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Pachydermata

Pachydermata is an obsolete taxonomic order within the class Mammalia, first proposed by Gottlieb Storr in 1780 and formalized in 1796 by Georges Cuvier to group large, thick-skinned mammals characterized by hoofed feet and non-ruminant digestion, including elephants, rhinoceroses, hippopotamuses, tapirs, pigs, peccaries, and hyraxes.^[1] The term derives from the Greek words pachys (thick) and derma (skin), reflecting the superficial morphological trait of thickened hide that unified these animals in early classifications.^[2] Historically, the concept traces back to Carl Linnaeus's Systema Naturae (1758), where similar ungulates were loosely categorized, but Cuvier formalized Pachydermata in a series of 1796 papers as "hoofed, non-ruminant" mammals, later expanding it to encompass horses and even marine forms like walruses and dugongs.^[1] This grouping persisted into the 19th century, with naturalists like Richard Owen refining ungulate taxonomy by establishing orders such as Perissodactyla (odd-toed ungulates) in 1848, which separated rhinos, tapirs, and horses from even-toed artiodactyls like hippos and pigs.^[1] By the early 20th century, works like Richard Lydekker's surveys (1913–1915) still referenced Pachydermata as a broad category based on traits like enlarged toenails, but its artificial nature became evident.^[3] Pachydermata fell out of use due to its polyphyletic composition, meaning the included taxa do not share a common ancestor exclusive to the group, as revealed by advances in comparative anatomy, paleontology, and molecular phylogenetics.^[2] Modern classifications reassign its members: elephants and hyraxes to the clade Afrotheria (Proboscidea and Hyracoidea, respectively), rhinos, tapirs, and horses to Perissodactyla, and hippos, pigs, and peccaries to Artiodactyla (now Cetartiodactyla, incorporating whales).^[1] This shift, detailed in comprehensive reviews like Groves and Grubb's Ungulate Taxonomy (2011), emphasizes monophyletic groups based on evolutionary relationships rather than convergent traits like skin thickness.^[3] Today, "pachyderm" persists colloquially for elephants and rhinos but holds no systematic validity in zoology.^[2]

Etymology and Definition

Origin of the Term

The term "Pachydermata" originates from the Greek roots pachys (παχύς), meaning "thick," and derma (δέρμα), meaning "skin," literally translating to "thick-skinned."^[4]^[5] French naturalist Georges Cuvier introduced the singular form "pachyderme" in 1797 as a biological descriptor for certain non-ruminant hoofed mammals, emphasizing their shared anatomical trait of dense, often hairless skin.^[4]^[5] This initial usage appeared in Cuvier's Tableau élémentaire de l'histoire naturelle des animaux (1797–1798), where the term served to categorize animals based on this prominent physical characteristic in comparative anatomy.^[5] Subsequently, "pachyderme" transitioned into the plural Latinized form "Pachydermata" as a formal taxonomic order within the developing framework of zoological classification in the early 19th century.^[6]

Original Characteristics

The order Pachydermata, as originally conceived by Georges Cuvier, grouped non-ruminant ungulates—hoofed mammals with simple digestive systems lacking the multi-chambered stomachs of ruminants—based on shared traits including thick, leathery skin as a protective adaptation, quadrupedal locomotion with pillar-like limbs and hoofed feet for weight support, and herbivorous diets processed via hindgut fermentation or similar mechanisms.^[2] Body sizes varied widely across members, from small forms like hyraxes to massive species such as elephants and rhinoceroses. Dentition was generally adapted for grinding fibrous vegetation, with large molars, though specifics differed (e.g., prominent tusks in elephants). Some exhibited semi-aquatic adaptations, like webbed toes in hippopotamuses.

