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Fasciola hepatica

Fasciola hepatica, commonly known as the common , is a parasite that primarily infects the livers of mammals, including humans and ruminants such as sheep, , and goats. This leaf-shaped hermaphroditic worm measures approximately 20–30 mm in length and 8–15 mm in width, with a conical anterior end and a flattened body adapted for its parasitic lifestyle. Belonging to the phylum Platyhelminthes and class , it is closely related to , though the two species differ in size and geographic prevalence, with hybrids reported in regions like and . The of F. hepatica is complex and involves both and stages, requiring freshwater snails as hosts and mammals as definitive hosts. flukes reside in the ducts of the definitive host, where they produce up to 25,000 operculated eggs per day that are excreted in feces. These eggs embryonate in freshwater over about two weeks, hatching into free-swimming miracidia that penetrate lymnaeid snails (e.g., Galba truncatula or species) to undergo multiplication, producing sporocysts, rediae, cercariae, and finally metacercariae that encyst on aquatic vegetation or in water. occurs when the definitive host ingests contaminated plants, such as ; the metacercariae excyst in the intestine, migrate through the to the liver over 4–6 weeks, and mature in the ducts within 3–4 months. F. hepatica causes fascioliasis (or fasciolosis), a neglected zoonotic disease recognized by the World Health Organization as a neglected tropical disease, affecting over 70 countries worldwide, particularly in temperate and tropical regions where livestock farming is prevalent, including Europe, Latin America, Asia, and Africa. In humans, an estimated 2.4–17 million people are infected (as of recent estimates), leading to significant morbidity with around 90,000 disability-adjusted life years (DALYs) lost annually (as of 2023). The disease manifests in two phases: an acute migratory phase with symptoms like fever, abdominal pain, hepatomegaly, and marked eosinophilia due to larval tissue penetration and hemorrhage, followed by a chronic biliary phase involving cholangitis, bile duct fibrosis, and potential complications such as gallstones or secondary bacterial infections. In livestock, it results in substantial economic losses—estimated at over €2.5 billion annually worldwide—through reduced milk and meat production, liver condemnation, and mortality, especially in sheep. The parasite's success as a stems from its virulence factors, including cathepsin peptidases that degrade host for tissue invasion, hemoglobin-degrading enzymes that lyse red blood cells, and excretory-secretory products that modulate the host toward a Th2-biased profile to evade expulsion. typically involves detecting characteristic eggs (130–150 µm by 60–90 µm) in stool, though or may be used early in when eggs are absent. Treatment relies on , the drug of choice, which is effective against both immature and adult stages. Control measures focus on preventing ingestion of contaminated vegetation, population management, and strategic use in to interrupt transmission.

Taxonomy and etymology

Scientific classification

Fasciola hepatica belongs to the kingdom Animalia, phylum Platyhelminthes, class , subclass , order Plagiorchiida, family Fasciolidae, genus , and species F. hepatica. This hierarchical placement positions it among the digenetic trematodes, characterized by complex life cycles involving molluscan and vertebrate hosts.00203-4)
Taxonomic RankClassification
KingdomAnimalia
PhylumPlatyhelminthes
Class
Subclass
OrderPlagiorchiida
FamilyFasciolidae
Genus
SpeciesF. hepatica
The species is distinguished from its close relative Fasciola gigantica primarily by morphological traits, such as a shorter body length (typically 20–30 mm in F. hepatica versus 25–75 mm in F. gigantica) and a more acute anterior cone in F. hepatica. Genetically, the two species show , including differences at five positions in the 1 (ITS-1) region of , supporting their separation as distinct species despite occasional hybridization. The class has undergone significant taxonomic revisions, including the elevation of its status within Platyhelminthes from a subclass to a full class in modern classifications, alongside refinements in subclass divisions such as Aspidogastrea and . No scientific synonyms are recognized for F. hepatica, with the binomial name established by Linnaeus in 1758 remaining the valid authority.

Discovery and naming

The earliest documented observation of Fasciola hepatica dates to 1379, when shepherd Jehan de Brie described symptoms of infection in sheep in his treatise Le Bon Berger, commissioned by King Charles V; he linked the disease to consumption of "dauve" (swamp grass), a term that later evolved into the "douve du foie" for the parasite. Earlier archaeological evidence suggests the presence of F. hepatica eggs in animal coprolites from sites like Shillourokambos, (8th-7th BC), indicating its ancient impact on herbivores. In the , Italian naturalist provided one of the first detailed descriptions of the adult in his 1684 work Osservazioni intorno agli animali viventi che si trovano negli animali viventi, where he illustrated the parasite from sheep and livers, recognizing its parasitic nature and contributing to early . Subsequent observations, such as those by Hieronymus Gabucinus in 1547 (describing the fluke as "squash seed"-shaped in sheep livers) and Cornelius Gemma in 1552 (reporting an epizootic in the ), built on these accounts, though without formal classification. The species was formally named Fasciola hepatica in 1758 by in his (10th edition), deriving "Fasciola" from the Latin fasciola (diminutive of fascia, meaning a small band or ribbon, alluding to the worm's flat, leaf-like body) and "hepatica" from hepar (liver), reflecting its primary habitat in the bile ducts of the liver. During the , initial taxonomic confusion arose with other trematodes due to morphological similarities, particularly with , which Thomas Cobbold named in 1855 from a giraffe specimen; variants like F. hepatica var. angusta and var. aegyptica were later synonymized with F. gigantica. This period saw clarification through improved and studies, such as those by Rudolf Leuckart in 1881, distinguishing F. hepatica as a distinct species primarily affecting temperate regions.

