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Cleaner fish

Cleaner fish are small marine species, primarily from the wrasse (Labridae) and goby (Gobiidae) families, that engage in mutualistic cleaning symbioses by removing ectoparasites, dead skin, scales, mucus, and damaged tissue from larger "client" fish and other marine animals, thereby gaining access to food in return.^[1] These interactions typically occur at fixed "cleaning stations" on coral reefs, where cleaners perform up to thousands of services daily, often signaled by distinctive behaviors such as dances or bold color patterns like blue-and-yellow stripes to attract clients.^[1] The symbiosis is characterized by cooperation, with cleaners providing health benefits to clients—such as reduced parasite loads and improved growth—while clients offer nutritional rewards, though cleaners sometimes "cheat" by preferring client mucus over parasites, leading to complex partner choice dynamics.^[2] Notable examples include the bluestreak cleaner wrasse (Labroides dimidiatus), an obligate cleaner species endemic to the Indo-Pacific that can remove over 1,200 parasites per day from clients, and the neon goby (Elacatinus oceanops) in the Atlantic, which acts as a facultative cleaner alongside shrimp partners.^[1] Cleaner fish exhibit advanced cognitive abilities, including numerical discrimination and strategic decision-making to prioritize high-value clients or evade predators, as demonstrated in lab studies where they solve foraging tasks comparable to primates.^[2] These behaviors are mediated by tactile stimulation, where cleaners "massage" clients to encourage repeat visits, highlighting the role of communication in sustaining the mutualism.^[3] Ecologically, cleaner fish play a pivotal role in coral reef ecosystems by enhancing client abundance, diversity, and body condition; experimental removals of cleaners have shown parasite infestations increasing by up to 4-fold and long-term declines in reef fish populations over 8–13 years.^[1] With over 200 fish species and numerous shrimp involved in cleaning across tropical and temperate waters, these symbioses influence broader marine community structure, though threats like overfishing and habitat degradation pose risks to their persistence.^[3]

Introduction and Overview

Definition and Ecological Role

Cleaner fish are small species, typically from families such as Labridae and Gobiidae, that engage in mutualistic symbiosis by removing ectoparasites, dead tissue, mucus, and sometimes scales from the bodies, gills, and mouths of larger "client" fish or other marine organisms, providing nutritional benefits to the cleaners while enhancing client hygiene.^[4]^[5] This cleaning behavior is a form of interspecific cooperation prevalent in coral reef ecosystems, where cleaners establish designated stations to attract clients, fostering a network of interactions that supports both parties.^[6] Ecologically, cleaner fish play a crucial role in preventing ectoparasite outbreaks on reefs by consuming high volumes of parasites, such as gnathiid isopods, which can otherwise proliferate and impair client health; for instance, the bluestreak cleaner wrasse (Labroides dimidiatus) removes an average of 1,218 gnathiids per day per individual.^[7]^[8] This parasite control promotes client growth and survival rates—for example, long-term removal of L. dimidiatus from reefs led to a 37% decline in resident fish abundance and shifts toward smaller body sizes in damselfishes due to elevated parasite loads—thereby stabilizing food webs by curbing disease transmission and supporting larger predatory fish populations essential for biodiversity.^[9]^[6] Reefs with active cleaners exhibit up to double the species diversity and four times the abundance of visiting fish compared to those without, underscoring their indirect facilitation of community structure.^[6] Beyond parasite management, cleaner fish contribute to ecosystem dynamics through microbial exchanges during interactions, acting as potential vectors for beneficial bacteria that influence reef microbiomes; a 2025 study on Caribbean cleaner gobies demonstrated that their stations alter microbial communities on damselfish and reef substrates, enhancing diversity and possibly aiding coral health by dispersing microbes that mitigate pathogens or support resilience against bleaching.^[10]^[11] Additionally, by consuming organic waste like mucus and dead tissue, cleaners participate in nutrient recycling, converting potential pollutants into biomass that sustains reef productivity, though their precise quantitative impact on cycling remains under investigation.^[4]

Evolutionary Origins

Cleaning symbiosis in fish has evolved independently multiple times within the teleost lineage, with phylogenetic analyses indicating 26–30 separate origins within the Labridae family alone, primarily during the late Miocene approximately 10–5 million years ago.^[12] The fossil record of Labridae, which includes many cleaner species, dates back to the Early Eocene around 50 million years ago, with early wrasse-like forms such as Phyllopharyngodon longipinnis and Labrobolcus giorgioi preserved in Monte Bolca, Italy, suggesting that the morphological foundations for diverse feeding strategies, including potential cleaning behaviors, were present in ancient reef ecosystems.^[13] Convergent evolution is evident across unrelated families, such as Labridae (wrasses) and Gobiidae (gobies), where cleaning has arisen at least four times independently in the latter, driven by similar selective pressures in marine environments.^[14] This pattern highlights the repeated emergence of mutualistic cleaning as an adaptive strategy in coral reef habitats. Adaptive pressures favoring cleaning symbiosis stem from the abundance of ectoparasites in parasite-rich environments like coral reefs, where cleaners gain access to a reliable food source—parasites and dead tissue—that is unavailable or risky for non-cleaning congeners.^[14] By forming alliances with larger client fish, cleaners benefit from reduced predation risk, as clients refrain from consuming them during interactions, allowing small-bodied species to exploit niches otherwise dominated by predators.^[15] This mutualism is reinforced through co-evolution with parasites, as cleaning reduces ectoparasite loads on hosts, thereby enhancing cleaner survival by maintaining a sustainable client population and minimizing disease transmission risks.^[14] Phylogenetically, cleaner fish are distributed primarily within the orders Labriformes and Gobiiformes, with Labridae and Gobiidae accounting for the majority of species exhibiting this behavior.^[16] Independent origins occur in marine lineages, though some gobies bridge marine and freshwater habitats, suggesting parallel evolutionary trajectories in distinct aquatic systems.^[17] Genetic markers, particularly serotonin-related genes, are associated with the modulation of cooperative behaviors in cleaners like Labroides dimidiatus, influencing social motivation and interaction willingness during symbiosis.^[18] Recent genomic research on Labroides species reveals adaptations tailored to symbiotic cleaning, including gene losses in olfactory receptors and immune-related families, which reduce reliance on smell and enhance parasite resistance.^[19] Convergent evolutionary changes, such as substitutions in taste receptor genes (TAS1R3) and bone development pathways, parallel those in other cleaners, supporting specialized feeding morphology for ectoparasite removal.^[19] Heightened expression of glutamate receptors in the brain further facilitates sensory processing for client interactions, underscoring the molecular basis of this mutualism.^[19]

