Fact-checked by Grok 2 weeks ago

Piscivore

A piscivore is a carnivorous organism that primarily or exclusively consumes fish as its main source of food.^[1] This feeding strategy, known as piscivory, is observed across diverse taxa in aquatic and semi-aquatic environments, including birds, mammals, reptiles, and certain fish species themselves.^[2] Piscivores exhibit specialized adaptations to capture and consume their prey, such as sharp teeth, powerful jaws, or dexterous limbs for hunting in water.^[1] Notable examples include birds like pelicans, ospreys, and cormorants, which use diving or surface-feeding techniques; mammals such as otters and seals, equipped with webbed feet or streamlined bodies for pursuit; and predatory fish like groupers, reef sharks, and piranhas, which employ ambush or schooling behaviors.^[1] These adaptations vary by habitat, with freshwater piscivores like the North American river otter relying on sensitive whiskers for detection, while some marine species such as bottlenose dolphins utilize echolocation. Ecologically, piscivores are vital top predators in aquatic food webs, regulating prey fish populations to prevent overgrazing on lower trophic levels and mediating energy transfer between primary producers and higher consumers.^[3] Their presence influences prey behavior, such as inducing shelter-seeking or migration patterns, which in turn shapes community structure in ecosystems like coral reefs and freshwater rivers.^[1] However, human activities like overfishing can disrupt piscivore populations, leading to cascading effects on biodiversity and ecosystem stability.^[4]

Definition and Etymology

Definition

A piscivore is defined as a carnivorous animal whose diet consists primarily of fish, typically comprising the majority of its caloric intake or biomass consumed. This dietary specialization distinguishes piscivores from omnivores, which incorporate plant material or other non-fish foods, and from generalist carnivores that rely on a broader range of animal prey such as mammals, birds, or invertebrates.^[2]^[1] Classification of piscivores is based on dietary composition, often assessed through stomach content analysis, stable isotope ratios, or observational studies of feeding behavior. Strict piscivores exhibit a diet approaching 100% fish, showing high specialization in prey selection, whereas facultative piscivores include fish as the dominant component—generally over 50% of the diet—but supplement with other prey when fish availability fluctuates, reflecting opportunistic feeding strategies common in dynamic aquatic environments. Fossil evidence indicates that early tetrapods were primarily piscivorous, as evidenced by their sharp, conical teeth suitable for grasping fish and the presence of fish remains in the jaws of species like Acanthostega, reflecting their largely aquatic lifestyle during the Late Devonian.^[5] The term piscivore derives from Latin roots but is conceptually equivalent to the Greek-derived "ichthyophagous," both denoting fish-eating organisms; unlike herbivory, which involves plant consumption at a primary producer level, or insectivory, focused on arthropod prey, piscivory represents a specialized carnivorous niche within aquatic and semi-aquatic food webs.^[6]

Etymology

The term "piscivore" derives from the Latin roots piscis, meaning "fish," and vorare, meaning "to devour," forming a compound noun that denotes an organism primarily consuming fish.^[7] This construction parallels other dietary descriptors like "herbivore" and "carnivore," which similarly blend Latin elements to indicate feeding habits. The noun "piscivore" emerged as a back-formation from the earlier adjective "piscivorous," which itself combines piscis with the English suffix -vorous (from Latin -vorus, "devouring").^[8] The earliest documented use of "piscivore" in English scientific literature dates to 1948, appearing in a report by the Fisheries Research Board of Canada, marking its entry into biological discourse during mid-20th-century studies on aquatic feeding ecology.^[7] Prior to this, descriptive phrases such as "fish-eater" or the Greek-derived term "ichthyophagous"—from ichthys ("fish") and phagein ("to eat")—were more common in natural history texts, with "ichthyophagous" first attested in English around 1656.^[6] By the late 20th century, "piscivore" gained prominence in ecological and ethological contexts for its alignment with the standardized Latin-based "-vore" nomenclature, facilitating consistent classification across trophic levels.^[1] This terminological shift reflected broader trends in biology toward precise, uniform vocabulary in studies of predator-prey dynamics.

Biological Characteristics

Morphological and Physiological Adaptations

Piscivores exhibit a range of morphological adaptations that facilitate the capture and consumption of elusive, slippery fish prey. These include elongated snouts that extend reach during strikes, sharp conical teeth designed to grasp and hold wriggling bodies without slippage, and powerful jaws capable of delivering forceful bites to subdue targets.^[1] In many fish piscivores, mouth size is gape-limited, constraining prey selection to sizes that fit within the expanded oral cavity during ingestion, which optimizes energy efficiency in aquatic hunting.^[9] Physiological adaptations enhance detection and endurance in piscivorous pursuits. Aquatic piscivores often possess advanced sensory systems, such as the lateral line, a network of mechanoreceptors that detect vibrations and water displacements from nearby fish movements, enabling precise tracking even in low-visibility conditions.^[10] For prolonged submersion, efficient gill structures in fish and lung capacities in air-breathing piscivores support extended dives by maximizing oxygen extraction from water or air, respectively.^[11] Specialized structures further aid in piscivory across taxa. Webbed feet in birds and flippers in mammals provide propulsion through water, reducing drag and increasing maneuverability during chases.^[1] Some invertebrate piscivores have evolved venomous delivery mechanisms, such as harpoon-like structures that inject paralytic toxins to immobilize fish rapidly.^[12] Convergent evolution is evident in the streamlined body forms of piscivores from unrelated lineages, where fusiform shapes minimize hydrodynamic resistance for swift swimming, as seen in ancient reptiles like ichthyosaurs and modern mammals like dolphins adapted to fish-based diets.^[13]

Behavioral Adaptations and Ontogeny

Piscivores exhibit a range of hunting strategies tailored to their aquatic environments, including ambush tactics where predators remain stationary and concealed, such as waiting near water surfaces or structures to strike at passing fish.^[14] Pursuit strategies involve active chasing in open water, allowing piscivores to close distances on schooling or fleeing prey through sustained swimming.^[3] Bottom-oriented foraging, meanwhile, targets demersal fish by probing sediments or hovering near the substrate, often combining stealth with opportunistic strikes.^[14] These behaviors are influenced by prey density and habitat structure, with ambush and pursuit modes showing complementary efficiencies in mixed predator assemblages.^[15] Ontogenetic shifts to piscivory typically occur in a size-dependent manner, constrained by gape limitations that prevent smaller individuals from consuming fish prey.^[16] In many species, particularly fish, the transition begins at lengths typically ranging from 50-300 mm, depending on the species, when mouth size allows ingestion of appropriately sized prey.^[16] This shift is often interrupted by periods of reliance on alternative foods, such as macroinvertebrates, when fish prey availability declines, as observed in populations facing seasonal or habitat-driven shortages. Early adoption of piscivory confers advantages, including reduced overwinter mortality through accelerated pre-winter growth.^[16] Interspecific variation in piscivory onset is strongly linked to birth size and mouth gape, with species exhibiting larger initial sizes and wider gapes initiating fish consumption at younger ages and smaller overall body lengths.^[16] Across 27 freshwater piscivore species, those with enhanced gape capabilities achieve piscivory earlier, leading to greater size advantages by age one that persist through later life stages.^[16] These differences highlight how morphological starting points shape dietary progression, independent of factors like spawning temperature.^[16] The shift to piscivory markedly improves energy efficiency, boosting growth rates by 2-3 times relative to invertebrate-based diets due to higher caloric density and assimilation rates. Piscivorous individuals exhibit gross energy conversion efficiencies exceeding 40% across a broader temperature range (6.5-12°C) compared to 30% for invertebrate feeders (7-11°C).^[17] This dietary transition is modeled using adaptations of the von Bertalanffy growth equation, which incorporates stage-specific parameters for diet shifts, such as yearling growth rate (ρ_y) influencing asymptotic length:

L(t) = L_\infty \left(1 - e^{-K(t - t_0)}\right)

where adjustments for piscivory onset, like increased K (growth coefficient) post-shift, account for enhanced somatic growth in species like walleye.^[18] Such models demonstrate how piscivory accelerates size attainment, with early shifters showing up to 63% higher growth compared to delayed individuals.

