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Superregnum: Eukaryota
Regnum: Animalia
Subregnum: Eumetazoa
Cladus: Bilateria
Cladus: Nephrozoa
Superphylum: Deuterostomia
Phylum: Chordata
Cladus: Craniata
Subphylum: Vertebrata
Infraphylum: Gnathostomata
Superclassis: Tetrapoda
Cladus: Reptiliomorpha
Cladus: Amniota
Classis: Reptilia
Cladus: Eureptilia
Cladus: Romeriida
Subclassis: Diapsida
Cladus: Sauria
Infraclassis: Archosauromorpha
Cladus: Crurotarsi
Divisio: Archosauria
Subsectio: Ornithodira
Subtaxon: Dinosauromorpha
Cladus: Dinosauria
Ordo: †Ornithischia
Cladus: †Genasauria
Cladus: †Neornithischia
Cladus: †Cerapoda
Cladus: †Euornithopoda
Taxon: †Hypsilophodontia

Familia: †Hypsilophodontidae
Genus: †Thescelosaurus
Species (3): T. assiniboiensis – T. garbanii – T. neglectus

Thescelosaurus Gilmore, 1913
Holotype: Thescelosaurus neglectus


Nomenclator Zoologicus

Vernacular names
한국어: 테스켈로사우루스
中文: 奇異龍

Thescelosaurus (/ˌθɛsɪləˈsɔːrəs/ THESS-il-ə-SOR-əs; ancient Greek θέσκελος- (theskelos-) meaning "godlike", "marvellous", or "wondrous" and σαυρος (sauros) "lizard")[2] was a genus of small neornithischian dinosaur that appeared at the very end of the Late Cretaceous period in North America. It was a member of the last dinosaurian fauna before the Cretaceous–Paleogene extinction event around 66 million years ago. The preservation and completeness of many of its specimens indicate that it may have preferred to live near streams.

This bipedal neornithischian is known from several partial skeletons and skulls that indicate it grew to between 2.5 and 4.0 meters (8.2 to 13.1 ft) in length on average. It had sturdy hind limbs, small wide hands, and a head with an elongate pointed snout. The form of the teeth and jaws suggest a primarily herbivorous animal. This genus of dinosaur is regarded as a specialized neornithischian, traditionally described as a hypsilophodont, but more recently recognized as distinct from Hypsilophodon. Several species have been suggested for this genus. Three currently are recognized as valid: the type species T. neglectus, T. garbanii and T. assiniboiensis.

The genus attracted media attention in 2000, when a specimen unearthed in 1993 in South Dakota, United States, was interpreted as including a fossilized heart. There was much discussion over whether the remains were of a heart. Many scientists now doubt the identification of the object and the implications of such an identification.

Discovery, history, and species
T. neglectus holotype at the Smithsonian Museum, with skull and neck restored after Camptosaurus

The type specimen of Thescelosaurus (USNM 7757) was discovered in 1891 by paleontologists John Bell Hatcher and William H. Utterback, from beds of the late Maastrichtian-age Upper Cretaceous Lance Formation of Niobrara County (at the time part of Converse County), Wyoming, USA. The skeleton, however, remained in its shipping crates for years until Charles W. Gilmore of the Smithsonian Institution's National Museum of Natural History had it prepared and described it in a short paper in 1913, naming it T. neglectus (neglectus: "neglected"). At the time, he thought it was related to Camptosaurus.[3] He provided a detailed monograph in 1915, describing the well-preserved skeleton.[4] The type specimen was found largely in natural articulation and was missing only the head and neck, which were lost due to erosion.[4] The name comes from the surprise Gilmore felt at finding such a good specimen that had been unattended to for so long. He considered it to be a light, agile creature, and assigned it to the Hypsilophodontidae, a family of small bipedal dinosaurs.[4]
Charles Gilmore's 1915 reconstruction of the T. neglectus type specimen