Morphology and anatomy

Overall body plan

Fasciola hepatica adults possess a characteristic leaf-shaped, dorsoventrally flattened body that measures 20–30 mm in length and 8–15 mm in width. This flattened form aids in navigating the confined spaces of the host's biliary system. The anterior end is tapered and conical, which facilitates tissue penetration during migration into the liver , while the posterior end is broader and more rounded. An oral sucker is located at the tip of the conical anterior, serving primarily for ingestion of host fluids and nutrients. Posterior to this is a larger ventral sucker, or , positioned on the ventral surface near the anterior third of the body, enabling firm attachment to host tissues. As a hermaphroditic , F. hepatica exhibits no , with both male and female reproductive structures incorporated into the overall body architecture to support self- or cross-fertilization. The body is covered by a thin tegument that provides protection and facilitates .

Tegument and surface structures

The tegument of Fasciola hepatica forms a non-ciliated, syncytial cytoplasmic layer that envelops the entire body surface, serving as the primary interface with the environment. This distome structure consists of an outer syncytial stratum connected via cytoplasmic processes to underlying nucleated tegumental cells, bounded externally by a plasma membrane. The surface features include prominent spines that project from the tegument, aiding in anchorage to tissues and facilitating during . These spines are particularly dense on the ventral surface and oral , varying in and across developmental stages. A thick , composed of carbohydrate-rich glycoproteins, coats the tegumental , providing protection against and immune effectors while enabling immune evasion through shedding and renewal. Sensory papillae, often clustered in groups of 7–25 units, are distributed across the surface, particularly around the suckers, contributing to tactile and chemical sensing for navigation and attachment. The tegument exhibits remarkable regenerative capacity, rapidly repairing damage by sloughing off compromised areas and replenishing the surface layer during tissue migration or immune challenge. Unlike the , which primarily handles of host macromolecules via secreted proteases in the gut lumen, the tegument specializes in direct of low-molecular-weight nutrients such as glucose and through transtegumental transporters and pinocytotic vesicles. It also facilitates waste by releasing excretory-secretory products across the surface, bypassing the gut and enhancing overall metabolic efficiency in the habitat. This dual role underscores the tegument's evolutionary for nutrient scavenging and in a nutrient-variable environment.

Internal organ systems

The digestive system of Fasciola hepatica consists of a simple, incomplete, sac-like gut that begins with a ventral enclosed by the oral sucker, leading into a muscular , a short , and a bifurcated intestinal ceca that extend posteriorly and branch into numerous diverticula, ending blindly without an . Waste materials and undigested remnants are egested through the mouth, while occurs extracellularly in the gut through the secretion of proteolytic enzymes such as cathepsin L from gastrodermal cells, which break down host tissues like , , and epithelial cells. The , derived from , facilitates nutrient absorption into the surrounding via , supplemented by the tegument's role in uptake of small molecules across the body surface. The is a protonephridial network comprising numerous flame cells—ciliated, bulbous structures embedded in the —that collect metabolic wastes such as , fatty acids, and excess through ciliary beating, channeling them via a of collecting tubules and canals into a main longitudinal excretory duct that opens at a posterior . This labyrinthine arrangement of ducts and flame cells, numbering in the hundreds, forms an interconnected mesh that not only eliminates nitrogenous waste but also regulates osmotic balance by adjusting and in response to the host's environment, where and osmolarity fluctuate. The exhibits a orthogonal typical of flatworms, centered on paired cerebral ganglia located posterior to the oral sucker and connected by a transverse commissure encircling the , from which three pairs of longitudinal cords (, lateral, and ventral) extend posteriorly, linked by oblique commissures and transverse connectives. The neuropile within the ganglia contains unmyelinated processes, including prominent giant fibers (>12 μm diameter) for rapid , and supports simple chemical synapses with small clear vesicles; sensory organs such as eyespots and tactile papillae are present in larval stages like the miracidium for detection but are absent in the adult worm. Respiration in Fasciola hepatica lacks dedicated organs such as lungs or gills, relying instead on cutaneous across the thin body surface for , with oxygen uptake limited in the hypoxic habitat. metabolism is predominantly , centered on in the to produce pyruvate, which is then processed in mitochondria via malate dismutation and fumarate reduction pathways to yield and propionate as major end products (in a 2:1 ratio), generating approximately 5 ATP per glucose molecule through without reliance on an oxidative . This adaptation involves key enzymes like and fumarate reductase, with rhodoquinone facilitating , enabling survival in low-oxygen conditions.

