Oksoko avarsan

The four known specimens of Oksoko avarsan

(MPC-D 100/33, MPC-D 102/11, MPC-D 102/12, and MPC-D 102/110) compriseatleastsixindividuals.MPC-D 100/33 andMPC-D 102/12 each represent a single partial skeleton, whereas MPC-D 102/11 includes a relatively complete skeleton (MPC-D 102/11.a) and three cranial bones of another individual (MPC-D 102/11.b). The main block of MPC-D 102/110 includes two relatively complete skeletons and a partial skeleton of a third individual. These individuals are sub-numbered MPC-D 102/110.a, MPC-D 102/110.b, and MPC-D 102/110.c, in descending order of completeness. MPC-D 102/11 and MPC-D 102/110 were probably collected from the same assemblage (Funston et al. 2020), which has a minimum number of four individuals based on right quadrates. As discussed by Funston et al. (2020), the provenance of this assemblage is uncertain because the specimens were confiscated from poachers, who excavated the skeletons illegally. Several lines of evidence suggest that MPC-D 102/110 was collected from either Bugiin Tsav or Guriliin Tsav in the north-western part of the Nemegt Basin. Geochemical fingerprinting on MPC-D 102/110 strongly suggests that the specimens are from the Nemegt Formation, specifically the Nemegt locality, although the Bugiin Tsav and Guriliin Tsav localities were not included in that sample ( Fanti et al. 2017). Another line of evidence is an abandoned ankylosaur skeleton re-discovered in 2018 at Guriliin Tsav, poached using similar methods and materials as used to collect MPC-D 102/110 ( Fig. 2C, D View Figure 2 ). Both field jackets are made of thin pre-prepared blaster bandages with blue fibres, and yellow plastic bags were used as a separating layer. As these features of the specimens are unusual, this suggests, minimally, that the same group of poachers collected both specimens. Lastly, legitimately collected specimens of Oksoko avarsan are known from Bugiin Tsav (MPC-D 100/33) and Guriliin Tsav (MPC-D 102/12), showing that this taxon was present in the area.

Specimens of Oksoko avarsan and other oviraptorosaurs housed in the collections of the CMN, MPC, ROM, TMP, and UALVP were examined firsthand and measured using digital calipers (±0.1 mm) or a fabric measuring tape (± 1 mm). Information about other specimens was taken from the literature. The specimens were photographed using a Nikon D5000, Nikon D7200, or Nikon COOLPIX AW120 camera with a variety of lenses.

CT scans of MPC-D 102/110 were performed at The National Museum of Natural History and Science in Tokyo, Japan.Despite minimal matrix adhered to the specimen, the scans suffered from severe beam hardening artefacts and ghosting, such that the borders of many elements at the surface are difficult to discern. Contrast within the block is relatively poor, especially within the endocranial cavities, which cannot be segmented. Contrast surrounding each cranium is particularly low, and thus details of their morphology cannot be ascertained from the CT scans. However, many of the more robust postcranial bones, including the vertebrae and limbs, can be adequately distinguished from the matrix and each other, and thus are useful for visualizing which parts of the individuals are preserved and how they are arranged, although their morphologies cannot be reconstructed. These images verify the arrangement of the specimens, their positions with respect to each other, and the associations between skulls and postcrania ( Fig. 5 View Figure 5 ). This latter aspect of the arrangement of the skeletons was initially ambiguous because of the unusual positions of the skulls appressed to the sternae. However, CT images show that the cervical vertebrae of each specimen are curled to form a spiral, confirming the ownership of each skull, as interpreted by Funston et al. (2020).

D E SCR I P T I O N

Between the six skeletons known, every skeletal element of Oksoko avarsan is represented ( Figs 3 View Figure 3 , 4 View Figure 4 ). Each of these is exquisitely preserved and has suffered minimal post-mortem scavenging or weathering, and moderate to no crushing. These specimens reveal an oviraptorid with a distinctive cranial crest, short forelimbs with only two functional digits, elongate hindlimbs, and a relatively short tail ( Fig. 3 View Figure 3 ). MPC-D 102/110.a is the most complete skeleton, including a complete skull and skeleton, missing only the distal caudal vertebrae. MPC-D 102/110.b preserves a slightly disarticulated skull, parts of the vertebral column, a forelimb, the pelvis, and the hindlimbs. MPC-D 102/110.c preserves a partial ilium, some vertebrae, and a complete tibiotarsus that was revealed by CT scans. Thus, the individuals in MPC-D 102/110 ( Figs 3 View Figure 3 , 5 View Figure 5 ) provide excellent representation of the skeleton of Oksoko avarsan . Nonetheless, articulation of these specimen means that some elements are not visible in all views, and so some bones are better represented by the completely prepared specimens: MPC-D 100/33, MPC-D 102/11.a, MPC-D 102/12, and the fully prepared manus of MPC-D 102/110.a.

Cranial skeleton

The skulls of MPC-D 102/110.a and MPC-D 102/110.b are complete ( Figs 6 View Figure 6 , 7 View Figure 7 ), but are crushed mediolaterally. The posterior portion of the skull of MPC-D 102/110.b, including the braincase and suspensorium, is disarticulated slightly from the anterior part of the skull and rotated so that it is oriented perpendicular to the remainder of the cranium ( Fig. 6 View Figure 6 ). The skull of MPC-D 102/11.a is relatively complete, but is missing most of the anterior parts of the face, palate, and mandible ( Figs 8 View Figure 8 , 9 View Figure 9 ). The left side of the skull is roughly articulated and is well preserved. The right and posterior sides have been crushed and lie on a single plane parallel to the left side of the skull. Three extra skull bones from a second individual (MPC-D 102/11.b) are preserved alongside the more complete skull of MPC-D 102/11.a: the postorbital, quadratojugal, and quadrate ( Fig. 10 View Figure 10 ). The other specimens (MPC-D 100/33 and MPC-D 102/12) lack cranial elements.

Premaxilla

The premaxilla ( Figs 6 View Figure 6 , 7 View Figure 7 ) is completely preserved in MPC-D 102/110.a and MPC-D 102/110.b, but only a small portion is present in MPC-D 102/11.a ( Fig. 8 View Figure 8 ). It is tall dorsoventrally and constricted anteroposteriorly. Dorsally, it is divided by the naris into two processes: the nasal process extending dorsally and the subnarial process directed posterodorsally. The nasal process is much narrower than the subnarial process in lateral view, unlike in Citipati osmolskae Clark et al. 2001 , Khaan mckennai Clark et al. 2001 , Nemegtomaia barsboldi ( Lü et al. 2004) , and Rinchenia mongoliensis ( Barsbold 1986) , where these processes are subequal in width ( Barsbold 1986, Clark et al. 2001, 2002, Lü et al. 2004, Balanoff and Norell 2012, Funston et al. 2018). In contrast, the nasal process is wider than the subnarial process in Banji long Xu and Han 2010, Huanansaurus ganzhouensis Lü et al. 2015 , and Tongtianlong limosus Lü et al. 2016 . The nasal process of Oksoko curves posterodorsally so that it forms a small part of the continuous semicircular crest with the nasals, frontals, and parietals, but not to the same extent as the anteroposteriorly broad premaxilla of Tongtianlong limosus . In Oksoko avarsan , the nasal process extends dorsally to the ventral third of the naris, whereas in Banji long and Rinchenia mongoliensis the premaxilla extends far above the naris (Xu and Han 2010, Funston et al. 2018). The subnarial process of the premaxilla is broad and tapers posteriorly. Posteriorly, it separates the lacrimal and nasal anteriorly and prevents the maxilla from contacting the nasal on the lateral surface of the skull. The lateral surface of the body of the premaxilla is pierced by multiple small foramina. Ventral to the small, oval naris, there is a lateral depression in the premaxilla similar to that of Citipati osmoslkae ( Clark et al. 2001) , but shallower than the prominent fossa in Banji long (Xu and Han 2010). The occlusal margin of the premaxilla has at least two denticulations, but this area is broken in both individuals and there may have been more. The occlusal edge of the premaxilla is relatively longer anteroposteriorly than in Rinchenia mongoliensis or Corythoraptor jacobsi Lü et al. 2017 , more comparable to Citipati osmolskae or Nemegtomaia barsboldi . The palatal surface of the premaxilla cannot be seen on any of the specimens.

Maxilla

The maxilla ( Figs 6 View Figure 6 , 7 View Figure 7 ) is missing in MPC-D 102/11.a and poorly preserved in both individuals of MPC-D 102/110, but best observed in MPC-D 102/110.b ( Fig. 6B View Figure 6 ). The antorbital fossa is small and the antorbital fenestra is divided in two by a dorsally expanding strut of bone ( Fig. 6B View Figure 6 ), as in most oviraptorids. The jugal process is relatively short and extends only partway under the orbit. The labial–buccal transition on the lateral side of the maxilla is marked by a ridge, ventral to which there is a pronounced lateral tubercle, as in Rinchenia mongoliensis ( Funston et al. 2018) . The presence of longitudinal palatal ridges on the maxilla, as exhibited in Citipati , cannot be determined because of overlying matrix. Likewise, the maxillovomeral tubercle (=palatal ‘tooth’), which is present in all oviraptorids, is obscured by matrix in MPC-D 102/110, so the contribution of the maxilla cannot be determined.