Other remains of similar animals were found throughout the late 19th century and 20th century. Another well-preserved skeleton from the slightly older Horseshoe Canyon Formation, in Alberta, Canada, was named T. warreni by William Parks in 1926.[5] This skeleton had notable differences from T. neglectus, and so Charles M. Sternberg placed it in a new genus, Parksosaurus, in 1937.[6] Sternberg also named an additional species, T. edmontonensis, based on another articulated skeleton, this time including a partial skull (NMC 8537), and drew attention to the genus' heavy build and thick bones. Due to these differences from the regular light hypsilophodont build, he suggested that the genus warranted its own subfamily, Thescelosaurinae.[7] T. edmontonensis has, since Peter Galton's 1974 review, generally been considered a more robust individual (possibly the opposite sex of the type individual)[8] of T. neglectus.[9][10] However, Boyd and colleagues found that they could not assign it to either of their valid species of Thescelosaurus and regarded the specimen as of uncertain placement within the genus.[1] The other point of contention regarding T. edmontonensis is its ankle, which Galton claimed was damaged and misinterpreted, but which was regarded by William J. Morris (1976) as truly different from T. neglectus.[11]
Cast of CMN 8537, described as the type specimen for T. edmontonensis (T. sp. per Boyd et al., [2009])

In his paper, Morris described a specimen (SDSM 7210) consisting of a partial skull with heavy ridges on the lower jaw and cheek, four partial vertebrae, and two finger bones as an unidentified species of Thescelosaurus, from the late Maastrichtian-age Hell Creek Formation of Harding County, South Dakota, USA. He drew attention to its premaxillary teeth and deeply inset toothline which he interpreted as supporting the presence of muscular cheeks. Morris also pointed out the outwardly flaring premaxilla (which would have given it a wide beak) and large palpebrals.[11] This skull was recognized as an unnamed hypsilophodont for many years,[10] until Galton made it the type specimen of new genus and species Bugenasaura infernalis ("large-cheeked lizard belonging to the lower regions", infernalis being a reference to the Hell Creek Formation).[12] Morris also named a new possible species of Thescelosaurus for specimen LACM 33542: ?T. garbanii (with a question mark because he was uncertain that it belonged to the genus). LACM 33542 comprised a large partial hindlimb ("a third larger than described specimens of T. neglectus and Parksosaurus or nearly twice as large as Hypsilophodon") including a foot, tarsus, shin bones, and partial thigh bone, along with five cervical (neck) and eleven dorsal (back) vertebrae, from the Hell Creek Formation of Garfield County, Montana, USA. The specimen was discovered by amateur paleontologist Harley Garbani, hence the name. T. garbanii would have been about 4.5 meters (15 feet) long, greater than average specimens of T. neglectus. Aside from the size, Morris drew attention to the way the ankle was constructed, which he considered to be unique except in comparison with Thescelosaurus edmontonensis, which he regarded as a separate species. Because Morris believed that the ankles of T. garbanii compared favorably to those of T. edmontonensis, he tentatively assigned it to Thescelosaurus.[11] However, the scientific literature has favored Galton's view that T. edmontonensis was not different from T. neglectus (see above). In the same paper that he described Bugenasaura, Galton demonstrated that the features Morris had thought connected T. garbanii and T. edmontonensis were the result of damage to the latter's ankle, so T. garbanii could also be considered distinct from Thescelosaurus. To better accommodate this species, Galton suggested that it belonged to his new genus Bugenasaura as B. garbanii, although he also noted that it could be belong to the similarly sized pachycephalosaurid Stygimoloch, or be part of a third, unknown dinosaur.[12]
Thescelosaurus with skin impressions, Museum of the Rockies specimen 979

Clint Boyd and colleagues published a reassessment of Thescelosaurus, Bugenasaura, and Parksosaurus in 2009, using new cranial material as a starting point. They found that Parksosaurus was indeed distinct from Thescelosaurus, and that the skull of Bugenasaura infernalis was essentially the same as a skull found with a postcranial skeleton that matched Thescelosaurus. Because B infernalis could not be differentiated from Thescelosaurus, they regarded the genus as a synonym of Thescelosaurus, the species as dubious, and SDSM 7210 as an example of T. sp. They found that LACM 33542, although fragmentary, was a specimen of Thescelosaurus, and agreed with Morris that the ankle structure was distinct, returning it to T. garbanii. Finally, they noted that another specimen, RSM P.1225.1, differed from T. neglectus in some anatomical details, and may represent a new species. Thus, Thescelosaurus per Boyd et al. (2009) is represented by at least two, and possibly three valid species: type species T. neglectus, T. garbanii, and a possible unnamed species.[1] In December 2011, RSM P.1225.1 was assigned to its own species, Thescelosaurus assiniboiensis. It was named by Caleb M. Brown, Clint A. Boyd and Anthony P. Russell and is known only from its holotype, a small, articulated and almost complete skeleton from the Frenchman Formation (late Maastrichtian stage) of Saskatchewan.[13]
Size of two Thescelosaurus species (right) compared to its relatives Parksosaurus (center) and Orodromeus (left), as well as a human