Ecological Significance

Role in Aquatic Ecosystems

Piscivores typically occupy apex or mesopredator trophic positions in aquatic food webs, where they exert top-down control by preying on fish populations, thereby mediating the transfer of energy from primary producers and plankton to higher trophic levels.^[19] This predation prevents overgrazing by herbivorous or planktivorous fish, stabilizing lower trophic levels and maintaining overall energy flow efficiency, with approximately 90% energy loss occurring at each successive level.^[20] In freshwater systems, such as rivers in Nigeria and Cameroon, carnivorous piscivores like Clarias gariepinus regulate prey densities, ensuring balanced community structure and preventing cascading disruptions to primary production.^[19] By reducing prey abundance, piscivores promote biodiversity regulation within aquatic ecosystems, fostering coexistence among species through density-dependent mechanisms.^[19] Functional groups among piscivores, such as grabbers that use long-distance horizontal strikes and engulfers that employ suction-based capture, enable niche partitioning by allowing differential exploitation of prey types and habitats, which minimizes intraspecific competition and enhances overall community resilience.^[3] For instance, in diverse piscivore guilds, these groups divide resources spatially and temporally, supporting higher species diversity in streams and lakes.^[21] Piscivores contribute to nutrient cycling by facilitating the transfer of essential elements like phosphorus (P) and nitrogen (N) through excretion and decomposition of carcasses, directly influencing primary productivity and algal dynamics.^[22] In neotropical streams, fish excretion rates exceed ecosystem demand by 1.6- to 1.8-fold for P and N, recycling nearly all consumed nutrients back into the water column and potentially fueling algal blooms in nutrient-limited environments.^[23] Over extended periods, piscivores release up to 99.9% of ingested N and 99.7% of P via these processes, underscoring their role in sustaining biogeochemical cycles.^[22] In certain aquatic systems, piscivores exhibit keystone effects by disproportionately influencing ecosystem structure through targeted predation.^[24] For example, sharks as apex piscivores control populations of mesopredatory rays, reducing predation on bivalves like scallops and thereby preserving habitat complexity and biodiversity in coastal marine environments.^[24] This trophic cascade enhances the stability of food webs, preventing shifts toward less diverse states dominated by unchecked intermediate consumers.^[24]

Interactions with Prey, Competitors, and Humans

Piscivores engage in complex interactions with their fish prey, where prey species have evolved various anti-predator adaptations to mitigate predation risk. One prominent adaptation is schooling, in which fish aggregate to confuse attackers and reduce individual encounter rates with piscivores; for instance, schools dilute the risk per individual and can perform synchronized evasive maneuvers that lower overall predation success.^[25] These behaviors are particularly effective against visually hunting piscivores like pikeperch (Sander lucioperca), which rely on clear sight lines for detection.^[26] In response, piscivores often exhibit size-selective predation, preferentially targeting larger individuals within prey populations that exceed a certain gape-limited threshold, as smaller prey may evade capture more readily due to higher escape velocities relative to predator size. This selectivity can drive evolutionary pressures on prey morphology and behavior, favoring faster growth or enhanced schooling in vulnerable size classes.^[26] Competition among piscivores shapes their foraging strategies and spatial distribution, occurring both intraspecifically and interspecifically. Intraspecific competition arises when individuals of the same species vie for limited prey resources, often leading to hierarchical dominance where larger piscivores monopolize prime feeding areas and displace subordinates to suboptimal habitats.^[27] For example, in Aegean Sea fish assemblages, intraspecific interactions intensify at shallower depths with structured substrates, influencing individual growth rates and site fidelity.^[27] Interspecific competition is frequently more pronounced in freshwater systems where piscivores overlap in habitat use with other predators, resulting in partitioned distributions based on seasonal and diurnal activity patterns to minimize resource overlap.^[28] Such competition can alter community structure by excluding less competitive piscivores from high-prey-density zones, thereby affecting overall biodiversity and ecosystem stability.^[28]^[27] Human activities profoundly impact piscivores through direct and indirect mechanisms, exacerbating population declines. Overfishing depletes prey stocks such as herring and capelin, which serve as primary food sources for many piscivores, leading to cascading effects like reduced growth and recruitment in species such as cod (Gadus morhua).^[29] Bycatch in commercial fisheries incidentally captures large piscivorous fish, including sharks and groupers, contributing to unintended mortality that disrupts age structures and recovery potential.^[29] Habitat alterations, particularly from dams, impede migration routes for anadromous piscivores like salmon (Oncorhynchus spp.), blocking access to spawning grounds and reducing freshwater inflows essential for prey habitat in estuarine systems.^[29] Conservation efforts for piscivores address these threats, with many species classified as threatened due to cumulative human pressures. A significant proportion of large-bodied piscivorous fish, such as groupers and tunas, face elevated extinction risks, primarily from overexploitation and habitat degradation; as of 2024, approximately 12.7% of marine teleost fish species are threatened, with higher rates among apex predators.^[30] Management strategies include establishing marine protected areas (MPAs) to safeguard critical habitats and allow biomass recovery. Ecosystem-based approaches, such as co-management with reduced bycatch gear, further support population stability by integrating prey protection and habitat restoration.^[29]

Extant Piscivores

Invertebrates

Invertebrate piscivores are predominantly represented by semi-aquatic spiders in the genus Dolomedes, particularly species like Dolomedes triton, which actively hunt small fish at the water's edge. These fishing spiders employ vibration-sensing mechanisms, using specialized sensory organs such as lyriform organs on their legs to detect concentric surface waves generated by fish movements, allowing them to pinpoint prey from distances up to 18 cm away.^[31]^[32] This tactile hunting strategy enables them to anchor their hind legs on vegetation or solid substrate while extending their elongated front legs across the water surface to reach and seize fish, often ambushing prey that approaches within striking range.^[33] Key adaptations facilitate their piscivorous lifestyle, including hydrophobic body hairs that trap air bubbles, permitting submersion for hunts lasting up to 30-45 minutes while breathing through a personal air supply.^[32]^[33] These spiders can also dabble their front legs on the water to mimic prey vibrations, luring fish closer before injecting potent venom that immobilizes targets in seconds to minutes.^[31] Their ability to walk, row, or gallop across water surfaces at speeds exceeding 0.4 m/s further enhances pursuit, with dives reaching depths of up to 18 cm to capture evasive fish.^[32] Habitat preferences confine Dolomedes triton and related species to the margins of freshwater ecosystems, such as ponds, streams, lakes, and wetlands with emergent vegetation like cattails, where they exploit the interface between land and water; they are rarely found in fully marine environments due to intense competition from specialized aquatic predators.^[31]^[33] Ecologically, these spiders serve as vital connectors in terrestrial-aquatic food webs, preying on small fish (typically 2-6 cm long, such as mosquitofish) that can weigh up to 4.5 times their own body mass, thereby influencing neuston community dynamics and supplementing their diet with aquatic insects and tadpoles.^[31]^[32] This predation bridges nutrient transfer between ecosystems, with fish comprising a nutritionally significant portion of their intake in high-density prey areas.^[31]

