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Phyllocarida

Phyllocarida is a subclass of the class , characterized by a large bivalved composed of two valves that enclose the head and most thoracic segments, connected by an adductor muscle and often featuring a movably hinged rostral plate anteriorly. These primitive s possess biramous antennules, a with lacinia mobilis, biramous maxillules and maxillae, thoracic endopods typically with exopodites or epipodites, eight thoracic somites, seven free abdominal somites, and a bearing furcal rami, with a pair of uropods arising from the seventh abdominal somite. The subclass encompasses small, primarily benthic marine forms, with extant members limited to the order Leptostraca, while extinct groups were more abundant in ancient seas. The taxonomic scope of Phyllocarida includes one living order, Leptostraca (introduced by Claus in 1880), which contains three families—Nebaliidae, Paranebaliidae, and Sarsinebalidae—and approximately 66 described worldwide as of 2024, all confined to marine environments from shallow coastal waters to the . Additionally, the subclass incorporates three extinct orders: Hymenostraca, Archaeostraca, and Hoplostraca, which dominated ecosystems and exhibit a fossil record extending back to the Lower , highlighting a once-diverse lineage that has since diminished dramatically. Living leptostracans, such as those in the Nebalia, are distinguished by a folded that broods eggs and a hinged rostrum, adaptations suited to their detritivorous, infaunal lifestyles on soft sediments; recent discoveries include new species like Nebalia holothurophila described in 2024. In evolutionary terms, Phyllocarida occupies a basal position within , often regarded as the sister group to the more derived (encompassing orders like decapods and isopods), based on shared primitive traits such as the bivalved and phyllopodous appendages. This placement underscores their significance in understanding the origins of malacostracan diversity, with fossils revealing a radiation of bivalved arthropods that paralleled early molluscan and forms in ecological roles. Despite their ancient lineage—first named as an order by in —modern phyllocarids persist as "living fossils," offering valuable models for studying development and phylogeny amid the class's overall expansion to over 40,000 .

Taxonomy and systematics

Higher classification

Phyllocarida is defined as a subclass within the class , which belongs to the superclass , subphylum Crustacea, phylum Arthropoda, and kingdom Animalia. In some classifications, it is treated as an infraclass of . The taxon was introduced by Alpheus S. Packard Jr. in 1879. In older systems, Phyllocarida was sometimes regarded as an order within , another major malacostracan subclass. Key diagnostic traits of Phyllocarida at the subclass level include a bivalved enclosing the body, seven pleonal somites (contrasting with the typical six in other malacostracans), and thoracic gills borne on the thoracic limbs, which distinguish it from subclasses such as Hoplocarida (characterized by a spiny and appendages) and (with a more fused and diverse appendage modifications). The current taxonomic consensus, as reflected in authoritative databases, places Phyllocarida as a basal subclass under > .

Included orders

Phyllocarida is divided into three orders: the extant Leptostraca and the two extinct orders Archaeostraca and Hymenostraca. The order Leptostraca comprises the only living phyllocarids, with approximately 40 described distributed across three families: Nebaliidae (containing about 33 in five genera, including Nebalia with such as Nebalia bipes), Nebaliopsidae (one genus, Nebaliopsis, with two ), and Paranebaliidae (three genera—Paranebalia, Levinebalia, and Saronebalia—with six ). The extinct order Archaeostraca, ranging from the to the , encompasses multiple families, including Caryocarididae and Rhinocarididae, with hundreds of species known from marine deposits. The extinct order Hymenostraca, documented from the to the (with some extensions into the ), includes families such as Ceratiocarididae and Hymenocarididae, represented by diverse taxa exhibiting varied forms. In older literature, Archaeostraca and Hymenostraca were occasionally merged due to superficial similarities in bivalved carapaces, but recent phylogenetic analyses, incorporating and morphology, support their separation as distinct orders within Phyllocarida. Overall, Phyllocarida includes around 40 extant species and several hundred species across these orders, with no recognized suborders.