Reproductive system

Fasciola hepatica is a hermaphroditic trematode, possessing both male and female reproductive organs that enable self- or cross-fertilization within the same individual. The female system features a single dendritic positioned anteriorly on the left side, which generates oogonia and oocytes through mitotic and meiotic divisions. These oocytes travel via the to the ootype, a chamber where fertilization takes place. The Mehlis' gland encircles the ootype and secretes mucoproteins and other substances critical for formation and hardening. The , a highly branched and coiled tube extending anteriorly from the ootype to the genital pore, serves to store and propel fertilized eggs outward. Lateral and posterior consist of numerous follicles that produce vitelline cells, supplying granules, , and proteins essential for embryonic nourishment and construction. The male reproductive apparatus includes two lobed, branched testes located in the posterior third of the body, where occurs, yielding mature spermatozoa. Spermatozoa are collected by the vasa efferentia, which merge into the , leading to the cirrus sac near the anterior end; within this sac, the vas deferens coils around the vesicle before terminating in the , a , eversible organ used for . A common genital atrium receives both the and cirrus, facilitating reciprocal mating between flukes. Internal fertilization occurs in the ootype, where spermatozoa from the enter the to meet oocytes, often before the fully forms. Although self-fertilization is viable—particularly in solitary infections, where single flukes can produce viable eggs via —cross-fertilization predominates in multi-worm infections to minimize and enhance . In dense infections, reduces the risk of , as evidenced by higher egg viability and output in paired versus isolated flukes. Mature flukes produce up to 25,000 eggs daily, each an operculated, ellipsoidal structure measuring 130–150 µm long by 60–90 µm wide. These eggs acquire a yellow-brown hue from bile pigments as they traverse the host's biliary ducts before excretion in feces.

Genome and genetics

The genome of Fasciola hepatica was first sequenced in 2015 using a whole-genome shotgun approach, yielding a draft assembly of approximately 1.3 Gb, making it one of the largest genomes among known pathogens. This size is substantially larger than that of related trematodes, such as Schistosoma mansoni (approximately 400 Mb), and is attributed to extensive gene duplication and proliferation of repetitive elements. The assembly, generated from Illumina short-read and mate-pair libraries, captured about 500 Mb in scaffolds with an N50 of 1.2 Mb, but the full estimate accounts for unassembled repetitive regions. Improved assemblies, such as a PacBio-based version from the sensitive Adult fluke S strain, have since enhanced contiguity and annotation. Repetitive sequences constitute a significant portion of the genome, estimated at over 45% overall, though only 32% was annotated in the assembled scaffolds due to assembly challenges with highly repetitive DNA. Key gene families show marked expansions adapted to parasitism, including cysteine proteases such as cathepsins L (17 predicted members) and B (7 members), which facilitate host tissue invasion and nutrient acquisition. Antioxidant enzymes, essential for surviving oxidative stress in host environments, include single-copy genes for superoxide dismutase, peroxiredoxin, and thioredoxin glutathione reductase. Genetic variation within F. hepatica populations exhibits relatively low diversity, with nucleotide diversity (π) around 5.2 × 10⁻⁴, though certain regions show high polymorphism potentially aiding adaptation to hosts and drugs. For species differentiation from the closely related Fasciola gigantica, the internal transcribed spacer (ITS) region of ribosomal DNA serves as a reliable marker due to its conserved yet species-specific sequence variations.

Life cycle

Egg and miracidium stages

The eggs of Fasciola hepatica are broadly ellipsoidal to ovoid in shape, measuring 130–150 µm in length by 60–90 µm in width, with a thin, operculated shell that features a roughened or irregular abopercular end and a yellowish-brown coloration. They are passed unembryonated in the feces of the definitive host and require immersion in freshwater for development. Embryonation occurs within the over approximately 9–15 days at optimal temperatures of 22–26°C, during which the miracidium forms inside; lower temperatures (e.g., 13–20°C) can extend this period to about 51 days, while development is inhibited below 10°C. is triggered by exposure to light and suitable temperatures (typically 20–30°C), which prompts the miracidium to secrete enzymes that dissolve the opercular , allowing the lid to open and the larva to emerge. The miracidium is a free-swimming, ciliated approximately 130–140 µm long and 70–80 µm wide, with a pear-shaped or elongated conical body featuring a broad anterior end, tapering posterior, and a prominent apical at the front. It is covered in cilia of varying lengths for , possesses two adjacent reniform eyespots near the anterior end for phototaxis, and has primitive sensory structures to detect suitable hosts. Once hatched, the miracidium remains viable for 8–24 hours depending on temperature (shorter at warmer conditions, e.g., ~6 hours at 25°C), actively swimming in a helical to penetrate the soft tissues of an intermediate lymnaeid host before its energy reserves are depleted.

Intramolluscan development

Upon penetrating the intermediate , the miracidium of Fasciola hepatica rapidly transforms into a sporocyst, a sac-like structure containing germinal cells that serve as the foundation for . This transformation typically occurs within hours to a few days post-infection, depending on environmental conditions within the . The sporocyst undergoes parthenogenetic development to produce the first generation of rediae, elongated larval forms equipped with a and that migrate through the snail's tissues, primarily the digestive and . These mother rediae, in turn, asexually generate daughter rediae through further , enabling multiplicative amplification; under optimal conditions, up to four generations of rediae can develop sequentially. This intramolluscan phase, from sporocyst formation to the maturation of later redial generations, spans 4–7 weeks at 22°C. Compatible intermediate hosts for this development are restricted to lymnaeid snails, particularly species in the Lymnaea (or Galba) genus, such as L. truncatula, which provide the necessary physiological environment for parasite proliferation. The process is highly temperature-dependent, with optimal intramolluscan development occurring between 10°C and 30°C; below 10°C, progression halts, while temperatures above 30°C inhibit redial formation and reduce overall productivity. At 15–25°C, sporocyst duration shortens from approximately 21 days to 4–7 days, and redial generations accelerate, enhancing transmission potential.