Nasals

The fused nasals ( Figs 6–9 View Figure 6 View Figure 7 View Figure 8 View Figure 9 , 11 View Figure 11 ) are complete but crushed in both individuals of MPC-D 102/110. Only the posterolateral wings of the nasals are preserved in MPC-D 102/11.a ( Figs 8 View Figure 8 , 9 View Figure 9 , 11 View Figure 11 ). In this individual, the nasals are fused along the midline, but posteriorly a suture is still visible ( Fig. 11 View Figure 11 ). Like Rinchenia mongoliensis and Corythoraptor jacobsi , the great size of the nasals is mostly due to expansion of the lateral descending processes. Similar to Citipati osmolskae ( Clark et al. 2001) and Khaan mckennai ( Balanoff and Norell 2012) , the posterodorsal part of the premaxilla excludes the maxilla from contributing to the naris and from contacting the nasal on the lateral surface of the skull. The elliptical naris is displaced far dorsally, unlike Huanansaurus ganzhouensis and Tongtianlong limosus , and overlies the antorbital fenestra, similar to Citipati osmolskae ( Clark et al. 2001) , but differing from the elongate naris of Banji long (Xu and Han 2010), which extends further ventrally. In Oksoko , the naris extends above the dorsal margin of the orbit; posteriorly its ventral margin is level with the top of the orbit. In contrast, the naris is smaller and situated further anteroventrally in Rinchenia mongoliensis and probably Corythoraptor jacobsi (contra Lü et al. 2017). In Oksoko , the anterior midline process forms less than half the length of the nasal, and curves anteroventrally to meet the posterodorsal process of the premaxilla. It lacks the step-like process present in Banji long that demarcates the posterior extent of the premaxillo-nasal crest. In lateral view ( Figs 6 View Figure 6 , 7 View Figure 7 , 8 View Figure 8 ), the anterior midline process of Oksoko is broad dorsoventrally, the result of a septal ridge on its ventral surface. The lateral descending processes host several pneumatic cavities, which vary in position between each specimen. In the better-preserved MPC-D 102/11.a ( Figs 8 View Figure 8 , 11 View Figure 11 ), the midline rami of the fused nasals are thickened and rounded dorsally, delimiting a lateral recess in which the pneumatic cavities lie. These complex asymmetric pneumatic pockets are similar to those of MPC-D 100/42 and Citipati osmolskae and Banji long, and appear to fully penetrate the nasal and open into the nasal passage, but they are not as extensive as in Corythoraptor jacobsi or Rinchenia mongoliensis , where they form a honeycomb-like internal structure. The buttress formed by the fused nasals above the pneumatic pockets in Oksoko is confluent with the similarly thickened dorsal parts of the frontals and parietals. Together, they form a raised rim on the dorsal margin of the cranial crest. The posterior suture with the frontal is simple and straight, like in Citipati osmolskae ( Clark et al. 2001) , and does not have the interdigitating irregularity present in Khaan mckennai and Tongtianlong limosus ( Balanoff and Norell 2012, Lü et al. 2016). The fused nasals are arched transversely so that their wing-like posterolateral processes are nearly vertically oriented, as in Corythoraptor jacobsi and Rinchenia mongoliensis . Although this may be exaggerated by transverse crushing of the skulls in MPC-D 102/110, a similar arched morphology is present in an undeformed skull of Citipati osmolskae (MPC-D 100/978; Clark et al. 2001), where the nasals contribute to a cranial crest.

Lacrimal

The lacrimal ( Fig. 6B View Figure 6 ) is well preserved in all three skulls, but best observed in MPC-D 102/110.b. The lacrimal contacts the nasal dorsally, the maxilla and premaxilla anteriorly, and the frontal posteriorly above the orbit. Like other oviraptorids, the lacrimal has a poorly developed anterior nasal process, and lacks the T-shape present in Caudipteryx zoui Qiang et al. 1998 and deinonychosaurs. The foramen for the lacrimal duct faces anteriorly and opens into a shallow subhorizontal channel on the lateral surface of the lacrimal. The pneumatic pockets seen on Banji long (Xu and Han 2010), Citipati osmolskae ( Clark et al. 2001) , Khaan mckennai ( Balanoff and Norell 2012) , and Tongtianlong limosus are present on only one individual, MPC-D 102/110.b. The frontal process is long, but does not extend posteriorly past the nasal. A triangular process of the frontal separates the lacrimal from the dorsal edge of the orbit, creating a Z-shaped suture in lateral view. The jugal process curves posteroventrally to meet the jugal, forming an inclined posterodorsal margin to the antorbital fenestra. The preorbital bar of the lacrimal is anteriorly pierced at its midlength by a small, vertical slit that communicates with the orbit. The preorbital bar is flared slightly laterally, its posterior margin is broadly concave, and it forms the entire anterior margin of the orbit.

Frontal

The frontal ( Figs 6–9 View Figure 6 View Figure 7 View Figure 8 View Figure 9 , 11 View Figure 11 ) is well preserved in each skull. It is taller dorsoventrally than long anteroposteriorly, which is unusual for a theropod. It forms most of the dorsal part of the orbit, with the postorbital, and is invaded by the supratemporal fenestra posteriorly. It tapers dorsally, so that it is longer anteroposteriorly above the orbit than on the dorsal margin of the cranial crest. It contacts the lacrimal and nasal anteriorly, the postorbital laterally, the parietal posteriorly, and the laterosphenoid posterolaterally. The postorbital process is elongated dorsoventrally to accommodate the tall frontal process of the postorbital, and continues dorsally as a distinct ridge separating the supraorbital and supratemporal portions of the frontal. The supraorbital part of the frontal is concave laterally, and has a dorsoventrally oriented pneumatic depression on most of its lateral surface. The supratemporal part of the frontal is not pierced by pneumatic openings, but the breakage pattern on the left side of MPC-D 102/11.a suggests that it may have been hollow above the braincase, as in Citipati osmolskae ( Clark et al. 2001) . Unlike MPC-D 102/110, the frontals of MPC-D 102/11.a are not fused, but all three individuals have a simple, straight contact. The frontals are separated only slightly posteriorly by the parietals, with which they have a simple, obtusely angled contact. The supraorbital rim lacks a supraciliary lip, which is the case in Citipati osmolskae ( Clark et al. 2001) , but not in Khaan mckennai ( Balanoff and Norell 2012) . The dorsal surface of the orbit is badly crushed in all individuals, but appears to have a groove posteriorly.

Parietal

The parietal ( Figs 6–9 View Figure 6 View Figure 7 View Figure 8 View Figure 9 , 11 View Figure 11 ) is preserved in each skull. It is tall dorsoventrally, similar to Tongtianlong limosus , but this has probably been slightly exaggerated by transverse crushing in each individual. The parietals of MPC-D 102/11.a are fused completely, although a furrow is still visible on the dorsal midline ( Fig. 11 View Figure 11 ). The lateral surface of the parietal is deeply concave, to accommodate mandibular adductor musculature. The sagittal crest is tall, extending about 20 mm above the apex of the nuchal crest in MPC-D 102/11.a, and is transversely expanded, tapering posteriorly. The nuchal crest is pronounced, like in Huanansaurus ganzhouensis , and merges at the midline with the sagittal crest. The posterior end of the sagittal crest is near the apex of the cranial crest, posterior to which the skull roof descends steeply ( Figs 6 View Figure 6 , 7 View Figure 7 , 12 View Figure 12 ). A similarly sloped skull roof is present in most oviraptorids, except Banji long (Xu and Han 2010), Conchoraptor gracilis Barsbold 1986 ( Funston et al. 2018), Khaan mckennai ( Balanoff and Norell 2012) , and Yulong mini Lü et al. 2013 . The parietal contributes only to the posterior half of the medial surface of the supratemporal fenestra, contrasting with Khaan mckennai ( Balanoff and Norell 2012) , where it forms the majority of this surface. The transversely straight but dorsally arched occipital margin of the parietal is the widest point of the bone ( Fig. 11 View Figure 11 ). In MPC-D 102/110.a, b, the arched margin of the parietal contacts the supraoccipital and exoccipital posteriorly and the squamosal laterally.

Jugal

The jugal ( Figs 7 View Figure 7 , 8 View Figure 8 ) is best observed in MPC-D 102/110.a and MPC-D 102/11.a. It is triradiate and relatively robust compared to other oviraptorids, but remarkably similar to that of Banji long (Xu and Han 2010) and somewhat similar to Huanansaurus ganzhouensis and Tongtianlong limosus ( Lü et al. 2015, 2016). Unlike most oviraptorids where the ventral margin of the jugal is straight or dorsally arched, in Oksoko it is slightly sinuous, also similar to Huanansaurus ganzhouensis and Tongtianlong limosus . The maxillary process is dorsoventrally broad towards its posterior base and tapers anteriorly where it meets the lacrimal and maxilla. The postorbital process is wide in lateral view, and has an anterior facet for the postorbital that extends ventrally only a third of the length of the postorbital process. In Citipati osmolskae ( Clark et al. 2001) and Khaan mckennai ( Balanoff and Norell 2012) this facet extends much further ventrally, almost to the junction of the postorbital process and the other two processes of the jugal. The quadratojugal process of the jugal is short and laterally overlies the quadratojugal. It is much shorter and more robust than that of Rinchenia mongoliensis ( Funston et al. 2018) , where it is bifurcated posteriorly to interfinger with the quadratojugal.

Postorbital

The postorbital ( Figs 6–8 View Figure 6 View Figure 7 View Figure 8 , 10 View Figure 10 ) is preserved in all of the articulated skulls and an isolated postorbital is present with MPC-D 102/11.b ( Fig. 10 View Figure 10 ). The postorbital is tall and its frontal process is vertical, which distinguishes this taxon from all other oviraptorids, except Rinchenia mongoliensis ( Funston et al. 2018) . In other oviraptorids, the frontal process is oriented anterodorsally, and is typically shorter than the jugal process. In MPC-D 102/11.a ( Figs 8 View Figure 8 , 10 View Figure 10 ) and MPC-D 102/110.b, the jugal process is shorter than the frontal process, and only forms half of the posterior orbital margin. It is slightly longer in MPC-D 102/110.a ( Fig. 7 View Figure 7 ), where it forms almost two-thirds of the orbital margin. Overall, the jugal process is less robust and more gently curved than in Corythoraptor jacobsi , Huanansaurus ganzhouensis , or Tongtianlong limosus ( Lü et al. 2015, 2016, 2017), but is similar in these respects to Citipati osmolskae ( Clark et al. 2001) . The anterior (orbital) margin of the postorbital is strongly sinuous, with a concave orbital portion and a convex frontal portion. In most oviraptorids, the anterior margin of the postorbital is smoothly concave. The squamosal process is unbroken only in MPC-D 102/110.b, where it is dorsoventrally broad and anteroposteriorly short.

Squamosal

The squamosal ( Figs 6–9 View Figure 6 View Figure 7 View Figure 8 View Figure 9 ) forms the posterodorsal corner and upper margin of the subrectangular infratemporal fenestra. The postorbital process has a lateral rugosity and a dorsolateral groove for the postorbital. The lateral aspect of the squamosal is divided into two main parts by a curved ridge that delimits the corner of the infratemporal fenestra ( Fig. 12 View Figure 12 ). Anteroventral to this ridge, the squamosal is laterally depressed and probably would have anchored adductor musculature. Medially the squamosal has an anteroposteriorly wide contact with the parietal, best observed in MPC-D 102/110.b ( Fig. 6B View Figure 6 ). The squamosal bifurcates ventrally, as in all oviraptorids. The posterior process contacts the paroccipital process of the exoccipital and encapsulates the external auditory meatus. Ventromedially, the squamosal contacts and fuses to the quadrate, and ventrolaterally it contacts the quadratojugal, where it borders the external auditory meatus.