Description

External

Phyllocarida exhibit a distinctive external dominated by a bivalved formed from two laterally compressed valves fused along the midline without a functional , enclosing the head and most of the to create a cephalo-thorax region. This typically bears a forward-projecting rostrum at the anterior margin, prominent scars from adductor muscles that held the valves together, and concentric growth lines indicating incremental molting. In extant Leptostraca, the surface is generally smooth or lightly calcified, while many taxa display tuberculate, pitted, or spinose ornamentation for protection or camouflage. The underlying segmentation is evident externally through the exposed portions of the body. The head is fused to eight thoracic somites, bearing eight pairs of biramous, leaf-like (phyllopodous) appendages that project ventrally from beneath the ; the posterior four thoracic somites often remain partially exposed. Posterior to the cephalo-thorax is a flexible, seven-segmented pleon (), with each except the last bearing biramous pleopods for swimming; the pleon terminates in a distinct bearing paired furcal rami. Externally visible cephalic appendages include biramous antennules and multiannulate antennae, which extend forward from under the rostrum. Compound eyes are a prominent external feature, typically sessile in some primitive forms or mounted on movable stalks in most extant species, providing a wide field of vision; pigmentation and ommatidial structure vary but are adapted for low-light marine environments. Overall size ranges from 3 to 17 mm in extant Leptostraca, though some reach up to 30 mm, while fossil phyllocarids like Ceratiocaris (Hymenostraca) attained lengths of 50–100 mm, reflecting greater diversity in body proportions among Paleozoic representatives.

Internal anatomy

The respiratory system of Phyllocarida primarily relies on branchial gills attached to the endopods of the thoracic appendages, which are biramous and flattened to facilitate gas exchange through a thin, vascularized surface. These gills, often divided into a gill lobe and a flabellum on the exopodite, support active blood circulation for oxygen transport. In addition, supplementary pseudobranchiae form a respiratory membrane lining the inner carapace surface, enhancing oxygen uptake particularly in hypoxic conditions by increasing the effective respiratory area. The digestive system includes a straight gut extending from mouth to , comprising a short , , and , with peristaltic contractions aiding food movement. The , a paired digestive enveloping much of the head , secretes enzymes for and absorbs nutrients, functioning as both liver and equivalents. Mandibular glands, located near the mouthparts, produce salivary secretions to initiate enzymatic breakdown of ingested particles. The is relatively simple, consisting of a small, two-lobed supraesophageal connected to optic and antennal , which integrates sensory input. A ventral nerve cord runs posteriorly along the body, featuring fused ganglia in thoracic and abdominal segments for segmental control of and visceral functions. Reproductive anatomy varies, with extant forms being dioecious. Females possess a ventral brood pouch formed by the and thoracic limbs, where fertilized eggs undergo direct development without free-living larval stages such as zoea, hatching as miniature adults. Sensory structures include chemoreceptors, primarily aesthetascs on the antennae, enable detection of chemical cues in the for foraging and .

Distribution and ecology

Modern distribution

Phyllocarida, represented primarily by the order Leptostraca, exhibit a cosmopolitan distribution across marine environments worldwide, with species recorded in all major ocean basins including the Atlantic, Pacific, and Indian Oceans. The family Nebaliidae, which encompasses the majority of extant species, is particularly widespread, occurring from coastal shelves to deep-sea habitats in these regions. In contrast, the family Nebaliopsidae is more restricted, with its sole genus Nebaliopsis showing a predominantly pelagic distribution in the Southern Hemisphere, including parts of the Indo-Pacific deep sea. Depth ranges for Phyllocarida span from intertidal zones to abyssal depths exceeding 3000 meters, though records beyond 5000 meters are rare and typically limited to specific genera. For instance, species of the genus Nebalia, such as N. bipes, are commonly found in shallow coastal muds and sediments from intertidal to subtidal areas. Deeper occurrences include Nebaliella caboti (378–2900 m) and Dahlella caldariensis (2450–2620 m), reported from bathyal to upper abyssal environments, often associated with hydrothermal vents or soft sediments. As of 2025, species diversity within Phyllocarida totals 66 extant species across 10 genera, with the highest concentrations in temperate and tropical shelf seas of the and Pacific. Diversity diminishes in polar regions, where only a few species, such as Nebalia in the and N. bipes in the , have been documented, reflecting limited adaptation to extreme cold or ice-covered conditions. Recent explorations have expanded knowledge of Phyllocarida distributions in extreme habitats. In 2021, a new species, Sarsinebalia ledoyeri, was described from mud volcanoes on the Moroccan margin of the Gulf of Cadiz in the northeast Atlantic, marking the first record of this genus in the region and highlighting their presence in chemosynthetic environments at bathyal depths. Additional findings include Nebaliella ochotica from the northwest Pacific deep sea (3287–4469 m), and in 2024, Nebalia holothurophila from southern California seagrass beds, underscoring ongoing discoveries in both abyssal and coastal settings.