Historical Classification

Cuvier's Proposal

Étienne Geoffroy Saint-Hilaire and Georges Cuvier introduced the term Pachydermata in 1795, which Cuvier formalized in a series of 1796 papers and detailed as a taxonomic order in 1798 as part of his foundational classification system for mammals, in Tableau élémentaire de l'histoire naturelle des animaux. This publication served as preparatory groundwork for his later comprehensive work, Le Règne Animal (1817), and proposed a quadripartite division of mammals into four orders: Ferae (encompassing carnivorous forms), Glires (including rodents and related gnawing animals), Cete (cetaceans), and Pachydermata. Cuvier's system marked a shift toward a more anatomically grounded taxonomy, integrating fossil evidence with living species to establish natural groupings based on organizational principles rather than arbitrary divisions.^[7] At the core of Cuvier's proposal, Pachydermata was defined as a cohesive order of thick-skinned, hoofed mammals characterized by robust skeletal structures and non-ruminant digestive systems, distinguishing them from other ungulates. He initially highlighted elephants (Elephas), rhinoceroses (Rhinoceros), and hippopotamuses (Hippopotamus) as archetypal members, emphasizing their shared integumentary features—such as tough, nearly hairless skin—and skeletal adaptations for weight-bearing and terrestrial locomotion. These animals were grouped together due to their uniform possession of thick cuticles and heavy, columnar limb bones, which Cuvier viewed as correlated traits supporting a semi-aquatic or heavily armored lifestyle in elephants and rhinoceroses, and amphibious habits in hippopotamuses. By excluding ruminants, despite superficial similarities in ungulate foot structure, Cuvier underscored that Pachydermata lacked the multi-chambered stomachs and cud-chewing behavior typical of ruminants, thereby rejecting any close affinity based on those traits.^[7] Cuvier's formulation of Pachydermata drew heavily from his pioneering work in comparative anatomy, prioritizing functional correlations among organ systems—such as the integration of skin, skeleton, and dentition for survival—over the external morphological criteria emphasized in Linnaean taxonomy. This approach allowed him to infer whole-animal adaptations from partial remains, including fossils, and positioned Pachydermata as a functionally coherent assemblage adapted to environments demanding physical durability over agility or predation. His emphasis on these adaptive interdependencies influenced subsequent naturalists, establishing comparative anatomy as a cornerstone of vertebrate classification.^[8]

19th-Century Revisions

In the early decades of the 19th century, naturalists revised Georges Cuvier's original Pachydermata order to accommodate new anatomical insights and fossil discoveries, shifting emphasis from skin thickness to skeletal and dental features. John Edward Gray, in his 1821 classification of vertebrose animals, subdivided Pachydermata into two primary groups: Bruta, which included elephants and their allies characterized by trunk-like appendages and reduced dentition, and Pachydermes proper, encompassing rhinoceroses, hippopotamuses, and swine-like forms with more robust, hoofed limbs.^[9] This subdivision aimed to highlight distinctions in locomotion and feeding adaptations within the thick-skinned mammals. By the mid-19th century, Richard Owen refined the classification in his 1848 work on mammalian classification by establishing the order Perissodactyla for odd-toed ungulates, including horses (Equidae), tapirs (Tapiridae), and rhinoceroses based on their shared odd-toed (perissodactylous) foot structure and grinding dentition, thus separating them from even-toed artiodactyls like hippos and pigs. These changes sparked debates among systematists over boundary definitions, with some proposals including armadillos (Dasypodidae) due to armored skin or hyraxes (Hyracoidea) for superficial resemblances to small pachyderms, though such inclusions were contested for lacking consistent anatomical ties. The evolving focus on hoof morphology over cutaneous traits marked a conceptual shift toward functional adaptations for terrestrial locomotion, influencing subsequent classifications. The influence of Charles Darwin's evolutionary theory, published in 1859, intensified scrutiny of Pachydermata's coherence, as naturalists questioned whether the order represented true phylogenetic relationships or merely convergent forms adapted to similar environments. Expansions occurred primarily between the 1820s and 1850s, but by the 1860s, the group fragmented into specialized suborders, such as Proboscidea for proboscideans and Solidungula for solid-hoofed forms, reflecting growing specialization in taxonomy.