Overall, the skeletal anatomy of this genus is well documented, and restorations have been published in several papers, including skeletal restorations[1][4][8][14] and models.[7][4] The skeleton is known well enough that a detailed reconstruction of the hip and hindlimb muscles has been made.[15] The animal's size has been estimated in the 2.5–4.0 m range for length (8.2–13.1 ft)[8] for various specimens, and a weight of 200–300 kilograms (450–660 pounds),[16] with the large type specimen of T. garbanii estimated at 4–4.5 meters (13.1–14.8 feet) long.[11] As discussed more fully under "Discovery, history, and species", it may have been sexually dimorphic, with one sex larger than the other.[8] Juvenile remains are known from several locations, mostly based on teeth.[17][18]

Thescelosaurus was a heavily built bipedal animal, probably herbivorous, but potentially not.[9] There was a prominent ridge along the length of both maxillae (the tooth-bearing "cheek" bones),[1] and a ridge on both dentaries (tooth-bearing bone of the lower jaw).[19] The ridges[19] and position of the teeth, deeply internal to the outside surface of the skull, are interpreted as evidence for muscular cheeks.[11] Aside from the long narrow beak, the skull also had teeth in the premaxilla, or upper beak (a primitive trait among neornithischians).[20] Long rod-like bones called palpebrals were present over the eyes, giving the animal heavy bony eyebrows.[20] Its teeth were of two types: small pointed premaxillary teeth, and leaf-shaped cheek teeth.[7] Six small teeth were present in both premaxillae, with a toothless section at the tip of the beak.[1]
T. neglectus protofeathered reconstruction

Thescelosaurs had short, broad, five-fingered hands, four-toed feet with hoof-like toe tips, and a long tail braced by ossified tendons from the middle to the tip, which would have reduced the flexibility of the tail.[4] The rib cage was broad, giving it a wide back, and the limbs were robust.[7] The animals may have been able to move on all fours, given its fairly long arms and wide hands,[8] but this idea has not been widely discussed in the scientific literature, although it does appear in popular works.[21][22] Charles M. Sternberg reconstructed it with the upper arm oriented almost perpendicular to the body,[7] another idea that has gone by the wayside. As noted by Peter Galton, the upper arm bone of most ornithischians articulated with the shoulder by an articular surface that consisted of the entire end of the bone, instead of a distinct ball and socket as in mammals. The orientation of the shoulder's articular surface also indicates a vertical and not horizontal upper arm in dinosaurs.[23]

Large thin flat mineralized plates have been found next to the ribs' sides.[24] Their function is unknown; they may have played a role in respiration.[25] However, muscle scars or other indications of attachment have not been found for the plates, which argues against a respiratory function. Recent histological study of layered plates from a probable subadult indicates that they may have started as cartilage and became bone as the animal aged.[26] Such plates are known from several other cerapodas.[27]

The nature of this genus' integument, be it scales or something else, is currently unknown, although potential evidence exists: Charles Gilmore described patches of carbonized material near the shoulders as possible epidermis, with a "punctured" texture, but no regular pattern,[4] and William J. Morris suggested that armor was present, in the form of small scutes he interpreted as located at least along the midline of the neck of one specimen.[11] Scutes have not been found with other articulated specimens of Thescelosaurus, though, and Morris's scutes could be crocodilian in origin.[27]
Front of reconstructed skeleton, Rocky Mountain Dinosaur Resource Center

Thescelosaurus has generally been allied to Hypsilophodon and other small neornithischians as a hypsilophodontid, although recognized as being distinct among them for its robust build, unusual hindlimbs, and, more recently, its unusually long skull.[9][7][8][10] Peter Galton in 1974 presented one twist to the classic arrangement, suggesting that because of its hindlimb structure and heavy build (not cursorial, or built for running, by his definition), it should be included in the Iguanodontidae. This has not been followed, with Morris arguing strongly against Galton's classification scheme.[11] At any rate, Galton's Iguanodontidae was polyphyletic and not a natural group, and so would not be recognized under modern cladistic usage.