Habitat preferences and behavior

Phyllocarida, commonly known as leptostracans, predominantly inhabit benthic environments in soft sediments such as and , where they are often associated with organic-rich substrates like algal mats, meadows, and detrital accumulations. These habitats range from intertidal zones and shallow subtidal areas to deeper submarine canyons and mud volcanoes, with species tolerating a wide spectrum of conditions including low dissolved oxygen levels and elevated . For instance, Nebalia hessleri thrives in dynamic detrital mats composed of surf grass and at depths of around 19 meters off , where oxygen is scarce, surviving anoxic conditions for 8-12 hours by accessing surface air or through physiological adaptations. Similarly, Paranebalia belizensis occupies algal beds of Halimeda opuntia in ecosystems of , favoring protected sites with salinities of 33-36.5‰ and temperatures around 28°C. This preference for soft, organic-laden bottoms supports their role as ecosystem engineers in processing , though some species, like Nebalia sp. in Australian beds, occur epifaunally on . Feeding in phyllocarids is primarily detritivorous and scavenging, with individuals using their biramous thoracic limbs—phyllopodous in structure—to filter suspended particles or grasp larger from the . Unlike decapods, they lack highly specialized mouthparts, relying instead on the coordinated action of maxillae and maxillipeds to manipulate food, as described in classic studies of Nebalia bipes where limb setae create currents for particle capture. Species such as Nebalia hessleri exhibit omnivorous tendencies, consuming plant , carrion, and a broad range of offered foods in settings, reflecting opportunistic in nutrient-poor sands or detritus-rich mats. This mechanism allows efficient exploitation of microbially decomposed organic material, contributing to nutrient cycling in benthic communities. Behaviorally, phyllocarids display low mobility, often burrowing nocturnally into sediments to avoid diurnal predators, with activities peaking at night in habitats. Short-distance occurs via pleopod paddling, enabling brief swims or repositioning, while brooding females carry eggs and juveniles in a ventral marsupium, facilitating direct development without free-living larvae. is typically continuous or seasonal, with ovigerous females dominant in populations, and juveniles comprising the majority, as seen in Nebalia sp. where growth rates reach 0.050-0.088 mm/day and lifespans span 49-102 days. Ecologically, they serve as key decomposers in food webs, breaking down and supporting secondary production (e.g., 5.8 g ash-free dry weight m⁻² annually in beds), while acting as prey for nocturnal fishes and larger crustaceans, with predation driving high mortality at dense populations up to 1.5 million individuals/m².