Quadratojugal

The triradiate quadratojugal ( Figs 6–10 View Figure 6 View Figure 7 View Figure 8 View Figure 9 View Figure 10 ) is not fused to the quadrate, even in the large, isolated individual (MPC-D 102/11.b; Fig. 10 View Figure 10 ) associated with MPC-D 102/11.a. The anterior process lies medial to the jugal and forms about two-thirds of the ventral margin of the infratemporal fenestra. Dorsally, the ascending process forms at least half of the posterior border of the infratemporal fenestra, although its full extent is obscured by fusion to the squamosal. The ascending process contacts the quadrate along most of its length, but is separated ventrally by a quadrate foramen. The posterior process of the quadratojugal forms a cap on the lateral surface of the quadrate, and has a tab-like posteroventral extension. The posterior process is relatively long, comparable to Banji long Xu and Han 2010, Citipati osmolskae ( Clark et al. 2001) , and Nemegtomaia barsboldi ( Fanti et al. 2012) .

Quadrate

The quadrate ( Figs 6–10 View Figure 6 View Figure 7 View Figure 8 View Figure 9 View Figure 10 ) is poorly exposed in MPC-D 102/110, and in MPC-D 102/11.a it is badly damaged on the left and preserved only in posterior view on the right ( Fig. 9 View Figure 9 ). The isolated right quadrate from MPC-D 102/11.b is incomplete, but useful for determining morphology ( Fig. 10 View Figure 10 ). Medially, the quadrate contacts the parasphenoid, pro-otic, and pterygoid; laterally, the quadratojugal; and dorsally, the squamosal. It does not appear to contact the exoccipital/opisthotic extensively, although on both sides of MPC-D 102/11.a these bones are disarticulated and this area is not visible in the skulls of MPC-D 102/110. The optic wing of the quadrate is oblique to the midline, extending anterodorso-medially to postero-ventro-laterally, and covers most of the lateral surface of the braincase. Anteriorly, the optic wing of the quadrate contacts the epipterygoid. At this point, it also contacts the pterygoid ventrally. The condyles of the quadrate are saddle-shaped as in other oviraptorosaurs. There is a large, vertically oriented, oval quadratojugal foramen, formed entirely by excavation of the quadrate. Just medial to this, on the posterior side of the quadrate, there is a deep depression. There is a vertical ridge on the posterior surface of the quadrate, just lateral to the optic wing. The lateral surface of the quadrate contacts—but is not fused with—the quadratojugal, and this contact is raised into a distinct process with a cotyle bifurcated by a ridge.

Palatal skeleton

The palatal skeleton is incomplete in MPC-D 102/11.a ( Figs 8 View Figure 8 , 9 View Figure 9 ), with only the pterygoids, ectopterygoids, and a small part of the right palatine preserved. In MPC-D 102/110, the palatal skeleton is mostly obscured by the overlying mandible ( Fig. 6 View Figure 6 ). The ectopterygoid has a dorsally curved maxillary process, which would have contacted the maxilla dorsally and the palatine anteriorly. Anteriorly, the pterygoid has a crescentic contact with the ectopterygoid in lateral view, as in almost all oviraptorids, although this suture appears more pointed in Banji long (Xu and Han 2010) than in Oksoko avarsan . The ramus of the pterygoid is short anteroposteriorly, tall dorsoventrally, and concave on its ventral surface. The pterygoid ramus lacks the deep dorsal excavation present in Banji long (Xu and Han 2010). The pterygoids are separated by an interpterygoid vacuity like in Jiangxisaurus ganzhouensis ( Wei et al. 2013) , and like other oviraptorosaurs ( Clark et al. 2002, Balanoff et al. 2009), the pterygoid lacks a transverse flange, although this area is poorly exposed in MPC-D 102/11.a. The pterygoid has a broad posterodorsally facing contact with the quadrate, from which it tapers anteriorly. Posteriorly, it underlies the optic wing of the quadrate, and is mostly obscured by crushing. At its posterior end, it is dorsoventrally tall and transversely thin. At this point, it contacts the basipterygoid process of the basisphenoid medially.

Occiput

The occiput is not visible on either skull of MPC-D 102/110 ( Fig. 6 View Figure 6 ). In MPC-D 102/11.a ( Figs 9 View Figure 9 , 13 View Figure 13 ) it is well preserved and none of the bones of the occiput are fused, although the basioccipital and basisphenoid have begun to co-ossify. The trapezoidal supraoccipital is disarticulated from the rest of the occiput. The facets for the exoccipitals on the supraoccipital are separated by a groove, indicating that the supraoccipital contributed to the foramen magnum. The supraoccipital tapers anterodorsally, where it would have fit between the squamosal processes of the fused parietals. The dorsal surface of the supraoccipital bears two longitudinal, shallow, elliptical depressions. The ventral surface of the supraoccipital has a lateral lamina on each side, which would have formed the walls of the foramen magnum. The exoccipitals were not yet fused to the basioccipital, similar to Banji long, the holotype of which probably also represents a juvenile individual (Xu and Han 2010). Both exoccipitals have been rotated anterolaterally from life position, which exposes their medial sides ( Fig. 13 View Figure 13 ). A medioventral process indicates that the exoccipital formed only the dorsolateral corner of the occipital condyle. The exoccipital is thickened dorsomedially where it contacts the supraoccipital, and tapers laterally towards the dorsal border of the paroccipital process. The paroccipital process curves ventrally, and has a raised, undulating lateral edge. Medially, the base of the paroccipital process has a depression, which is bordered laterally by a rounded ridge that extends along the long axis of the paroccipital process. On the medial (internal) surface, which forms the posterior wall of the foramen magnum, there are multiple foramina ( Fig. 13D View Figure 13 ). The largest, the metotic foramen, remains filled with matrix, but presumably housed the foramen for cranial nerves IX, X, and XI, as in Incisivosaurus and deinonychosaurians ( Currie and Zhao 1993, Currie 1995, Balanoff et al. 2009). The opening of the metotic foramen on the external surface of the braincase is not visible in MPC-D 102/11.a because of the dislocation of the exoccipitals, and this area has not been fully prepared in MPC-D 102/110.a and MPC-D 102/110.b. Posteroventral to the metotic foramen are three internal foramina for cranial nerve XII ( Fig. 13D View Figure 13 ), one extra compared to Incisivosaurus , where there are two. Cranial nerve XII also exits through two foramina on the exterior surface of the exoccipital ventrolateral to the occipital condyle ( Fig. 13C View Figure 13 ). On the internal surface of the foramen magnum, dorsal to the foramina for cranial nerve XII, is a small foramen set in a concavity, for the ductus endolymphaticus ( Fig. 13D View Figure 13 ). The basioccipital is articulated with the basisphenoid, and although they have begun to co-ossify in this individual, they were not yet fully fused. The occipital condyle is kidney-shaped, and has a ventrally constricted neck. The basal tubera are situated ventral to the occipital condyle in posterior view ( Fig. 13 View Figure 13 ), rather than level with it as in Citpati osmolskae ( Clark et al. 2001: fig. 6). The basal tubera are not widely spaced and are relatively small, which may be a consequence of the early developmental stage of MPC-D 102/11.a. The basisphenoid is not well exposed in MPC-D 102/11.a, but several features can be discerned. It has begun to co-ossify with the basioccipital, but there is still a suture. The basipterygoid processes face ventrolaterally, and are separated by a dorsoventrally oriented groove. This groove extends dorsally to the basisphenoid recess. Lateral wings of the basisphenoid extend dorsally to encapsulate the basioccipital, and contact the exoccipital and probably pro-otic.

Braincase wall

Most of the lateral wall of the braincase is obscured by the overlying bones in MPC-D 102/110 ( Fig. 6 View Figure 6 ), but on the left side of MPC-D 102/11.a parts of the laterosphenoid and parasphenoid are exposed ( Fig. 8 View Figure 8 ). The laterosphenoid extends dorsally into the supratemporal fenestra, terminating just dorsal to the supratemporal bar in lateral view. Only the anterior part of the pro-otic is exposed, where it is pierced by the large foramen ovale. For such a delicate element, the parasphenoid rostrum is exceptionally preserved in MPC-D 102/11.a ( Fig. 8 View Figure 8 ). It occupies the space dorsal to the interpterygoid vacuities, and has been taphonomically shifted dorsally so that it lies at the centre of the orbit. It is transversely narrow but dorsoventrally tall and straplike. The anterior end is modified into a ‘boot’, superficially similar in shape to the pubic boot of most oviraptorosaurs. At its posterior end, it is pierced by two small foramina.

Scleral ossicles

Dozens of small, crushed plates of bone are present in the orbits of both MPC-D 102/110.a–b ( Figs 6 View Figure 6 , 7 View Figure 7 ). The more complete plates are roughly square, with rounded corners. The largest is 6.5 mm in height and 9 mm in length, about 20% the anteroposterior length of the orbit.

Mandible

The lateral surface of the mandible is well preserved in MPC-D 102/110.a ( Figs 6 View Figure 6 , 7 View Figure 7 ), but is mostly missing from MPC-D 102/11.a. The dentary is tall and downturned anteriorly like in Jiangxisaurus ganzhouensis ( Wei et al. 2013) , but with a pronounced ventral chin. The occlusal margin is concave anterodorsally and the labial surface is marked by minute foramina. The posterodorsal ramus is broad and strap-like, tapering posteriorly where it contacts the surangular above the heartshaped external mandibular fenestra, which does not extend as far anteriorly into the dentary as in Banji long (Xu and Han 2010). The posteroventral ramus of the dentary is long, extending as far as the surangular fossa on the lateral side of the surangular, and it tapers where it underlies the angular. The coronoid process is tall and protrudes far above the rest of the mandible, but does not appear to be medially deflected like it is in Jiangxisaurus ganzhouensis ( Wei et al. 2013) . The dorsal margin of the mandible has only a single apex, in the surangular, rather than two apices, as is the case in Huanansaurus ganzhouensis and the Dzamyn Khondt oviraptorid. The surangular prong is broken in MPC-D 102/110.a, but appears to be present in MPC-D 102/110.b. The angular is straplike and extends to the anterior end of the external mandibular fenestra. The surangular has a deep recess, which may have housed a surangular foramen, but this region is broken. The articular has a tall, convex articular ridge and a small, posteriorly directed retroarticular process. As in Rinchenia mongoliensis ( Funston et al. 2018) , and unlike all other oviraptorosaurs, the retroarticular process of MPC-D 102/110.a is composed predominantly of the surangular, rather than including a contribution from the angular. The presence of a coronoid, reported only occasionally but probably present throughout Oviraptorosauria ( Clark et al. 2002, Balanoff et al. 2009, Funston and Currie 2020), cannot be determined because none of the mandibles can be observed in medial view.

Ceratobranchial

A long, rod-shaped ceratobranchial is preserved just lateral to the mandible of MPC-D 102/110.a ( Fig. 7 View Figure 7 ). The anterior end of the element is expanded dorsoventrally. The shaft is straight and cylindrical, unlike the curved ceratobranchial of Citipati osmolskae ( Clark et al. 2001) . The ceratobranchial is nearly half the length of the mandible, and about one-third the length of the skull.