Birds

Piscivorous birds are avian species that have evolved specialized adaptations for capturing and consuming fish as their primary food source, utilizing a combination of aerial surveillance and precise diving techniques to exploit aquatic prey. These birds often exhibit morphological features such as elongated bills, reversible toes, or expandable throat pouches that enhance their efficiency in fish capture. Their hunting strategies typically involve visual detection from elevated positions, followed by rapid dives that minimize energy expenditure while maximizing success. Widespread across coastal, estuarine, and freshwater habitats globally, many piscivorous birds undertake seasonal migrations aligned with the movements of fish schools, ensuring access to abundant prey throughout the year.^[34]^[35]^[36] Prominent examples include pelicans, which employ plunge-diving tactics from heights of up to 20 meters, using their distinctive pouched bills to scoop up stunned fish upon impact with the water surface. Ospreys, renowned for their piscivorous specialization, hunt by soaring at altitudes of 10 to 30 meters before executing feet-first dives, aided by reversible outer talons that rotate to grip slippery fish securely, achieving success rates of 70-80% in mature individuals. Cormorants pursue prey underwater through prolonged dives, leveraging streamlined bodies and hooked beaks for chasing and seizing fish in open water, often submerging for 20-30 seconds per attempt. Mergansers, such as the common merganser, dive repeatedly in shallow waters, utilizing serrated, saw-edged bills to impale and hold small fish during pursuit.^[34]^[35]^[37]^[36]^[38]^[39]^[40]^[41] The diets of these birds are predominantly piscivorous, with fish comprising 80-99% of intake depending on the species and season; for instance, ospreys rely on fish for nearly all their nutrition, while pelicans and cormorants occasionally supplement with crustaceans or amphibians during prey shortages. This dietary focus drives their broad distribution in temperate and tropical regions, from North American coasts to Eurasian inland waters, with many populations exhibiting migratory patterns that track seasonal fish aggregations, such as salmon runs or schooling baitfish migrations. In some species, ontogenetic shifts occur as juveniles develop more refined diving proficiency over time.^[38]^[35]^[39]^[34]^[41]^[42]

Fish

Piscivorous fish, which prey primarily on other fish species, exhibit intra-guild predation that shapes aquatic food webs through direct consumption and behavioral influences on prey populations. These predators range from ambush specialists to high-speed pursuers, adapting to diverse environments while often undergoing ontogenetic shifts in habitat use as they grow. Key examples include the northern pike (Esox lucius), a freshwater ambush predator that lurks in vegetated areas to strike unsuspecting prey with rapid lunges, relying on its elongated body and sharp teeth for capture.^[43] In African rivers, tigerfish (Hydrocynus spp.), such as the goliath tigerfish (H. goliath), are notorious for explosive hunting bursts reaching speeds of up to 40 km/h, enabling them to overpower schools of smaller fish in fast-flowing waters.^[44] Marine environments feature species like the great barracuda (Sphyraena barracuda), which employs short, powerful sprints up to 56 km/h to ambush prey near coral reefs, using its streamlined form and razor-like teeth to sever victims.^[45] Predation dynamics among piscivorous fish are constrained by gape limitation, where the maximum mouth opening determines viable prey size, typically selecting for individuals 20-50% of the predator's length to ensure successful swallowing.^[46] This selectivity favors smaller or juvenile prey, but can extend to larger items if body depth allows, as seen in studies of bass and other piscivores where prey up to 140% of gape width are occasionally consumed.^[47] Prey schooling behaviors counter these tactics by diluting individual risk and confusing attackers, thereby reducing capture efficiency; schools can lower per capita predation rates by increasing predator confusion during strikes.^[48] Such anti-predator strategies force piscivores to target isolated or disrupted groups, influencing overall hunting success in both freshwater and marine settings.^[49] Piscivorous fish occupy a broad habitat spectrum, from freshwater rivers and lakes—such as the vegetated pools preferred by northern pike—to marine reefs frequented by barracuda, with tigerfish thriving in the pelagic zones of large African river basins like the Congo.^[50]^[51] Many undergo ontogenetic habitat shifts, transitioning from shallow, protected nurseries to open waters as juveniles mature into larger predators, enhancing access to suitable prey sizes and reducing competition.^[52] These shifts align with dietary changes toward piscivory, optimizing energy intake in dynamic aquatic landscapes. In lake ecosystems, piscivores exert substantial population impacts, often reducing prey fish biomass by 40-60% through intensified predation pressure, as observed in biomanipulation efforts that enhance top-down control.^[53] This biomass suppression can cascade to lower trophic levels, altering community structure and promoting clearer waters in eutrophic systems.^[54]

Amphibians

Amphibians that include piscivory in their diet are primarily aquatic or semi-aquatic species adapted to freshwater environments, where they prey on small fish alongside other aquatic organisms. Piscivorous behavior among amphibians is uncommon, with most species being generalist or primarily insectivorous; notable examples occur mainly among salamanders in the order Urodela. These amphibians employ suction-based feeding mechanisms suited to their soft-skinned, gill- or lung-breathing physiology, distinguishing them from fully aquatic fish or more terrestrial reptiles. They thrive in transitional habitats like streams and lakes, where clear, oxygenated water supports both their respiration and prey availability. Many face severe conservation threats, including habitat loss and disease; for instance, the hellbender is endangered and the axolotl critically endangered as of the 2023 IUCN assessments.^[55]^[56]^[57]^[58]^[59] The hellbender (Cryptobranchus alleganiensis), a stream-dwelling North American salamander, includes fish in its diet but primarily consumes crayfish, with small fish such as darters and minnows as an occasional component. Hellbenders are bottom-dwelling ambush predators that employ a sit-and-wait strategy, using rapid lunges and suction to draw prey into their wide mouths while foraging nocturnally along rocky substrates. Their habitat is restricted to clear, oxygen-rich freshwater streams and rivers in the eastern United States, rendering them highly vulnerable to sedimentation, pollution, and altered water quality from human activities.^[55]^[60]^[61] The axolotl (Ambystoma mexicanum), a neotenic salamander endemic to Mexico's Xochimilco lakes and canals, maintains larval features like external gills indefinitely, enabling prolonged aquatic life. In the wild, adult axolotls are generalist predators that consume small fish alongside worms, insects, crustaceans, snails, and other salamanders, using an ambush tactic involving sudden mouth opening to generate suction for capturing evasive prey. This feeding style relies on their sedentary, benthic lifestyle in shallow, vegetated freshwater habitats, though introduced fish species have intensified competition and reduced native prey availability. The axolotl's neoteny supports extended predatory behavior in low-flow lake environments susceptible to eutrophication and contamination.^[56]^[62]^[63] Giant salamanders, such as the Chinese giant salamander (Andrias davidianus), represent the largest extant amphibians and consume fish as a key prey item in Asian river systems, alongside frogs, invertebrates, and small mammals. These species target prey through powerful suction generated by their broad heads and hyobranchial apparatus during nocturnal ambushes from concealed positions. Adults lunge forward asymmetrically to engulf prey, adapting to fast currents in forested streams and caves. Confined to pristine freshwater streams and lakes in central China, they face severe threats from habitat degradation, including water pollution and damming, which disrupt prey populations and oxygenation. Like other featured amphibians, giant salamanders retain larval-like gill structures in part, prolonging their aquatic predatory phase in these dynamic habitats.^[57]^[64]^[65]