Fossil record

Temporal and spatial distribution

The fossil record of Phyllocarida spans from the middle , with the earliest known occurrences dating to approximately 505 million years ago (Ma), such as Canadaspis perfecta from the . The group achieved its peak diversity during the and periods, coinciding with the , which represented a post-Cambrian phase that facilitated widespread radiation on marine shelves. Following this zenith, diversity declined after the , with most extinct lineages disappearing by the late , though some Archaeostraca persisted into the Upper . Spatially, Phyllocarida fossils are distributed across major paleocontinents, including , , and , reflecting their adaptation to shallow marine environments worldwide. In , for instance, members of the order Archaeostraca were particularly abundant in shales of , such as those in and , underscoring their dominance in epicontinental seas during the period of peak diversification. Similar assemblages appear in (e.g., and ) and (e.g., and ), indicating a broad trans-equatorial presence on global marine shelves. Extinction patterns among Phyllocarida orders highlight a progressive loss of diversity, with Hymenostraca vanishing by the end of the and Archaeostraca persisting until the Upper . In contrast, the order Leptostraca endured as relict "living s," maintaining low diversity through the and to the present. Overall, more than 200 have been documented, predominantly from strata, illustrating the group's historical prominence before its reduction to modern remnants.

Preservation and key discoveries

Phyllocarid fossils are typically preserved as compressed impressions in fine-grained shales and mudstones, where the bivalved is often retained as a carbonaceous film, sometimes with traces of appendages visible. This mode of preservation is common in deposits, reflecting rapid burial in low-oxygen environments that minimized decay and scavenging. Exceptional preservation occurs in Konservat-n, such as the Middle Cambrian in , , where Archaeostraca species like Canadaspis perfecta exhibit detailed soft-tissue features including biramous appendages and digestive structures. Similarly, the in the UK has yielded three-dimensionally preserved phyllocarids with intact appendages, revealing antennal structures and biramous limbs through serial sectioning techniques. Taphonomic biases favor the recovery of phyllocarid carapaces due to their bivalved, chitinous composition, which resists and provides a protective for internal during burial. However, soft parts such as limbs and gills are rarely preserved outside of exceptional sites, as they decay rapidly unless conditions inhibit microbial activity and bioturbation. This bias results in an overrepresentation of carapace-only specimens in the fossil record, potentially underestimating morphological diversity. Significant recent discoveries include the first caryocaridid phyllocarid, Soomicaris ordosensis sp. nov., reported from Upper black shales in western , , extending the group's known range in that region. In the same year, excavations in yielded four Silurian Archaeostraca species, including the new Cugocaris future gen. et sp. nov. and Cugocaris? latus sp. nov., from deposits in Province, highlighting a shift from caryocaridid to ceratiocaridid dominance. These finds, preserved in finely laminated shales, include ontogenetic series that inform growth patterns. More recent discoveries as of 2025 include a new hoplostracan species, Aridelocaris ohioensis n. gen., n. sp., from the Early Mississippian of , , representing one of the oldest members of Hoplostraca, new records of Pennsylvanian phyllocarids from , and a new occurrence in the (Mississippian) of the , . Advances in non-destructive imaging, such as scanning, have enabled visualization of internal in compressed phyllocarid fossils, including those of Hymenostraca, revealing hidden appendage details without physical preparation. For instance, analyses of phyllocarids have clarified antennal and thoracic structures previously obscured in two-dimensional views.

Evolutionary history

Origins and diversification

The origins of Phyllocarida trace back to the stem-group in the early , approximately 520 million years ago, with the earliest records appearing in early strata, such as the Chengjiang biota (around 520–518 Ma). These primitive forms, such as early archaeostracans, exhibit basal malacostracan traits including homonomous, foliaceous limbs that suggest ancestry from stem-eumalacostracans, positioning Phyllocarida as a foundational group in malacostracan evolution rather than an evolutionary dead end. Phylogenetic analyses based on morphology from to modern taxa support this stem-group status, highlighting shared features like a bivalved carapace and biramous appendages that bridge early crustacean diversification. Diversification accelerated during the , coinciding with the (GOBE) around 485–443 Ma, following the relatively low-diversity baseline. This "Ordovician explosion" involved niche partitioning, with benthic archaeostracans dominating infaunal and epifaunal habitats while nektonic hymenostracans, such as early caryocaridids emerging from late ancestors in the middle (~477 Ma), adapted to pelagic lifestyles. Diversity peaked in the to (443–359 Ma), with over 50 genera documented across suborders like Ceratiocaridina and Caryocaridina, reflecting adaptive radiations into shallow marine environments. Key drivers included the expansion of epicontinental seas and oxygenated shallow-water habitats during the , which facilitated ecological opportunities amid competition from trilobites and emerging eumalacostracans. The benthic-to-pelagic transition in groups like caryocaridids contributed to the Plankton Revolution, enhancing trophic complexity in marine ecosystems. However, post-Devonian decline ensued, with non-Leptostraca orders facing elevated rates that outpaced , leading to the of diverse archaeostracan lineages by the late . This pattern may relate to Late Devonian anoxic events and rising predation pressures, though only Leptostraca persisted into modern times.