Axial skeleton

Alongside the anteriormost cervical vertebrae, only the posterior sacral vertebrae and the ventral surfaces of the caudal vertebrae are exposed in MPC-D 102/110 ( Fig. 3 View Figure 3 ). The axial skeleton of MPC-D 102/11.a is represented by an incomplete atlas, a partial axis, two anterior cervical vertebrae ( Fig. 9 View Figure 9 ), four posterior dorsal vertebrae, a sacrum composed of three co-ossified vertebrae, and a complete caudal series. A nearly complete vertebral column is known from MPC-D 102/12, although it is missing the sacrum and the anterior cervical vertebrae. Only the sacrum and caudal vertebrae are currently mounted with MPC-D 100/33, but photographs taken in September 2001 by P. Currie show a nearly complete axial series, including the atlas–axis, anterior cervical vertebrae, dorsal vertebrae, a sacrum, and caudal vertebrae. Together, the vertebrae from all specimens represent the entire axial column, and most positions are represented by multiple individuals.

Cervical vertebrae

There are 12 cervical vertebrae, including the atlas and axis ( Fig. 14 View Figure 14 ). The anterior cervical vertebrae of MPC-D 102/11.a ( Fig. 9 View Figure 9 ) are incompletely ossified, and their articulation with the base of the skull obscures the morphology of the centra. The neural arches are not fused to the centra and have low neural spines. The right side of the neural arch of the atlas is exposed and is separate from the left, but the two halves would probably have fused later in life.The atlas intercentrum and the odontoid process of the axis are missing, so their morphology cannot be discerned. The axis has an anteroposteriorly long neural spine, which is transversely thickened distally and extends posteriorly past the centrum. The first postaxial cervical vertebra has a relatively tall and fingerlike neural spine, although the rest of the neural arch is broad and dorsoventrally flattened, typical of oviraptorosaurs ( Balanoff and Norell 2012). MPC-D 102/12 and MPC-D 100/33 provide more information on the entire cervical vertebral series ( Fig. 14 View Figure 14 ). The atlas–axis ( Fig. 14C View Figure 14 ) of MPC-D 100/33 is tightly adhered, but sutures are still visible between the atlas intercentrum and the axis. The neuropophyses of the atlas are fused to each other along the midline and have begun to co-ossify with the intercentrum. The neural spine of the axis is missing in this specimen, but its morphology is bulbous in MPC-D 102/110 and MPC-D 102/11.a ( Fig. 9 View Figure 9 ). In contrast, the neural spine of the third cervical is peglike ( Fig. 9 View Figure 9 ). The centra of the anterior cervical vertebrae have steeply inclined articular faces and widely spaced parapophyses, resulting in a triradiate appearance in ventral view ( Fig. 14F View Figure 14 ). Each has a deep, lateral pleurocoel and a concave, posterior articular surface.The neural arches are as wide as they are long and have large, circular, dorsomedially facing, anteriorly extending prezygapophyses. These are connected to the postzygapophyses by a broad lamina, from which the transverse processes barely protrude. Large, moundlike epipophyses ( Fig. 14E View Figure 14 ) sit on the dorsal surfaces of the postzygapophyses, seemingly comparable to those in Jiangxisaurus ganzhouensis and Tongtianlong limosus ( Wei et al. 2013, Lü et al. 2016), and these appear to become larger in more posterior vertebrae, like in Huanansaurus ganzhouensis ( Lü et al. 2015) . The neural spines are low and square. Based on their absence, the cervical ribs had not yet fused in MPC-D 100/33, but in MPC-D 102/12, some appear to have fused to the parapophyses. MPC-D 102/12 is missing the anterior cervical vertebrae but preserves the mid and posterior cervical vertebrae. The centra become relatively taller posteriorly along the cervical vertebral series ( Fig. 14B View Figure 14 ), and this is accompanied by broadening of the neural arches so that they are wider than they are long, like in Khaan mckennai and Tongtianlong limosus . The centra retain large pleurocoels, but the articular faces become less inclined posteriorly along the series. Regardless, the posterior articular face remains concave throughout the series. The transverse processes become better developed and fuse to the cervical ribs, which decrease in relative length successively. The epipophyses are large until about the eighth postaxial cervical vertebra, after which they decrease in size.

Dorsal vertebrae

A complete dorsal vertebral series is preserved with each of MPC-D 102/12 and MPC-D 100/33, although they are better preserved in MPC-D 102/12 ( Fig. 15 View Figure 15 ). The posterior dorsal vertebrae, the sacral vertebrae, and four of the anterior caudal vertebrae are articulated with the right ilium of MPC-D 102/11.a ( Fig. 16 View Figure 16 ). The dorsal vertebral series comprises 10 vertebrae, which increase in size successively. The anterior three vertebrae have hypapophyses, which are largest on the anterior one and smallest on the posterior one. The centra are barrel-shaped with a ventral keel and develop a ventral curve in lateral view towards the posterior end of the series. This is accompanied by an increase in the size of the lateral pleurocoel—which is present on all dorsal vertebrae—and a transverse broadening of the centrum. In MPC-D 102/12, the neural arches are fused to the centra, and in most cases the suture is closed ( Fig. 15 View Figure 15 ). This is not the case in MPC-D 100/33, where the neural arches are not fused and in many cases have become disarticulated. The parapophyses of MPC-D 102/12 are large and concave. They become more dorsally positioned posteriorly along the dorsal vertebral series, transitioning from a location exclusively on the centrum (D1–D5), to bridging the neurocentral suture (D6–D8), to exclusively on the neural arch (D9, D10). The neural arches are deeply excavated by infraprezygapophyseal, infradiapophyseal, and infrapostzygapophyseal fossae, which in some cases have merged, leaving a strut of bone remaining ( Fig. 15H View Figure 15 ). The infraprezygapophyseal fossae become shallower in more posterior vertebrae, whereas the infradiapophyseal and infrapostzygapophyseal fossae remain deep throughout. The neural spines become taller until D8, after which they are slightly shorter.

Sacral vertebrae

There are six sacral vertebrae ( Fig. 16 View Figure 16 ), which are all fused in MPC-D 100/33. In contrast, only three vertebrae have been co-ossified to form the sacrum in MPC-D 102/110.a, MPC-D 102/110.b, and MPC-D 102/11.a ( Fig. 16B View Figure 16 ), which reflects the early ontogenetic stages of these individuals. Like all oviraptorosaurs, the centra of the sacrum have large, lateral pleurocoels and are flattened ventrally. However, they are not flattened to the same degree as in caenagnathids and the pleurocoels sit above the ventral surface of the sacrum rather than opening to the ventral surface. The second sacral vertebra shows an incipient ventral keel, whereas sacral vertebrae 3–6 have a midline groove. The anterior sacral neural arches of MPC-D 100/33 are missing, but the posterior ones have fused together into a fan-like sheet of bone. In MPC-D 102/11.a, the neural spines remain separate dorsally ( Fig. 16A View Figure 16 ), but their ventral bases have begun to fuse. Unlike in caenagnathids, the transverse processes and their accompanying sacral ribs do not vary in position along the sacral series. Rather, in each vertebra they are consistently located at the level of the neurocentral suture. As in caenagnathids, however, the transverse process and sacral rib of sacral vertebra 5 appear to be the largest, although not forming the same hatchet-shaped process. The lack of sacral fusion in MPC-D 102/11.a provides insight into the somitic origin of the sacral series. The three fused sacral vertebrae probably represent the primordial sacral vertebrae, based on the extent of their fusion early in life. Indeed, three sacral vertebrae are fused even before hatching in oviraptorids ( Norell et al. 2001). Accordingly, the anteriormost sacral vertebra must have been recruited from the dorsal series and two caudosacral vertebrae must have been incorporated from the tail ( Fig. 16A View Figure 16 ). This is supported by the morphology of these vertebrae, which most closely resemble the dorsal and caudal vertebrae, respectively.

Caudal vertebrae

The complete caudal vertebral series of Oksoko avarsan would have had 29 caudal vertebrae, the last three of which fuse into a pygostyle later in life for a total count of 27 caudal vertebrae ( Fig. 17 View Figure 17 ). MPC-D 102/11.a preserves 27 of the 29 caudal vertebrae ( Fig. 17B View Figure 17 ), and is missing only the last two pygal vertebrae. MPC-D 102/12 has the complete pygal series, but is missing the proximal caudal vertebrae ( Fig. 17C View Figure 17 ), which were presumably lost at the same time as the sacral vertebrae, resulting in a total of 27 vertebrae, the last three of which are fused into the pygostyle. MPC-D 100/33 has 23 caudal vertebrae from the middle part of the tail, missing both the proximal and distal vertebrae. MPC-D 102/110.a–c preserve seven, four, and seven caudal vertebrae, respectively, from the base of the tail, but are missing the distal parts of the tail. The centra of the proximal caudal vertebrae have pleurocoels, like in Jiangxisaurus ( Wei et al. 2013) , although in Oksoko they are reduced in size relative to the dorsal and sacral vertebrae. From the 19th caudal vertebra to the tip of the tail, pleurocoels are absent. In MPC-D 102/12, some of the proximal pleurocoels have become infilled with bone, but their borders can still be discerned ( Fig. 17D View Figure 17 ). The centra of the caudal vertebrae are barrel-shaped, rather than anteroposteriorly elongated as in many theropods. Posteriorly along the vertebral series, each centrum is slightly more elongate relative to its height ( Fig. 17H–J View Figure 17 ), but not to the degree seen in theropods like deinonychosaurs, ornithomimids, and tyrannosaurs. In MPC-D 102/11.a, the anterior neural arches are not fused to the caudal vertebrae, but the 17 posteriormost vertebrae have neural arches that are fused with a closed suture. In contrast, all of the caudal vertebrae of MPC-D 102/12 have fused neurocentral sutures. The neurocentral fusion of the posterior caudal vertebrae and the lack of fusion in all the other vertebrae of MPC-D 102/11.a suggests that closure of the neurocentral sutures proceeds posterior to anterior, as in crocodylians ( Brochu 1996, Irmis 2007). This lends support to previous suggestions that closure of the neurocentral sutures in the cervical vertebrae provides evidence of maturity in oviraptorosaurs (Funston and Currie 2016). There is a relatively large infradiapophyseal fossa below the high transverse process on the anterior caudal vertebrae. In MPC-D 102/12, this is accompanied by a supradiapophyseal fossa on the anterior two caudal vertebrae. The transverse processes descend progressively towards the lateral surface of the centra posteriorly and become shorter mediolaterally. Their orientation also changes from being directed posteroventrally to more directly laterally. In MPC-D 102/11.a, the transverse processes persist until the eighth last vertebra, whereas in MPC-D 102/12 they persist until the last vertebra preceding the pygostyle. However, these distal transverse processes are anteroposteriorly elongate and hatchet-shaped in dorsal view ( Fig. 17I View Figure 17 ), barely protruding from the centrum. Similar transverse processes are present in MPC-D 100/33, but they do not extend as far down the tail, probably representing an intermediate ontogenetic stage of development.