Diversity

Marine Cleaner Fish

Marine cleaner fish are predominantly found in tropical and subtropical ocean environments, where they play a vital role in maintaining reef health by removing parasites from larger fish species. Over 200 species across various families, including wrasses (Labridae) and gobies (Gobiidae), have been identified as engaging in cleaning behaviors in marine habitats. Recent estimates indicate a global total of approximately 208 cleaner fish species, the majority of which are marine.^[20] These species are adapted to high-biodiversity coral reef ecosystems, with cleaning interactions concentrated in areas of high fish density. The bluestreak cleaner wrasse, Labroides dimidiatus, serves as the classic example of a marine cleaner fish, widely distributed across Indo-Pacific coral reefs. This species exhibits bold coloration, featuring a blue body with yellow stripes that signal its cleaning role to potential clients, enhancing recognition and attracting larger fish for mutualistic interactions. Juveniles display more pronounced stripe patterns, which fade slightly in adults, aiding in species identification during early life stages when cleaning activity is most intense.^[21]^[22]^[23] In Caribbean reefs, the bluehead wrasse, Thalassoma bifasciatum, represents a prominent facultative cleaner, particularly in its juvenile phase. Juveniles establish cleaning stations on reefs, where they remove ectoparasites from client fish, contributing to the overall health of western Atlantic coral ecosystems. This species forms large schools over shallow reefs, allowing juveniles to transition from cleaning to other feeding strategies as they mature.^[24]^[25] The neon goby, Gobiosoma oceanops (now classified under Elacatinus oceanops), is another key marine cleaner, often establishing cleaning stations alongside cleaner shrimp, such as Pederson's cleaner shrimp (Ancylomenes pedersoni), which together provide cleaning services to client fish in the western Atlantic. These stations are set up on reefs, fostering a stable mutualism with client fish.^[26]^[27]^[28] Marine cleaner fish exhibit specialized adaptations suited to their oceanic habitats, including vibrant blue and yellow stripes that facilitate client recognition against reef backgrounds. Their small body size, generally under 10 cm, minimizes predation risk while allowing access to hard-to-reach parasite sites on clients. In Indo-Pacific reefs, these fish achieve high densities, supporting frequent interactions in densely populated ecosystems.^[22] These species primarily inhabit coral reefs and rocky subtidal zones in tropical and subtropical marine environments, where water temperatures range from 24–30°C and structural complexity provides shelter and client access. Their presence enhances biodiversity by reducing parasite loads, indirectly benefiting reef community stability. Recent studies from 2024 highlight niche partitioning between L. dimidiatus and L. bicolor, where differences in cleaning aggression levels allow coexistence by targeting distinct client preferences and reducing interspecific competition.^[5]^[29]^[30]

Brackish and Freshwater Cleaner Fish

Brackish and freshwater cleaner fish inhabit dynamic environments characterized by fluctuating salinity, including estuaries where river water mixes with seawater, as well as rivers and lakes with stable low-salinity conditions. These species typically engage in facultative cleaning behaviors, removing ectoparasites, dead tissue, and debris from client fish, but unlike the highly specialized marine cleaners, their interactions are often opportunistic and supplemented by other feeding strategies such as grazing on algae and detritus. This adaptability allows them to thrive in habitats with lower client densities compared to coral reefs, though cleaning symbiosis plays a less dominant role in their ecology. Notable examples in brackish waters include euryhaline gobies that occur in coastal areas, where they pick parasites from larger fish. In freshwater systems, the doctor fish (Garra rufa), a cyprinid native to rivers and streams in Turkey, Syria, Iraq, and Iran, exemplifies cleaning activity by nibbling on dead skin and organic matter; it is also commercially utilized in pedicures to exfoliate human skin by removing flakes of dead tissue. Other freshwater cleaners encompass species from diverse families, including poeciliids like guppies (Poecilia reticulata) and various cichlids that occasionally remove parasites from conspecifics in lakes and rivers.^[31] These fish exhibit physiological adaptations for tolerating salinity variations between 0 and 30 parts per thousand (ppt), primarily through specialized osmoregulatory processes in the gills and kidneys that actively transport ions to maintain internal fluid balance amid osmotic challenges. In environments with sparser client populations, such as Asian rivers or African lakes, they establish smaller territories and broaden their diet to include algae, plankton, and detritus alongside parasites, enhancing their resilience in nutrient-variable habitats.^[32] Research on brackish and freshwater cleaners remains limited relative to marine studies, with fewer than 20 well-documented freshwater species engaging in dedicated cleaning behaviors, often as part of broader ecological roles rather than obligate symbiosis. For G. rufa, studies indicate potential anti-inflammatory effects on human skin through its exfoliating action, aiding conditions like psoriasis by promoting skin renewal, though its wild ecological contributions include controlling algal overgrowth and removing necrotic tissues that could foster infections in other fish.^[33]^[34]

Cleaning Symbiosis

Facultative versus Obligate Cleaners

Cleaner fish are categorized into facultative and obligate (or dedicated) types based on their reliance on cleaning interactions for nutrition. Facultative cleaners, such as many species of wrasses including the bluehead wrasse (Thalassoma bifasciatum), engage in cleaning opportunistically alongside foraging for other prey like small invertebrates or plankton, deriving only a small portion of their diet from client ectoparasites.^[5] In contrast, obligate cleaners, exemplified by the bluestreak cleaner wrasse (Labroides dimidiatus), obtain over 80% of their food from cleaning, specializing almost exclusively in removing parasites from client fish.^[35] Of the approximately 208 known cleaner fish species, the majority (~93%, or about 192 species) are facultative, with only around 16 obligate specialists, reflecting a broader ecological distribution for facultatives compared to the fewer obligate species.^[35]^[19] Lifestyle differences between these groups are pronounced, influencing their spatial behavior and life history. Obligate cleaners typically establish and defend fixed cleaning stations on reefs, where they remain sedentary to attract passing clients, often exhibiting territorial behaviors to secure prime locations.^[20] Facultative cleaners, however, are more mobile, roaming larger areas to hunt alternative food sources while opportunistically initiating cleaning interactions, particularly during juvenile stages before transitioning to other foraging strategies.^[14] This roaming behavior in facultatives allows for seasonal shifts in cleaning frequency, adapting to prey availability or environmental changes, whereas obligates maintain consistent cleaning year-round due to their dietary dependence.^[12] The strategies carry distinct advantages and trade-offs shaped by ecological pressures. Obligate cleaners benefit from reliable access to nutrient-rich ectoparasites, enabling specialized morphological adaptations like precise jaw structures for parasite removal, but they face heightened risks of starvation during periods of low client density or environmental disruptions.^[36] Facultative cleaners gain flexibility, reducing vulnerability by diversifying their diet and avoiding dependence on unpredictable client visits, though this comes at the cost of increased competition for occasional cleaning opportunities and potentially lower proficiency in specialized cleaning tasks compared to obligates.^[37]