Taxonomic Composition

Included Orders and Families

The primary groups included within Pachydermata across historical classifications encompassed the order Proboscidea, the family Rhinocerotidae, the family Hippopotamidae, the family Tapiridae, the families Suidae and Tayassuidae, and the family Procaviidae (hyraxes), unified by their thick skins, hoofed feet, and non-ruminant digestion. Proboscidea encompassed modern elephants (family Elephantidae) along with numerous extinct relatives, such as mammoths (Mammuthus), mastodons (family Mammutidae), and deinotheres (family Deinotheriidae), characterized by elongated trunks for manipulation and ivory tusks for foraging and combat. These forms ranged from the Miocene to the Pleistocene, with mastodons featuring low-crowned molars suited to browsing in forested environments, while deinotheres possessed downward-curving lower tusks adapted for stripping bark.^[10] Rhinocerotidae included the various species of rhinoceroses, distinguished by one or two prominent nasal horns formed from compacted keratin and odd-toed (perissodactyl) hooves that supported their massive, tank-like bodies weighing up to 2,300 kg in some species. Historical taxonomies placed both extant African and Asian rhinoceroses within this family as quintessential pachyderms due to their armored skin and solitary habits. Hippopotamidae comprised the hippopotamuses, semi-aquatic mammals with barrel-shaped torsos, wide mouths featuring large canines, and skin up to 5 cm thick that secretes a reddish oil for protection in aquatic habitats; the common hippopotamus (Hippopotamus amphibius) and pygmy hippopotamus (Choeropsis liberiensis) were the principal members. Tapiridae included tapirs, odd-toed ungulates with elongated, flexible snouts for foraging in dense forests and wetlands, featuring short, thick legs and skin folds that provided some protection; species like the Malayan tapir (Tapirus indicus) were viewed as linking rhinos and more primitive forms. Suidae and Tayassuidae encompassed pigs and peccaries, even-toed ungulates with bristly coats, mobile snouts, and omnivorous to herbivorous diets; pigs (e.g., Sus scrofa) and peccaries (e.g., Pecari tajacu) were included for their robust builds and non-ruminant digestion, though later separated due to foot structure differences. Procaviidae included hyraxes, small, rodent-like mammals with rubbery feet, short tails, and leathery skin resembling that of elephants, leading to their early placement as primitive pachyderms despite closer relations to elephants in modern phylogeny. Extinct inclusions extended to palaeotheres (family Palaeotheriidae), primitive tapir-like perissodactyls from the Eocene epoch, which were grouped under the Solipedes division of Pachydermata for their single-toed feet and inferred thick-skinned anatomy, bridging early horse and rhino lineages.

Variations Across Classifications

Throughout the 19th century, the taxonomic group Pachydermata exhibited significant variations in composition as naturalists refined classifications based on anatomical, ecological, and fossil evidence. Originally proposed by Georges Cuvier in the late 18th century as a broad category for non-ruminant ungulates with thick skin, Pachydermata encompassed elephants (Proboscidea), rhinoceroses (Rhinocerotidae), hippopotamuses (Hippopotamidae), tapirs (Tapiridae), pigs and peccaries (Suidae and Tayassuidae), and hyraxes (Procaviidae). Subsequent systems built on this foundation, with some classifications emphasizing dental and skeletal similarities.^[11] Further variations arose with the occasional addition of Equidae (horses) by figures like Richard Owen, who briefly aligned them with Pachydermata based on ungulate foot structure and fossil resemblances to early perissodactyls, despite their cursorial adaptations.^[12] Hyraxes (Procaviidae) were included in core and peripheral classifications owing to their tough, leathery hides akin to elephants, though these placements were debated and not always central.^[13] Meanwhile, exclusions intensified for Suidae (pigs), which were progressively removed from core Pachydermata in mid-century revisions due to their even-toed feet and omnivorous digestion contrasting with the odd-toed, herbivorous traits of rhinos and tapirs; this shift reflected emerging distinctions between perissodactyls and artiodactyls.^[14] Debates also surrounded sirenians (manatees and dugongs, order Sirenia), with some 19th-century naturalists proposing affinities to Pachydermata based on aquatic lifestyles and blunt, herbivorous forms, interpreting them as "pachydermous" sea mammals derived from terrestrial ungulates. Specific schemes underscored these inconsistencies: Henri-Marie Ducrotay de Blainville's 1839 classification expanded Pachydermata to include hippopotamuses, pigs, tapirs, hyraxes, rhinoceroses, and elephants, emphasizing integumentary and locomotor traits over digestive uniformity.^[14] In contrast, some 1850s works broadened it further to encompass all non-ruminant ungulates, incorporating equids and sirenians while questioning ruminant exclusions, reflecting a trend toward inclusive, phenotype-driven taxonomy amid fossil discoveries.^[15] These fluctuations illustrate how Pachydermata served as a flexible construct in early mammalian systematics, prone to revision as comparative anatomy evolved.