Although Hypsilophodontidae was interpreted as a natural group in the early 1990s,[10][28] this hypothesis has fallen out of favor and Hypsilophodontidae has been found to be an unnatural family composed of a variety of animals more or less closely related to Iguanodontia (paraphyly), with various small clades of closely related taxa.[1][9][29][30][31] "Hypsilophodontidae" and "hypsilophodont" are better understood as informal terms for an evolutionary grade, not a true clade. Thescelosaurus has been regarded as both very basal[28] and very derived[9] among the hypsilophodonts. One issue that has potentially interfered with classifying Thescelosaurus is that not all of the remains assigned to T. neglectus necessarily belong to it.[32] Clint Boyd and colleagues found that while the clade Thescelosaurus included the genus Bugenasaura and the species that had been assigned to that genus, there were at least two and possibly three species within Thescelosaurus, and several specimens previously assigned to T. neglectus could not yet be assigned to a species within the genus.[1] It appears to be closely related to Parksosaurus.[1][9][30][13][33]

The dissolution of Hypsilophodontidae has been followed by the recognition of the distinct family Thescelosauridae. This area of the dinosaur family tree has historically been complicated by a lack of research, but papers by Clint Boyd and colleagues[1] and Caleb Brown and colleagues[13][33] have specifically addressed these dinosaurs. Boyd et al. (2009) and Brown et al. (2011) found North American "hypsilophodonts" of Cretaceous age to sort into two related clusters, one consisting of Orodromeus, Oryctodromeus, and Zephyrosaurus, and the other consisting of Parksosaurus and Thescelosaurus.[1][13] Brown et al. (2013) recovered similar results, with the addition of the new genus Albertadromeus to the Orodromeus clade and several long-snouted Asian forms (previously described under Jeholosauridae)[29] to the Thescelosaurus clade. They also formally defined Thescelosauridae (Thescelosaurus neglectus, Orodromeus makelai, their most recent common ancestor, and all descendants) and the smaller clades Orodrominae and Thescelosaurinae. The below cladogram is that of Brown et al..[33]
Skull of T. neglectus NCSM 15728 ("Willo") in left and right view


TMP 2008.045.0002










Thescelosaurus assiniboiensis

Thescelosaurus neglectus

T. neglectus scaly restoration

Thescelosaurus would have browsed in the first meter or so from the ground, feeding selectively,[9] with food held in the mouth by cheeks while chewing.[8] Thescelosaurus was probably slower than other hypsilophodonts, because of its heavier build and leg structure. Compared to them, it had unusual hindlimbs, because the upper leg was longer than the shin, the opposite of Hypsilophodon and running animals in general.[7] One specimen is known to have had a bone pathology, with the long bones of the right foot fused at their tops, hindering swift movement.[34] Examinations of the teeth of Thescelosaurus and comparisons with the contemporary pachycephalosaur Stegoceras suggest that Thescelosaurus was a selective feeder, while Stegoceras was a more indiscriminate feeder, allowing both animals to share the same environment without competing for food.[35]
Supposed fossilized heart
"Willo" specimen, with the possible heart left of the shoulder blade

In 2000, a skeleton of this genus (specimen NCSM 15728) informally known as "Willo", now on display at the North Carolina Museum of Natural Sciences, was described as including the remnants of a four-chambered heart and an aorta. It had been originally unearthed in 1993 in northwestern South Dakota. The authors had found the internal detail through computed tomography (CT) imagery. They suggested that the heart had been saponified (turned to grave wax) under airless burial conditions, and then changed to goethite, an iron mineral, by replacement of the original material. The authors interpreted the structure of the heart as indicating an elevated metabolic rate for Thescelosaurus, not reptilian cold-bloodedness.[24]

Their conclusions have been disputed; soon after the initial description, other researchers published a paper where they asserted that the heart is really a concretion. As they noted, the anatomy given for the object is incorrect (for example, the "aorta" narrows coming into the "heart" and lacks arteries coming from it), it partially engulfs one of the ribs and has an internal structure of concentric layers in some places, and another concretion is preserved behind the right leg.[36] The original authors defended their position; they agreed that it was a type of concretion, but one that had formed around and partially preserved the more muscular portions of the heart and aorta.[37]
"Willo"'s supposed "heart"

A study published in 2011 applied multiple lines of inquiry to the question of the object's identity, including more advanced CT scanning, histology, X-ray diffraction, X-ray photoelectron spectroscopy, and scanning electron microscopy. From these methods, the authors found the following: the object's internal structure does not include chambers but is made up of three unconnected areas of lower density material, and is not comparable to the structure of an ostrich's heart; the "walls" are composed of sedimentary minerals not known to be produced in biological systems, such as goethite, feldspar minerals, quartz, and gypsum, as well as some plant fragments; carbon, nitrogen, and phosphorus, chemical elements important to life, were lacking in their samples; and cardiac cellular structures were absent. There was one possible patch with animal cellular structures. The authors found their data supported identification as a concretion of sand from the burial environment, not the heart, with the possibility that isolated areas of tissues were preserved.[38]