Relation to other crustaceans

Phyllocarida occupies a basal position within the class , consistently resolved as the to in both morphological and molecular phylogenies. This relationship is supported by shared morphological traits, including the possession of seven pleonites and phyllopodous biramous limbs on the trunk, which represent plesiomorphic features of the malacostracan . Molecular from 18S rDNA sequences of extant Leptostraca further corroborates this placement, positioning Phyllocarida as the earliest-diverging malacostracan lineage. Several structural homologies underscore the close affinity between Phyllocarida and other malacostracans, reflecting an evolutionary continuum in modification for sensory and locomotor functions. The significance of Phyllocarida's position is highlighted by the extant Leptostraca, often regarded as "living s" due to their morphological stasis since the , providing a window into the ancestral malacostracan ground pattern. Features like the tripartite brain and protocerebral organization in Leptostraca inform reconstructions of early malacostracan and tagmosis. However, integrating phyllocarids into molecular phylogenies poses challenges, as long-branch attraction in datasets can distort basal relationships and complicate calibrations for divergence timing. Debates persist regarding the exact rooting of , with some cladistic analyses based on morphological characters placing Phyllocarida as an outgroup to the entire malacostracan clade, potentially due to autapomorphic specializations in taxa. This positioning has implications for understanding pancrustacean , as Phyllocarida's traits, such as undifferentiated trunk limbs, help delineate the from non-malacostracan crustaceans to the diverse eumalacostracan radiation.

