populations, and provide a summary of the tools currently available in the conservation physiology toolbox. Overall, we illustrate how a conservation physiology approach can provide sensitive biomarkers of environmental change, reveal the underlying mechanisms of conservation issues, and allow for proactive conservation strategies. In turn, conservation physiology can tackle diverse conservation issues ranging from monitoring environmental stress, predicting the impact of climate change, understanding disease dynamics, improving captive breeding, reducing human–wildlife conflict, and many others. The diversity of taxa, biological scales, and ecosystems that are highlighted illustrate the far-reaching nature of the discipline and allow readers to gain an appreciation of the purpose, value, and status of the field.

A veterinary perspective on the conservation physiology and rehabilitation of sea turtles

Sea turtle populations are threatened globally due to anthropogenic and natural factors, including fisheries interactions, watercraft strike, hunting, habitat loss, pollution, climate change, and severe weather. Injured and ill sea turtles are often evaluated by wildlife rehabilitation centres, and many sea turtles can be returned to the wild after rehabilitation. Physiological evaluation of injured and ill sea turtles has revealed life-threatening physiological dysfunction such as acidosis, hypoxia, hypercarbia, dehydration, and hyperkalaemia. Recognition and management of such conditions has improved the outcome for these patients. In addition to clinical advancement, veterinary evaluation has improved our understanding of general sea turtle biology, and increased the safety of procedures such as anaesthesia and laparoscopy. These modalities, combined with emerging biotelemetry technologies, will continue to improve our understanding of sea turtle ecology and conservation physiology.

Improving ‘shark park’ protections under threat from climate change using the conservation physiology toolbox

Sharks and rays are among the most threatened aquatic vertebrate taxa. This is due to a combination of their slow generation times, exploitation within the fisheries, and habitat degradation. Climate change was added as an additional, major threat to sharks and rays in the first decade of the 21st century. While marine protected areas are becoming more widespread, managing and conserving sharks and rays is complicated. Yet, the conservation physiology toolbox can be used to address such challenges. Here, we highlight studies from the Physioshark project, a conservation physiology research programme initiated to understand how human-induced stressors, primarily climate change, will affect tropical sharks and rays and the consequences for the health and viability of populations. We also highlight how other research teams from around the world have taken physiological approaches to understanding conservation problems for sharks. We then emphasize the importance of public outreach and education about the conservation issues sharks encounter, the benefits of using social media to disseminate key concepts, publications, presentations, media, and successes, and we underscore the power of storytelling through digital media as an important means for attracting attention to research, which can result in support and action.

Applying conservation physiology in response to a devastating wildlife disease, white-nose syndrome in bats

White-nose syndrome (WNS) is a fungal skin disease that has killed millions of bats since its introduction to North America around 2007. Despite rapid and unprecedented mortality of multiple bat species from WNS, some bats suffer little to no impact. While a conservation physiology approach has allowed for tremendous progress connecting WNS pathophysiology with population impacts, a fundamental question about the disease remains: why does a simple skin infection disrupt hibernation behaviour and energetics in some bats but not others? Here we review what is known about pathophysiological processes in hibernating bats with WNS, and connections between these processes and population impacts. We then outline how a conservation physiology approach has been useful for informing our understanding of resistance and tolerance mechanisms, and conclude by showing how conservation physiology could help with the design of mitigation strategies and treatments for WNS and other infectious diseases of wildlife.