The question of how this find reflects metabolic rate and dinosaur internal anatomy is moot, though, regardless of the object's identity.[38] Both modern crocodilians and birds, the closest living relatives of dinosaurs, have four-chambered hearts (albeit modified in crocodilians), so dinosaurs probably had them as well; the structure is not necessarily tied to metabolic rate.[39]
Temporal and geographic range
Pie chart of the time averaged census for large-bodied dinosaurs from the entire Hell Creek Formation in the study area

True Thescelosaurus remains are known definitely only from late Maastrichtian-age rocks, from Alberta (Scollard Formation) and Saskatchewan (Frenchman Formation), Canada, and Wyoming (Lance Formation), South Dakota (Hell Creek Formation), Montana (Hell Creek), and Colorado (Laramie Formation), USA.[1][9] With the exception of birds, it was one of the last genera of dinosaurs, its remains being found as close as 3 meters to the boundary clay containing the iridium layer that closes the Cretaceous.[40] The Laramie Formation is the oldest formation that Thescleosaurus is known from, and magnetostratigraphy suggests an age of 69-68 Ma for the Laramie Formation.[41] There are reports of teeth from older, Campanian-age rocks, particularly from the Dinosaur Park Formation of Alberta,[42] but these specimens are not from Thescelosaurus and are much more likely those of Orodromeus.[12] More specimens are known than have been officially described for this genus, such as the Triebold specimen,[43] which has been the source of several skeletal casts for museums.

When Galton revisited Thescelosaurus and Bugenasaura in 1999, he described the dentary tooth UCMP 46911 from the Upper Jurassic of Weymouth, England as cf. Bugenasaura.[19] If it is indeed a tooth from a thescelosaur-like animal, this would significantly extend the stratigraphic range of the group.

Conflicting reports have been made as to its preferred habitat; two papers suggest it preferred channels to floodplains,[44][45] but another suggests it preferred the opposite.[46] The possible preference for channels is based on the relative abundance of thescelosaur fossils in sandstones, representing channel environments, in comparison to mudstones, representing floodplain environments.[45] No bonebeds or accumulations of multiple individuals have yet been reported. Dale Russell, in a popular work, noted that Thescelosaurus was the most common small herbivore in the Hell Creek Formation of the Fort Peck area. He described the environment of the time as a flat floodplain, with a relatively dry subtropical climate that supported a variety of plants ranging from angiosperm trees, to bald cypress, to ferns and ginkgos. Although most dinosaur skeletons from this area are incomplete, possibly due to the low preservation potential of forests, Thescelosaurus skeletons are much more complete, suggesting that this genus frequented stream channels. Thus when a Thescelosaurus died, it may have been in or near a river, making it easier to bury and preserve for later fossilization. Russell tentatively compared it to the capybaras and tapirs.[47] Other dinosaurs that shared its time and place include the ceratopsids Triceratops and Torosaurus, hadrosaurid Edmontosaurus, ankylosaurid Ankylosaurus, pachycephalosaurian Pachycephalosaurus, and the theropods Ornithomimus, Troodon, and Tyrannosaurus.[48][49] Thescelosaurus was also abundant in the Lance Formation. Toe bones from this genus are the most common finds after fossils of Triceratops and Edmontosaurus, and it may have been the most common dinosaur there in life, if the Lance Formation had a preservational bias against small animals.[50]