Modern Perspectives

Reasons for Obsolescence

The obsolescence of Pachydermata as a taxonomic order stemmed primarily from its polyphyletic nature, wherein the included groups—such as elephants, rhinoceroses, and hippopotamuses—did not share a recent common ancestor exclusive to them, rendering the grouping artificial and non-reflective of evolutionary history.^[16] This polyphyly arose because the classification relied on superficial morphological traits, notably the thickness and wrinkling of the skin, which represented convergent adaptations to similar ecological niches rather than shared phylogenetic origins. The rise of cladistics in the mid-20th century further underscored this flaw, as it prioritized monophyletic clades defined by shared derived characteristics and evolutionary branching patterns over Linnaean hierarchies based on overall similarity. A pivotal development in abandoning Pachydermata was George Gaylord Simpson's 1945 reclassification of mammals, which fragmented ungulates into distinct orders like Proboscidea (elephants), Perissodactyla (odd-toed ungulates including rhinoceroses), and Artiodactyla (even-toed ungulates including hippopotamuses), emphasizing phylogenetic relationships derived from fossil evidence over Cuvierian morphology. Simpson explicitly critiqued artificial groupings like Pachydermata for failing to align with evolutionary principles, advocating instead for a system grounded in the modern synthesis of Darwinian evolution and genetics. The shift from descriptive morphology to evolutionary and phylogenetic systematics, beginning in the 19th century and accelerating with the modern synthesis in the 1930s–1940s, ultimately rendered Pachydermata untenable, with molecular evidence in the late 20th century providing further confirmation. Molecular evidence from the 1990s and 2000s provided definitive confirmation of Pachydermata's polyphyly, revealing distant relationships among its former members; for instance, hippopotamuses were shown to be more closely related to cetaceans (whales and dolphins) than to elephants or rhinoceroses, forming the monophyletic clade Whippomorpha within Artiodactyla.^[17] Concurrently, genomic analyses established elephants and hyraxes within the superordinal clade Afrotheria, a grouping evolutionarily remote from artiodactyls like hippopotamuses, thus highlighting the convergent evolution of thick skin as a misleading classificatory trait.^[18] These findings, building on cladistic principles, solidified the rejection of Pachydermata by demonstrating that its constituents diverged phylogenetically over 60 million years ago.^[19]

Current Taxonomic Placement

In contemporary mammalian taxonomy, the taxa historically united under Pachydermata are dispersed across distinct phylogenetic lineages within the subclass Eutheria of the class Mammalia. The order Proboscidea, encompassing elephants, stands as an independent order within the superorder Afrotheria, a clade primarily originating from African lineages and supported by molecular evidence.^[20]^[21] The sole extant family, Elephantidae, includes two genera: Loxodonta (African elephants, with savanna and forest species) and Elephas (Asian elephant).^[20] Also within Afrotheria, the order Hyracoidea includes hyraxes in the family Procaviidae, comprising three genera (Procavia, Heterohyrax, Dendrohyrax) and 11 species distributed in Africa and the Middle East.^[22] The odd-toed ungulates formerly included in Pachydermata are classified in the order Perissodactyla, which falls under the superorder Laurasiatheria—a diverse group encompassing many Eurasian-derived mammals.^[23] This order features the family Rhinocerotidae, comprising five extant species in four genera (two African and three Asian), all characterized by their single or double nasal horns and critically endangered status due to poaching and habitat loss.^[24] The family Tapiridae includes four species of the genus Tapirus, distributed across Central and South America as well as Southeast Asia, noted for their prehensile snouts and semi-aquatic habits.^[25] The family Equidae includes horses and relatives, with seven extant species in the single genus Equus.^[26] Even-toed ungulates from the historical Pachydermata, such as hippopotamuses, are placed in the order Artiodactyla, also within Laurasiatheria.^[23] The family Hippopotamidae contains two extant species: the common hippopotamus (Hippopotamus amphibius), widespread in sub-Saharan African rivers, and the pygmy hippopotamus (Choeropsis liberiensis), restricted to West African forests.^[27] These hippopotamids form a close sister group to cetaceans (whales and dolphins), together comprising the Whippomorpha clade, a relationship established through molecular and morphological analyses.^[28] Other even-toed ungulates formerly included, such as pigs and peccaries, are classified in the infraorder Suina within Artiodactyla. The family Suidae (pigs) includes about 18 species across six genera, primarily in Eurasia and Africa, while the family Tayassuidae (peccaries) includes three species in three genera, native to the Americas.^[23] Later expansions of Pachydermata included marine forms like walruses (family Odobenidae, order Carnivora, superorder Laurasiatheria) and dugongs (family Dugongidae, order Sirenia, superorder Afrotheria).^[23]^[20] Collectively, these lineages—spanning Afrotheria and Laurasiatheria—lack a shared monophyletic clade beyond Eutheria, underscoring the polyphyletic composition of the obsolete Pachydermata grouping in modern phylogenetics.^[29]