Cleaner Stations and Client Interactions

Cleaner stations are fixed territories, often centered on prominent structures such as coral heads or crevices, where cleaner fish like the bluestreak cleaner wrasse (Labroides dimidiatus) establish and vigorously defend their operational areas against intruders.^[2] These stations typically support one to two cleaners, functioning as dedicated hubs for mutualistic interactions on coral reefs.^[29] To attract clients from distances up to several meters, cleaners employ visual signals, including conspicuous dances characterized by rapid, oscillating body movements that advertise their availability and location.^[38] Upon arrival, client fish signal their intent by adopting submissive poses, such as spreading their fins, opening their mouths, or flaring their gills to expose parasite-laden areas for inspection.^[39] Cleaners then approach, nipping at and removing ectoparasites like gnathiid isopods from the client's body, scales, and gills, though they occasionally consume preferred client mucus, which can elicit client objections in the form of jolts or chases. This inspection process emphasizes targeted parasite removal while providing incidental tactile stimulation, which clients may find beneficial. Interactions at these stations exhibit dynamic social structures, with popular sites often featuring queues of waiting clients, including both resident reef fish and transient visitors, leading to interspecies cooperation among multiple cleaners or competition for access.^[2] Cleaning sessions typically last 1 to 10 minutes, depending on client size and mobility, allowing a single station to service over 800 clients daily in high-traffic areas.^[40] Recent research highlights an additional ecological role, revealing that cleaner fish facilitate microbial transfer during these interactions, influencing bacterial and archaeal diversity across reef substrates and potentially enhancing overall reef health through the dispersal of beneficial microbes.^[41]

Behavioral Mechanisms

Partner Control and Cheating

In cleaning mutualisms, cleaner fish such as the bluestreak cleaner wrasse (Labroides dimidiatus) often exhibit cheating behavior by preferring to bite and consume healthy client mucus rather than focusing solely on ectoparasites, as mucus provides higher nutritional value despite the risk of client retaliation.^[42] This preference creates a conflict of interest, where cleaners gain short-term benefits from mucus but jeopardize long-term access to clients who may abandon or punish them.^[43] Clients enforce partner control through immediate responses to cheating, such as chasing the cleaner fish or abruptly terminating the cleaning session to prevent further mucus bites. Over repeated interactions, clients also demonstrate image scoring by preferentially selecting cleaners with a history of honesty, avoiding those known for frequent cheating to maximize service quality.^[44] The evolutionary stability of this mutualism relies on relatively low cheating rates that prevent full defection while allowing cleaners some nutritional gains. Cleaners mitigate client punishment through tactile stimulation, such as gentle fin touches that appease clients and prolong interactions even after occasional cheating. Experimental observations from 2020 indicate that juvenile cleaners can learn about cheating consequences through social observation.^[45] Interspecific variation highlights differences in honesty levels; for instance, cleaning gobies (Elacatinus spp.) exhibit lower cheating rates than wrasses, as they preferentially consume ectoparasites over mucus, reducing the need for extensive partner control. A 2025 study on cleaner wrasses revealed greater behavioral flexibility in honesty among species like L. dimidiatus, with reduced cheating toward high-value clients.^[46]

Memory, Learning, and Decision-Making

Cleaner fish, particularly species in the genus Labroides, demonstrate memory capabilities that enable them to track interactions with clients over varying timescales. Long-term memory persists for months, as evidenced by Labroides dimidiatus remembering aversive events like capture in a net even after 11 months, which may influence general avoidance behaviors.^[47] Such retention helps cleaners build and maintain cooperative relationships, reducing the risk of retaliation over time.^[40] Learning in cleaner fish involves both observational and associative processes that refine their interaction strategies. Juveniles of Labroides dimidiatus engage in social learning by observing conspecifics, acquiring knowledge about the consequences of cheating—such as client punishment—without direct experience, which accelerates their adaptation to mutualistic norms.^[48] Decision-making relies on cost-benefit analyses, where cleaners weigh potential gains from scale-eating against risks; they tend to cheat smaller, less aggressive clients while providing honest ectoparasite removal to larger, predatory ones to avoid punishment.^[49] This selective strategy optimizes energy intake while preserving access to high-value partners. Experimental studies underscore these cognitive faculties. Laboratory observations reveal that Labroides dimidiatus can distinguish and prefer familiar clients, spending more time inspecting known individuals in choice tests, indicative of individual recognition capacity for over 100 clients in natural settings.^[40]^[50] Research from 2025 demonstrates that cleaner wrasse exhibit temporary cognitive deficits in visual discrimination tasks under simulated marine heatwave stress, with performance recovering after 14 days, highlighting the resilience yet vulnerability of cognitive processing in high-pressure ecological contexts.^[51] A key concept in cleaner fish cognition is the image scoring model, first demonstrated in a 2006 study, where cleaners monitor and respond to clients' assessments of their reputation based on prior interactions.^[52] Under this framework, bystanders—other potential clients—observe cleaning events and favor cleaners with a history of honest service, prompting cleaners to track client "reputations" to anticipate retaliation or partner switching. For novel clients lacking interaction history, cleaners adapt through trial-and-error, testing behaviors like tactile stimulation to gauge responses and refine future approaches.^[49] These mechanisms collectively enable cleaners to navigate complex social dynamics, prioritizing long-term mutualism over short-term exploitation.

Biological Adaptations

Neurobiology and Cognition

Cleaner fish, particularly species like the bluestreak cleaner wrasse (Labroides dimidiatus), exhibit notable neuroanatomical adaptations that support their complex social interactions. The telencephalon, a key component of the forebrain, is enlarged in individuals from high-population-density reefs, correlating with enhanced social cognition and decision-making in cleaning mutualisms.^[53] This enlargement, observed to be up to 14% larger in dense habitats, facilitates the processing of social cues from client fish, enabling cleaners to adapt behaviors to local ecological conditions.^[54] Serotonin pathways play a critical role in modulating aggression versus cooperation; depletion of serotonin reduces motivation for client interactions and increases cheating behaviors, while enhancement promotes cooperative cleaning and decreases intraspecific aggression.^[55] These neural mechanisms underscore how brain structure influences the balance between mutualistic benefits and self-serving actions in cleaner fish.^[56] Stress responses, mediated by neural pathways, alter decision-making; for instance, acute stress elevates cortisol, shifting cleaners from cooperation to cheating via interactions with dopamine and serotonin systems.^[57] A 2025 study on cleaner wrasse exposed to marine heatwaves revealed temporary cognitive impairments, with reduced task success rates during exposure, alongside brain morphology changes including a smaller telencephalon and larger brainstem, though performance recovered post-exposure.^[51] These findings highlight how environmental stressors disrupt neural processing of social decisions in cleaners.^[58] Neurotransmitter systems further underpin cleaning behaviors, with dopamine facilitating reward from successful interactions; stimulation of D1 receptors enhances learning capacity for cooperative tasks, while disruptions increase negotiation for better rewards from clients.^[59] Oxytocin analogs, such as isotocin, promote bonding with clients and pair partners; higher forebrain isotocin levels in males correlate with stronger pair associations and improved service quality in mixed-sex cleaning pairs.^[56] Arginine vasotocin, a vasopressin analog, inversely affects interspecific cooperation, with elevated levels linked to reduced client inspections and increased cheating.^[60] Recent 2024-2025 research links cognitive decline to environmental stressors like warming reefs, with heatwave exposure causing temporary impairments in visual discrimination tasks.^[51] These neural adaptations position cleaner fish as valuable models for studying cognition under climate change pressures.^[61]