Boyd, Clint A.; Brown, Caleb M.; Scheetz, Rodney D.; Clarke, Julia A. (2009). "Taxonomic revision of the basal neornithischian taxa Thescelosaurus and Bugenasaura". Journal of Vertebrate Paleontology. 29 (3): 758–770. doi:10.1671/039.029.0328. S2CID 84273584.
Liddell & Scott (1980). Greek-English Lexicon, Abridged Edition. Oxford University Press, Oxford, UK. ISBN 978-0-19-910207-5.
Gilmore, Charles W. (May 1913). "A new dinosaur from the Lance Formation of Wyoming". Smithsonian Miscellaneous Collections. 61 (5): 1–5.
Gilmore, Charles W. (1915). "Osteology of Thescelosaurus, an orthopodus dinosaur from the Lance Formation of Wyoming" (PDF). Proceedings of the U.S. National Museum. 49 (2127): 591–616. doi:10.5479/si.00963801.49-2127.591.
Parks, William A (1926). "Thescelosaurus warreni, a new species of orthopodous dinosaur from the Edmonton Formation of Alberta". University of Toronto Studies (Geological Series). 21: 1–42.
Sternberg, Charles M. (1937). "Classification of Thescelosaurus, with a description of a new species". Geological Society of America Proceedings for 1936: 365.
Sternberg, Charles M. (1940). "Thescelosaurus edmontonensis, n. sp., and classification of the Hypsilophodontidae". Journal of Paleontology. 14 (5): 481–494.
Galton, Peter M. (1974). "Notes on Thescelosaurus, a conservative ornithopod dinosaur from the Upper Cretaceous of North America, with comments on ornithopod classification". Journal of Paleontology. 48 (5): 1048–1067.
Norman, David B.; Sues, Hans-Dieter; Witmer, Larry M.; Coria, Rodolfo A. (2004). "Basal Ornithopoda". In Weishampel, David B.; Dodson, Peter; Osmólska, Halszka (eds.). The Dinosauria (2nd ed.). Berkeley: University of California Press. pp. 393–412. ISBN 978-0-520-24209-8.
Sues, Hans-Dieter; Norman, David B. (1990). "Hypsilophodontidae, Tenontosaurus, Dryosauridae". In Weishampel, David B.; Dodson, Peter; Osmólska, Halszka (eds.). The Dinosauria (1st ed.). Berkeley: University of California Press. pp. 498–509. ISBN 978-0-520-06727-1.
Morris, William J. (1976). "Hypsilophodont dinosaurs: a new species and comments on their systematics". In Churcher, C.S. (ed.). Athlon. Toronto: Royal Ontario Museum. pp. 93–113. ISBN 978-0-88854-157-4.
Galton, Peter M. (1995). "The species of the basal hypsilophodontid dinosaur Thescelosaurus Gilmore (Ornithischia: Ornithopoda) from the Late Cretaceous of North America". Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen. 198 (3): 297–311. doi:10.1127/njgpa/198/1995/297.
Brown; Caleb M.; Boyd, Clint A.; and Russell, Anthony P. (2011). "A new basal ornithopod dinosaur (Frenchman Formation, Saskatchewan, Canada), and implications for late Maastrichtian ornithischian diversity in North America". Zoological Journal of the Linnean Society. 163 (4): 1157–1198. doi:10.1111/j.1096-3642.2011.00735.x.
Brett-Surman, Michael K. (1997). "Ornithopods". In Farlow, James O.; Brett-Surman, Michael K. (eds.). The Complete Dinosaur. Bloomington and Indianapolis: Indiana University Press. pp. 330–346. ISBN 978-0-253-33349-0.
Romer, Alfred S. (1927). "The pelvic musculature of ornithischian dinosaurs". Acta Zoologica. 8 (2–3): 225–275. doi:10.1111/j.1463-6395.1927.tb00653.x.
Erickson, Bruce R. (2003). Dinosaurs of the Science Museum of Minnesota. St. Paul, Minnesota: The Science Museum of Minnesota. p. 31.
Carpenter, Kenneth (1982). "Baby dinosaurs from the Late Cretaceous Lance and Hell Creek formations and a description of a new species of theropod". Contributions to Geology. 20 (2): 123–134.
Russell, Dale A.; Manabe, Makoto (2002). "Synopsis of the Hell Creek (uppermost Cretaceous) dinosaur assemblage". In Hartman, Joseph H.; Johnson, Kirk R.; Nichols, Douglas J. (eds.). The Hell Creek Formation and the Cretaceous-Tertiary Boundary in the Northern Great Plains: An Integrated Continental Record of the End of the Cretaceous. Geological Society of America Special Paper, 361. Boulder, Colorado: Geological Society of America. pp. 169–176. ISBN 978-0-8137-2361-7.