Metacercaria and infection

Following emergence from the infected intermediate host snail, free-swimming cercariae of Fasciola hepatica actively seek out suitable substrates for encystment, typically attaching to aquatic or semi-aquatic vegetation such as (Nasturtium officinale). These cercariae rapidly shed their tails and secrete a robust cyst wall, forming the metacercarial stage within hours to days. The cyst features a tough, double-layered structure: an outer operculated proteinaceous layer for initial protection and an inner laminated lipid-rich membrane that resists and environmental stressors. Metacercariae encysted on vegetation can remain viable for up to 12 months under favorable moist conditions, such as in pastures or damp hay, enabling prolonged infectivity for grazing herbivores. Infection occurs when the definitive host ingests contaminated vegetation harboring viable metacercariae, which measure approximately 0.15–0.2 mm in diameter. Upon reaching the , the cysts initially encounter the acidic environment of the , where host and low (around 2–4) enzymatically digest the outer cyst layer, initiating the excystation process. As the partially digested cysts move to the , neutral (approximately 7–8), salts, elevated CO₂ tension, and reducing conditions trigger the final activation phase, leading to the emergence of motile newly excysted juveniles (NEJs) within 1–2 hours.30249-X) This two-stage excystation ensures synchronized release of infectious juveniles primed for host . The liberated NEJs, equipped with a specialized tegument and secretory glands, immediately penetrate the duodenal mucosa using proteolytic enzymes to breach the intestinal wall and enter the peritoneal cavity.30249-X) From there, they traverse the and Glisson's capsule to reach the , a migratory that typically spans 4–6 weeks during which the juveniles grow and develop while navigating hepatic tissues. This initial host entry establishes the acute of fascioliasis, setting the stage for subsequent intrahepatic progression.

Adult stage in definitive host

Following excystation in the of the definitive host, juvenile Fasciola hepatica migrate through the and before reaching the hepatic bile ducts approximately 8–12 weeks post-infection. Once established in the bile ducts, the juveniles continue to develop and into sexually reproductive adults over an additional 3–4 months, at which point they begin producing eggs. In sheep, the primary host, adult flukes can live for 9–13 years, contributing to infections and sustained egg output; in humans, the lifespan is generally shorter, estimated at 5–10 years or up to 13.5 years in some cases based on limited data. Adult F. hepatica reside primarily in the tertiary and quaternary branches of the hepatic bile ducts, where they attach to the biliary using oral and ventral suckers. They feed on , tissue fluids, , , and epithelial fragments, employing proteases such as L1 and leucine aminopeptidases to digest and other host proteins. As hermaphroditic organisms, adults are capable of both self-fertilization and cross-fertilization; while self-fertilization ensures reproduction in low-density infections, pairing for cross-fertilization is preferred when multiple flukes are present, as it promotes and enhances egg viability compared to selfed eggs. Each mature adult produces 10,000–20,000 operculated eggs per day, which are released into the and eventually passed in the host's to continue the . Post-maturity, adult flukes undergo further growth, increasing in size from approximately 20 mm long and 8 mm wide at initial maturity to up to 30 mm long and 15 mm wide, depending on host species, infection intensity, and nutritional factors. This size increase supports enhanced reproductive capacity, with larger flukes capable of higher egg outputs; however, crowding in heavy infections can limit individual growth and .

Ecology and distribution

Habitat preferences

_Fasciola hepatica thrives in aquatic and semi-aquatic environments characterized by slow-moving freshwater bodies, such as rivers, drainage ditches, springs, and roadside ditches, often with lush aquatic vegetation like that supports metacercariae encystment. These habitats provide the moist conditions essential for the survival and reproduction of its intermediate host , primarily species of the genus , including in temperate regions. The fluke's transmission is optimized in areas with shallow water or exposed moist mud, where temperatures range from 10 to 25°C and pH levels between 6.0 and 8.0, facilitating miracidial infectivity and snail activity. Intermediate host snails inhabit wetlands, floodplains, and irrigated pastures, preferring poorly draining clay soils over peatlands, which limits their distribution to regions with consistent moisture. Definitive hosts, such as ( and sheep), are typically found in areas adjacent to these bodies, where they ingest contaminated during foraging. These ecological niches depend on the fluke's , which requires standing or slow-flowing for egg hatching and larval stages. Globally, F. hepatica hotspots are concentrated in temperate zones, including much of (e.g., , , ) where suitable snail habitats abound in damp meadows and riverbanks, and the Andean highlands of , particularly the Bolivian with its hyperendemic areas supported by alpine wetlands. The parasite avoids arid climates unless artificial irrigation creates moist microhabitats, restricting its natural range to humid, temperate, and subtropical regions across all continents except .