Sensory and Morphological Specializations

Cleaner fish possess visual adaptations that enhance their ability to detect ectoparasites on clients and interpret signals during interactions. Many species exhibit tetrachromatic vision, including sensitivity to ultraviolet (UV) light, which allows them to perceive UV-reflective patterns or signals on client fish that may indicate parasite presence or readiness for cleaning.^[62] This UV sensitivity is particularly relevant in coral reef environments where short-wavelength light penetrates water effectively. Additionally, cleaner fish display conspicuous blue and yellow body colorations that are evolutionarily linked to their cleaning role; these colors provide high contrast against reef backgrounds, aiding client recognition from a distance.^[63] Tactile specializations in cleaner fish enable precise and non-damaging contact with clients during parasite removal. In wrasses such as Labroides dimidiatus, pelvic and pectoral fins are used to deliver gentle tactile stimulation by stroking the client's dorsal area, which reduces client stress and prolongs interactions without causing injury to scales or mucus layers. Cleaning gobies in the genus Elacatinus possess pectoral fins with enhanced mechanosensory capabilities, allowing them to probe substrates and client surfaces with high sensitivity for detecting irregularities like parasites. Paired cleaning by gobies further enhances tactile efficiency, as cooperative inspections improve service quality and precision in locating ectoparasites. Morphological features of cleaner fish support agile navigation and non-threatening appearance during symbiosis. Their typically small and slender body forms facilitate maneuvering into tight crevices or gill cavities of larger clients, minimizing disturbance while accessing hidden parasites.^[64] Bold lateral stripes and contrasting patterns, common in obligate cleaners like bluestreak wrasses, evolve as visual cues that signal harmless intent, deterring aggression from clients and promoting approach behavior. Studies on facultative cleaners indicate that variations in fin morphology, such as relative length and robustness, correlate with cleaning proficiency, with more specialized fins linked to higher ectoparasite removal rates in species like western Atlantic gobies.

Interspecies Interactions

Mimicry by Saboteur Species

Saboteur species, such as the false cleanerfish Aspidontus taeniatus, exploit the cleaning symbiosis by mimicking the appearance and behaviors of genuine cleaner wrasse like Labroides dimidiatus to gain close access to unsuspecting client fish. These mimics closely resemble juvenile and adult cleaner wrasse in morphology, featuring a similar black body with blue stripes, comparable body size (typically under 7 cm), and overall shape that allows them to blend seamlessly at cleaning stations. Behaviorally, A. taeniatus replicates the characteristic jiggling or dancing motions used by cleaners to signal availability, luring clients into a vulnerable pose where the mimic can then bite chunks from their fins, scales, or mucus instead of providing parasite removal. This aggressive mimicry primarily occurs in reef habitats overlapping with cleaner territories, enabling saboteurs to intercept clients drawn to established stations.^[65]^[66] The deception succeeds initially because clients, expecting mutualistic cleaning, allow close approach without defensive aggression, with A. taeniatus fooling approximately 50-60% of potential victims in observed interactions, particularly smaller or naive clients. Success rates vary by mimic size, with smaller individuals (<7 cm) achieving higher fin-biting frequencies due to their enhanced resemblance to juvenile cleaners, while larger saboteurs shift to alternative foraging like egg predation. However, repeated encounters reduce effectiveness as clients learn to distinguish mimics through subtle differences, such as the saboteur's ventral mouth position or lack of actual cleaning. This initial high deception rate provides saboteurs with nutrient-rich fin tissue when benthic resources, like tube worms or bivalves, are scarce in their habitat.^[65]^[66] Evolutionarily, this system exemplifies Batesian mimicry, where the rare saboteur gains protective benefits by masquerading as the abundant, defended model (L. dimidiatus), deterring attacks from predatory clients that avoid harming cleaners. The low density of mimics relative to models sustains the deception, as frequent exposures would erode client trust in the cleaner's signal; studies show mimic attack success increases with model abundance and client density, amplifying the dilution effect. For saboteurs, the strategy yields dual advantages: reduced predation risk and opportunistic access to prey, driving the evolution of precise morphological and behavioral fidelity, especially in juveniles reliant on mimicry before developing other predatory skills.^[67]^[68] Cleaners have evolved counters to this exploitation, including unique tactile cues during interactions that saboteurs cannot fully replicate, such as gentle fin stimulation to appease clients and reinforce mutualism. Recent research highlights how signal evolution in cleaners, including enhanced tactile dancing behaviors, helps discriminate genuine services from mimicry, maintaining symbiosis integrity amid saboteur pressure. These adaptations underscore the ongoing coevolutionary arms race between cleaners, clients, and imposters in coral reef ecosystems.^[2]^[69]

Predation Risks and Defensive Strategies

Cleaner fish face significant predation risks due to their small size and bold behavior in approaching larger reef inhabitants for cleaning interactions. Piscivorous clients, such as groupers and jacks, pose a primary threat by occasionally attempting to consume cleaners during or immediately after service, exploiting the close proximity established in the mutualism.^[15] Ambush predation by non-client predators is another hazard, as the cleaners' conspicuous coloration and active signaling can inadvertently attract opportunistic hunters rather than deter them.^[70] Their diminutive body size, typically under 15 cm for adults like Labroides dimidiatus, further amplifies vulnerability to swift strikes from a wide array of reef piscivores.^[71] To counter these threats, cleaner fish employ several defensive strategies centered on behavioral caution and physical prowess. Obligate cleaners selectively approach "safer" non-piscivorous clients when possible, using visual cues to assess risk and prioritizing interactions that minimize exposure to predators, though they cannot entirely avoid dangerous clients due to their reliance on cleaning for sustenance.^[72] In interactions with high-risk piscivores, cleaners perform tactile dancing—gentle body caresses on the client's body—to reduce aggression and predation likelihood, effectively calming the predator and promoting prolonged, safer cleaning sessions.^[73] Juveniles enhance survival through group schooling, which dilutes individual risk by confusing predators and allowing coordinated escapes, a tactic particularly vital during settlement when predation pressure is highest.^[25] Adults and juveniles alike rely on exceptional agility for rapid evasion, maintaining fast-start escape responses comparable to non-cleaning reef fish despite their privileged mutualistic status.^[15] Ecologically, these risks are mitigated by the mutualism's value, resulting in exceptionally low predation rates on cleaners, with no observed predation events despite extensive field observations, as clients benefit from repeated parasite removal and thus restrain predatory impulses to preserve future services.^[71] This dynamic influences population stability, with predation pressure shaping territorial behaviors and station fidelity among obligate species; recent field observations indicate that heightened predation risk reinforces site-specific residency at protected cleaning stations, reducing dispersal and enhancing local abundance.^[74] Juveniles of Labroides dimidiatus employ crypsis, blending into algal substrates with subdued coloration to evade detection during vulnerable early stages before adopting the adult cleaning role.^[75]