References

  1. [1]
    Subclass PHYLLOCARIDA Packard, 1879
    Malacostraca with large carapace of two valves, with or without hinge line dorsally; valves connected by adductor muscle; produced anteriorly into movably ...
  2. [2]
    WoRMS - World Register of Marine Species - Phyllocarida
    ### Summary of Phyllocarida (WoRMS ID: 146995)
  3. [3]
    World Register of Marine Species - Leptostraca - WoRMS
    Leptostraca is an order of marine animals classified under Animalia, Arthropoda, Crustacea, Multicrustacea, Malacostraca, and Phyllocarida. It is an order ...
  4. [4]
    [PDF] A new genus and species of leptostracan (Crustacea: Malacostraca
    KEYWORDS: Phyllocarida, Leptostraca, Nebaliacea, systematics, Caribbean. Leptostracans are marine crustaceans defined by a hinged rostrum, a folded carapace ...<|control11|><|separator|>
  5. [5]
    A new crustacean from the Herefordshire (Silurian) Lagerstätte, UK ...
    Mar 22, 2017 · Leptostraca and the fossil archaeostracans constitute the Phyllocarida, which is normally considered sister to Eumalacostraca [4,8], and ...
  6. [6]
    Early Evolution of Phyllocarid Arthropods: Phylogeny and ...
    May 20, 2016 · A phylogenetic analysis and review of Paleozoic phyllocarid systematics is presented using morphology-based characters from Cambrian to ...
  7. [7]
    Phyllocarida and the origin of the Malacostraca - ScienceDirect.com
    ... Phyllocarida, are the most basal malacostracan crustaceans (e.g. Manton, 1934; Rolfe, 1981; Dahl, 1987; Spears and Abele, 1998; Giribet and Ribera, 2000 ...Missing: taxonomy | Show results with:taxonomy
  8. [8]
    Phyllocarida | Evolution and Phylogeny of Pancrustacea
    Phyllocarida, a distinct infraclass of the subclass Malacostraca within the class Multicrustacea, has a deep history extending into the Paleozoic; its ...
  9. [9]
    [PDF] MALACOSTRACAN PHYLOGENY AND EVOLUTION
    The higher classification of the Malacostraca with one single deviation from that of Cai- man (1909) appears as follows. All definitions are as formulated ...
  10. [10]
    Phyllocarida: Hoplostraca) from the Early Mississippian of Ohio, USA
    Jun 4, 2025 · Phyllocarid crustaceans are characterized by a bivalved carapace, a pleon composed of seven somites, and a spike-like telson with caudal rami ( ...Missing: taxonomy | Show results with:taxonomy
  11. [11]
    The Cambrian origin of the circulatory system of crustaceans | Lethaia
    Organs on the thoracopods of Cambrian supposed crustaceans, such as Canadaspis, resemble the foliaceous thoracic gills of Recent nebaliid phyllocarids and ...<|control11|><|separator|>
  12. [12]
    [PDF] A Phylogeny of the Leptostraca (Crustacea) with keys to families and ...
    Literature relating to six species and three subspecies of Nebaliidae was either not obtainable or provided insufficient diagnostic information; these taxa were ...Missing: Obebiidae | Show results with:Obebiidae
  13. [13]
    [PDF] British Carboniferous Malacostraca - ia801303
    Feb 23, 1979 · Phyllocarida is attempted with the exception of the Hoplostraca. ... Order: Hymenostraca Rolfe, 1969. Order: Archaeostraca Claus, 1888.
  14. [14]
    A new species of Nebalia (Crustacea, Leptostraca) from a ... - NIH
    Dec 9, 2019 · (1996) Description, external morphology, and natural history observations of Nebalia hessleri, new species (Phyllocarida: Leptostraca), from ...
  15. [15]
    (PDF) Early Evolution of Phyllocarid Arthropods: Phylogeny and ...
    Aug 6, 2025 · Phyllocarida Packard, 1879, which have long been considered a monophyletic group, may represent the most basal group of malacostracans ...
  16. [16]
    The morphology, mode of life, and affinities of Canadaspis perfecta ...
    A bivalved carapace covered the thorax; no rostral plate was present. The abdomen lacked appendages, apart from a pair of spinose ventral projections of the pre ...
  17. [17]
    A new species of Nebalia (Crustacea, Leptostraca) from a ... - ZooKeys
    Dec 9, 2019 · The genus Nebalia is a member of the Order Leptostraca, Suborder Nebaliacea, Family Nebaliidae. The family includes four other genera ...<|control11|><|separator|>
  18. [18]
    Nebalia bipes | INFORMATION - Animal Diversity Web