Global prevalence and environmental influences

_Fasciola hepatica has a widespread distribution, putting an estimated 180 million people at risk of , with approximately 2.4 million cases reported worldwide. In livestock, the parasite causes significant , with pooled prevalence rates of 17% in and 13% in sheep based on systematic reviews of global data. High infection rates are observed in endemic regions; for instance, coprological prevalence in reaches 33.7% in parts of , contributing to substantial economic losses in . fascioliasis is particularly prevalent in the Andean highlands of and , where hyperendemic areas show infection rates exceeding 60% in some communities, as well as in and parts of such as the and . Environmental factors play a critical role in the distribution and transmission of F. hepatica, as the parasite's depends on suitable conditions for its intermediate hosts. , characterized by rising temperatures and altered precipitation patterns, is expanding the parasite's range by enhancing habitat suitability and metacercariae survival. Recent studies from 2024 and 2025 indicate that warmer temperatures and increased humidity in previously marginal areas, such as southern , northern , and extreme latitudes in the , are facilitating the spread of fascioliasis into new territories, including hotspots in southeastern and risks in southern like . Additionally, human activities like and flooding promote the parasite's proliferation by creating persistent environments that support lymnaeid populations. In regions with extensive systems, such as parts of and , these modifications have been linked to elevated infection rates in both livestock and humans. As a zoonotic parasite, F. hepatica relies on animal reservoirs for maintenance and amplification in endemic areas, with domestic ruminants serving as primary hosts. Sheep and are the main reservoirs, harboring high parasite burdens that facilitate environmental contamination with eggs through feces. species, including deer (cervids), act as secondary reservoirs, potentially sustaining transmission in natural ecosystems and complicating control efforts in mixed agricultural-wildland interfaces.

Parasitic adaptations

Host invasion mechanisms

Upon by the mammalian , metacercariae of Fasciola hepatica exhibit to gastric acids through their double-layered cyst wall, which protects the enclosed juvenile from degradation in the . The outer cyst layer is selectively removed by host acid peptidases, initiating activation without compromising viability, while the inner layer maintains structural integrity until environmental cues in the trigger excystation. This process is rapid, completing within approximately 3 hours, driven by reducing conditions, salts, elevated CO₂ tension, and neutral that promote the emergence of newly excysted juveniles (NEJ). The NEJ stage initiates host invasion by penetrating the intestinal epithelium, facilitated by a suite of proteolytic enzymes, particularly cathepsin L and B family cysteine peptidases such as FhCL3, FhCB2, and FhCB3. These enzymes, secreted from the parasite's tegument and caecal contents, degrade key extracellular matrix components including and , and interact with host fibrinolytic factors like plasminogen by binding and activating it to , enabling enzymatic digestion of the liver during juvenile migration. Concurrently, biomechanical adaptations support burrowing: the oral and ventral suckers generate suction to anchor and propel the juvenile forward, while tegumental spines provide traction and facilitate mechanical tearing of tissues as the parasite traverses the toward the liver. Once in the hepatic tissues, juveniles continue migration using similar mechanisms, with cathepsins sustaining tissue degradation and suckers/spines aiding navigation through parenchymal barriers. Upon maturation in the bile ducts, adult flukes secure attachment via the ventral sucker, which creates a powerful vacuum to resist bile flow and maintain position against the ductal epithelium. Tegumental spines further anchor the parasite by gripping the mucosal surface, ensuring stable habitation and access to nutrients.

Immune modulation strategies

Fasciola hepatica employs sophisticated immune modulation strategies to establish and maintain infections in mammalian hosts, primarily by dampening pro-inflammatory responses and promoting regulatory mechanisms that favor parasite survival. These strategies involve the secretion of bioactive molecules and surface modifications that interfere with both innate and adaptive immunity, shifting the host response toward rather than expulsion. Such adaptations allow the parasite to persist in the liver and ducts for years, evading clearance by immune effectors like macrophages, T cells, and . Excretory-secretory products (ESPs) released by F. hepatica play a central role in suppressing host immune responses. These include proteases, glutathione S-transferases (GSTs), and fatty acid-binding proteins (FABPs) that inhibit Th1-mediated inflammation while promoting a Th2-biased response characterized by elevated IL-4 and IL-10 production. For instance, FhFABP induces alternative activation of macrophages (M2 ), reducing TNF-α and release, which collectively dampens bactericidal and parasiticidal activities. Additionally, ESPs, including FhHDM-1, promote regulatory immune mechanisms that can indirectly support (Treg) activity and suppress effector T cell proliferation and IFN-γ production. Antioxidants within ESPs, such as GSTs, neutralize (ROS) generated by host , protecting the parasite from oxidative damage during tissue migration and residence. The parasite's glycocalyx, a carbohydrate-rich layer coating the tegument, contributes to immune evasion by dynamically altering surface antigens to avoid host recognition. This undergoes continual renewal and shedding, masking immunogenic epitopes and preventing binding or complement activation. Glycoconjugates within the glycocalyx, such as fucosylated and mannose-rich structures, interact with host dendritic cells to impair their maturation and promote IL-10 secretion, thereby inhibiting and Th1 priming. Furthermore, F. hepatica releases microRNAs (miRNAs) via extracellular vesicles derived from the glycocalyx and ESPs, which are taken up by host and downregulate genes involved in innate immunity, including those encoding pro-inflammatory cytokines like IL-1β and IL-6. Notable examples include fhe-miR-125b, which targets TRAF6 in host cells to suppress pro-inflammatory signaling pathways including , leading to reduced inflammatory responses shortly after . Additionally, recent studies (as of 2025) have shown that F. hepatica releases extracellular vesicles containing miRNAs and proteins like , which further modulate host macrophage responses and promote anti-inflammatory environments. In chronic infections, F. hepatica induces host hyporesponsiveness, fostering long-term tolerance that minimizes immune-mediated damage to the parasite. This phase is marked by a shift from an initial mixed Th1/Th2 response to immune exhaustion, with diminished T cell activation and proliferation in the liver and lymphoid tissues. activity, prominent in acute stages for tissue repair and parasite containment, is progressively reduced through Treg-mediated suppression and ESP-induced , preventing excessive formation that could expel the fluke. Studies in models demonstrate that by 20 weeks post-infection, splenic and hepatic lymphocytes exhibit hyporesponsiveness to mitogens, correlating with elevated IL-10 and TGF-β levels that sustain parasite viability. The tegument's further supports this tolerance by continuously modulating local immune signaling.