Reptiles

Reptilian piscivores encompass a diverse array of semi-aquatic and fully aquatic species that primarily prey on fish, utilizing ectothermic physiology to thrive in varied aquatic environments. Crocodilians, such as the American alligator (Alligator mississippiensis), exemplify ambush predators that lurk motionless near the water's surface before launching rapid strikes to capture fish, often employing a "death roll" maneuver—a powerful spinning motion in water to dismember and subdue prey.^[66] This technique is widespread among crocodilians and enhances their efficiency in handling slippery, evasive fish. In many populations, fish constitute a dominant portion of their diet, comprising 54–90% by biomass depending on habitat, underscoring their piscivorous specialization.^[67] Sea snakes of the subfamily Hydrophiinae represent highly specialized marine piscivores, adapted to oceanic and coastal waters where they hunt sedentary or burrowing fish such as eels, gobies, and catfishes. These venomous elapids employ stealthy approaches, using tongue-flicking to detect prey in crevices before delivering precise lunges and injecting neurotoxic venom to immobilize targets rapidly, allowing them to swallow fish whole without constriction.^[68] Their diet is overwhelmingly piscivorous, with most species feeding almost exclusively on fish from diverse families, supplemented occasionally by fish eggs or invertebrates. Freshwater turtles, including the common snapping turtle (Chelydra serpentina) and alligator snapping turtle (Macrochelys temminckii), adopt similar ambush strategies in rivers and lakes, remaining camouflaged on the bottom with mouths agape to lure fish close before snapping shut with powerful jaws; fish form a primary component of their omnivorous yet predominantly carnivorous diet.^[69] These piscivores occupy a broad environmental spectrum, from freshwater rivers and lakes inhabited by alligators and snapping turtles, to brackish estuaries and coastal mangroves favored by species like the saltwater crocodile (Crocodylus porosus), which can venture into full oceanic salinity. Sea snakes, conversely, range across tropical Indo-Pacific oceans, coral reefs, and estuaries, diving to depths up to 100 meters to pursue prey. To support prolonged submersion during hunts, many aquatic reptiles exhibit diving bradycardia—a reflexive slowing of heart rate that redirects oxygen to vital organs like the brain and heart, conserving limited stores and enabling extended apnea periods.^[70]^[68]^[71] This physiological adaptation aligns with their morphological traits, such as valvular nostrils and efficient lung compression, for efficient underwater foraging.

Mammals

Mammalian piscivores encompass a range of semi-aquatic and fully marine species adapted to diverse aquatic environments, including coastal marine zones, riverine systems, and lacustrine habitats. These mammals exhibit specialized morphological and behavioral traits that facilitate fish capture, such as streamlined bodies for propulsion and sensitive sensory organs for prey detection in turbid waters. While some species are obligate piscivores with diets dominated by fish, others incorporate piscivory opportunistically alongside other prey. Habitats vary by taxon: pinnipeds like sea lions inhabit coastal and pelagic waters, mustelids such as river otters occupy freshwater rivers and lakes, and felids like fishing cats frequent wetland margins.^[72] A prominent example is the sea lion (family Otariidae), which employs cooperative herding techniques using their hind flippers to corral schools of fish into tighter groups, enhancing capture success during group hunts. In species like the Galápagos sea lion (Zalophus wollebaeki), such social foraging targets large pelagic fish, with individuals coordinating dives to surround prey. Diets of sea lions are predominantly piscivorous, often comprising over 80% fish by volume, including sardines, anchovies, and salmonids, depending on regional availability. Vibrissae, or whiskers, play a crucial role in underwater detection for pinnipeds; these specialized structures sense hydrodynamic trails left by swimming fish, allowing precise tracking even in low-visibility conditions.^[73]^[74]^[75]^[76] Among freshwater specialists, the fishing cat (Prionailurus viverrinus) exemplifies semi-aquatic piscivory in riverine and coastal wetlands of South and Southeast Asia, where it paws at fish from perches on banks or shallow edges. This species spends significant time waiting motionless before striking, with fish constituting 70-76% of its diet in wild populations, supplemented by amphibians and crustaceans. Similarly, the North American river otter (Lontra canadensis) pursues fish through playful yet strategic chases in rivers and lakes, using agile maneuvers to corner prey in currents; its diet includes 40-60% fish, varying by habitat and season. These pursuits often involve social play, which hones hunting skills in family groups. Vibrissae in otters also aid in detecting prey vibrations underwater, complementing visual cues.^[77]^[78]^[79]^[80] Social hunting in pinnipeds boosts foraging efficiency, with group coordination in sea lions increasing prey encounter rates by up to 25% compared to solitary dives, as observed in benthic and pelagic strategies. In contrast, some mammals like the polar bear (Ursus maritimus) engage in opportunistic piscivory along Arctic coasts, catching salmon during seasonal runs when primary seal prey is scarce, though fish rarely exceeds 10% of their overall diet. Ontogenetic shifts toward piscivory occur in many species, with juveniles learning capture techniques through observation and play.^[81]^[82]

Extinct Piscivores

Prehistoric Fish

Prehistoric piscivorous fish emerged as dominant predators during the Paleozoic era, particularly in the Devonian period (approximately 419–358 million years ago), marking the "Age of Fishes" when jawed vertebrates diversified rapidly in marine environments. These early piscivores, including placoderms and primitive sharks, evolved specialized feeding mechanisms to exploit fish prey, contributing to the intensification of predation pressures that reshaped aquatic food webs. Fossil records from this time reveal a transition from simple jawless filter feeders to active hunters, with adaptations like robust cranial structures enabling the consumption of evasive, scaled prey. A quintessential example is Dunkleosteus terrelli, a Late Devonian arthrodire placoderm that attained lengths of up to 10 meters, making it one of the largest known prehistoric fish. Armored with thick dermal plates and equipped with self-sharpening bony shearing plates in lieu of teeth, Dunkleosteus was adapted for slicing and crushing fish, functioning as a hypercarnivorous apex predator in ancient seas. Its jaw mechanism, capable of rapid 45-degree openings in fractions of a second, generated bite forces exceeding those of modern great white sharks relative to body size, ideal for gape-limited piscivory where prey dimensions were constrained by mouth width.^[83]^[84]^[85] Another notable case involves Jurassic hybodont sharks, such as Hybodus, which preyed on the gigantic pachycormid fish Leedsichthys problematicus, a filter feeder reaching over 16 meters in length. These sharks, growing to about 2–3 meters, exhibited opportunistic piscivory, with dual tooth morphologies for grasping and crushing fish; fossil evidence includes Hybodus teeth embedded in Leedsichthys dermal bones, suggesting attacks on schools or weakened individuals in reef-associated habitats.^[86]^[87] Hybodonts like these bridged Paleozoic and Mesozoic predatory guilds, targeting large-bodied prey to exploit nutrient-rich Jurassic oceans. Fossil evidence underscores these behaviors through preserved jaw architectures indicating gape-limited feeding strategies across Devonian taxa, where expansive oral cavities facilitated whole-fish ingestion. Coprolites from Late Devonian pelagic settings, dating to around 370 million years ago, contain abundant fish scales and bone fragments, providing direct dietary confirmation of piscivory among early jawed fish.^[88]^[89] The evolutionary role of these piscivores was pivotal in the Paleozoic diversification of marine vertebrates, as their emergence drove anti-predator adaptations in prey species, such as enhanced schooling and scale reinforcement, while fostering complex trophic guilds that influenced subsequent radiations of bony fish and chondrichthyans. Size extremes among them, exemplified by Dunkleosteus at 10 meters, highlight their capacity to dominate ancient reef and open-water ecosystems by preying on aggregated schools of smaller fish.^[90]^[91]