References

[1]
Perissodactyla Owen, 1848 - GBIF
In 1795, Étienne Geoffroy Saint-Hilaire (1772–1844) and Georges Cuvier (1769–1832) introduced the term "pachyderm" (Pachydermata), including in it not only the ...
[2]
Pachyderms Revealed | San Diego Zoo Wildlife Alliance
It was in the late 1700s when naturalist Georges Cuvier used the term in a taxonomic way, to describe what he considered to be a group of related animals: they ...Missing: sources | Show results with:sources
[3]
None
Below is a merged summary of Pachydermata based on all provided segments from "Ungulate Taxonomy" by Groves and Grubb (2011). To retain all information in a dense and comprehensive format, I will use a combination of narrative text for overarching themes and a table in CSV format to capture detailed specifics across definitions, history, included groups, obsolescence, key facts, and useful URLs. This approach ensures no information is lost while maintaining clarity and structure.
[4]
Pachyderm - Etymology, Origin & Meaning
Originating from Greek pakhydermos meaning "thick-skinned," pachyderm was adopted in 1838 from French to describe thick-skinned, non-ruminant hoofed ...
[5]
Etymologie de PACHYDERME
PACHYDERME, adj. et subst. masc. PACHYDERME, adj. et subst. masc. Étymol. et ... a) 1797-98 subst. masc. plur. «ordre de mammifères à peau épaisse ...<|control11|><|separator|>
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PACHYDERMATOUS Definition & Meaning - Merriam-Webster
The word, from Greek roots, means "thick-skinned" in New Latin (the Latin used in scientific description and classification). In the 19th century, we began ...Missing: original taxonomy
[7]
Natural History: Mammalia/Pachydermata - Wikisource
Jul 20, 2024 · They are generally also uncouth and clumsy in form, and heavy in their motions. The name, which Cuvier selected to distinguish the Order, ...
[8]
Description of Teeth and portions of Jaws of two extinct ...
by which Cuvier illustrated the affinities linking together the Perisso- dactyle pachyderms, he first pointed out a common character in their femur, the ...
[9]
On Prof. Huxley's attempted refutation of Cuvier (1856)
Cuvier specifies the Ungulata (including the Pachydermata, Solidungula, and Ruminantia): Mr. Huxley meets him with the Sloth, which, although herbivorous, does ...<|control11|><|separator|>
[10]
Tableau élémentaire de l'histoire naturelle des animaux
Nov 26, 2009 · Tableau élémentaire de l'histoire naturelle des animaux. by: Cuvier, Georges, baron, 1769-1832; Oliveira, A. ... DOWNLOAD OPTIONS. download 1 file.
[11]
Essay: The Cuvier-Geoffroy Debate | Embryo Project Encyclopedia
Oct 7, 2013 · Cuvier's functional anatomy and Geoffroy's philosophical anatomy represented divergent research programs in comparative anatomy and natural ...
[12]
A new method of combating fungus on fishes in captivity - Biodiversity Heritage Library
**Summary of Content Issue:**
[13]
Introduction to the Proboscidea
Elephants are sometimes called pachyderms, a term that also applies to rhinos and hippos, and refers to their thick skin. These other pachyderms are not ...
[14]
Cuvier, Georges. 1830. The animal kingdom arranged in conformity ...
Dec 10, 2024 · The characteristics of the bird are all perfect in it. From the discovery of some other feet, into a detailed description of which it is ...
[15]
Pachydermata Facts for Kids