Epidemiology

Transmission patterns

The transmission of Fasciola hepatica primarily occurs through a fecal-oral route, where unembryonated eggs are excreted in the feces of infected definitive hosts, such as mammals, and embryonate in freshwater environments over approximately two weeks to release miracidia. These miracidia must infect compatible snail intermediate hosts within a short timeframe, after which the parasite undergoes asexual reproduction inside the snail, eventually producing cercariae that encyst as metacercariae on aquatic vegetation or in water. Definitive hosts, including livestock and occasionally humans, become infected by ingesting these metacercariae-contaminated plants or water, with excystation occurring in the small intestine to initiate migration to the liver. This indirect cycle ensures no direct mammal-to-mammal transmission, relying entirely on environmental contamination for propagation. As a zoonotic parasite, F. hepatica maintains its primary cycle in populations, particularly sheep and , which serve as hosts and amplify transmission through in contaminated pastures. Human infections are incidental and typically result from consumption of uncooked aquatic plants like in salads or contaminated in endemic areas, often in regions with shared livestock-watering practices. In , infection rates are highest during seasons when metacercariae are abundant on wet vegetation, sustaining enzootic transmission in systems. Transmission patterns are heavily influenced by the population dynamics of intermediate snail hosts, primarily species in the family Lymnaeidae such as Galba truncatula, whose abundance and infection rates drive outbreak frequency. Snail populations exhibit seasonal fluctuations tied to environmental conditions, with peaks in activity and miracidial infection during warmer, wet periods that favor egg embryonation and larval development. In regions with distinct wet seasons, such as parts of and , fasciolosis cases and metacercarial availability surge in summer and autumn due to increased rainfall, humidity (55–70%), and temperatures (22–25°C) that enhance snail survival and reproduction. These dynamics often lead to biseasonal or monoseasonal transmission patterns, with overwintering snails contributing to early-season infections in spring, while summer infections dominate overall outbreak risks in livestock.

Risk factors and human impact

Human fascioliasis risk is primarily associated with the consumption of raw or undercooked aquatic plants, such as , that are contaminated with metacercariae in endemic regions. This behavioral factor is exacerbated by reliance on untreated water sources for or drinking, which facilitates larval contamination in rural settings. Socioeconomic elements, including and , heighten vulnerability, as impoverished communities often lack access to safe water and practices, while herding increases exposure through shared environments. Recent 2025 analyses indicate that expanded systems in and , driven by agricultural , have contributed to rising case numbers by creating favorable habitats for intermediate hosts. The disease imposes a significant human burden, particularly as it remains underdiagnosed in tropical and subtropical regions due to limited surveillance and overlapping symptoms with other illnesses. Classified as a neglected tropical disease since 2010, fascioliasis disproportionately affects over 2.4 million people globally, mostly in rural, low-income areas with inadequate healthcare. Economically, it leads to substantial losses in the livestock sector, estimated at over $3 billion annually worldwide, stemming from reduced animal productivity, treatment costs, and condemned livers at slaughter. A framework has gained prominence for addressing fascioliasis, integrating , animal, and to mitigate zoonotic . Studies from 2025 underscore the need for coordinated monitoring of infections alongside cases to enable early and reduce overall in endemic zones.