    Order, Leptostraca ; Family, Nebaliidae ; Genus, Nebalia ; Species, Nebalia bipes ; Development. It should be noted that the developmental processes of animals in ...
  19. [19]
    None
    Below is a merged summary of the internal anatomy of Phyllocarida/Leptostraca (Nebalia) based on the provided segments. To retain all information in a dense and organized manner, I will use a table in CSV format for each anatomical system (Respiratory, Digestive, Nervous, Reproductive, Sensory), followed by a consolidated text summary with direct quotes and useful URLs. This approach ensures all details are preserved while maintaining clarity and accessibility.
  20. [20]
    (PDF) Taxonomic Review of the Orders Mysida and Stygiomysida ...
    Aug 6, 2025 · ... pseudobranchiae at the base of each endo-. pod. These pseudobranchiae ... [Show full abstract] Leptostraca que posee siete en el pleon.
  21. [21]
    Eumalacostraca Leptostraca
    The original mode of feeding as filter feeders (Leptostraca) is given up. The leaf-shaped filter-legs on thoracic segments 1-8 are transformed into rod ...
  22. [22]
    The Project Gutenberg eBook of The Life Of Crustacea, by W. T. ...
    The Water-fleas (Cladocera), however, differ from most of the other Branchiopoda in having a direct development. The eggs are[81] carried in a brood-pouch under ...
  23. [23]
    https://www.researchgate.net/publication/277348301_Taxonomic_Review_of_the_Orders_Mysida_and_Stygiomysida_Crustacea_Peracarida
  24. [24]
    Phyllocarida (Leptostracans) - Encyclopedia.com
    Phyllocarida. (Leptostracans). Subphylum Arthropoda. Class Malacostraca. Subclass Phyllocarida. Number of families 3. Thumbnail description. Small crustaceans ...
  25. [25]
    [PDF] Leptostracans (Crustacea: Phyllocarida) from mud volcanoes at the ...
    Some leptostracans have been reported from bathyal depths down to 3000 m, such as. Dahlella caldariensis Hessler, 1984 (2490–2620 m depth), Nebaliella caboti ...
  26. [26]
    A NEW SPECIES OF LEPTOSTRACA, NEBALIA KOREANA ...
    Nebalia is found within all of the world's oceans including the Arctic and the Antarctic regions; its taxonomy is more or less well studied from the coasts ...<|control11|><|separator|>
  27. [27]
    A new species of Nebalia (Crustacea, Leptostraca) from coral reefs ...
    Jul 14, 2016 · Dahl (1985) revised the Leptostracans of the European Shelf and described a new genus with Sarsinebalia typhlops (G.O. Sars, 1870), formerly ...
  28. [28]
    Nebalia antarctica Dahl, 1990 - Register of Antarctic Species (RAS)
    World List of Phyllocarida. Nebalia antarctica ... Register of Antarctic Species. Nebalia ... Documented distribution (2); Attributes (6); Links ...
  29. [29]
    Phyllocarida) from mud volcanoes at the Gulf of Cadiz (NE Atlantic ...
    Mar 2, 2021 · Three leptostracan species (Crustacea: Phyllocarida) are reported from mud volcanoes at the Moroccan margin of the Gulf of Cadiz (NE ...
  30. [30]
    Nebaliella ochotica sp. nov.—new deep-sea species of ...
    Aug 9, 2025 · All these specimens relate to new species of genera Nebaliella Thiele, 1904 from family Nebaliidae: N. ochotica. Nebaliella ochotica sp. nov.
  31. [31]
    [PDF] LEPTOSTRACA - Marine Biodiversity Center
    —Holotype 9, l,ACM 92-169.1, carapace length (CL) 5.1 mm, total length (TL) 10.1 mm, collected 29 February 1992, Scripps Canyon, La. Jolla, California, 19 m ...
  32. [32]
    [PDF] Contributions to the Ecology of Paranebalia belizensis from the ...
    ABSTRACT. Characteristics that define the habitat of the leptostracan Paranebalia belizensis Modlin, inhabiting the waters of Twin Cays, a group of Belizian ...
  33. [33]
    Ecology and production of Nebalia sp. (Crustacea : Leptostraca) in a ...
    Nebalia sp. is an abundant epifaunal crustacean in seagrass meadows at Seven Mile Beach, Western Australia, in water temperatures of 16-27ºC.
  34. [34]
    V. On the embryology of the crustacean Nebalia Bipes - Journals
    ... Leptostraca and the Eumalacostraca have recently been shown to be ... Lovett D and Felder D (2005) Ontogeny of gut morphology in the white shrimp ...
  35. [35]
    Leptostraca): the failure of form to predict function | Marine Biology
    This species occurred at very high densities in the field, and ate essentially everything offered in the laboratory, with a diet in the field consisting largely ...