Galton, Peter M. (1999). "Cranial anatomy of the hypsilophodont dinosaur Bugenasaura infernalis (Ornithischia: Ornithopoda) from the Upper Cretaceous of North America". Revue Paléobiologie, Genève. 18 (2): 517–534.
Galton, Peter M. (1997). "Cranial anatomy of the basal hypsilophodontid dinosaur Thescelosaurus neglectus Gilmore (Ornithischia; Ornithopoda) from the Upper Cretaceous of North America". Revue Paléobiologie, Genève. 16 (1): 231–258.
Lambert, David; the Diagram Group (1990). "Thescelosaurids". The Dinosaur Data Book. New York: Avon Books. p. 153. ISBN 978-0-380-75896-8.
Lessem, Donald; Glut, Donald F. (1993). The Dinosaur Society Dinosaur Encyclopedia. Random House, Inc. p. 475. ISBN 978-0-679-41770-5.
Galton, Peter M. (1970). "The posture of hadrosaurian dinosaurs". Journal of Paleontology. 44 (3): 464–473.
Fisher, Paul E.; Russell, Dale A.; Stoskopf, Michael K.; Barrick, Reese E.; Hammer, Michael; Kuzmitz, Aandrew A. (April 2000). "Cardiovascular evidence for an intermediate or higher metabolic rate in an ornithischian dinosaur". Science. 288 (5465): 503–505. Bibcode:2000Sci...288..503F. doi:10.1126/science.288.5465.503. PMID 10775107.
Novas, Fernando E.; Cambiaso, Andrea V; Ambrioso, Alfredo (2004). "A new basal iguanodontian (Dinosauria, Ornithischia) from the Upper Cretaceous of Patagonia". Ameghiniana. 41 (1): 75–82.
Boyd, Clint A.; Cleland, Timothy P. (2008). "The morphology and histology of thoracic plates on neornithischian dinosaurs". Abstract with Programs - Geological Society of America; Southeast Section, 57th Annual Meeting. 40 (2): 2.
Butler, Richard J.; Galton, Peter M. (2008). "The 'dermal armour' of the ornithopod dinosaur Hypsilophodon from the Wealden (Early Cretaceous: Barremian) of the Isle of Wight: a reappraisal". Cretaceous Research. 29 (4): 636–642. doi:10.1016/j.cretres.2008.02.002.
Weishampel, David B.; Heinrich, Ronald E. (1992). "Systematics of Hypsilophodontidae and Basal Iguanodontia (Dinosauria: Ornithopoda)" (PDF). Historical Biology. 6 (3): 159–184. doi:10.1080/10292389209380426. Retrieved 2007-03-10.
Han, Feng-Lu; Paul M. Barrett; Richard J. Butler; Xing Xu (2012). "Postcranial anatomy of Jeholosaurus shangyuanensis (Dinosauria, Ornithischia) from the Lower Cretaceous Yixian Formation of China". Journal of Vertebrate Paleontology. 32 (6): 1370–1395. doi:10.1080/02724634.2012.694385. S2CID 86754247.
Weishampel, David B.; Jianu, Coralia-Maria; Csiki, Z.; Norman, David B. (2003). "Osteology and phylogeny of Zalmoxes (n.g.), an unusual euornithopod dinosaur from the latest Cretaceous of Romania". Journal of Systematic Palaeontology. 1 (2): 1–56. doi:10.1017/S1477201903001032. S2CID 86339025.
Varricchio, David J.; Martin, Anthony J.; Katsura, Yoshihiro (2007). "First trace and body fossil evidence of a burrowing, denning dinosaur". Proceedings of the Royal Society B: Biological Sciences. 274 (1616): 1361–1368. doi:10.1098/rspb.2006.0443. PMC 2176205. PMID 17374596.
Butler, Richard J.; Upchurch, Paul; and Norman, David B. (2008). "The phylogeny of the ornithischian dinosaurs". Journal of Systematic Palaeontology. 6 (1): 1–40. doi:10.1017/S1477201907002271. S2CID 86728076.
Brown, Caleb Marshall; Evans, David C.; Ryan, Michael J.; Russell, Anthony P. (2013). "New data on the diversity and abundance of small-bodied ornithopods (Dinosauria, Ornithischia) from the Belly River Group (Campanian) of Alberta". Journal of Vertebrate Paleontology. 33 (3): 495–520. doi:10.1080/02724634.2013.746229. S2CID 129160518.