Fasciolosis

Pathogenesis and disease progression

The pathogenesis of Fasciola hepatica infection unfolds in two primary phases, beginning with the acute migratory following excystation of metacercariae in the host's . During the acute phase, which typically lasts 4-6 weeks, juvenile flukes penetrate the intestinal wall and migrate through the to the liver, where they burrow into the hepatic . This migration causes extensive mechanical disruption, leading to hemorrhage along the migratory tracts as the flukes' cuticular spines and suckers lacerate blood vessels and hepatic tissue. The resulting tissue damage triggers of hepatocytes and inflammatory responses, with significant blood loss contributing to , particularly in heavily infected hosts such as sheep or . In the chronic phase, spanning months to years, the flukes mature and establish residence in the bile ducts, where they can persist for up to a decade. Adult worms attach to the using their suckers, causing ongoing mechanical that erodes the duct walls and leads to , , and eventual thickening of the ductal tissue through excessive deposition. This chronic irritation induces cholangitis, an inflammatory condition of the ducts, and can progress to biliary obstruction due to fluke biomass, epithelial proliferation, and secondary , impairing flow and liver function. The damaged also predisposes to secondary bacterial infections, such as those by Clostridium novyi, which can exacerbate and lead to conditions like infectious necrotic in ruminants. Several key pathogenic factors drive tissue damage throughout the infection. Mechanical trauma from the parasites' spines and suckers directly abrades hepatic and biliary tissues during and attachment, creating entry points for hemorrhage and secondary pathogens. Additionally, toxic metabolites in the flukes' excretory-secretory products, such as , promote host activation and synthesis, accelerating in the bile ducts. Recent 2024 research highlights the role of cathepsin L proteases in , where these enzymes degrade host components like and , facilitating invasion and triggering inflammatory cascades through tissue disruption and immune cell recruitment.

Clinical symptoms and complications

Fasciolosis caused by Fasciola hepatica manifests in two primary phases in humans: an acute migratory phase and a chronic biliary phase, with symptoms varying in intensity and many cases remaining asymptomatic. In the acute phase, which lasts up to 3-4 months, patients commonly experience fever, right upper quadrant abdominal pain, hepatomegaly, nausea, vomiting, diarrhea, weight loss, and urticaria due to larval migration through the liver parenchyma. Prominent eosinophilia, often exceeding 20% of total white blood cells, is a hallmark laboratory finding during this period, reflecting the host's immune response to the invading parasites. The chronic phase, involving adult flukes in the bile ducts, can persist for years and is frequently asymptomatic, though symptomatic cases may present with intermittent , , , and from biliary obstruction and . Complications in this phase include cholangitis, biliary obstruction leading to gallstones, from ectopic migration, and progressive liver or in severe, untreated infections. Human fasciolosis often mimics other hepatobiliary disorders, such as or cholelithiasis, complicating initial recognition. In animals, particularly livestock like sheep and cattle, fasciolosis presents distinct clinical signs that underscore its economic impact on agriculture. In sheep, the acute phase can cause sudden death from massive liver hemorrhages, lethargy, anemia, and dyspnea, while subacute and chronic forms lead to ill-thrift, progressive weight loss, bottle-jaw edema, reduced wool quality, and hypoalbuminemia. A notable complication in sheep is black disease, an often fatal secondary infection by Clostridium novyi facilitated by liver damage and necrosis. Cattle exhibit similar patterns, including chronic weight loss, diarrhea, reduced milk production, and increased susceptibility to bacterial infections, though they generally tolerate heavier burdens better than sheep.

Treatment options and control measures

The primary pharmacological treatment for fasciolosis caused by Fasciola hepatica is , administered at a dose of 10 mg/kg body weight twice, 12 hours apart, which achieves approximately 90% efficacy against both immature and adult stages of the parasite in humans and . This derivative disrupts formation in the fluke, leading to its immobilization and death, and is recommended by the as the of choice due to its broad-spectrum activity. For , alternative flukicides include nitroxynil and closantel, which target adult flukes with high efficacy (over 95% in many cases) but are less effective against immature stages. In humans, serves as an alternative, dosed at 500 mg orally twice daily for 7 days with food, though efficacy varies. to has emerged since the mid-1990s, initially reported in and subsequently in the , where field studies documented reduced efficacy below 80% in affected sheep flocks. to has also been reported in human cases, necessitating monitoring and potential alternative therapies. This resistance is attributed to frequent use and suboptimal dosing, leading to selection pressure on parasite populations. Recent genomic analyses in 2024 identified the F200Y in the β-tubulin as a key marker associated with resistance, present at high frequencies in resistant isolates from multiple regions, which alters binding and reduces success. Control measures for fasciolosis emphasize integrated approaches targeting the snail intermediate host (Galba truncatula) and transmission routes. Snail habitat management, including drainage of wet pastures and application of molluscicides like , can reduce intermediate host populations by up to 90% in high-risk areas. Fencing off contaminated pastures prevents access to snail-infested zones, while thorough washing of with clean water or solutions minimizes human infection from contaminated produce. Vaccination trials using recombinant cathepsin L proteases as antigens have shown promise, inducing 40-60% protection in sheep and models by eliciting responses that impair fluke migration and survival, with ongoing research aimed at commercial development.