Applications and Implications

Use in Aquaculture

Cleaner fish are deployed in aquaculture systems, particularly Atlantic salmon farms, to biologically control sea lice infestations through the introduction of wild-caught or hatchery-reared individuals. Common species include ballan wrasse (Labrus bergylta) and goldsinny wrasse (Ctenolabrus rupestris), which are stocked at ratios typically ranging from 1:10 to 1:50 cleaner fish per salmon to optimize lice removal while minimizing competition for resources.^[76]^[77] These ratios are adjusted based on farm conditions, such as water temperature and lice pressure, with hatchery-reared fish often preferred for their consistency in size (around 60-70 g) and reduced risk of disease introduction.^[78] Monitoring involves tagging systems to assess survival, behavior, and escape rates, ensuring effective deployment and compliance with regulations.^[79] The primary benefits of using cleaner fish in aquaculture include significant reductions in sea lice populations, often up to 90% under controlled conditions, which decreases reliance on chemical delousing agents and mitigates associated environmental risks.^[80] This biological approach also enhances overall fish welfare by reducing stress from parasitic loads and can lead to improved growth rates in salmon, as lice infestations otherwise impair feeding and health.^[81] For instance, lumpfish (Cyclopterus lumpus) and wrasse species have demonstrated efficacy in slowing lice development stages, allowing longer intervals between treatments.^[82] In Norwegian salmon farms, goldsinny wrasse (Ctenolabrus rupestris) has been a key case study, with widespread adoption since the 1990s showing effective lice control in commercial pens but highlighting challenges like survival rates as low as 20-50% due to predation, stress, and poor adaptation to captivity.^[83]^[84] These issues are being addressed through specialized training programs for farm operators on handling and deployment techniques, as well as research into genetic selection for more docile and delousing-efficient strains of ballan wrasse, with ongoing breeding initiatives including recent farm efforts in North Wales as of 2025.^[85]^[86]^[87]

Environmental and Conservation Impacts

Human activities pose significant threats to cleaner fish populations and their ecological roles in marine ecosystems. Overharvesting for use in aquaculture has depleted wild stocks of species such as wrasse, with approximately one million individuals fished annually in Scottish waters alone (as estimated in 2019), leading to concerns over long-term population declines and genetic impacts from escaped farmed fish hybridizing with wild populations.^[88]^[89] Habitat loss from coral reef degradation further exacerbates these pressures, as cleaner fish rely on complex reef structures for cleaning stations; studies show that reduced coral cover directly correlates with lower abundances of coral-dependent cleaner species.^[90] Climate change compounds these threats, with ocean acidification impairing cognitive functions in cleaner wrasse, such as decision-making during cleaning interactions, thereby diminishing their effectiveness in parasite removal under projected CO2 levels.^[91] A 2025 study also documented lasting neurological impairments in cleaner wrasse cognition following marine heatwaves, highlighting vulnerability to warming events.^[92] Despite these challenges, cleaner fish provide essential positive impacts to reef ecosystems by reducing parasite loads and disease prevalence among client species. Through mutualistic cleaning behaviors, they remove ectoparasites like gnathiids and corallanid isopods, alleviating physiological stress and improving overall fish health, which in turn supports higher biodiversity and abundance in resident populations.^[93] Long-term experimental removals of cleaners have demonstrated cascading effects, including smaller body sizes, reduced species richness, and increased injury rates in client fishes due to unchecked parasitism.^[9] Their potential role in reef restoration is emerging, with suggestions that restocking or protecting cleaners could enhance recovery in degraded habitats by bolstering parasite control and facilitating settlement of juvenile fishes.^[94] Conservation efforts aim to mitigate these impacts through regulatory measures and research initiatives. In the European Union, wrasse fisheries are governed by national management plans requiring licenses for commercial fishing, though species like ballan wrasse remain non-quota stocks, prompting calls for stricter export controls to curb overexploitation.^[95] Sustainable breeding programs for cleaner fish, such as selective breeding of ballan wrasse for enhanced delousing behaviors, seek to reduce reliance on wild captures and alleviate pressure on natural populations.^[86] Amid coral bleaching events, cleaners play a role in maintaining reef microbiome health by influencing microbial dispersal at cleaning stations, potentially buffering against dysbiosis; a 2025 field study linked cleaner presence to altered reef microbial diversity, suggesting their decline could exacerbate pathogen proliferation during stress events.^[96] Some cleaner fish species, such as the broken-back cleaner-goby (Elacatinus figaro), are assessed as vulnerable on the IUCN Red List due to collection and habitat pressures, underscoring the need for targeted protections.^[97] Recent 2025 research further connects cleaner fish declines to elevated parasite loads on reefs, with microbial community shifts amplifying disease risks in client populations.^[98] In 2025, some salmon farms received welfare awards for transitioning away from cleaner fish to alternative sea lice controls, potentially alleviating pressure on wild populations.^[99]