Extinct Reptiles

Extinct reptiles adapted for piscivory were prominent in Mesozoic marine ecosystems, particularly during the Triassic, Jurassic, and Cretaceous periods, where they evolved specialized traits for pursuing fish in oceanic environments. These sauropsids, including ichthyosaurs, mosasaurs, and plesiosaurs, dominated as apex predators, with ichthyosaurs from approximately 250 to 90 million years ago and mosasaurs and plesiosaurs until 66 million years ago, filling niches similar to modern dolphins and sharks. Fossil evidence, such as preserved stomach contents containing fish remains and coprolites with fish scales, confirms their primary reliance on fish prey, supplemented occasionally by cephalopods or other marine vertebrates.^[92]^[93] Ichthyosaurs, appearing in the Early Triassic around 252 million years ago and persisting until the Cenomanian stage of the Late Cretaceous around 90 million years ago, exemplified dolphin-like piscivores with streamlined bodies and powerful tails. These reptiles, up to 20 meters long in some species, hunted fish using acute vision and rapid swimming, as evidenced by gastric contents in Liassic specimens revealing undigested fish bones and cephalopod beaks. Their fossils, often found in marine deposits from Europe and North America, show conical teeth suited for grasping slippery prey, underscoring a diet dominated by schooling fish.^[92]^[93] Mosasaurs, emerging in the Early Cretaceous about 100 million years ago and thriving until the end of the period, were serpentine squamates with elongated bodies and double-hinged jaws that allowed wide gape for engulfing large fish. Originating from terrestrial lizards, these varanid-like reptiles adapted to fully aquatic life, with fossils from the Western Interior Seaway preserving bite marks on fish skeletons and isolated fish vertebrae in association with mosasaur remains, indicating active pursuit hunting. Early mosasaur species, such as those with conical teeth, primarily targeted soft-bodied fish, while later forms incorporated harder prey like armored teleosts.^[94]^[93] Plesiosaurs, spanning the Triassic to Late Cretaceous from about 200 to 66 million years ago, included long-necked forms like elasmosaurs that ambushed fish near the seafloor using needle-like teeth for snatching. Stomach contents from Jurassic and Cretaceous specimens, such as those containing disarticulated fish bones, provide direct evidence of piscivory, particularly in polycotylid and elasmosaurid lineages adapted for feeding on large, fast-swimming fish. Their four-flippered propulsion enabled stealthy approaches in shallow to deep marine settings, with fossils distributed globally in chalk and limestone formations.^[95]^[96] Fossil adaptations among these piscivores highlight convergent evolution for aquatic efficiency, notably in ichthyosaurs where preserved soft tissues reveal vertical tail flukes supported by a downward-flexed vertebral column, optimizing thrust for high-speed chases after fish schools. Mosasaurs exhibited flattened tails for lateral undulation, while plesiosaurs relied on limb-based rowing, all facilitating pursuit piscivory in open oceans as inferred from biomechanical analyses of skeletal morphology. These traits, documented in specimens from 250 to 66 million years ago, underscore their specialization for fish-dominated food webs.^[97]^[93] The decline of these piscivorous reptiles culminated in the end-Cretaceous mass extinction event 66 million years ago, triggered by the Chicxulub asteroid impact, which disrupted marine productivity and led to a collapse in fish populations at the base of the food chain. Mosasaurs and plesiosaurs vanished abruptly alongside 80-90% of marine species, while ichthyosaurs had already diminished earlier due to reduced evolutionary rates and global environmental volatility; this event's aftermath, marked by oceanic anoxia and plankton crashes, severed the prey base essential for their survival.^[98]^[99]

Extinct Mammals

Extinct mammalian piscivores primarily emerged during the Cenozoic era, following the Cretaceous-Paleogene extinction event that eliminated non-avian dinosaurs and opened marine niches for mammalian diversification. Early cetaceans, known as archaeocetes, represent the most prominent group, transitioning from semi-aquatic ancestors to fully marine predators adapted for fish consumption. These mammals evolved specialized dentition and skeletal features for pursuing aquatic prey, with fossil evidence from the Eocene epoch (approximately 56 to 33.9 million years ago) documenting their piscivorous habits.^[100] Basilosaurus, an iconic archaeocete genus from the late Eocene, exemplifies this adaptation, reaching lengths of up to 18 meters with elongated bodies and powerful tails suited for undulating swimming. Its jaws featured conical teeth serrated for grasping slippery fish, alongside evidence of broader carnivory. Direct fossil evidence from stomach contents in Basilosaurus isis specimens from Egypt includes remains of large bony fish and sharks, confirming piscivory as a core component of its diet, though it also preyed on smaller cetaceans like Dorudon atrox calves. Similarly, Basilosaurus cetoides from North American Eocene deposits preserved gut contents dominated by teleost fish and shark fragments up to 50 cm long, indicating active predation in shallow epicontinental seas.^[101]^[102] The evolutionary shift toward piscivory in archaeocetes is traced through transitional fossils from around 50 million years ago, where teeth evolved from terrestrial carnassial forms to piscivorous designs with interlocking cusps for securing fish. Vertebrae and limb structures in these early forms, such as reinforced caudal regions, supported agile swimming to chase prey, filling post-extinction roles akin to modern odontocetes. Associated Eocene sediments often contain fish fossils alongside archaeocete remains, underscoring their ecological integration as top marine piscivores.^[100] Earlier examples include Ichthyoconodon from the Early Cretaceous of Morocco, a eutriconodont mammal whose multi-cusped molars suggest piscivory, potentially indicating semi-aquatic foraging in marine environments despite its Mesozoic origins. Such finds highlight sporadic mammalian incursions into piscivorous niches before the Cenozoic radiation.^[103]