  36. [36]
    The First Lower Cambrian Phyllocarids from Yakutia - ResearchGate
    These animals are found very soon after the first appearance of trilobites in their respective sequences (early Ovetian Stage and Profallotaspis jakutensis ...Missing: Cambro earliest
  37. [37]
    [PDF] The Crustacea of China - UvA-DARE (Digital Academic Repository)
    cosmopolitan distributions. The fossil Phyllocarida thus appeared to reach a peak in biodiver- sity during the Upper Ordovician/Devonian. Recent ...
  38. [38]
    First occurrence of caryocaridids (Crustacea, Phyllocarida) in the ...
    Aug 1, 2023 · Systematic paleontology. Subclass Phyllocarida Packard, 1879. Order Archaeostraca Claus, 1888. Suborder Caryocaridina Collette and Hagadorn, ...
  39. [39]
    Leptostraca as Living Fossils - SpringerLink
    Some aspects of leptostracan morphology bridge the gap between the vast class Malacostraca and other crustaceans, particularly primitive ones (see below). They ...
  40. [40]
    Soft-part preservation in a bivalved arthropod from the Late ...
    Nov 3, 2009 · Its non-biomineralized carapace is preserved as a carbonaceous residue, as is more labile anatomy (soft-parts) including the inner lamella and ...
  41. [41]
    The Morphology, Mode of Life, and Affinities of Canadaspis Perfecta ...
    The Morphology, Mode of Life, and Affinities of Canadaspis Perfecta (Crustacea: Phyllocarida), Middle Cambrian, Burgess Shale, British Columbia.
  42. [42]
    [PDF] A new phyllocarid (Crustacea: Malacostraca) from the Silurian Fossil ...
    Dec 5, 2003 · Cinerocaris magnifica displayed the tagmosis characteristic of phyllocarids, with eight thoracic and seven abdominal somites, terminating in a ...Missing: traits | Show results with:traits
  43. [43]
    Soft-part preservation in a bivalved arthropod from the Late ...
    Nov 3, 2009 · Its non-biomineralized carapace is preserved as a carbonaceous residue, as is more labile anatomy (soft-parts) including the inner lamella and ...
  44. [44]
    Silurian phyllocarid crustaceans (Phyllocarida, Archaeostraca) from ...
    Abstract. In the Silurian, the suborder Caryocaridina of the phyllocarids was replaced by the suborder Ceratiocaridina as the dominant group.Missing: Hoplostraca Hymenostraca<|control11|><|separator|>
  45. [45]
    Silurian phyllocarid crustaceans (Phyllocarida, Archaeostraca) from ...
    Apr 4, 2023 · In the Silurian, the suborder Caryocaridina of the phyllocarids was replaced by the suborder Ceratiocaridina as the dominant group.
  46. [46]
    A new phyllocarid (Crustacea: Malacostraca) from the Silurian Fossil ...
    Oct 9, 2025 · The remarkable preservation of the appendages makes this the earliest completely known malacostracan crustacean. Two pairs of antennae (the ...<|control11|><|separator|>
  47. [47]
    The evolution and initial rise of pelagic caryocaridids in the Ordovician
    As a representative of Malacostraca (Arthropoda), the Phyllocarida has significance in the early evolution of crustaceans due to their morphological diversity ...
  48. [48]
    Integrating evolution and biogeography: A case study involving ...
    May 20, 2016 · A case study based on patterns in Middle and Late Devonian phyllocarids (Crustacea) illustrates the usefulness of this integrated approach.
  49. [49]
    The Malacostraca (Crustacea) from a neurophylogenetic perspective: New insights from brain architecture in Nebalia herbstii Leach, 1814 (Leptostraca, Phyllocarida)
    ### Summary of Phylogenetic Position of Phyllocarida within Malacostraca
  50. [50]
    A new crustacean from the Herefordshire (Silurian) Lagerstätte, UK ...
    Mar 22, 2017 · Leptostraca and the fossil archaeostracans constitute the Phyllocarida, which is normally considered sister to Eumalacostraca [4,8], and ...
  51. [51]
    Major Revisions in Pancrustacean Phylogeny and Evidence of ...
    Aug 8, 2023 · The phylogeny is estimated with expanded taxon sampling, particularly of malacostracans. We show small changes in taxon sampling have large impacts on ...
  52. [52]
    Phylogenetic Analyses of the Malacostraca (Crustacea)
    Aug 10, 2025 · The Malacostraca comprises about 28 000 species with a broad disparity in morphology, anatomy, embryology, behaviour and ecology.