Chimpanzees shed light on origins of human walking


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A research team led by Stony Brook University investigating human and chimpanzee locomotion have uncovered unexpected similarities in the way the two species use their upper body during two-legged walking. The results, reported in Nature Communications, indicate that our early human ancestors, including the famous fossil ‘Lucy’ (a species known as Australopithecus afarensis), may have been able to use their torsos to increase walking efficiency in the same way as modern humans.

Chimpanzees shed light on origins of human walking
Pelvis and ribcage rotations during bipedal locomotion. Despite differences
 in overall motion, there is as much mobility between the pelvis and ribcage
 in humans as in chimpanzees, suggesting more human-like abilities in our 
earliest ancestors than previously thought [Credit: Nathan Thompson,
 Lucille Betti-Nash, and Deming Yang]

The torso (the part of the body that includes the ribcage, belly and pelvis) of chimpanzees has long been thought to be a rigid block, best suited for a life of tree climbing. Humans, on the other hand, have long and flexible torsos that aid in walking by allowing us to rotate our upper body in the opposite direction of our lower body. The findings from the paper, titled “Surprising trunk rotational capabilities in chimpanzees and implications for bipedal walking proficiency in early humans,” changes the evolutionary view of how early human ancestors walked and what they were able to do.

“During walking, we actually observed as much rotation within the torsos of chimpanzees as in humans,” said Nathan Thompson, lead author and a PhD student in the Department of Anatomical Sciences at Stony Brook University. “This means that the widely accepted assumptions in the scientific community about how the chimpanzee torso works based on the skeleton alone are incorrect. Our results also point to the notion that a limitation to upright walking that we thought affected Lucy and other early human ancestors probably was not a limitation at all.”

The research team used high-speed cameras to track and compare how the torsos of humans and chimpanzees actually moved during bipedal walking. They studied the movements by way of three-dimensional kinematic analyses and computer-generated comparisons.

Chimpanzees shed light on origins of human walking
The skeleton of a human (left) and chimpanzee (right). The wide ribcage and pelvis 
and short lower back in chimpanzees, long thought to be rigid, was found to be 
as mobile as humans during walking. This means the chimp-like aspects 
of early human ancestors might not have hindered their walking abilities 
[Credit: Stony Brook University]

They discovered that the main difference between human and chimpanzee bipedalism is that chimps swing their hips much more.

“Only when our early ancestors were able to reduce this hip rotation were their upper bodies able to play a human-like role in promoting efficient bipedal walking,” said Thompson. “When this actual transition occurred is still an open question.”

There is a continuing debate about how the hips of our ancestors worked compared to ours.

“For instance, depending on who you ask, the 3.2 million-year-old Lucy fossil either rotated her pelvis exactly like modern humans or up to 2.5 times more,” he explained.

Given this uncertainty, the research team modeled the transition from a more chimp-like pattern of the upper body movement to that of a more human-like pattern. They found that even if Lucy rotated her pelvis 50 percent more than modern humans, her upper body would have functioned essentially like ours. This means that even as early as 3.2 million years ago Lucy might have been able to save work and energy in much the same way as humans do today.

“As we get a better idea of how our closest living relatives move, we are able to learn much more about the isolated piles of early human bones that the fossil record leaves us,” added Thompson. “Only then can we paint a complete picture of how we evolved into what we are today.”

Source: Stony Brook University [October 06, 2015]


  1. This article is astonishing anthropocentric: "the transition from a more chimp-like pattern … to that of a more human-like pattern": we did not evolve from chimps! Pan & Homo evolved from the same last common ancestor (LCA) c 5 Ma with a mosaic of bonobo-, common chimp-, human-, australopith-like, primitive-hominoid & unique features. Comparative data suggest this LCA was probably partially bipedal (for wading rather than walking: australopith fossils are found in wetlands, flooded forests, papyrus swamps, lagoons etc., Reed 1998 JHE) with very flat feet & probably shorter legs than humans today, and with a very broad pelvis, long femoral neck & very valgus knee for lateral movements of the leg (femoral abduction), and also with more curved hand bones for climbing vertically in the branches above the swamp (google aquarboreal): this LCA apparently dwelt in swamp forests (or in mangrove forests, where fossilisation is very difficult), not unlike bonobos or lowland gorillas wading for waterlilies or sedges in forest swamps but more frequently, google researchGate marc verhaegen.



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