References

[1]
Piscivore - an overview | ScienceDirect Topics
Piscivores are organisms that consume diets primarily composed of fish, with examples including pelicans, storks, cormorants, mergansers, and osprey. AI ...
[2]
Piscivore Definition and Examples - Biology Online Dictionary
Jan 18, 2021 · A carnivorous animal that primarily or exclusively eats on fish. Supplement Examples include the sea lion, tigerfish, fishing cat, and aquatic genet.
[3]
https://pmc.ncbi.nlm.nih.gov/articles/PMC8462170/
[4]
Functional groups in piscivorous fishes - PMC - NIH
Sep 2, 2021 · Piscivory is a key ecological function in aquatic ecosystems, mediating energy flow within trophic networks. However, our understanding of the ...
[5]
Harvesting forage fish can prevent fishing-induced population ...
In many marine ecosystems, fisheries target predatory fish, known as piscivores, as well as their prey fish, known as forage fish.Materials And Methods · Fishing For Clupeids Can... · Discussion<|control11|><|separator|>
[6]
Early Vertebrate Evolution Follow the footprints and mind the gaps
this, and both elpistostegids and tetrapods seem to have been primarily piscivorous. During the Middle Devonian, continuing into the Late. Devonian ...
[7]
ICHTHYOPHAGOUS Definition & Meaning - Merriam-Webster
The meaning of ICHTHYOPHAGOUS is eating or subsisting on fish.
[8]
piscivore, n. meanings, etymology and more
piscivore is formed within English, by compounding; perhaps modelled on a French lexical item. Etymons: pisci- comb. form, ‑ivore comb. form ...
[9]
PISCIVORE Definition & Meaning - Merriam-Webster
First Known Use. 1952, in the meaning defined above. Time Traveler. The first known use of piscivore was in 1952. See more words from the same year. Rhymes for ...Missing: scientific literature
[10]
PISCIVORY LIMITS DIVERSIFICATION OF FEEDING ...
As the lineage splits, the adaptive peak constrains morphological diver- gence between daughter lineages, slowing the accumulation of diversity within a ...
[11]
The importance of the lateral line in nocturnal predation of ...
Aug 1, 2004 · We found that a functional lateral line is indispensable for following the wake of swimming prey. The frequency of attack and capture was ...
[12]
The Evolution of Unidirectional Pulmonary Airflow | Physiology
Jul 1, 2015 · Second, the avian respiratory system consists of unique structures: avascular air sacs that effect ventilation and highly vascular lungs with ...
[13]
to fish-hunting in a venomous cone snail | Nature Communications
Jun 13, 2023 · Our results demonstrate how coordinated morphological, behavioural and molecular changes facilitate the shift from worm- to fish-hunting in C. magus.
[14]
Effects of body plan evolution on the hydrodynamic drag and energy ...
During their approximately 160 Myr existence, they evolved from elongate and serpentine forms into stockier, fish-like animals, convergent with sharks and ...Missing: piscivory | Show results with:piscivory
[15]
Piscivore - an overview | ScienceDirect Topics
The top predators of the prior Black Sea ecosystem were the secondary piscivores – Atlantic bonito, Sarda sarda, and blue fish, Pomatomus salator (Gucu, 2002), ...
[16]
Foraging Modes of Predators and Behaviors of Prey Determine the ...
Aug 8, 2011 · We hypothesized that the foraging strategies of the ambush and cruising predator will be complementary leading to more captures in the combined ...
[17]
https://www.researchgate.net/publication/229574871_Optimum_energy_intake_and_gross_efficiency_of_energy_conversion_for_brown_trout_Salmo_trutta_feeding_on_invertebrates_or_fish
[18]
The ontogeny of piscivory and its ecological consequences
Focusing on interspecific variation, we found that species that were born ... mouth gapes became piscivorous at younger ages and at smaller sizes. However ...
[19]
Optimum energy intake and gross efficiency of energy conversion for ...
Aug 10, 2025 · According to Elliott and Hurley (2000) , a shift to piscivory is energetically advantageous because a fish diet brings about a faster growth ...
[20]
[PDF] A stage-explicit expression of the von Bertalanffy growth model for ...
Walleye is a piscivore, and on a yearly scale, its primary diet typically switches from inverte- brates to fish during yearling growth. We included walleye.
[21]
[PDF] Ecological Role of Carnivorous Freshwater Fish in the Trophic ...
Sep 18, 2025 · As apex predators, carnivorous freshwater fishes exert regulatory control over prey populations, thereby influencing nutrient cycling processes ...
[22]
Trophic Position of the Species and Site Trophic State Affect Diet ...
Aug 10, 2023 · The trend is more evident at the apex predator position, likely due to an overall 90% energy loss at each level in the food web [61].
[23]
Functional groups in piscivorous fishes - Wiley Online Library
Sep 2, 2021 · We identify two major functional groups: grabbers and engulfers. Grabbers are characterized by horizontal, long-distance strikes, capturing their prey ...
[24]
Fish, Including Their Carcasses, Are Net Nutrient Sources ... - Frontiers
Sep 9, 2019 · Over the 20-year period, almost all nutrients (99.9% of N and 99.7% of P) consumed by piscivores were released back to the water column via ...
[25]
The Role of Fish in Nutrient Recycling Across a Conservation ...
Oct 16, 2025 · We found that fish were significant nutrient recyclers, excreting nitrogen and phosphorus at rates approximately 1.8- and 1.6-fold higher, ...Missing: position | Show results with:position
[26]
Species with a Large Impact on Community Structure - Nature
The otter-urchin-kelp interaction is an example of a trophic cascade. In this system, the otter (keystone species) increases the abundance of kelp (foundation ...
[27]
Predation on schooling fish is shaped by encounters between prey ...
Fish schools reduce their predators' encounter rates not only by performing evasive maneuvers but also by increasing distances between prey patches.
[28]
Piscivore-Prey Fish Interactions: Mechanisms behind Diurnal ... - NIH
Nov 7, 2014 · Piscivore foraging can be divided into different foraging-cycle stages, including encounter, reaction, attack, capture and ingestion of prey [6] ...
[29]
Quantification of intraspecific and interspecific competition in fish ...
Dec 24, 2023 · Competition shapes species coexistence and community assembly, playing a central role in maintaining biodiversity and ecosystem resilience.
[30]
Network analysis of intra- and interspecific freshwater fish ...
Oct 20, 2021 · We collected and analysed a large dataset of 108 freshwater fish from four species, tracked every few seconds over 1 year in their natural environment.
[31]
3 Fishing and Marine Ecosystems | Sustaining Marine Fisheries | The National Academies Press
### Summary of Overfishing Effects and Habitat Loss from Dams (Chapter 3, Sustaining Marine Fisheries)
[32]
[PDF] Fishing groupers towards extinction: a global assessment of threats ...
In all, 30% of all species are considered to be Data Deficient. Given that the major threat is overfishing, accompanied by a general absence and/or poor ...
[33]
[PDF] Overfishing of Inland Waters - Winemiller Aquatic Ecology Lab
The status of inland waters and their species should be of broad concern, yet threats to freshwater fisheries and asso- ciated biodiversity have received scant ...
[34]
Fish Predation by Semi-Aquatic Spiders: A Global Pattern | PLOS One
Dolomedes fimbriatus is perhaps less well-adapted to predating fish in the wild. An extensive observational study by Poppe & Holl [101] in moorlands of ...
[35]
Dolomedes fishing spider biology: gaps and opportunities for future ...
In this review, we critically evaluate what is known of Dolomedes biology, focusing on their systematics and morphology, ecology, behavior, and conservation.Missing: piscivory | Show results with:piscivory
[36]