Ribs and gastralia

The dorsal ribs are poorly exposed in MPC-D 102/110 ( Fig. 3 View Figure 3 ), but CT scans show that they are present in MPC-D 102/110.a ( Fig. 5 View Figure 5 ). In this individual, some of the proximal parts of the posterior dorsal ribs are exposed on the left side of the individual, and the distal portions of the shafts of the dorsal ribs are exposed where they are articulated with the gastral basket. Ventral (sternal) ribs are also preserved on the right side of MPC-D 102/110.a ( Fig. 3 View Figure 3 ), where four relatively straight, straplike ventral ribs are associated with the right sternal plate, as in Jiangxisaurus , although the posterior rib is not fused in Oksoko . Each has been displaced to some degree from their natural articulations, but it is clear that the anteriormost and posteriormost ventral ribs are distinctly smaller than the other two ventral ribs, of which the third is largest. The proximal end of each ventral rib is positioned between the sternocoracoidal process and lateral trabecula of the sternum. Two posterior rib heads are preserved with MPC-D 102/11.a, but they provide little information. Four partial ribs are preserved with MPC-D 102/12 ( Fig. 18 View Figure 18 ). The head of the ribs are relatively simple, lacking the pneumatization present in caenagnathids like Apatoraptor pennatus Funston and Currie 2016 . The largest of the four ribs has a broad capitulum, suggesting that it is from the middle part of the dorsal series. On the posterolateral surface of the shaft, there is a facet for the attachment of an uncinate process ( Fig. 18D View Figure 18 ). However, the uncinate process was not recovered with the skeleton. Uncinate processes are not visible in the CT scans of MPC-D 102/110.a, suggesting that they had not yet ossified at this ontogenetic stage. Whether they ossified later in life is unclear. The gastralia are well preserved and articulated in MPC-D 102/110, but not the other specimens. The complete gastral basket is preserved in MPC-D 102/110.a. There are 12 rows of medial gastralia, and lateral gastralia are associated with most of these rows. The right medial gastralia are offset anteriorly from the left gastralia, and anteriorly some of the medial gastralia fuse, as in other theropods.

Chevrons

The anterior chevrons are preserved in MPC-D 102/110.a–c ( Fig. 19A, B View Figure 19 ), and relatively complete series of chevrons are preserved with MPC-D 100/33, MPC-D 102/11.a, and MPC-D 102/12. The anterior chevrons of MPC-D 102/110.a, MPC-D 102/110.c, MPC-D 102/11.a, MPC-D 100/33, and MPC-D 102/12 are elongate and taper distally to a bulbous process ( Fig. 19C View Figure 19 ), similar to Heyuannia yanshini ( Barsbold 1981) ( Funston et al. 2018) . However, the first chevron of MPC-D 102/110.b is unusual and extremely small compared to the other specimens ( Fig. 19B View Figure 19 ), despite similarity in the size of the associated caudal vertebrae. Indeed, the first chevrons of MPC-D 102/110.a, c are more than twice the dorsoventral height of MPC-D 102/110.b. This condition is reminiscent of the dimorphism described in the chevrons of Khaan mckennai , although it is more extreme than in Khaan mckennai ( Persons et al. 2015) . Without a larger sample size, the nature of this dimorphism cannot be determined, although the similarity in size and morphology of MPC-D 102/110.a and MPC-D 102/110.b suggests that it is unlikely to be the result of ontogenetic differences. All of the distal chevrons are preserved with MPC-D 102/11.a ( Fig. 17B View Figure 17 ), and some of the series is preserved with MPC-D 100/33. These are all elongate dorsoventrally, rather than becoming platelike, as is the case in caenagnathids and MPC-D 100/42, the Dzamyn Khondt oviraptorid.

Pectoral girdle

The complete pectoral girdle of MPC-D 100/33 is preserved and was disarticulated during preparation, allowing for detailed description. Both halves of the pectoral girdle are present but the left scapula is missing its distal end and the right coracoid is slightly damaged. The pectoral girdles of MPC-D 102/110.a, b are probably complete, but are mostly obscured by the overlying bodies. The pectoral girdles of MPC-D 102/11 and MPC-D 102/12 are unknown.

Scapula

The scapula is long and gracile ( Fig. 20A–E View Figure 20 ). The distal end is slightly expanded and has a rounded end. In cross-section, the lateral surface of the scapula is flat, whereas the medial side is rounded, which produces a lens-shaped outline. The ventral edge of the scapula is sharp, but the dorsal edge is rounded. The scapular blade thickens transversely and curves medially towards the glenoid. About 30 mm distal to the glenoid, there is a small protrusion on the ventral edge of the blade that may have anchored musculature. Just anterior to this, on the dorsal edge of the blade, there is a shallow groove. The acromion process is small and rounded in dorsal view ( Fig. 20E View Figure 20 ). Its dorsal surface is flat, but this flattened area does not extend far posteriorly, and although it probably contacted the furcula, there is no distinct area marking its articulation. The lateral edge is dorsally upturned and has a rounded, thickened edge. The anterior edge is thick and barely protrudes from the region where it connects medially to the body of the scapula. The acromion does not extend anteriorly past the contact of the scapula and coracoid. The glenoid of the scapula is approximately rectangular in articular view. Its lateral edge extends anterodorsally, whereas its medial edge is parallel to the scapular blade. As a result, the anterior part of the articular surface is exposed laterally ( Fig. 20D View Figure 20 ). The articular surface is slightly concave and tapers transversely towards the posterior side. The unfused contact between the scapula and coracoid is crescentic ( Fig. 20B View Figure 20 ). The anterior surface of the scapula is convex, whereas the posterior side of the coracoid is concave. Accordingly, the scapula has a relatively large, dorsal flange anterior to both the glenoid and acromion, which differs from other oviraptorids like Heyuannia yanshini ( Funston et al. 2018) , where the acromion is the most anterior part of the scapula, or caenagnathids where it is set posterior to the glenoid ( Funston et al. 2021). On the medial side of the head of the scapula, there is a proximodistal groove that extends to the same level as the glenoid. This groove is continuous with a groove leading to the coracoid foramen, so it probably accommodated vasculature and nerves.

Coracoid

The coracoid is long dorsoventrally ( Fig. 20B, D View Figure 20 ). The contact for the scapula is concave and tapers in transverse thickness dorsally. The glenoid is approximately square and faces completely posteriorly, with a slight lateral exposure. The coracoid foramen is oval and oriented with its long axis anteroventrally to posterodorsally. On the medial surface, it is connected to a deep groove that extends to the scapulacoracoid contact. The biceps’ tubercle is relatively large and circular. Its apex is rounded, rather than rugose, and there are no other ridges on the lateral surface of the coracoid. On the medial surface there are two fossae separated by a trabecula that correspond in position to the biceps tubercle ( Fig. 20B View Figure 20 ). The body of the coracoid has two main processes: the posteroventral process and an anteriorly projecting flange—the acrocoracoid process. The latter process is rounded in profile and its apex is thickened. There is a concavity in the edge of the coracoid separating this process from the posteroventral process. This notch is shallower than a similar feature present in the coracoid of Heyuannia yanshini (MPC-D 100/30). The posteroventral process curves strongly posteriorly. It tapers in transverse thickness towards all edges and the apex, except that the apex itself is thickened and bulbous.

Furcula

The furcula is excellently preserved ( Fig. 20F–J View Figure 20 ), and is missing only the very distal ends. The hypocleidium is long and pointed, but is relatively gracile, especially compared to the robust hypocleidium of Citipati osmolskae ( Clark et al. 1999, Norell et al. 2018). In Tongtianlong limosus , the hypocleidium is small ( Lü et al. 2016). The entire furcula is gracile and its curvature follows a rounded V-shape (i.e. the epicleidal processes are not parallel), compared to the U-shaped furcula of Tongtianlong limosus . Each epicleidal process expands transversely to its midpoint, and then tapers again distally. At the midpoint, there is a ventral facet where the furcula contacts and rests upon the acromion process of the scapula ( Fig. 20G, H View Figure 20 ). In lateral view, this facet invades the lateral edge of the bone, which accommodates the upturned lateral edge of the acromion. In articulation, the hypocleidium of the furcula extends nearly to the acrocoracoid process of the coracoid, but a relatively large, lens-shaped triosseal fenestra remains.

Sternum

Both sternal plates are partly exposed in MPC-D 102/110.a, but not in the other individuals of MPC-D 102/110. The sternals are well preserved in MPC-D 100/33 ( Fig.20K, L View Figure 20 ), but were difficult to observe because they were mounted behind glass at the time of observation. The sternal plates are not fused along the midline and their posterior ends are separated. The sternocoracoidal process and lateral trabecula are both well developed, and are separated by an incised notch where the ventral ribs articulated. However, there are no distinct articular facets for the ventral ribs in this notch. Whereas the sternocoracoidal process is pointed in MPC-D 102/110.a, it is rounded and bulbous in MPC-D 100/33, possibly the result of older age and increased ossification. Sternal plates are described and illustrated for Jiangxisaurus ganzhouensis as oval plates, which would be unusual for an oviraptorid. However, this morphology does not match the photographs provided in the article, where the sternal plates appear more similar to other oviraptorids, with well-developed sternocoracoidal processes and lateral trabeculae. Unfortunately, no further comparison with Oksoko is possible based on the limited information available. In Oksoko , at least one foramen consistently pierces the sternal plate, but its position varies. In MPC-D 100/33, it is closer to the sternocoracoidal process ( Fig. 20K, L View Figure 20 ), whereas in MPC-D 102/110.a, it is further medially, near the midline, and consists of two foramina. The right sternal of MPC-D 100/33 has a large fenestra near the centre of the plate ( Fig. 20K View Figure 20 ). It is possible that this is pathological, but it could also be the result of variable ossification of the plates. Unfortunately, the detailed examination necessary to support these hypotheses was not possible.

Forelimb

The right forelimb of MPC-D 100/33 is completely preserved ( Fig. 21 View Figure 21 ), although it appears to be either missing phalanx III-1 or this element had not ossified. The left forelimb is represented by the humerus, ulna, and radius, but the carpals, metacarpals and ungual II-3 are missing. The right humerus, ulna, radius, and manus of MPC-D 102/110.a are exposed ( Fig. 21 View Figure 21 ), as is the left manus. Only the left ulna, radius, and manus of MPC-D 102/110.b are visible, although it is likely that the right forelimb is preserved under the body of MPC-D 102/110.a. The quarry of MPC-D 102/12 was revisited in 2018 and a manual ungual I-2 was recovered, but otherwise the forelimb of that individual is unknown.