References

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A marine cleaning mutualism provides new insights in biological ...
In marine cleaning mutualisms, cleaners remove ectoparasites, scales, ectodermal mucus and tissue from clients. The vast majority of cleaners and clients are ...
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Cleaner Fish - an overview | ScienceDirect Topics
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Jul 13, 2010 · This is known as cleaning behaviour and involves 'cleaners', animals which remove parasites, tissue, mucus and sometimes even blood from other ...Missing: definition | Show results with:definition
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In such situations, the ecological role of cleaner fish, with their ability to reduce fish parasite loads [10], should therefore not be ignored. Indeed, ...
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Jan 11, 2025 · This study estimates the rate at which parasites (mainly gnathiids) are removed by the cleaner wrasse Labroides dimidiatus from host fish using ...
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Cleaner fish, Labroides dimidiatus, prefer the mucus of the parrotfish, Chlorurus sordidus, to parasitic gnathiid isopods, the main items in their diet.
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Jun 5, 2025 · UC Davis-led research shows that these tiny fish not only help remove parasites but may also shape microbial diversity across reef environments.
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Jun 7, 2025 · Cleaner fish dart around bigger “clients,” even entering mouths to remove parasites and bacteria. Some even offer what looks like a massage.
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[13]
[PDF] A review of the fossil record of the Labridae
Jan 15, 2019 · The published fossil record of the Labridae is critically evaluated. In total, fossils from 14 genera are provisionally placed within the ...
[14]
Co-evolution of cleaning and feeding morphology in western Atlantic ...
The study found four independent origins of cleaning in gobies, with dedicated cleaners having smaller size-corrected traits, and high convergence in ...
[15]
Mutualistic cleaner fish maintains high escape performance despite ...
Apr 19, 2017 · Predatory reef fishes regularly visit mutualistic cleaner fish (Labroides dimidiatus) to get their ectoparasites removed but show no interest in eating them.Missing: adaptive | Show results with:adaptive
[16]
Phylogenetic classification of bony fishes | BMC Ecology and Evolution
Jul 6, 2017 · Some of the most diverse orders (e.g., Perciformes, Labriformes, Lophiiformes, and Tetraodontiformes) and families (e.g., Labridae, Serranidae, ...
[17]
Phylogeny and evolution of Indo-Pacific shrimp-associated gobies ...
We show that the mutualist shrimp association has arisen twice among gobies, once in a clade composed of Amblyeleotris, Ctenogobiops, and Vanderhorstia.
[18]
The role of serotonin in the modulation of cooperative behavior
Apr 22, 2015 · Our results provide first evidence that serotonin is a neuromodulatory driver of cooperative behavioral activities and contribute to the understanding of ...
[19]
Gene losses, parallel evolution and heightened expression confer ...
Aug 23, 2023 · This study reveals that L. dimidiatus harbours substantial losses in specific gene families, convergent evolutions across cleaners and a large-scale high gene ...
[20]
Blue and Yellow Signal Cleaning Behavior in Coral Reef Fishes
Aug 11, 2009 · We show that cleaner fish are more likely to display a blue coloration, in addition to a yellow coloration, compared to noncleaner fish.Missing: recognition | Show results with:recognition
[21]
Size and stripes: how fish clients recognize cleaners - ScienceDirect
... Labroides dimidiatus, which varied in size and stripe ... yellow is most contrasting against blue water backgrounds or against black lateral stripes.
[22]
(PDF) Cleaning up the biogeography of Labroides dimidiatus using ...
Aug 10, 2025 · All obligate cleaner fishes share this body stripe pattern, which is an important signal for attracting client fishes. However, variability in ...
[23]
Bluehead – Discover Fishes - Florida Museum of Natural History
May 29, 2025 · They are social fish that school in the hundreds or thousands in shallow reef zones, and are valued as cleaners, removing parasites and dead ...
[24]
The selective cleaning behaviour of juvenile blue-headed wrasse ...
These wrasse displayed two cleaning strategies: stationary versus wandering cleaning, with cleaning frequency being highest for stationary cleaners. A specific ...
[25]
Propagating The Neon Goby, Gobiosoma Oceanops - Reefs.com
May 15, 2003 · We often keep them with large clownfish and frequently observe symbiotic cleaning behavior. The clownfish assumes a head up position and ...
[26]
A Record of Cleaning Symbiosis Involving Gobiosoma sp. and ... - jstor
in cleaning symbiosis. In the Caribbean, clean- ing behavior is particularly well developed within the genus Gobiosoma: i.e., G. oceanops, G. Page 2 ...
[27]
Size and stripes: How fish clients recognize cleaners - ResearchGate
Aug 8, 2025 · Thus, in fish, blue colouration and dark lateral stripes may be signals that, on average, reliably identify cleaners. ... The behavioural ...
[28]
Functional niches of cleanerfish species are mediated by habitat use ...
Sep 3, 2021 · Ectoparasite removal by cleanerfish species is considered a behaviourally complex interspecific interaction in vertebrates, but differences in ...
[29]
Interspecific variation in cleaning behaviour and honesty among ...
Jul 16, 2025 · Here, we quantify differences among three coexisting species of morphologically similar cleaner wrasses (Labroides bicolor, L. dimidiatus and L.
[30]
Elacatinus figaro, Barber goby : fisheries, aquarium - FishBase
Occurs over coral and rocky bottoms on the mainland coast and at or off coastal islands; solitary or in groups of up to 6 individuals on coral heads.Missing: mangroves | Show results with:mangroves
[31]
[PDF] Red Garra (Garra rufa) ERSS - U.S. Fish and Wildlife Service
Biological and ecological information is available for Garra rufa. No records of introduction to the wild were found for this species but G. rufa is heavily ...
[32]
[PDF] Salinity tolerance of fishes - the NOAA Institutional Repository
Variations in salinity are among the physical parameters that drive the capacity of fish to survive and thrive in a range of environments; from freshwater (FW) ...
[33]
Cleaner fishes and shrimp diversity and a re-evaluation of cleaning ...
Mar 27, 2017 · Researchers estimate there are about 208 species of marine and freshwater cleaner fish and 51 species of marine cleaner shrimp known to the scientific ...
[34]
Fish Pedicure: Review of Its Current Dermatology Applications - PMC
Jun 30, 2020 · Ichthyotherapy or fish pedicure is a unique form of biotherapy in which the species Garra rufa or doctor fish is used to exfoliate the skin and potentially aid ...Missing: ecological | Show results with:ecological
[35]
[PDF] Influences on the cleaning activity and distribution of cleaner fish
Jul 1, 2009 · Obligate cleaners acquire over 80% of their food through cleaning, whereas only a small portion of the diet of facultative cleaners comes from ...
[36]