Diagnosis

Parasitological methods

Parasitological methods for diagnosing Fasciola hepatica primarily involve the direct microscopic detection of eggs in fecal samples, which is the gold standard for confirming patent infections in the chronic phase. These techniques are essential for identifying the parasite's operculated eggs, which measure 130–150 µm in length and 60–90 µm in width, with a thin, translucent shell and an inconspicuous operculum at one end. Egg detection is only possible after the prepatent period of approximately 3–4 months post-, when adult flukes begin producing eggs in the ducts, leading to their in . However, these methods have limitations, including low sensitivity due to intermittent shedding, low egg output in light infections, and the need for multiple samples to improve diagnostic accuracy. The Kato-Katz thick smear technique is a widely recommended parasitological method by the for detecting helminth eggs, including those of F. hepatica, in epidemiological surveys and clinical settings. In this procedure, approximately 41.7 mg of sieved stool is placed in a template on a slide, covered with glycerin-malachite green , pressed to spread the sample evenly, and examined under a light after 30–60 minutes to clear the feces. The large size and distinct morphology of F. hepatica eggs facilitate their identification, but the method's sensitivity is notably low in early chronic fascioliasis due to sparse egg excretion and potential degradation of eggs on the slide. Studies comparing Kato-Katz to techniques have shown it detects fewer positive cases in low-burden infections, emphasizing the need for repeated examinations. Sedimentation and formalin-ether concentration techniques offer higher for concentrating F. hepatica eggs from fecal samples, particularly in cases with low parasite loads. In the basic method, 5–10 g of is mixed with or saline, allowed to settle for 1–2 hours, and the is examined microscopically after decanting the supernatant. The formalin-ether (or ) variant enhances this by suspending the sample in 10% formalin, adding to dissolve and , centrifuging at around 1500–2500 × g for 2–5 minutes, and scrutinizing the for eggs. These approaches effectively isolate viable eggs—distinguished by their developing miracidia—from non-viable ones and fecal contaminants, making them suitable for both qualitative and egg viability assessment. Despite their advantages, these methods are labor-intensive and require trained personnel, with varying based on sample volume and intensity.

Serological and molecular techniques

Serological techniques for diagnosing Fasciola hepatica infections primarily rely on that detect host antibodies against parasite , such as excretory-secretory (ES) products derived from adult flukes. These assays target IgG antibodies and have demonstrated high , ranging from 90% to 98% across , , and sheep hosts, depending on the antigen used, with ES antigens achieving 96.8% sensitivity in humans and over 97% in . However, ELISAs employing crude ES antigens can exhibit cross-reactivity with other trematodes, such as spp. or paramphistomes, leading to false positives in endemic areas; recombinant antigens like cathepsin L1 or saposin-like protein 2 mitigate this issue, improving specificity to 95-99%. Molecular methods offer direct detection of F. hepatica DNA or RNA, enhancing diagnostic precision through polymerase chain reaction (PCR) assays targeting conserved regions like the internal transcribed spacer 2 (ITS2) of ribosomal DNA or the cytochrome c oxidase subunit 1 (cox1) mitochondrial gene. Conventional and real-time PCR using these targets can detect as little as DNA from a single egg, equivalent to less than 1 egg per gram of feces, allowing identification even in low-burden infections. Recent advancements include loop-mediated isothermal amplification (LAMP), optimized in 2024 for fecal samples from cattle and sheep, which requires no thermocycler and enables field deployment via portable incubators, with sensitivity comparable to PCR for detecting F. hepatica DNA at low concentrations. Both serological and molecular approaches provide key advantages over traditional methods by identifying pre-patent infections—serology through early responses during the migratory phase, and molecular techniques via parasite DNA in feces or blood before egg shedding begins. Additionally, molecular assays facilitate species differentiation between F. hepatica and F. gigantica by analyzing single nucleotide polymorphisms (SNPs) in ITS2 or cox1 sequences through PCR-restriction fragment length polymorphism (RFLP) or next-generation sequencing, enabling accurate identification of hybrids or regional variants.

Imaging and clinical approaches

Ultrasound is a primary modality for detecting -related liver , particularly in the acute parenchymal phase where it reveals focal hypoechoic or hyperechoic lesions corresponding to migrating larvae tracks, as well as increased liver . In the chronic ductal phase, identifies dilation, wall thickening, and occasionally mobile flukes within dilated ducts, with characteristic "bull's eye" appearances reported in some cases of clustered lesions. Computed tomography (CT) provides detailed visualization of hypodense subcapsular tracts and clustered lesions with peripheral contrast enhancement during the parenchymal migration phase, reflecting inflammatory responses to larval invasion. In the biliary phase, CT demonstrates dilated intrahepatic and extrahepatic bile ducts with periportal tracking and, rarely, residual calcifications from dead flukes. Magnetic resonance imaging (MRI) complements CT by showing T2-hyperintense lesions with T1-hypointensity and peripheral enhancement in the acute phase, while in chronic fibrosis, it highlights ductal dilatation and filling defects from live worms, though it may underperform in mild cases compared to CT. Endoscopic retrograde cholangiopancreatography (ERCP) or direct cholangioscopy allows visualization of adult flukes in the bile ducts during the obstructive phase, often revealing linear or coiled worms causing ductal and facilitating therapeutic extraction. Clinical evaluation integrates with laboratory findings, such as marked and elevated liver enzymes (e.g., , , and GGT), which correlate with hepatic and biliary obstruction. A history of consuming raw plants, like , in endemic areas is crucial for contextualizing these findings and distinguishing fascioliasis from other hepatobiliary diseases.