Humerus

Both humeri of MPC-D 100/33 are well preserved and identical in size and shape. The humeral head is modestly developed ( Fig. 21A, C View Figure 21 ), but does protrude slightly from the shaft. It is anteroposteriorly thin and appears more like a crest than a condyle. The proximal end is roughly parallelogram-shaped in proximal view ( Fig 21E View Figure 21 ). On the posterior side of the humerus, the articular surface overhangs the surface of the rest of the bone. The deltopectoral crest extends distally from the lateral side of the head, which is anteriorly deflected. The crest thickens towards its apex, which is not downturned like in Heyuannia yanshini (MPC-D 100/30). The edge of the crest is rounded and slightly rugose on either side. The apex of the crest is just under half the length of the humerus (47%) from the proximal end, similar to Jiangxisaurus ganzhouensis and Tongtianlong limosus ( Wei et al. 2013) , but much greater than in citipatiines like Corythoraptor jacobsi , Huanansaurus ganzhouensis , and the Dzamyn Khondt oviraptorid. The anterior surface of the crest is concave, whereas the posterior surface has a plateau with a slightly depressed surface. The ridge outlining its anterior side has faint striations for muscle attachment, but there is no rugose mound like the one in Heyuannia yanshini (MPC-D 100/30). The depression is slightly triangular, tapering distally. The shaft of the humerus is almost perfectly cylindrical, but the anterior face is slightly flattened. There are no ridges or features on the shaft, which has less torsion and is more gracile than that of Heyuannia yanshini and Tongtianlong limosus ( Lü et al. 2016, Funston et al. 2018). The distal end is about as wide as the head and is roughly rectangular in distal view. The entepicondylar tuber is larger than the ectepicondylar tuber ( Fig. 21A, F View Figure 21 ), but both are small compared to the large, anteriorly curving ones of Heyuannia yanshini ( Funston et al. 2018) . In MPC-D 100/33, the entepicondylar tuber is dorsally hooked but does not protrude more than the ectepicondylar tuber, which itself extends proximally as a rounded ridge. In Heyuannia yanshini , this ridge is large and extends far anteriorly to become wing-like. In MPC-D 100/33, the medial side of the condyle is swollen and larger than the lateral side; the opposite is true in Heyuannia yanshini .

Ulna

The ulnae and radii of MPC-D 100/33 and MPC-D 100/110.a, b ( Fig. 21G, H View Figure 21 ) are preserved, but those of MPC-D 100/33 were mounted and unavailable for detailed examination. Like other heyuannines, the antebrachium is shorter than the humerus, whereas in citipatiines, it is longer. The ulna is robust, expanding towards both the proximal and distal ends. The proximal end has a tall, bulbous coronoid process but a poorly developed olecranon, so that the socket for the humerus is poorly pronounced. The shaft tapers in dorsoventral thickness to the distal end, where it instead becomes transversely broad. The distal end of the ulna is crescentic in outline, with a distinct medial process, similar to the one in Heyuannia yanshini (MPC-D 100/30).

Radius

The radius is also robust ( Fig. 21G, H View Figure 21 ), but is only half the thickness of the ulna throughout the shaft, comparatively more gracile than in Jiangxisaurus ganzhouensis . Its proximal end is square and about the same dimensions as the shaft. A slight ridge extends distally from the ventromedial edge, probably to accommodate the interosseum membrane. The distal end is expanded but does not appear to have a styloid process; however, this region is broken in MPC-D 100/33 and not visible in MPC-D 102/110.

Carpals

The carpals ( Fig. 22 View Figure 22 ) of the left hand of MPC-D 102/110.a are excellently preserved, and provide considerable information on the homology and development of the oviraptorid carpals. The radiale is the most proximal carpal ( Fig. 22G, H View Figure 22 ), but it differs in shape from the angular, trapezoidal radiales of most theropods. Instead, it is more rounded and essentially featureless, although it is slightly wedged dorsally ( Fig. 22H–M View Figure 22 ). The semilunate carpal ( Fig. 22A–G View Figure 22 ) is the largest of the wrist and it covers the proximal ends of metacarpals I and II. It is roughly dumbbellshaped, with a flat distal surface and a rounded proximal surface. Its proximal surface forms a distinct trochlea, with which the radiale and the crescentic distal end of the ulna articulate. The dorsal side of the trochlea is slightly smaller than the ventral side, but both are semicircular in lateral view. The flat distal side of the semilunate carpal is divided into two distinct faces separated by a shallow ridge ( Fig. 22F View Figure 22 ). The medial face would have articulated with metacarpal I, although it did not overlie its entire proximal surface ( Fig. 22B, D, E View Figure 22 ). The lateral facet for metacarpal II is concave, and in this depression sit two miniscule carpals, which are closely appressed if not fused ( Fig. 22F, G View Figure 22 ). The larger of these is roughly triangular, and the smaller one is spherical. These carpals would have separated the proximal ends of the metacarpal I and metacarpal II in life ( Fig. 22B View Figure 22 ). It is unclear whether these minute carpals are sesamoid bones, or if they represent the vestiges of the intermedium and ulnare, which typically lie lateral to the semilunate carpal and cover the proximal ends of metacarpals II and III. In the latter case, the larger element would more likely be the intermedium, whereas the smaller element would be the ulnare ( Fig. 22F, G View Figure 22 ). However, this would necessitate a reorganization of the carpal region, as these carpals are typically proximal to the semilunate carpal, rather than distal. Thus, the interpretation that they represent sesamoid ossicles is preferred here. Further work and disarticulation of the carpal regions of other well-preserved oviraptorosaurs may clarify the homologies of these extra bones. Previous work has suggested that one or more of these carpals are missing in oviraptorids ( Osmólska et al. 2004, Balanoff and Norell 2012) but are present in caenagnathids ( Zanno and Sampson 2005). The wrist of Oksoko is apparently similar to that of Khaan in having only two carpal bones ( Balanoff and Norell 2012), although this would indicate multiple losses of the ulnare and intermedium in oviraptorids, as other oviraptorids more closely related to Oksoko , like Heyuannia spp. (Lü et al. 2005; MPC-D 100/30), have three.

Manus

The manus of MPC-D 100/33 and MPC-D 102/110 are well preserved. The left hand of the latter specimen was disarticulated and provides detailed information on the elements ( Fig. 23 View Figure 23 ). As in other heyuannines (e.g. Heyuannia , Jiangxisaurus , and Nemegtomaia ), the first digit is the most robust, whereas digits II and III are much more gracile. Metacarpal I is roughly rectangular ( Fig. 23A–F View Figure 23 ). The proximal end is kidney-shaped in proximal view ( Fig. 23E View Figure 23 ), with a convex medial side and a concave lateral side. It is inclined so that the medial side reaches further proximally. The lateral side of the metacarpal has a concavity ( Fig. 23E View Figure 23 ), which is deeper proximally, to accommodate metacarpal II. The edge of this concavity prevents metacarpal II from reaching the ventral surface of the metacarpus in life. In distal view, the distal end of the metacarpal is roughly rectangular, but with a deep notch in its medial side. The lateral condyle is larger than the medial one, and both are transversely constricted about halfway up their height ( Fig. 23F View Figure 23 ). The condyles are only weakly ginglymoid and almost straight in mediolateral view. Manipulation of phalanx I-1 with the condyles of metacarpal I results in a restricted range of motion when the condyles are kept in full contact. Phalanx I-1 is the largest of the hand ( Fig. 23T View Figure 23 ) and exceeds metacarpal I in length. Its proximal articular surface is relatively flat, rather than deeply excavated, which contrasts with most theropod manual phalanges. In dorsal view ( Fig. 23B View Figure 23 ), the shaft curves slightly medially. The collateral ligament pits are relatively shallow but the medial one is deeper, and the medial condyle is larger than the lateral one. The ungual I-2 is strongly recurved and has a well-developed flexor tubercle ( Fig. 23A, D View Figure 23 ). The proximal articular surface lacks a proximodorsal lip, unlike Huanansaurus ganzhouensis and other citipatiines, and there is no groove between it and the rounded flexor tubercle. The vascular grooves are shallow and the lateral one is positioned further dorsally.

Metacarpal II is the longest of the hand ( Fig. 23T View Figure 23 ), but is about half the transverse width of metacarpal I. Its proximal end is strongly compressed mediolaterally, and sits entirely within the concavity on metacarpal I. The shaft is straight and cylindrical, lacking any ridges or grooves. The medial condyle is slightly larger than the lateral one ( Fig. 23L View Figure 23 ), but this disparity is not as great as in metacarpal I. When articulated with the first metacarpal, metacarpal II is deflected laterally ( Fig. 23T View Figure 23 ). Phalanx II-1 is small, about half the length of phalanx I-1, but subequal in length to II-2. It is transversely compressed and minimally ginglymoid. The collateral ligament pits are shallow. Phalanx II-2 is more gracile than phalanx II-1, but overall similar in shape and size. It lacks the lateral groove on the distal end described for Jiangxisaurus ( Wei et al. 2013) . Ungual II-3 is relatively straight and has a poorly developed flexor tubercle. Like ungual I-2, it lacks a proximodorsal lip, but it has a more poorly developed proximal articular surface. The flexor tubercle is small and just dorsal to it there is a foramen on the lateral side.

Metacarpal III is diminutive and unusual in morphology ( Fig. 23M View Figure 23 ). Its proximal end is tongue-like and deflected laterally. In articulation, it does not reach the carpus ( Fig. 23T View Figure 23 ). The shaft is transversely compressed and less than half the transverse diameter of metacarpal II. The distal end is unusual for an oviraptorosaur, and indeed any theropod. The condyle is bulbous and spherical, rather than being divided into a true trochlea, and is overhung by a dorsal process ( Fig. 23M View Figure 23 ). In articulation, this restricts the mobility of phalanx III-1 to mild flexion. Phalanx III-1 is also unusual. It is exceptionally small, less than 1 cm in length, and has poorly developed articular surfaces ( Fig. 23M– S View Figure 23 ). Whereas the proximal articular surface is conventional, the distal end is blunted and transversely convex ( Fig. 23S View Figure 23 ). As a result, there is no distal articular surface, which starkly contrasts with the condition in all other oviraptorids. This suggests that digit III of the manus was comprised only of the metacarpal and a single phalanx. This is supported by the absence of any more distal phalanges in all three hands visible in MPC-D 102/110, despite preparation from fresh matrix and the preservation of delicate elements like sclerotic plates. The combined length of metacarpal III and phalanx III- 1 in articulation does not exceed the length of metacarpal II ( Fig. 23T View Figure 23 ), so it is unlikely that the third digit would have protruded from the manus in life.