Cleaner fishes and shrimp diversity and a re‐evaluation of cleaning ...
Dec 14, 2016 · Moreover, we propose the term 'dedicated' to replace 'obligate' to describe a committed cleaning lifestyle. Marine cleaner fishes have ...<|separator|>
[37]
The evolution of cleaner fish feeding morphology - Jonathan M. Huie
Obligate cleaners have substantially shorter and stronger jaws than non-cleaners, while facultative cleaner have an intermediate morphology. Cleaner gobies ...
[38]
Cleaning behavior is riskier and less profitable than an alternative ...
Aug 10, 2025 · Cleaning behavior is riskier and less profitable than an alternative strategy for a facultative cleaner fish. March 2007; Coral Reefs 26(1):87- ...
[39]
Cleaner host posing behavior of whitetip reef sharks (Triaenodon ...
Dec 18, 2007 · Similar open mouth and gill flaring behavior is demonstrated by ... cleaner fish. Tactile stimulation of the host is a key component of ...
[40]
Cleaner fish Labroides dimidiatus recognise familiar clients - PubMed
However, as some cleaner fish have more than 2,300 interactions per day with various individuals per species and various species of clients, basic ...
[41]
Context-dependent effects of a Caribbean cleaner goby on coral ...
May 28, 2025 · Species aggregation hubs provide a useful way to study microbial transfer in ecosystems as they could spread beneficial or pathogenic microbes.
[42]
Cleaner wrasse prefer client mucus: Support for partner control ...
Cleaner fish often prefer to bite the client's mucus instead of cooperating and eating ectoparasites only [49] . This creates a conflict of interest between ...
[43]
Reputation management promotes strategic adjustment of service ...
Aug 21, 2017 · Cleaner wrasse, Labroides dimidiatus, cooperate by eating ectoparasites off “client” fishes, or cheat (i.e. bite) and eat client mucus. Image ...
[44]
Biting cleaner fish use altruism to deceive image-scoring client reef ...
However, cheating cleaners use altruism in potentially low-pay-off interactions to deceive and attract image-scoring clients that will be exploited. Full Text.Missing: 2023 experiments remember
[45]
Juvenile cleaner fish can socially learn the consequences of cheating
Mar 3, 2020 · We show that juvenile cleaner fish (Labroides dimidiatus) can learn socially about cheating consequences in an experimental paradigm that mimics cleaners' ...Missing: frequency | Show results with:frequency
[46]
Interspecific variation in cleaning behaviour and honesty among ...
Jul 11, 2025 · Dedicated cleaners exhibited greater variability in both the amount of time spent interacting with clients and in cheating behaviour.Missing: gobies | Show results with:gobies
[47]
Cleaner wrasse failed in early testing stages of both visual and ...
Jun 4, 2025 · Cleaner wrasse failed in early testing stages of both visual and spatial working memory paradigms | Animal Cognition.Missing: observational benefit<|separator|>
[48]
Long‐term memory retention in a wild fish species Labroides ...
Oct 31, 2019 · Here, we document correlative evidence of cleaner fish Labroides dimidiatus remembering being caught in a barrier net for up to 11 months.Missing: repeat | Show results with:repeat
[49]
Juvenile cleaner fish can socially learn the consequences of cheating
Mar 3, 2020 · Clients use various control mechanisms (responses that reduce cheaters ... experimental paradigm that mimics cooperating/cheating in ...Missing: 2023 remember
[50]
Cue-based decision rules of cleaner fish in a biological market task
We exposed 'cleaner' fish (bluestreak cleaner wrasse, Labroides dimidiatus) to a biological market task, where giving priority to an ephemeral (i.e. 'visitor' ...
[51]
Cleaner fish with mirror self-recognition capacity precisely realize ...
Sep 11, 2024 · We show that cleaner fish, having attained MSR, construct a mental image of their bodies by investigating their ability to recall body size.
[52]
Alteration of cleaner wrasse cognition and brain morphology under ...
Feb 27, 2025 · Here, we exposed cleaner wrasses to a laboratory-simulated Category 1 marine heatwave for 55 days, mirroring the 2016 Great Barrier Reef event.
[53]
Image scoring and cooperation in a cleaner fish mutualism - Nature
Jun 22, 2006 · Image scoring evolves when bystanders gain personal benefits from information gathered, for example, by finding cooperative partners.
[54]
Population densities predict forebrain size variation in the cleaner ...
Nov 20, 2019 · A suitable study model is the mutualist 'cleaner' fish Labroides dimidiatus, a species that removes ectoparasites from a variety of 'client' ...
[55]
Brain morphology predicts social intelligence in wild cleaner fish
Dec 21, 2020 · We find that large forebrains enable individuals to show social competence by performing locally adaptive decision-rules, suggesting forebrain ...
[56]
The Neurobiology of Mutualistic Behavior: The Cleanerfish Swims ...
Oct 17, 2017 · In the cleaning mutualisms, cleaners rely on judgement based on their cognitive toolbox as to choose to cooperate (invest) or to defect (cheat).Missing: definition | Show results with:definition
[57]
The Neurobiology of Mutualistic Behavior: The Cleanerfish Swims ...
Oct 16, 2017 · This review surveys the current achievements of several recent studies, pointing towards the potential of the cleanerfish mutualism as a relevant model system.Missing: poses | Show results with:poses
[58]
Neuro-molecular characterization of fish cleaning interactions - Nature
May 19, 2022 · Arginine vasotocin regulation of interspecific cooperative behaviour in a cleaner fish. ... The role of serotonin in the modulation of cooperative ...
[59]
Dopamine and serotonin mediate the impact of stress on cleaner ...
Acute stress modulates cooperative behavior in cleaner fish. · Acute stress decreased the predisposal to interact and increased cortisol levels in cleaner fish.
[60]
Neurobiological and behavioural responses of cleaning mutualisms ...
Sep 4, 2019 · To analyse the behaviour component of cleaning interactions we measured cleaner fish and client motivation to interact (e.g. number of ...Missing: submissive | Show results with:submissive
[61]
Stimulation of dopamine D1 receptor improves learning capacity in ...
We demonstrate that there is an involvement of the DA system and D 1 receptor pathways on cleaners' natural abilities to learn both tasks.
[62]
Arginine Vasotocin Regulation of Interspecific Cooperative ...
Jul 3, 2012 · Here, we studied the influence of neuropeptide exogenous administration in female cleaner wrasse L. dimidiatus on their cleaning behaviour.
[63]
The UV visual world of fishes: a review - UQ eSpace
Many teleosts have three, or even four, classes of cone cells mediating colour vision in their retina and one can be sensitive to UV. These UV-sensitive ...
[64]
https://www.researchgate.net/publication/222686965_Size_and_stripes_How_fish_clients_recognize_cleaners
[65]
The false cleanerfish relies on aggressive mimicry to bite fish fins ...
May 26, 2020 · Comparison of the success rate of fish-fin biting (%) by the false cleanerfish Aspidontus taeniatus of the small size class (<7 cm total length) ...
[66]
Aggressive mimicry of the cleaner wrasse by Aspidontus taeniatus ...
Apr 19, 2018 · Success ratio of the fish fin biting by the mimic blenny (Aspidontus taeniatus) in relation to the body size of the blenny. When there is ...
