Vertebrate Ichnopathology: Pathologies Inferred from Dinosaur Tracks and Trackways from the Mesozoic

McCrea, Richard T.; Tanke, Darren H.; Buckley, Lisa G.; Lockley, Martin G.; Farlow, James O.; Xing, Lida; Matthews, Neffra A.; Helm, Charles; Pemberton, S. George; Breithaupt, Brent H.

doi:10.1080/10420940.2015.1064408

Cited by 32 publications

(23 citation statements)

References 77 publications

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“…18), and the inside of pes prints, and the heel, are (aside from claw marks) the deepest parts of hindfoot prints (cf. some sauropod trackways: Farlow et al, 2015). Webbing between digits II-III, and III-IV, of the pes may register as a shallow region of the print (Figs.…”

Section: Qualitative Features Of American Crocodile Trackwaysmentioning

confidence: 99%

Trackways of the American Crocodile (Crocodylus acutus) in Northwestern Costa Rica: Implications for Crocodylian Ichnology

Farlow

Robinson

Kumagai

et al. 2017

Ichnos

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Section: Qualitative Features Of American Crocodile Trackwaysmentioning

confidence: 99%

Trackways of the American Crocodile (Crocodylus acutus) in Northwestern Costa Rica: Implications for Crocodylian Ichnology

Farlow

Robinson

Kumagai

et al. 2017

Ichnos

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“…; from the Late Pleistocene (Lujanian Stage/Age) of Pehuen Co (Partido de Coronel Rosales) and Laguna del Monte (Partido de Guaminí) tracksites, Buenos Aires Province, Argentina (Figure 1). The differentiation of pathologic footprints was based on the detection of potential clinical signs (related to any of the limb affections known for modern ungulates); having previously discarded other types of intraspecific variations (intramorphological changes) and/or secondary alterations linked to external factors (extramorphological characters) (e.g., nature of the substrate, mechanical disturbance, presence of foreign objects, infauna influence; see McCrea et al, 2015). The recognition of the ungual diseases has been made indirectly, through interpretation of Owen, 1848(Camelidae Gray, 1821Cervidae Gray, 1821;Bobidae Gray, 1821;Giraffidae Gray, 1821;Hippopotamidae Gray, 1821;Suidae Gray, 1821;Tayassuidae Palmer, 1897), either on wild or captive animals (Fowler, 1978(Fowler, , 1980 (Kuntze, 1972(Kuntze, , 1980Fowler, 1980Fowler, , 2001von Houwald, 2001;Benz, 2005) ( Figure 2A).…”

Section: Methodsmentioning

confidence: 99%

“…In contrast, the advances in ichnopathology (paleopathology based on the fossil-tracks analysis) are much more restricted and specifically focused on dinosaurs (see Lockley et al, 1994;Tanke and Rothschild, 2002;McCrea et al, 2014McCrea et al, , 2015. In this regard, although this specialty has developed parallel to conventional ichnology since the mid-nineteenth century, its evolution was comparatively lesser, headed by sporadic contributions wherein a scarce number of anomalous records, from the Mesozoic of Northern Hemisphere, were described: Late Triassic-Early Jurassic (Hitchcock, 1844(Hitchcock, , 1858Abel, 1935;Lull, 1953) and Late Cretaceous (McCrea et al, 2014(McCrea et al, , 2015Tanke and Rothschild, 2015) of North America; Triassic s. l. (Tucker and Burchette, 1977) and Late Jurassic (Dantas et al, 1994;Avanzini et al, 2008) of Europe; Middle Jurassic of Africa (Jenny and Josen, 1982;Ishigaki, 1986Ishigaki, , 1988 and Late Cretaceous of Asia (Currie et al, 2003;McCrea et al, 2015). This is probably due to the high difficulty that imply the differentiation of pathological signs in footprints and trails, which reflect the influence of several extrinsic agents (e.g., nature of the track-bearing substrate, behaviour of the trackmaker, taphonomical factors) (see McCrea et al, 2015); made even worse in the cases where there are no modern species for comparison.…”

Section: Introductionmentioning

confidence: 99%

“…In this regard, although this specialty has developed parallel to conventional ichnology since the mid-nineteenth century, its evolution was comparatively lesser, headed by sporadic contributions wherein a scarce number of anomalous records, from the Mesozoic of Northern Hemisphere, were described: Late Triassic-Early Jurassic (Hitchcock, 1844(Hitchcock, , 1858Abel, 1935;Lull, 1953) and Late Cretaceous (McCrea et al, 2014(McCrea et al, , 2015Tanke and Rothschild, 2015) of North America; Triassic s. l. (Tucker and Burchette, 1977) and Late Jurassic (Dantas et al, 1994;Avanzini et al, 2008) of Europe; Middle Jurassic of Africa (Jenny and Josen, 1982;Ishigaki, 1986Ishigaki, , 1988 and Late Cretaceous of Asia (Currie et al, 2003;McCrea et al, 2015). This is probably due to the high difficulty that imply the differentiation of pathological signs in footprints and trails, which reflect the influence of several extrinsic agents (e.g., nature of the track-bearing substrate, behaviour of the trackmaker, taphonomical factors) (see McCrea et al, 2015); made even worse in the cases where there are no modern species for comparison. In this paper we present the results obtained from the paleopathological study of fossil tracks and trackways related to Holarctic ungulates (equids, camelids and gomphotherids), from the Late Pleistocene of Argentina (South America), and discuss the ichnopathological and ichnotaxonomical implications of these findings.…”

