Suspended Structures Reduce Variability of Group Risk-Taking Responses of Dicentrarchus labrax Juvenile Reared in Tanks

Arechavala-López, Pablo; Velazquez, Samira Nuñez; Díaz‐Gil, Carlos; Follana-Berná, Guillermo; Saraiva, João L.

doi:10.3390/fishes7030126

Cited by 2 publications

(2 citation statements)

References 38 publications

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“…There are a few recent studies in the literature that examined the effects of structural complexity on fish (e.g., [33,34,36,[46][47][48]), but their scope is frequently related to welfare under captivity, and is, therefore, more focused on aquaculture/model species and stressrelated endpoints (growth performance, anxiety-like behaviours, brain function). Other studies have made a great contribution to this field by looking at the effects of habitat degradation in the wild, but are focused on tropical reef fish species (e.g., [49][50][51]).…”

Section: Discussionmentioning

confidence: 99%

Effects of Water Temperature and Structural Habitat Complexity on the Routine Swimming Speed and Escape Response of Post-Settlement Stage White Seabream

Vicente,

Almeida,

Ribeiro

et al. 2024

Oceans

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Coastal habitats are increasingly threatened by multiple anthropogenic-related activities, which include ocean warming and loss of structural habitat complexity. These two pressures have the potential to severely affect the structure and function of marine biodiversity. Early life stages of many fish species recruit to coastal habitats at the end of their pelagic phase, benefiting from access to food, shelter and protection. However, changes in temperature have been shown to influence ecologically relevant behaviours in post-settlement stage fish, and the loss of structural habitat complexity has been related to low recruitment and deleterious behaviours of fish in coastal habitats. Here, we evaluated the individual and interactive effects of prolonged exposure to increasing temperature and changed structural habitat complexity on routine swimming speed and escape response of post-settlement white seabream, Diplodus sargus (Linnaeus, 1758). Fish were reared under different temperatures (control 19 °C; high 22 °C) and structural habitat complexity (low and high) scenarios, in a cross-experimental design, and the routine swimming and escape responses were analyzed after 6 weeks of exposure. Change in temperature did not induce alterations at the behavioural level, but loss of structural habitat complexity increased speed and distance travelled during routine swimming, and responsiveness to a stimulus during the escape response behaviour. The interaction of the two factors did not influence performance. Determining how species are affected by changes in their environment, and the mechanisms that underlie these changes, will be critical to understanding the fish recruitment and populations’ fitness and survival.

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Section: Discussionmentioning

confidence: 99%

Effects of Water Temperature and Structural Habitat Complexity on the Routine Swimming Speed and Escape Response of Post-Settlement Stage White Seabream

Vicente,

Almeida,

Ribeiro

et al. 2024

Oceans

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“…In a captive environment, the primary role of plants is to create an environment that allows animals to express the same type of movements (i.e., act as a locomotor substrate) and as many natural behaviours as in the wild (for species living in a three-dimensional environment). Moreover, the presence of plants and other structures that make the environment more complex, such as perches and ropes, is important to reduce the boredom caused by barren, low-stimulating enclosures, and by the management routine [ 38 , 39 , 40 ]. In addition, these structures help animals to cope with the presence of visitors, as they can provide physical barriers against noise produced by the public [ 41 , 42 ], or provide hiding places in case individuals do not want to be visible to visitors [ 43 , 44 ].…”

Section: Habitat Complexity: Definition Temporal Variation and Measuresmentioning

confidence: 99%

Review of the Effects of Enclosure Complexity and Design on the Behaviour and Physiology of Zoo Animals

Azevedo

Cipreste²,

Pizzutto

et al. 2023

Animals

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The complexity of the habitat refers to its physical geometry, which includes abiotic and biotic elements. Habitat complexity is important because it allows more species to coexist and, consequently, more interactions to be established among them. The complexity of the habitat links the physical structure of the enclosure to the biological interactions, which occur within its limits. Enclosure complexity should vary temporally, to be able to influence the animals in different ways, depending on the period of the day and season and throughout the year. In the present paper, we discuss how habitat complexity is important, and how it can positively influence the physical and mental states of zoo animals. We show how habitat complexity can ultimately affect educational projects. Finally, we discuss how we can add complexity to enclosures and, thus, make the lives of animals more interesting and functional.

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Suspended Structures Reduce Variability of Group Risk-Taking Responses of Dicentrarchus labrax Juvenile Reared in Tanks

Cited by 2 publications

References 38 publications

Effects of Water Temperature and Structural Habitat Complexity on the Routine Swimming Speed and Escape Response of Post-Settlement Stage White Seabream

Effects of Water Temperature and Structural Habitat Complexity on the Routine Swimming Speed and Escape Response of Post-Settlement Stage White Seabream

Review of the Effects of Enclosure Complexity and Design on the Behaviour and Physiology of Zoo Animals

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