Erickson, Bruce R. (2003). Dinosaurs of the Science Museum of Minnesota. St. Paul, Minnesota: The Science Museum of Minnesota. pp. 31–32.
Naylor Hudgins, Michael; Currie, Philip J.; Sullivan, Corwin (2021). "Dental assessment of Stegoceras validum (Ornithischia: Pachycephalosauridae) and Thescelosaurus neglectus (Ornithischia: Thescelosauridae): paleoecological inferences". Cretaceous Research. 130: 105058. doi:10.1016/j.cretres.2021.105058. S2CID 239253658.
Rowe, Timothy; McBride, Earle F.; Sereno, Paul C. (February 2001). "Technical comment: dinosaur with a heart of stone". Science. 291 (5505): 783a. doi:10.1126/science.291.5505.783a. PMID 11157158.
Russell, Dale A.; Fisher, Paul E.; Barrick, Reese E.; Stoskopf, Michael K. (February 2001). "Reply: dinosaur with a heart of stone". Science. 291 (5505): 783a. doi:10.1126/science.291.5505.783a. PMID 11157158.
Cleland, Timothy P.; Stoskopf, Michael K.; Schweitzer, Mary H. (2011). "Histological, chemical, and morphological reexamination of the "heart" of a small Late Cretaceous Thescelosaurus". Naturwissenschaften. 98 (3): 203–211. Bibcode:2011NW.....98..203C. doi:10.1007/s00114-010-0760-1. PMID 21279321. S2CID 2408562.
Chinsamy, Anusuya; and Hillenius, Willem J. (2004). "Physiology of nonavian dinosaurs". The Dinosauria, 2nd ed. 643–659.
Carpenter, Kenneth; Breithaupt, Brent H. (1986). "Latest Cretaceous occurrences of nodosaurid ankylosaurs (Dinosauria, Ornithischia) in Western North America and the gradual extinction of the dinosaurs". Journal of Vertebrate Paleontology. 6 (3): 251–257. doi:10.1080/02724634.1986.10011619.
*Hicks, J.F., Johnson, K.R., Obradovich, J. D., Miggins, D.P., and Tauxe, L. 2003. Magnetostratigraphyof Upper Cretaceous (Maastrichtian) to lower Eocene strata of the Denver Basin, Colorado. In K.R. Johnson, R.G. Raynolds and M.L. Reynolds (eds), Paleontology and Stratigraphy of Laramide Strata in the Denver Basin, Pt. II., Rocky Mountain Geology 38: 1-27.
Sahni, Ashok (1972). "The vertebrate fauna of the Judith River Formation, Montana" (free PDF, may not load). Bulletin of the American Museum of Natural History. 147: 321–412. Retrieved 2007-03-10.
Triebold Paleontology, Inc. "Thescelosaurus". Retrieved 2016-06-01.
Pearson, Dean A.; Schaefer, Terry; Johnson, Kirk R.; Nichols, Douglas J.; and Hunter, John P. (2002). "Vertebrate biostratigraphy of the Hell Creek Formation in southwestern North Dakota and northwestern South Dakota". The Hell Creek Formation and the Cretaceous-Tertiary Boundary in the Northern Great Plains: An Integrated Continental Record of the End of the Cretaceous. 145–167.
Lyson, Tyler R.; Longrich, Nicholas R. (2011). "Spatial niche partitioning in dinosaurs from the latest Cretaceous (Maastrichtian) of North America". Proceedings of the Royal Society B. 278 (1709): 1158–1164. doi:10.1098/rspb.2010.1444. PMC 3049066. PMID 20943689.
Carpenter, Kenneth; and Young; D. Bruce (2002). "Late Cretaceous dinosaurs from the Denver Basin, Colorado". Rocky Mountain Geology. 37 (2): 237–254. doi:10.2113/11.
Russell, Dale A. (1989). An Odyssey in Time: Dinosaurs of North America. Minocqua, Wisconsin: NorthWord Press, Inc. pp. 175–176. ISBN 978-1-55971-038-1.
Weishampel, David B.; Barrett, Paul M.; Coria, Rodolfo A.; Le Loeuff, Jean; Xu Xing; Zhao Xijin; Sahni, Ashok; Gomani, Elizabeth, M.P.; and Noto, Christopher R. (2004). "Dinosaur Distribution". The Dinosauria (2nd). 517–606.
Bigelow, Phillip. "Cretaceous "Hell Creek Faunal Facies"; Late Maastrichtian". Retrieved 2007-01-26.
Derstler, Kraig (1994). "Dinosaurs of the Lance Formation in eastern Wyoming". In Nelson, Gerald E. (ed.). The Dinosaurs of Wyoming. Wyoming Geological Association Guidebook, 44th Annual Field Conference. Wyoming Geological Association. pp. 127–146.


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