[67]
Frequency-dependent success of aggressive mimics in a cleaning ...
In summary, we found evidence that the success of aggressive cleanerfish mimics depends partly on their rarity relative to their models and partly on the ...Missing: 50-70% | Show results with:50-70%
[68]
Multiple selective pressures apply to a coral reef fish mimic - Journals
Feb 24, 2010 · This study provides empirical evidence that dual benefits apply to a coral reef fish mimic in terms of increased access to food (aggressive mimicry) and ...<|separator|>
[69]
Cleaner fish Labroides dimidiatus manipulate client reef fish ... - NIH
The cleaner wrasse Labroides dimidiatus often touches 'client' reef fish dorsal fin areas with its pelvic and pectoral fins.
[70]
Mutualistic cleaner fish maintains high escape performance despite ...
This might suggest that another anti-predator strategy is needed, because cleaner fish coloration attracts predators rather than inhibiting their predatory ...<|separator|>
[71]
Mutualistic cleaner fish maintains high escape performance despite ...
Apr 19, 2017 · Here, we ask whether reduced predation pressure on fish that provide cleaning services to predators can lead to decreased escape performance via ...Missing: adaptive | Show results with:adaptive
[72]
Client fish traits underlying variation in service quality in a marine ...
We explored how partner choice options and other key partner traits predict the quality of the service provided by cleaner fish.
[73]
Mutualistic cleaner fish initiate trait‐mediated indirect interactions by ...
Jan 18, 2012 · 3. Behavioural observations indicate that the bluestreak cleaner wrasse, Labroides dimidiatus, increases local predation pressure on corals at ...
[74]
[PDF] Review Article A Review of Mimicry in Marine Fishes
Juveniles of Labroides dimidiatus are black except for a bright blue dorsal ... Aggressive mimicry between juveniles of the snapper Lutjanus bohar and ...
[75]
[PDF] Use of 'Cleaner Fish' in UK aquaculture - Marine Conservation Society
More recent use, of cleaner fish, has concentrated on Ballan wrasse and Lumpfish, and it is these two species that are currently being farmed to supply the ...
[76]
Sea lice removal by cleaner fish in salmon aquaculture
Jan 30, 2020 · Cleaner fish are used to control sea lice by eating them off salmon. However, studies show varied efficacies, and most have insufficient ...
[77]
Biological control of sea lice - CABI Digital Library
Sep 27, 2024 · It may take 18–24 months to rear ballan wrasse to a minimum size for stocking of 60–70 g. However, some salmon farmers have stocked wrasse in ...<|separator|>
[78]
Cleaner fish escape salmon farms and hybridize with local wrasse ...
Mar 21, 2018 · We provide the first evidence that translocated wild corkwing wrasse used as cleaner fish in salmon farms escape and hybridize with local ...
[79]
Sea lice removal by cleaner fish in salmon aquaculture: A review of ...
Reported efficacies varied across species and experimental scale, from a 28% increase to a 100% reduction in lice numbers when cleaner fish were used. Further, ...Missing: ratios | Show results with:ratios
[80]
It works! Lumpfish can significantly lower sea lice infestation in large ...
Lumpfish are effective cleaner fish for biological delousing and can significantly lower average levels of pre-adult and female Lepeophtheirus salmonis and ...Results · Sea Lice Infestation Levels · Chalimus Stages Of L...
[81]
Effect of cleaner fish on sea lice in Norwegian salmon aquaculture
Cleaner fish use wasn't linked to lower louse density, but allowed longer delays before delousing and slowed louse growth, though effects were small and ...
[82]
Wrasse | Institute of Marine Research
In Norway, targeted fisheries for wrasse were initiated in 1988. The use of wrasse in Norway's salmon farming industry increased from about 1,000 fish in 1988 ...
[83]
Cleaner fish growth, welfare, survival in salmon sea cages
Nov 15, 2020 · Cleaner fish used as a biological control agent against salmon lice is rapidly increasing in Atlantic salmon aquaculture.
[84]
Cleaner fish course to address training gap - Fishfarming expert
Aug 17, 2021 · The 12-module course will provide a certificated Continuing Professional Qualification in biology, rearing, farm deployment, and health and ...
[85]
Breeding for behavior in pursuit of a better cleaner fish
Aug 23, 2021 · Researchers are investigating the behaviors of cleaner fish like ballan wrasse and lumpfish, hoping to spur greater interaction with salmon.Missing: docile | Show results with:docile
[86]
Assessing the implications of wrasse fishing for marine sites and ...
Sep 6, 2025 · The increased exploitation of wild wrasse has raised concerns over depletion of these stocks (Ottesen et al. ... one million wrasse being fished ...
[87]
Cleaner fish use affect wild populations | University of Gothenburg
Apr 20, 2021 · A growing demand for cleaner fish in salmon farms raises concerns about overfishing and human-mediated geneflow to wild populations.
[88]
Habitat quality effects on the abundance of a coral‐dwelling fish ...
Sep 22, 2024 · Microhabitat associated fishes are expected to be negatively affected by coral reef degradation, given that many species are coral dwellers.
[89]
The past, present and future of cleaner fish cognitive performance as ...
Dec 4, 2019 · We show that the cognitive performance of the cleaner wrasse, Labroides dimidiatus, has not suffered from the increase of CO 2 from pre-industrial levels to ...
[90]
Alteration of cleaner wrasse cognition and brain morphology under ...
Aug 9, 2025 · ... cleaners to prolong interactions and reconcile after cheating, interaction time and client jolt rate (a correlate of dishonesty) were not ...
[91]
Access to Cleaning Services Alters Fish Physiology Under Parasite ...
Jun 8, 2022 · Cleaning symbioses are key mutualistic interactions where cleaners remove ectoparasites and tissues from client fishes.Material And Methods · Cleaner Fish Removal... · Results
[92]
Potential contribution of fish restocking to the recovery of ... - PubMed
Feb 29, 2016 · This theoretical study examines the potential applicability and outcomes of restocking grazers as a restoration tool for coral reef recovery.Missing: cleaner | Show results with:cleaner
[93]
Scottish Government Defends Wrasse Management Amid ...
Dec 5, 2024 · The Scottish Government addresses wrasse conservation concerns amid commercial fishing but dismisses setting a total allowable catch limit.
[94]
Cleaner fish: Tiny healers or hidden spreaders in coral reef ...
Jun 12, 2025 · A study published in the journal Marine Ecology Progress Series is the first to investigate the influence of cleaner fish stations on reef microbial diversity.Missing: exchanges | Show results with:exchanges
[95]
Why the Humphead Wrasse Is Endangered - Treehugger
The humphead wrasse is primarily vulnerable to destructive overfishing practices and illegal fishing due to its high value in Southeast Asia's live reef fish ...Missing: cleaner | Show results with:cleaner
[96]
Tiny fish, big impact: Study explores how cleaner fish shape reef ...
Jul 7, 2025 · On Caribbean coral reefs, small striped gobies perform a vital service. These finger-length cleaner fish pick parasites and dead tissue from the ...