2003
DOI: 10.1242/jeb.00279
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Insights into the evolution of human bipedalism from experimental studies of humans and other primates

Abstract: SUMMARYAn understanding of the evolution of human bipedalism can provide valuable insights into the biomechanical and physiological characteristics of locomotion in modern humans. The walking gaits of humans, other bipeds and most quadrupedal mammals can best be described by using an inverted-pendulum model, in which there is minimal change in flexion of the limb joints during stance phase. As a result, it seems logical that the evolution of bipedalism in humans involved a simple transition from a relatively s… Show more

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Cited by 253 publications
(163 citation statements)
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References 161 publications
(152 reference statements)
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“…But even small differences in limb posture could have had important evolutionary implications. If the Laetoli G1 footprints were made by A. afarensis, and members of that taxon typically used a bipedal gait that involved relatively more flexed limbs, then A. afarensis probably would have experienced somewhat higher bipedal locomotor costs compared with modern humans [36][37][38] despite having similarly long lower limbs [39]. A higher cost of bipedal locomotion relative to modern humans could have had important adaptive consequences for A. afarensis, affecting mobility, home range size and many other aspects of interactions with the environment.…”
Section: Resultsmentioning
confidence: 99%
“…But even small differences in limb posture could have had important evolutionary implications. If the Laetoli G1 footprints were made by A. afarensis, and members of that taxon typically used a bipedal gait that involved relatively more flexed limbs, then A. afarensis probably would have experienced somewhat higher bipedal locomotor costs compared with modern humans [36][37][38] despite having similarly long lower limbs [39]. A higher cost of bipedal locomotion relative to modern humans could have had important adaptive consequences for A. afarensis, affecting mobility, home range size and many other aspects of interactions with the environment.…”
Section: Resultsmentioning
confidence: 99%
“…However, bipedalism can be found within a few families of mammals, reptiles and within all birds. Among mammals, various groups of primates (Schmitt, 2003), the macropods (Windsor and Dagg, 2010) and a few groups of heteromyd rodents (Djawdan, 1993) locomote bipedally. Within reptiles, some families of lizards are also capable of bipedal locomotion (Aerts et al, 2003), especially when running at high speeds (Irschick and Jayne, 1999).…”
Section: Introductionmentioning
confidence: 99%
“…Examples of diagonal sequence footfall patterns in a tetrapod and a non-human primate, also showing the ground reaction forces (arrows) on the ipsilateral and contralateral forelimbs and hind limbs. Notice greater ground reaction forces on the left forelimb and the contralateral right hind limb during walking on all four extremities in a tetrapod, and greater vertical force on the left hind foot (F hind ) than the contralateral (right) fore foot (F fore ) during diagonal sequence quadrupedal locomotion in a non-human primate (modified from Schmitt, 2003).…”
Section: Locomotionmentioning
confidence: 99%
“…By contrast most primates support their body weight more on their hind limbs than their forelimbs during diagonal sequence quadrupedal locomotion, whether they are standing or moving, on the ground or in trees (Kimura et al, 1979;Demes et al, 1994;Schmitt, 2003;Schmitt & Hanna, 2004). The increased hind limb weight support in non-human primates is generally interpreted as an adaptation that reduces stress on the forelimb joints, facilitating the forelimb mobility, especially for arboreal locomotion (Reynolds, 1985;Larson, 1998).…”
Section: Forelimb and Hind Limb Weight Supportsmentioning
confidence: 99%