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English: A comparison of animals shown rearing on their hindlimbs; including an African elephant (Loxodonta), a Gerenuk (Litocranius), and the sauropoda dinosaurs, Diplodocus, Giraffatitan, Barosaurus, and Opisthocoelicaudia.


Quadrupedal animals that can rear onto their hindlimbs can increase the height they can feed, giving access to food sources otherwise out of reach.[1] Living animals that are known to regularly rear up into a bipedal posture include the Gerenuk and the African Elephant.[2][3][1] It has been suggested that sauropod dinosaurs could have also reared for food gathering and defence, and sauropods have been depicted rearing in movies, documentaries, and museum exhibits. A famous example is in the movie Jurassic Park (1993), where a Brachiosaurus was shown rearing up to feed near the beginning of the film. The American Museum of Natural History mounted a cast of Barosaurus in a defensive rearing posture.[1]


Some researchers have argued that sauropods have several adaptations that make them better adapted for rearing than many modern mammals, such as elephants. For example, Gregory S. Paul has argued that sauropods have larger and taller dorsal vertebrae than similarly-sized mammals, suggesting their dorsal columns were stronger. Sauropod necks and torsos are lightened because of an extensive air sac system which, combined with long, muscular, and dense tails, helps shift the centre of mass (COM) backwards, closer to the hip socket in some sauropod species. The forelimbs of most sauropods are more lightly constructed than the hindlimbs; the opposite is true in most mammals. Some sauropods have retroverted pelves which might have allowed the legs to maintain greater functionality when rearing.[3]
In 1977, Magdalena Borsuk-Bialynicka described Opisthocoelicaudia as having adaptations that might imply that it reared regularly. The anterior part of the tail has strongly opisthocoelous vertebra which suggests flexibility; this was interpreted as the tail being able to serve as a prop when in a tripodal posture. Borsuk-Bialynicka also argued that the hip socket allowed for a large range of motion, more than needed for normal quadrupedal walking. The wide strongly flared pelvis was thought to further aid stability in a tripodal posture. However, other researchers have suggested these are adaptations for a wide-gauge posture that titanosaurs developed.[4][1]


Biomechanics researcher Heinrich Mallison built virtual models of Diplodocus and Brachiosaurus brancai (now Giraffatitan brancai) in order to investigate the potential rearing abilities of sauropods. The COM of Diplodocus is estimated to be very close to the hip socket; this makes prolonged rearing possible and does not require much effort to do it. Combined with its long, massive tail acting as a prop, it was also very stable. Mallison found Diplodocus to be better adapted for rearing then an elephant.[1] A previous study also found that of the several sauropods analysed, the COM of Diplodocus was the closest to the hip socket.[5]
Giraffatitan, on the other hand, was found to have a COM further forward, due to a reduced tail and larger forelimbs compared to other sauropods. When posed in a rearing posture, the COM was high above the hip socket; this makes prolonged rearing difficult and unstable. Small movements to the neck would require large correcting motions in the limbs to maintain an upright pose. Any backward movement puts a large amount of stress on the tail. The forelimbs could potentially suffer damage if they were to land too fast. Based on this analysis, it is unlikely that Giraffatitan would rear often.[1]



Diplodocus, Giraffatitan, Barosaurus, and Opisthocoelicaudia silhouettes are based on skeletal reconstructions by Scott Hartman. Used with permission. [1] [2] [3] [4]. The neck of Opisthocoelicaudia is unknown and greyed out in the diagram.
• The circles with black and white represent the approximate location of the centre of mass as estimated in biomechanical studies; their exact positions are approximate due to unknowns in the reconstruction of soft tissues. Center of mass location also changes as the animal changes posture. The dark crosses represent the location of the hip socket.
• Humans scaled to 170 cm and 160 cm respectively.

References

  1. a b c d e f Mallison, H. (2011) "Rearing Giants: Kinetic-Dynamic Modeling of Sauropod Bipedal and Tripodal Poses" in Biology of the Sauropod Dinosaurs: Understanding the Life of Giants, pp. 239–320 ISBN: 978-0-253-35508-9.
  2. (2015) The Kingdon Field Guide to African Mammals (2nd ed.), London, UK: Bloomsbury, pp. 569–71 ISBN: 978-1-4729-1236-7.
  3. a b Paul, Gregory S. (2017). "Restoring Maximum Vertical Browsing Reach in Sauropod Dinosaurs". The Anatomical Record 300 (10): 1802–1825. DOI:10.1002/ar.23617.
  4. Borsuk-Białynicka, M.M. (1977). "A new camarasaurid sauropod Opisthocoelicaudia skarzynskii gen. n., sp. n. from the Upper Cretaceous of Mongolia". Palaeontologia Polonica 37 (5): 5–64.
  5. Henderson, Donald M. (2006). "Burly gaits: centers of mass, stability, and the trackways of sauropod dinosaurs". Journal of Vertebrate Paleontology 26 (4): 907–921.
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Author Steveoc 86 And Scott Hartman, http://www.skeletaldrawing.com/

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Date/TimeThumbnailDimensionsUserComment
current22:33, 21 July 2024Thumbnail for version as of 22:33, 21 July 20241,920 × 960 (341 KB)Steveoc 86Update diplodocus skin & other adjustments
12:22, 11 July 2023Thumbnail for version as of 12:22, 11 July 20231,920 × 960 (307 KB)Steveoc 86Minor cosmetic updates, correct center of gravity symbol
15:53, 8 January 2021Thumbnail for version as of 15:53, 8 January 20211,920 × 960 (243 KB)Steveoc 86Image size. Change scapula position and orientation per Vidal et al. 2020
20:11, 16 December 2020Thumbnail for version as of 20:11, 16 December 20201,280 × 640 (245 KB)Steveoc 86Minor adjustments
15:30, 31 December 2018Thumbnail for version as of 15:30, 31 December 20181,280 × 640 (246 KB)Steveoc 86Add markers for the Hip Socket
16:02, 30 June 2018Thumbnail for version as of 16:02, 30 June 20181,280 × 640 (243 KB)Steveoc 86Minor Crop
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