Dolomedes triton | INFORMATION - Animal Diversity Web
In order to capture its prey, the fishing spider makes use of concentric surface waves on still water to pinpoint the exact location of the prey, up to 18cm ...Missing: piscivory | Show results with:piscivory
[37]
Brown Pelican Overview, All About Birds, Cornell Lab of Ornithology
They feed by plunge-diving from high up, using the force of impact to stun small fish before scooping them up. They are fairly common today—an excellent example ...Missing: adaptations diet distribution
[38]
Brown Pelican | Audubon Field Guide
Feeding Behavior. Forages by diving from the air, from as high as 60' above water, plunging into water headfirst and coming to surface with fish in bill. Tilts ...
[39]
All about Osprey hunting and feeding - Avian Report
In other studies, the success rate was up to 82%, meaning that of every 10 dives more than 8 were successful. In this study, Ospreys caught a fish every 11.8 ...
[40]
Pelecanus occidentalis (brown pelican) - Animal Diversity Web
Brown pelicans are carnivores, primarily feeding on fish but also small marine invertebrates. They are the only pelicans that dive for their food. Their ...
[41]
Osprey Diet and Fishing
A 2010 study of ospreys fishing on an estuary in the northern Iberian Peninsula showed an average success rate of 69%. Young birds caught fish around two times ...
[42]
Diet and Foraging - Great Cormorant - Phalacrocorax carbo
Instead the cormorants seemed to economize energy expenditure by halving time spent at sea, and halving number but doubling mass of each fish taken. Their diet ...Missing: piscivory | Show results with:piscivory
[43]
Diet and Foraging - Common Merganser - Birds of the World
Oct 4, 2020 · Main Foods Taken. Primarily small fish video , but also aquatic invertebrates (insects, mollusks, crustaceans video , worms), frogs, ...Missing: saw- edged piscivory
[44]
Common Merganser | Audubon Field Guide
This fish-eating duck is the typical merganser of freshwater lakes. Its ... Diet. mostly fish. Eats a wide variety of fish; also will eat mussels ...Missing: saw- edged piscivory
[45]
Common Merganser | Ducks Unlimited
Common Mergansers are the largest of the three merganser species, and among the largest ducks in North America, with a circumpolar distribution.Overview · Description · Migration And DistributionMissing: saw- edged piscivory
[46]
Northern Pike (Esox lucius) | U.S. Fish & Wildlife Service
They are a carnivorous fish with a snout full of sharp teeth and are ambush predators, hunting near and in underwater cover and structures. Northern pike are ...
[47]
13 Crazy Goliath Tigerfish Facts - Fact Animal
Color: Pale grey/olive with black stripes, red or orange fins, grey dorsal fin ; Diet: Fish ; Predators: Crocodiles, humans ; Top Speed: 40 kph (25 mph) ; No. of ...Missing: bursts | Show results with:bursts
[48]
Great Barracuda – Discover Fishes
Feb 12, 2025 · This is a successful daytime ambush hunter that can burst in speeds up to 35 mph, and is a danger to humans because it will mistakenly attack shiny objects or ...
[49]
[PDF] Size Selection of Prey by Young Largemouth Bass
Largemouth bass have generally been found to consume fish prey that are 30% to 50% of their total length (TL) depending on the body depth or girth of the prey.
[50]
Effect of Predator Size and Prey Characteristics on Piscivory of ...
Jun 2, 2015 · Within this range, Largemouth Bass selected prey between 25% and 140% of their gape, but all prey chosen with body depths greater than predator ...
[51]
Behavior pattern (innate action) of individuals in fish schools ...
One main way that the school reduces the predator's chance of making a successful kill is to confuse the predator as it makes its strike.
[52]
Fish Schooling: A Possible Factor in Reducing Predation
The schooling of fishes has long attracted attention, and a number of workers have studied fish schools and the behaviour pattern of the fish to gain some.
[53]
Esox lucius summary page
### Habitat, Ecology, Predation Strategy of Esox lucius (Northern Pike)
[54]
Hydrocynus goliath summary page
### Summary of Hydrocynus goliath (Giant Tigerfish)
[55]
Ontogenetic diet shifts and resource partitioning among piscivorous ...
Resource utilization by nine abundant piscivores from a diverse tropical fish assemblage was examined over the course of a year.
[56]
(PDF) Piscivores, Trophic Cascades, and Lake Management
Dec 19, 2015 · One of the commonly observed effects of increased piscivore biomass is a reduction in planktivore biomass and an increase in herbivore biomass ...
[57]
Piscivores, Trophic Cascades, and Lake Management - PMC - NIH
The concept of cascading trophic interactions predicts that an increase in piscivore biomass in lakes will result in decreased planktivorous fish biomass, ...Missing: 40-60% | Show results with:40-60%
[58]
Hellbender | Smithsonian's National Zoo and Conservation Biology ...
Cryptobranchus alleganiensis. The eastern hellbender is the largest ... They absorb up to 95 percent of their oxygen through their skin, primarily through these ...
[59]
Axolotl (Ambystoma mexicanum) Fact Sheet: Diet & Feeding
Apr 22, 2025 · Diet. Wild populations. Adults. Small fish, worms and insects (Zambrano 2006; Zambrano et al. 2010b); Small crustaceans (Zambrano et al. 2010b).
[60]
Chinese Giant Salamander | San Diego Zoo Animals & Plants
They spend their time filling the top predator niche in rushing, freshwater ecosystems, chowing down on fish, frogs, worms, snails, insects, crayfish, crabs, ...
[61]
Cryptobranchus alleganiensis (Hellbender) - Animal Diversity Web
This species typically forages for food at night and uses a suction feeding behavior to help uproot crayfish from the muddy substrate that they inhabit.
[62]
About - Purdue Agriculture
Sep 5, 2025 · When foraging, hellbenders walk along the bottom searching crevices for prey. Their diet consists almost entirely of crayfish, though they will ...
[63]
Ambystoma mexicanum - AmphibiaWeb
They found that feeding rates varied with age and size. Specifically, A. mexicanum fed more on cladocerans, and ostracods, with increased feeding on the largest ...<|control11|><|separator|>
[64]
Axolotl - Ambystoma mexicanum - PetMD
Oct 27, 2017 · Learn everything about Axolotl - Ambystoma mexicanum Reptile, including health and care information. All from the real vets at PetMD.
[65]
Chinese Giant Salamanders (Andrias spp.) Fact Sheet: Diet & Feeding
Oct 30, 2024 · Chinese giant salamanders create powerful water suction that pulls prey into their mouth. The wide, broad head and skin of the lower jaw create this powerful ...
[66]
Effect of meal size on the postprandial metabolic response in ...
May 5, 2022 · The Chinese giant salamander was fed by test diets at meal sizes of 0.5, 1, 2, 4, 8 and 12% of its body mass (4.41 ± 0.07 g), and the ...
[67]
Death roll of the alligator: mechanics of twist feeding in water
Crocodilians, including the alligator (Alligator mississippiensis), perform a spinning maneuver to subdue and dismember prey. The spinning maneuver, which ...
[68]
[PDF] DIET AND CONDITION OF AMERICAN ALLIGATORS (Alligator ...
Percent composition of fish was calculated as fish biomass/total sample biomass * 100. I hypothesized that the proportion of fish in the alligator diets would ...<|separator|>
[69]
[PDF] 36. family hydrophiidae - DCCEEW
The action of the venom not only subdues prey, but aids in its recovery should the snake lose it. Respiration, Circulatory System and Diving. Sea snakes can ...Missing: piscivory constriction
[70]
What's on the Menu? The Diet of the Alligator Snapper
Sep 12, 2016 · These turtles are highly piscivorous, albeit indiscriminate predators, with a broad diet that also includes crayfish, freshwater mussels, ...Missing: habits | Show results with:habits
[71]
Saltwater Crocodile | National Geographic
