DOCSLIB.ORG

Functional Morphology and Three-Dimensional Kinematics of the Thoraco-Lumbar Region of the Spine of the Two-Toed Sloth

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Functional Morphology and Three-Dimensional Kinematics of the Thoraco-Lumbar Region of the Spine of the Two-Toed Sloth 4278 The Journal of Experimental Biology 213, 4278-4290 © 2010. Published by The Company of Biologists Ltd doi:10.1242/jeb.047647 Functional morphology and three-dimensional kinematics of the thoraco-lumbar region of the spine of the two-toed sloth John A. Nyakatura* and Martin S. Fischer Institut für Spezielle Zoologie und Evolutionsbiologie mit Phyletischem Museum, Friedrich-Schiller-Universität, D-07743 Jena, Germany *Author for correspondence ([email protected]) Accepted 25 September 2010 SUMMARY Given the importance of thoraco-lumbar spine movements in the locomotion of mammals, it is surprising that in vivo three- dimensional (3-D) data on the intervertebral movement of the mammalian thoraco-lumbar vertebral column during symmetrical gaits is limited to horses and dogs. To test whether kinematic patterns similar to those published for these cursorial species are also present during a contrasting mode of quadrupedalism, we quantified thoraco-lumbar intervertebral movements, the resulting pelvic displacements and relative femoral movements during the trot-like steady-state suspensory quadrupedal locomotion of the two-toed sloth (Xenarthra, Choloepus didactylus). Scientific rotoscoping, a new, non-invasive approach that combines synchronous biplanar high speed X-ray videos and the reconstruction of skeletal elements from computed tomography bone scans, was used to quantify 3-D kinematics. An analysis of vertebral anatomy and epaxial muscle topography suggests that the thoraco-lumbar spine of sloths is well suited to producing lateral bending and long-axis rotation, but limits powerful sagittal extension. Sloths exhibit complex 3-D movements in the thoraco-lumbar spine that are comparable to those observed in other arboreal quadrupedal mammals. Monophasic lateral bending and long-axis rotation, biphasic sagittal bending and maximal amplitude of sagittal bending at the lumbo-sacral joint were also found in other quadruped mammals and may represent general aspects of mammalian symmetric gaits. Maximal amplitude of lateral bending and long-axis rotation vary in regard to the vertebral level. It is suggested that a cranio-caudal pattern of angular deflections of the spine results from the out-of-phase movement of diagonal forelimbs and hindlimbs in other walking gaits, because it is not evident in the trot-like locomotion analyzed here. The analysis also illustrates the difficulties that arise when lumbar movement is deduced from intervertebral joint morphology alone. Key words: intervertebral joint, vertebral column, XROMM, scientific rotoscoping, pelvis, femur, Choloepus didactylus, Xenarthra. INTRODUCTION morphology of the vertebrae (e.g. Slijper, 1946; Boszczyk et al., Movements of the vertebral column are of fundamental significance 2001). However, only a fraction of the possible in vitro mobility of in the locomotion of mammals, because they have been shown to the musculo-skeletal system or of the mobility at non-locomotor contribute significantly to propulsion (e.g. Howell, 1944). The most activities such as grooming, fighting or mating can be expected substantial movement of the vertebral column during symmetrical during cyclic locomotion (Fischer, 1998). Additionally, in at least gaits of mammals is a monophasic lateral bending that results in one available example of experimental in vivo motion analysis, the maximal lateral displacement of the pelvis to either side at touch- movements observed were greater than expected on the basis of the down of the hindlimb of the same side of the body (Shapiro et al., articular features (Haussler et al., 2001). 2001). Secondly, there occurs a less pronounced, biphasic sagittal Because 3-D intervertebral movements are difficult to observe, bending. Maximal sagittal flexion occurs at hindlimb touch-down necessitating 3-D in vivo methods, data relating to these movements whereas maximal extension occurs at hindlimb lift-off (Schilling have only been published for horses (Haussler et al., 2001) and, to and Fischer, 1999; Faber et al., 2000; Ritter et al., 2001; Licka et a limited extent, dogs (Wood et al., 1992; Schendel et al., 1995) – al., 2001). Thirdly, there is axial rotation about the long-axis of the both highly cursorial mammals adapted to sustained running. These spine, which is more pronounced in symmetrical gaits than in few studies relied on the invasive instrumentation of the vertebrae asymmetrical gaits (Faber et al., 2000). The pelvis is thus displaced analyzed. three dimensionally (3-D) during symmetrical gaits in mammalian In kinematic studies on the back movements of horses during a locomotion (cf. Jenkins and Camazine, 1977). slow lateral sequence walk, maximal intervertebral lateral bending In view of the importance of these 3-D axial movements in was observed to occur earlier between the lumbar vertebrae than mammalian symmetrical gaits, it is surprising that the kinematic between the more cranial thoracic intervertebral joints, whereas in data available on the body axis are limited. Although published a trotting gait this shift was not evident (Faber et al., 2000; Haussler quantifications of 3-D pelvic displacements during symmetric et al., 