Oct 17, 2025 · Pachydermata (say "pak-ee-DER-mah-tuh") is an old way of grouping certain mammals. The word comes from ancient Greek and means "thick skin."Missing: sources | Show results with:sources
[16]
[PDF] MB-84.3 - Rhino Resource Center
or two species constitute the genus HYRAX in their anato- mical characters ... more or less, of the order Pachydermata. It is beside our purpose here ...
[17]
https://digitallibrary.amnh.org/server/api/core/bi...
... Cuvier and Geoffroy were familiar with the works of Blumenbach and Storr; and indeed in the 'Tableau Elementaire,' Cuvier refers to Blumenbach's system as ...
[18]
[PDF] Two New Oligocene Desmostylians anci a Discussion
Blainville. Although some workers in the late nineteenth century championed sirenian-probos- cidean affinity (e.g., Kneeland, 1850; Kaup,. 1855), most ...
[19]
https://www.biodiversitylibrary.org/itemtext/217608
No information is available for this page. · Learn why
[20]
Classification of mammals : Simpson, George Gaylord
May 9, 2020 · Classification of mammals. by: Simpson, George Gaylord. Publication date: 1945. Collection: taxonomyarchive; additional_collections. Language ...Missing: Pachydermata | Show results with:Pachydermata
[21]
Hippopotamuses are the closest extant relatives of whales - NIH
In this study, we provide strong evidence that hippopotamuses and cetaceans form a monophyletic clade. With respect to the relationships among the other ...
[22]
Protein sequence signatures support the African clade of mammals
DNA sequence evidence supports a superordinal clade of mammals that comprises elephants, sea cows, hyraxes, aardvarks, elephant shrews, golden moles, and ...
[23]
Afrotheria: Plate tectonics meets genomics - PMC - NIH
Afrotheria is a superorder (4) that contains six orders: the elephants (Order Proboscidea), sea cows (Sirenia), hyraxes (Hyracoidea), aardvark (Tubulidentata), ...Afrotheria: Plate Tectonics... · Figure 1 · Figure 2Missing: hippos | Show results with:hippos
[24]
https://animaldiversity.org/accounts/Rhinocerotidae/
[25]
New Middle Eocene proboscidean from Togo illuminates the early ...
Oct 13, 2021 · Proboscideans are part of the Afrotheria, a supercohort of mammals originating in Africa, which was recognized based on molecular data (see ...
[26]
Laurasiatheria - NCBI - NIH
Artiodactyla (even-toed ungulates & whales) ; Carnivora (carnivores) ; Chiroptera (bats) ; Eulipotyphla (insectivores) ; Perissodactyla (odd-toed ungulates).
[27]
Rhinocerotidae (rhinoceroses) | INFORMATION | Animal Diversity Web
They are represented by 5 species placed in 4 genera. Three of these species are found in south-central Asia and the other two live in Africa south of the ...
[28]
Tapiridae (tapirs) | INFORMATION - Animal Diversity Web
Tapirs are shy, reclusive rainforest animals that live in nearly any wooded or grassy habitat with a permanent supply of water.
[29]
Hippopotamidae (hippopotamuses) | INFORMATION
The modern hippos are divided into two genera and two species. The genera are very different in size, so much so that the common name of one, ...
[30]
Relationships of Cetacea (Artiodactyla) Among Mammals
Sep 23, 2009 · 'Whippomorpha' was proposed as the name ... clade, Cetacea, evolved within a predominantly terrestrial, herbivorous clade, Artiodactyla.
[31]
[PDF] Toxodontia of Salla, Bolivia (late Oligocene) - UFDC Image Array 2
"Pachydermata" (now regarded as a polyphyletic group which included ... (Simpson, 1945:p. 13) and though the results of the following and recent.