Pelvic girdle

The pubes, ischia, and some parts of the ilium are visible on MPC-D 102/110, but are best seen in MPC-D 102.11.a, where they are exquisitely preserved ( Fig. 24 View Figure 24 ). All six bones of the pelvis are complete in MPC-D 102/11.a ( Figs 4 View Figure 4 , 24–26 View Figure 24 View Figure 25 View Figure 26 ), but the right ischium is broken into two pieces. The pubes and ischia of MPC-D 100/33 are preserved, but the ilia are missing. The right ilium and left ischium of MPC-D 102/12 are known.

Ilium

The ilium ( Fig. 24 View Figure 24 ) is dolichoiliac and the pre-acetabular and postacetabular blades are nearly equal in length, although the postacetabular blade is slightly longer. The two ilia diverge posteriorly, and do not contact dorsally, as the neural spines of the sacrum extend past the dorsal margins of the ilia ( Fig. 24A View Figure 24 ). The pre-acetabular blade has a rounded anterior margin, and is expanded anteroventrally anterior to the cuppedicus fossa. This anteroventral process is rounded, like in Corythoraptor jacobsi , and extends ventrally level with the dorsal margin of the acetabulum. The cuppedicus fossa is shallow, but posteriorly its medial border is demarcated by a sharp dorsal ridge. The pubic peduncle extends slightly further ventrally than the ischial peduncle, but it is equal in length anteroposteriorly to the transversely narrow ischial peduncle. The pubic peduncle has a flattened, ventrally facing surface where it meets the pubis, to which it was not fused or co-ossified in MPC-D 102/11.a or MPC-D 102/12. There is no supra-acetabular crest, but there is a bulge above the ischiadic peduncle, which probably represents a poorly developed antitrochanter. The ischiadic peduncle is triangular in lateral view and projects laterally past the lateral surface of the iliac blade. The brevis fossa is modestly developed and short, extending anteriorly about halfway as far as the base of the ischial peduncle. The brevis shelf of Oksoko avarsan is unique amongst oviraptorosaurs in that it is not continuous with the ischiadic peduncle ( Fig. 24E, G View Figure 24 ). Instead, the brevis shelf is short and the postacetabular blade has an extra posterodorsally inclined ridge, separated from the brevis shelf by a groove ( Fig. 24E, G View Figure 24 ). This unique morphology is clearly demonstrated in MPC-D 102/11.a and MPC-D 102/12, but is absent in all other oviraptorosaurs. The dorsal margin of the ilium is nearly flat from the pre-acetabular blade to the anterior margin of the brevis fossa, where it tapers dorsoventrally. The postacetabular blade is squared off posteriorly, as in Nemegtomaia barsboldi and Rinchenia mongoliensis , whereas it is more tapered in Corythoraptor jacobsi , Khaan mckennai , Nankangia jiangxiensis , and the Dzamyn Khondt oviraptorid.

Pubis

The pubis ( Fig. 25 View Figure 25 ) is strongly curved anteriorly, a feature shared with all other oviraptorids. When articulated with the rest of the pelvis ( Fig. 3 View Figure 3 ), the pubis extends anteriorly far past the anterior margin of the ilium. The iliac and ischiadic contacts of the pubis are widely separated by the rounded margin of the acetabulum. The iliac contact is long anteroposteriorly, with an anterior process, and wide transversely. The ischiadic contact is oriented vertically, and is tall dorsoventrally but very narrow transversely. It protrudes posteriorly from the shaft of the pubis, and is offset ventrally from the shaft by a square notch. Medial to the ischiadic contact, there is a shallow concavity that lacks the posterior circumscription of caenagnathids ( Sullivan et al. 2011). The shafts of the pubes are separated by a transversely narrow pubic apron ( Fig. 25A, B View Figure 25 ). Ventral to the pubic apron there is a long oval fenestra separating the shafts of the pubes before they converge again at the symphysis. Even in MPC-D 102/11.a, the pubic symphysis is fused, but there are grooves both dorsally and ventrally where the pubes meet and a wide anterior cleft separating the pubes. The pubic boot is longer anteriorly than posteriorly ( Fig. 25C, F View Figure 25 ).

Ischium

The ischium is long, gracile, and concave posterodorsally ( Fig. 26 View Figure 26 ). The ischium is much longer in Oksoko avarsan than in most other oviraptorids, particularly contrasting with the short ischia of Corythoraptor jacobsi and Nankangia jiangxiensis ( Lü et al. 2013b) . There is a proximal groove that separates the pubic and iliac contacts, which represents the minimal involvement of the ischium in the acetabulum. The pubic contact is pitted and rugose, indicative of a cartilaginous element separating it from the pubis. The anterior margin of the obturator process is gently convex, curving towards the apex. This contrasts with the concave anterior edges of the ischium in caenagnathids. The obturator process is more than halfway down the shaft of the ischium, and forms a square point. The obturator process is thin and delicate, and is broken in both MPC-D 102/11.a and MPC-D 102/12, although it is completely represented in the former. The ischia of both individuals of MPC-D 102/110 are excellently preserved, but they differ slightly in morphology. Whereas the shapes of the ischia of MPC-D 102/110.a are identical to those of MPC-D 102/11.a, MPC-D 102/12, and MPC-D 100/33, those of MPC-D 102/110.b differ. This individual has a deep notch in the ventral edge of the ischium ( Fig. 26B View Figure 26 ), separating the obturator from the distal end. Although this is incipiently developed in the other specimens, in MPC-D 102/110.b it is about three times as deep. It is important to note that this individual also has dimorphic chevrons, and therefore these elements may differ for the same reasons.

Hindlimb

Hindlimb elements are known for all individuals except MPC-D 102/11.b (although these bones may represent the cranium of MPC-D 102/110.c). All of the hindlimb elements are exquisitely preserved, with minimal crushing, a high degree of articulation, and pristine surface textures. The distal right hindlimb of MPC-D 102/11.a was left articulated and serves as an excellent reference for the in vivo positions of the bones, whereas the left hindlimb was disarticulated and shows the morphology of the bones more clearly. The hindlimb elements of MPC-D 102/12 were likewise disarticulated and so show the conditions in a skeletally mature individual.

Femur

The femora are complete in MPC-D 102/110, but are not fully exposed.Both femora are preserved in MPC-D 102/11.a, but the right femur ( Fig. 27A–E View Figure 27 ) is more complete than the left, which is represented by only the proximal half. The right femur lacks the medial side of the distal end, but the lateral condyle is present, so length can be estimated. The femur of MPC-D 102/12 is complete but badly damaged and comminuted ( Fig. 27F–K View Figure 27 ). The femora of MPC-D 100/33 are both well preserved but could not be observed because they were mounted. The femoral head is directed medially and has only a slightly constricted neck. The anterior face of the head is continuous with the neck, but the posterior edge projects posteriorly past the surface of the neck. In medial view ( Fig. 27C, H View Figure 27 ), the posterodorsal corner of the femoral head is depressed and the anterodorsal corner is more bulbous. There is no rugosity for the capitate ligament, although this area is damaged in the larger MPC-D 102/12. The greater trochanter is broadly curved, but does not extend far above the neck of the head. It does not form a crest, but rather a rounded mound. The lesser trochanter is narrow and fingerlike, appressed to the anterior surface of the greater trochanter throughout its length ( Fig. 27A, F View Figure 27 ). However, there is a small cleft between these structures proximally, which continues into a short groove distally. The shaft of the femur is cylindrical and curved anteriorly. It lacks a fourth trochanter and instead there is a posteromedially located patch of rugose bone for m. caudofemoralis. Distal and lateral to this, there is a dorsolateral to ventromedially inclined muscle scar just above the popliteal fossa. The lateral surface of the femur has no obvious muscle scars, but there is a slight mound just ventral to the greater trochanter, which continues distally as a posterolateral ridge. The anterior surface of the shaft has a long muscle scar that extends distally from the lateral groove of the lesser trochanter to just distal to the level of the insertion of m. caudofemoralis. This scar twists from the lateral side of the shaft to the medial side. On the distolateral part of the anterior surface, there is a pronounced rugosity with a mounded border. The popliteal fossa is very deep compared to most oviraptorids ( Fig. 27I View Figure 27 ), but is not overhung by the crista tibiofibularis, which is the case in Rinchenia mongoliensis ( Funston et al. 2018) . The crista tibiofibularis is divided by a deep notch, separating the more bulbous fibular condyle from the larger tibial condyle. The ectocondylar tuber is mounded and rugose, and appears to become larger through ontogeny.

Tibia

Like the femora, the tibiae of MPC-D 102/110 are intact but not completely visible. The left tibia of MPC-D 102/11.a ( Fig. 28J, K View Figure 28 ) is missing its proximal end, but the right tibia is completely preserved in articulation with the fibula, tarsals, and complete foot. The right tibia and fused astragalocalcaneum are preserved with MPC-D 102/12 ( Fig. 28 View Figure 28 ), and both tibiae were recovered for MPC-D 100/33, but were not available for examination. The cnemial crest is proximodistally short but is relatively well pronounced. It is only slightly everted laterally, and its apex is at its ventral end, rather than the dorsal edge as in ornithomimids. The fibular condyle has two main lobes, separated by a narrow groove into which the fibula inserts. The posterior lobe is larger than the anterior one. These two lobes are separated from the posterior surface of the femoral condyle by a notch. In MPC-D 102/12, the fibular condyle and femoral condyle coalesce external to this notch, leaving a circular tunnel ( Fig. 28B View Figure 28 ). The main portion of the femoral condyle is kidney-shaped in proximal view, and extends further proximally than the fibular condyle. The fibular crest is poorly defined but is thick and rugose, rather than platelike ( Fig. 28A, D View Figure 28 ). Posterior to the fibular crest there is a shallow groove, but it is not continuous with the large nutrient foramen that opens dorsally. The shaft of the tibia has a flat anterior surface, but there is a slight ridge at the distal end of the shaft, near the ascending process of the astragalus. The posterior surface of the tibia is rounded but the apex of the curvature is more medially located. The result is that the anteromedial corner of the tibia is sharp, whereas the lateral corner is more rounded. There is no facet or groove for the fibula, instead it rests upon the rounded lateral corner of the tibia. The anterior side of the distal end is obscured by the overlying astragalocalcaneum in each specimen, but it is clear that the medial malleolus protrudes anteromedially to create a bowl into which the astragalus fits ( Fig. 28C View Figure 28 ). The lateral malleolus is posteriorly deflected and has a modest postfibular flange that does not extend far proximally.