Saltwater crocs, or "salties," as Australians affectionately refer to them, have an enormous range, populating the brackish and freshwater regions of eastern ...Missing: piscivory | Show results with:piscivory
[72]
Diving bradycardia: A mechanism of defence against hypoxic damage
Aug 7, 2025 · Diving bradycardia in reptiles is controlled by interactions ... Diving bradycardia is a primordial oxygen-conserving reflex by which ...
[73]
Drivers of piscivory in a globally distributed aquatic predator (brown ...
Jul 9, 2020 · Data are displayed for type of ecosystem (riverine, lacustrine and marine) and type of fish community (one-species system, two-species ...
[74]
Hunting and cooperative foraging behavior of Galapagos sea lion
PDF | The Galapagos sea lion (Zalophus wollebaeki) (GSL) is one of the few otariids adapted to tropical ecosystems, and its populations are small.
[75]
Takes of Marine Mammals Incidental to Specified Activities
Jan 31, 2022 · Family Otariidae (eared seals and sea lions). California Sea Lion ... herding and charging schools of fish, passive listening, and echolocation.
[76]
[PDF] Consumption of Pacific salmon (Oncorhynchus spp.) by California ...
In northwest Washington from 2010 through 2013,. Pacific salmon made up 11.7% of the diet of Steller sea lions (Eumetopias jubatus) and 13.5% of the diet of ...
[77]
Flow sensing by pinniped whiskers - PMC - NIH
Each of the six vibrissae was used to detect the vortex-shedding frequency fVS of the Kármán vortex streets generated by the different cylinders. Every ...
[78]
How Fishing Cats Prionailurus viverrinus fish: Describing a felid's ...
Apr 25, 2020 · Our analysis shows that the cat spent much of its time (~52%) sitting and waiting for prey (fish) to come nearer and then took limited attempts ...
[79]
(PDF) Dietary habits of fishing cats in a human-dominated wetland ...
Aug 6, 2025 · Unlike other cat species, the fishing cat is unique because 70% of its diet consists of fish (Adhya et al., 2024;Wongson et al., 2024). It also ...
[80]
Diet of the North American river otter ( Lontra canadensis ) in North ...
Coastal Plain river otters primarily consumed crustaceans (50%) and fish (40%). Piedmont and Mountain river otters consumed fish (32% and 42%, respectively) ...Missing: piscivory | Show results with:piscivory
[81]
North American river otter - National Zoo
While river otters tend to live alone or in pairs, they often socialize in groups and are known for their playful behavior. Their long, agile bodies enable ...
[82]
Influence of hunting strategy on foraging efficiency in Galapagos sea ...
Apr 13, 2021 · Pinnipeds show high heterogeneity in foraging behaviour linked to habitat productivity and morphometrics (Páez-Rosas, Villegas-Amtmann & Costa, ...
[83]
What to eat now? Shifts in polar bear diet during the ice-free season ...
Some polar bears currently eat a variety of terrestrial animals and plants during the ice-free period, taking opportunistic advantage of abundant species.
[84]
Giant, swimming mouths: oral dimensions of extant sharks do not ...
Apr 10, 2023 · The size of Dunkleosteus and other late Devonian arthrodire placoderms has been a persistent problem in paleontology.
[85]
A Devonian Fish Tale: A New Method of Body Length Estimation ...
Thus, it is clear a new method is needed to estimate size in Dunkleosteus and other arthrodires. Specifically, this method must accurately estimate length ...
[86]
Dunkleosteus Jaw Motion - Cleveland Museum of Natural History
Using this mechanism, Dunkleosteus could open (and then shut) its crushing maw 45 degrees in 1/20 of a second.Missing: piscivory | Show results with:piscivory<|separator|>
[87]
Mechanisms of dermal bone repair after predatory attack in the giant ...
May 19, 2022 · Other specimens of Leedsichthys exhibit indications of post‐mortem scavenging, such as hybodont (elasmobranch chondrichthyans) teeth embedded in ...
[88]
Shark mandible evolution reveals patterns of trophic and habitat ...
May 8, 2023 · The majority of species have a piscivorous diet, most likely representing the ancestral state for the big predatory species. Also, the ...
[89]
Coprolite evidence for carnivorous predation in a Late Devonian ...
Aug 6, 2025 · Morphotype 5 are rare flattened disc-shaped coprolites that contain abundant fish-scales and are linked to the temnospondyl, Rhinesuchus ...Missing: piscivory | Show results with:piscivory
[90]
The first direct evidence of a Late Devonian coelacanth fish feeding ...
Mar 10, 2017 · A small spiral and phosphatic coprolite (fossil excrement) containing numerous conodont elements and other unrecognized remains was also found ...
[91]
(PDF) Predators and Predation in Paleozoic Marine Environments
Aug 10, 2025 · Middle Paleozoic predatory fishes. 1—Rhenanid, ray-like placoderm ... Major marine predators began to appear and diversify in the early Paleozoic ...
[92]
Devonian Period | Natural History Museum
Oct 29, 2012 · The Devonian* saw the peak of marine faunal diversity during the Paleozoic Era. New predators such as sharks, bony fishes and ammonoids ruled ...
[93]
[PDF] ichthyosaur from the lower lias of - The Palaeontological Association
The evidence of the gastric contents and coprolites suggests that Liassic ichthyo- saurs fed mainly on fish and/or dibranchiate cephalopods. Among fish-eaters ...Missing: piscivory | Show results with:piscivory<|control11|><|separator|>
[94]
The Evolution of Marine Reptiles
May 19, 2009 · Their diet included fish, cephalopods, other vertebrates, and hard-shelled invertebrates, whereas no herbivore is known at this point.
[95]
Meals of the Mighty Mosasaur - Smithsonian Ocean
Nov 9, 2018 · The earliest mosasaurs were most likely fish eaters. They almost exclusively had conical teeth, a simple shape common in present-day dolphins.Missing: piscivory | Show results with:piscivory<|control11|><|separator|>
[96]
Plesiosaurs - ScienceDirect.com
May 22, 2023 · Pliosaurs continued into the Late Cretaceous with smaller heads adapted to feeding on large fish, a diet also inferred for the polycotylids.
[97]
Diet and senses - Plesiosaur Directory
1. Incontrovertible evidence. e.g. Gut contents, distinctive bite marks. 2. Close association of fossil finds. e.g. Pliosaur teeth near a fish skeleton. 3 ...
[98]
Adaptations for stealth in the wing-like flippers of a large ichthyosaur
Jul 16, 2025 · Whereas lateral oscillatory motions generated by a long, but presumably rather low aspect ratio, fluke provided the primary means of propulsion ...
[99]
Calcium Isotopic Evidence for Vulnerable Marine Ecosystem ...
Jun 5, 2017 · The collapse of marine ecosystems during the end-Cretaceous mass extinction involved the base of the food chain [1] up to ubiquitous vertebrate ...
[100]
Extinction of fish-shaped marine reptiles associated with reduced ...
Mar 8, 2016 · The extinction of the ichthyosaurs had previously been attributed to increasing competition or to the loss of their main prey. Here, Fischer et ...
[101]
Paleoecology of archaeocete whales throughout the Eocene
Archaeocete microwear most strongly resembles that of modern pinnipeds. •. Archaeocetes had a mixed diet; cetacean piscivory is a dietary specialization.
[102]
Stomach contents of the archaeocete Basilosaurus isis
Jan 9, 2019 · Our observations, the first direct evidence of diet in Basilosaurus isis, confirm a predator-prey relationship of the two most frequently found ...
[103]
[PDF] evidence for middle-to-late Eocene Basilosaurus isis predation on ...
Nov 14, 2012 · Stomach contents have been identified for two basilosaurids: Basilosaurus cetoides fed on teleost fish and sharks of up to 50 cm in length ( ...
[104]
[PDF] Two possibly aquatic triconodont mammals from the Early ...
Three mammalian molars from the Early Cretaceous of Morocco reveal the existence, at that time, of two new and peculiar species, one of them assigned to.