Section: Introductionmentioning

confidence: 99%

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Mammalian ichnopathology: A case study of holartic ungulates (Gomphotheriidae, Equidae, Camelidae) of the Late Pleistocene of South America. Ichnotaxomic implications

Oliva¹,

Arregui²

2018

BSGM

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The analysis of paleoichnites and trackways corresponding to Holarctic ungulates, from the late Pleistocene (Lujanian Stage/Age) of Pehuen Co and Laguna del Monte tracksites (Buenos Aires Province, Argentina), allows the recognition of several clinical signs (ichnopathologies) that reflect some of the main pedal affections and alterations experienced by living members of the group. Proboscipeda australis (Aramayo and Manera de Bianco, 1987a) presents occasional fissures on its hoofprints, interpreted as fractures on the hornwall (vertical) and cracking of the sole (horizontal). Hippipeda isp. exhibits a series of morphologic anomalies in the digital impression, linked to contracted heel (transversely compressed hoof, narrowing and distal projection of talonar region, with an approximation of both heel-bulb impressions and an enlargement of the spacing between frog baseline and heel buttresses), distorted hoof (asymmetrical sole region and hoof wall, with forwardly projected internal pillar [toe-quarter junction] and anteriorly displaced external heel buttress), turkish-slipper foot (over-elongated hoofprint, showing hyper-lengthening of lateral walls [inner and outer quarters], and hypertrophy of frog and bars). Lamaichnum guanicoe Aramayo and Manera de Bianco, 1987b displays eventual evidence of horny overgrowth: inward/ subparallel (loss of bilateral symmetry, medial curving of digits, uneven sizing of toepad prints) and outward/divergent (lateral curving of digits, overexpansion of interclavular gap [with ample separation between both digital ends], enlargement and widening of the tracks, normal acquisition of a secondary heteropody). These intraspecific variations (ichnopathological characters) are often used to segregate a second llamoid ichnospecies: Lamaichnum tulipensis (Aramayo and Manera de Bianco, 1987b), herein proposed as teratologic synonym of Lamaichnum guanicoe.

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“…This method, whose practice is explained by several papers (e.g., Falkingham, ; Mallison & Wings, ; Petti et al, ), enables preservation and communication more objectively about ichnological data. Its adoption has greatly increased in recent times, becoming almost a standard taking advantage of a protocol for ichnological studies (Falkingham et al, ) and being used as support of different approaches related to ichnological analysis (e.g., Castanera et al, ; Citton, Carluccio, Nicolosi, & Nicosia, ; Citton, Nicolosi, Carluccio, & Nicosia, ; Citton, Nicosia, Nicolosi, Carluccio, & Romano, ; Citton et al, ; Citton, Romano, Salvador, & Avanzini, ; Lallensack, Sander, Knötschke, & Wings, ; McCrea et al, ; Romano & Citton, ). High‐resolution Digital Photogrammetry is based on Structure from Motion (SfM) (Ullman, ) and Multi View Stereo (MVS; Seitz, Curless, Diebel, Scharstein, & Szeliski, ) algorithms and produces high‐quality dense point clouds.…”

Section: Methodsmentioning

confidence: 99%

First tetrapod footprints from the Permian of Sardinia and their palaeontological and stratigraphical significance

Citton

Ronchi

Maganuco³

et al. 2018

Geological Journal

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The Torre del Porticciolo palaeontological locality (Alghero, north‐west Sardinia, Italy) is important for having provided the skeletal remains of the first Permian basal synapsid from Italy, Alierasaurus ronchii, the largest late early Permian to early middle Permian non‐therapsid synapsid known to date. Recently, other skeletal remains preliminarily attributed to a carnivorous non‐therapsid synapsid were described from a second site, approximately from the same stratigraphic level within the Cala del Vino Fm. During the excavation of this second site, tetrapod tracks were found near Cala Viola, about 1 km from the first two sites. The new find represents the first ichnological record from the Permian of Sardinia. The ichnological analysis allowed the recognition of tetrapods presently not recognized, just on the base of skeletal remains. This new evidence sheds more light on the faunal diversity within the Cala del Vino Fm., which is one of the few examples in the Permian of Europe of a combined ichno‐ and body‐fossil record. The tracks have been referred to as Merifontichnus, an ichnotaxon established from the uppermost portion of the Permian succession of the Lodève Basin in southern France. The new material is the first reliable occurrence of this ichnotaxon from Italy and would represent, to date, the oldest occurrence of the ichnogenus.

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Vertebrate Ichnopathology: Pathologies Inferred from Dinosaur Tracks and Trackways from the Mesozoic

Cited by 32 publications

References 77 publications

Trackways of the American Crocodile (Crocodylus acutus) in Northwestern Costa Rica: Implications for Crocodylian Ichnology

Trackways of the American Crocodile (Crocodylus acutus) in Northwestern Costa Rica: Implications for Crocodylian Ichnology

Mammalian ichnopathology: A case study of holartic ungulates (Gomphotheriidae, Equidae, Camelidae) of the Late Pleistocene of South America. Ichnotaxomic implications

First tetrapod footprints from the Permian of Sardinia and their palaeontological and stratigraphical significance

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