Fibula

Fibulae ( Fig. 28E–G View Figure 28 ) from each specimen are preserved. Unlike conventional reconstructions, each of the articulated fibulae is oriented with the broadest portion of the head oriented transversely, rather than anteroposteriorly. The head is concavoconvex and crescentic in dorsal view, with a larger lateral portion than medial portion. The medial part of the head is fingerlike in proximal view, whereas the lateral side is bulbous, which results in a central groove extending to a fossa on the posterior face. The lateral edge of the fibula distal to the head is sharply attenuated to a ridge ( Fig. 28G View Figure 28 ), and this continues distally to become the lateral edge of the shaft. Distal to the head, the shaft thickens and has a thick, rugose anteromedial ridge. This ridge lies adjacent to the fibular crest on the tibia, and likely accommodated the interosseum membrane. The remainder of the fibular shaft is slender and concavoconvex, with the concavity oriented towards the tibia. The distal end has a bulbous head and curves slightly posteriorly. It appears to be separated from the calcaneum in each specimen, although this may vary depending on the position of the leg.

Astragalocalcaneum

The astragalus ( Fig. 28H, I View Figure 28 ) is obscured in MPC-D 102/110 and the right foot of MPC-D 102/11.a by the overlying feet, but is exposed in MPC-D 100/33 and MPC-D 102/12. The medial condyle is much larger than the lateral one, and its medial surface is inclined to fit on to the medial malleolus of the tibia. The condyle is anteroposteriorly thin, which contrasts with the robust condyles of caenagnathids and some other oviraptorids. There is a concavity at the base of the ascending process that has a pronounced anterior lip ( Fig. 28I View Figure 28 ). Distal to this, there is a fossa in the anterolateral part of the intercondylar space. On the distal surface of the astragalus, there is another depression in the intercondylar sulcus. The posterior edge of the astragalus is relatively straight, rather than curved. The lateral condyle has a sinuous anterolateral edge, which overhands the calcaneum dorsally but is excavated by it ventrally. The ascending process covers the entire surface of the tibia at its base, and extends at least 30% of the length of the tibia. The lateral edge of the ascending process is vertical, whereas the medial edge inclines proximolaterally to give the ascending process its taper. The calcaneum is unfused in the smaller specimens (MPC-D 102/11.a, MPC-D 102/110, and MPC-D 100/33), but it is fused in MPC-D 102/12 ( Fig. 28H View Figure 28 ), which suggests that it fuses through ontogeny (see Discussion). The calcaneum is kidney-shaped, with the convex side facing anteriorly. Its lateral surface is concave, surrounded by a transversely thickened circumferential lip. The calcaneum is thicker at its anterior end than its posterior side.

Distal tarsals

Distal tarsals III and IV ( Fig. 29 View Figure 29 ) are preserved with each specimen. Distal tarsal III is roughly trapezoidal and, as in all oviraptorosaurs, thickens towards its posterior side. It covers the posterior half of metatarsal III in proximal view ( Fig. 29A, B View Figure 29 ), but even in the mature MPC-D 102/12, it does not expand anteriorly. However, although it covers only metatarsal III in MPC-D 102/11.a and MPC-D 102/110, it has expanded medially in MPC-D 102/12 to cover the posterolateral corner of metatarsal II. In MPC-D 102/11.a, the posterior edge of distal tarsal III is rounded, whereas it becomes more square and much thicker through ontogeny in MPC-D 102/12 ( Fig. 29A, B View Figure 29 ). In this individual, it has also begun to fuse to metatarsal III [ Fig. 29C View Figure 29 ), which resembles the condition in some derived caenagnathids [ Elmisaurus rarus Osmólska 1981 and Citipes elegans ( Parks 1933) ]. The medial side of distal tarsal III is rounded and bulbous. Although this is also the case for the lateral side in MPC-D 102/11.a, in the older MPC-D 102/12, the lateral edge is straight where it abuts—but does not fuse to—distal tarsal IV. Distal tarsal IV is circular except for a rounded process extendingfromthelateralside( Fig.29A,B View Figure 29 ). Thisprocessisprobably homologous with the proximodorsal process of caenagnathids. Although oviraptorids generally lack a well-developed process here, the distal tarsals are typically poorly described, and so this feature may be more prevalent. The distal tarsal is disc-shaped and both sides are equal in thickness, but it tapers in thickness towards each edge. The lateral process is bulbous and thicker than the neck leading to it. In MPC-D 102/12, this process has become greatly enlarged and projects dorsolaterally ( Fig. 29B, D View Figure 29 ), more closely resembling the proximodorsal process of caenagnathids. Furthermore, instead of remaining circular and disc-like, the fourth distal tarsal of MPC-D 102/12 is thickened posteriorly and has a straight medial edge where it meets distal tarsal III ( Fig. 29B View Figure 29 ).

Pes

Both feet ( Fig. 30 View Figure 30 ) are preserved in their entirety in all specimens, except MPC-D 102/12, which preserves only the right metatarsus, metatarsal III from the left side, and a single phalanx III-1 from the right. All five metatarsals are represented in most specimens, but the feet of MPC-D 102/11.a appear to lack metatarsal V. It is possible that it was disarticulated during preparation and is represented by indeterminate splint-like bones accessioned with the specimen. Alternatively, metatarsal V may not have ossified yet in this individual.

Metatarsal I has a flat shaft and a small condyle ( Fig. 30B, D, G View Figure 30 ). The shaft has a triangular proximal process and a tab-like posterior process. The lateral side is flat, whereas the medial side is rounded. The condyle is roughly triangular in distal view, with a narrower anterior side. The medial ligament pit is shallow and small, and the lateral one is large and deep. The posterior side of the condyles each have a small ridge, separated by a small depression. Phalanx I-1 is about the same length as the metatarsal and ungual. The proximal articular surface is inclined to face dorsomedially and is deeply concave. The shaft of the phalanx twists laterally and slightly dorsally. The condyle is narrow and the medial ligament pit is shallow but equal in size to the lateral one. Ungual I-2 is small and relatively straight, except for a slightly hooked tip. The proximal surface is crescentic and there is only a slight transverse constriction distal to it. The flexor tubercle is poorly developed. The medial and lateral grooves are poorly developed but the lateral one is deeper and slightly further dorsal.

Metatarsal II ( Fig. 30 View Figure 30 ) is the shortest of the weight-bearing metatarsals, but has a large proximal end. The proximal end is trapezoidal in proximal view, with the wider side facing metatarsal III and inclined about 50° mediolaterally. The shaft tapers from the proximal end but is consistent in thickness throughout most of its length. It is thicker than the other metatarsals anterioposteriorly but equal to metatarsal IV in transverse breadth. There is an incipient posteromedial ridge, but it is not well developed in the smaller specimens. In MPC-D 102/12, this ridge becomes larger and has a rugose surface. The proximal end of II-1 is inclined dorsomedially in proximal view. There are two ridges on either side of its ventral edge. The shaft of the phalanx is slightly curved laterally. The condyle is not ginglymoid and there is a large depression on the dorsal surface. The medial ligament pit is shallow, but the lateral one is deep. Phalanx II-2 is relatively symmetrical, but the proximal end is slightly skewed laterally. The phalanx is about half the length of phalanx II-1. Ungual II-3 is the largest ungual of the foot, but is only slightly larger than ungual III-4. The former is dorsoventrally deeper but slightly shorter in length. The flexor tubercle is weak and the claw is modestly recurved.

Metatarsal III is the longest of the foot ( Fig. 30B, G View Figure 30 ) and the widest at its distal end. Its proximal end is wider than the other two metatarsals posteriorly, but it is anteriorly pinched—albeit not to the same degree as in caenagnathids. The proximal end is, therefore, triangular in proximal view, with a flat posterior edge. There is a flattened shelf on the posterior surface of the head ( Fig. 30B, H View Figure 30 ) reminiscent of the posterior protuberance of Elmisaurus rarus ( Osmólska 1981, Currie et al. 2016, Funston et al. 2021), but much smaller. This raised area is continuous with similar platforms on metatarsals II and IV. The shaft of metatarsal III is square in cross-section, with sharp posterior corners and flat sides. The distal condyle is asymmetrical, with a larger medial condyle than lateral condyle. The postcondylar ridges are well developed but end abruptly, rather than continuing proximally. Digit III is the longest and widest ( Fig. 30B, G View Figure 30 ). Phalanx III-1 has a semicircular proximal face with two poorly developed ventral ridges. The shaft and condyle are symmetrical. The condyle is more ginglymoid than the phalanges of digit II and the collateral ligament pits are equal in depth. The more distal phalanges are virtually identical to phalanx III- 1 in morphology, but they are each about 30% shorter than the previous one. Ungual III-4 is the longest of the foot but is more gracile than II-3. It is nearly perfectly symmetrical, including equally deep vascular grooves positioned equally far dorsally. The flexor tubercle is small, but larger than that of ungual II-3, and the claw is slightly more recurved than the latter.

Metatarsal IV ( Fig. 30 View Figure 30 ) has a large, semicircular proximal end in proximal view, with the flat edge against metatarsal III. The raised posterior area is triangular with a 45° inclination to the dorsal edge. The shaft of the metatarsal is compressed anteroposteriorly so that it is wider than deep. There is no sign of a posterolateral ridge in the smaller specimens, but in MPC-D 102/12 there is a rugose patch on the posteromedial side. The condyle is not deflected laterally and the lateral condylar ridge is small. The lateral ligament pit is relatively shallow. Digit IV is about equal in length to digit II, including the unguals. Phalanx IV-1 is wider distally than proximally. It has a deeply concave, triangular proximal end. The shaft is directed slightly medially. The other phalanges are short, with barely any shaft separating the proximal and distal condyles. These phalanges are symmetrical except for a slight lateral skew to the proximal articular surfaces. Ungual IV-5 is small and straight with a weak flexor tubercle and greater transverse constriction than the other unguals. The medial vascular groove is deeper and more dorsally positioned.

Metatarsal V is missing in MPC-D 102/11.a ( Fig. 30 View Figure 30 ), either as a result of preparation or poor ossification, and in MPC-D 102/12, probably because it was lost before collection. In the other specimens, it is a tapering splint tightly appressed to the posterolateral surface of metatarsal IV. Its proximal end is expanded and rounded. The shaft curves slightly anteriorly, but not to the same degree as in caenagnathids like Chirostenotes pergracilis ( Gilmore 1924, Funston 2020). The distal end has a small bulb at its apex, but is otherwise simple. Its absence in MPC-D 102/12 suggests that it never fused throughout ontogeny, unlike in derived caenagnathids ( Elmisaurus rarus and Citipes elegans ), where it fuses to the proximodorsal process of distal tarsal IV ( Currie et al. 2016, Funston et al. 2016a, 2021).