2001). Accordingly, Schilling and Carrier documented mammalian quadrupedalism are themselves scant (Jenkins and sequential electromyographical (EMG) activation patterns in the Camazine, 1977; Schilling and Fischer, 1999; Wennerstrand et al., back muscles of dogs during walking and galloping, but 2004; Schmidt, 2005), the minute intervertebral movements synchronized activity during trotting (Schilling and Carrier, 2010). associated with these displacements are even less well investigated. The authors concluded that the cranio-caudal EMG patterns of dogs Efforts have been made to deduce intervertebral mobility from the are consistent with a traveling wave of trunk bending in walking THE JOURNAL OF EXPERIMENTAL BIOLOGY Morphology and 3-D kinematics of sloth thoraco-lumbar spine 4279 gaits and with a standing wave of trunk bending in trotting gaits Anatomical investigation (Schilling and Carrier, 2010). Kinematic data and EMG data thus Anatomical investigation was undertaken on a female cadaver of imply a close relationship between footfall pattern and the 3-D C. didactylus donated by Dresden Zoo (Germany). After dissection movements of the vertebral column during symmetric gaits. to study the epaxial muscular topography, the cadaver was macerated Furthermore, published studies on the 3-D axial movement of and the vertebrae of the thoraco-lumbar spine were photographed quadrupedal mammals have shown that there are regional differences to document the intervertebral joint configuration of the two-toed in the magnitude and pattern of the three axial rotations: lateral sloth. In this paper we use the anatomical nomenclature of the bending about a dorso-ventral axis, sagittal bending about a latero- Federative Committee on Anatomical Terminology (FCAT, 2008). lateral axis and long-axis rotation about a longitudinal axis (Haussler The subjects used in the anatomical investigation and the motion et al., 2001). analysis (see below) have been used in previous studies and have If previously published patterns of 3-D axial movement during been shown not to have uncharacteristic morphologies. Their symmetric mammalian quadrupedalism are also present in a morphometric parameters were within 1 s.d. of a larger sample that contrasting type of symmetric locomotor behavior, they are likely was composed of museum material (Nyakatura and Fischer, 2010). to represent a more general pattern. To this end, we present here Neither the female [10.6kg, 87cm in length (measured from the an in vivo analysis of 3-D thoraco-lumbar intervertebral movements anterior tip of nose to the ischium)] nor the male (6.5kg, 78cm) during suspensory quadrupedal locomotion in the two-toed sloth displayed any peculiarities. (Xenarthra, Choloepus didactylus, Linné 1758). The following statements reflect what we would expect with regard to the Experimental setup for biplanar high-speed X-ray video movements in the thoraco-lumbar spine of the two-toed sloth during recordings suspensory quadrupedal locomotion on the basis of data available The experimental setup for obtaining synchronous biplanar X-ray on horses and dogs: videos was described in detail in a previous publication (Nyakatura 1. Lateral bending will be monophasic and maxima will occur et al., 2010). Briefly, we recorded synchronous, digital high-speed to either side associated with touch-down events of the hindlimbs. X-ray videos from the dorso-ventral and latero-lateral perspectives 2. Sagittal bending will be biphasic and maxima of flexion will during steady-state locomotion in two individuals (Fig.1). Both be associated with touch-down events of the hindlimbs, whereas 40cm diameter image intensifiers were equipped with a Visario minima will occur at instances of hindlimb lift-off. SpeedcamTM (Weinberger GmbH, Erlangen, Germany) and recorded 3. Long-axis rotation will be monophasic and maximal rotations at a resolution of 1536ϫ1024pixels and a frame rate of towards one side of the body will be associated with touch-down 300framess–1. Any distortion of X-ray images was corrected with of the ipsilateral hindlimb, whereas minima will occur at lift-off of the help of a MatlabTM workflow developed by the XROMM group the ipsilateral hindlimbs. (Brown University, Providence, Rhode Island, USA). Images were 4. Amplitudes of intervertebral angular deflections will be highest undistorted by recording the X-ray
Load more

Recommended publications
  • Comparative Locomotor Performance of Marsupial and Placental Mammals
    J. Zool., Lond. (1988) 215, 505-522 Comparative locomotor performance of marsupial and placental mammals T. GARLAND,JR Department of Zoology, University of Wisconsin, Madison, WZ 53706, USA School of Biological Sciences, The Flinders University of South Australia, Bedford Park, Adelaide, 5042, South Australia (Accepted 13 October 1987) (With 6 figures in the text) Marsupials are often considered inferior to placental mammals in a number of physiological characters. Because locomotor performance is presumed to be an important component of fitness, we compared marsupials and placentals with regard to both maximal running speeds and maximal aerobic speeds (=speed at which the maximal rate of oxygen consumption, \jozmax, is attained). Maximal aerobic speed is related to an animal's maximal sustainable speed, and hence is a useful comparative index of stamina. Maximal running speeds of 1 I species of Australian marsupials, eight species of Australian murid rodents, two species of American didelphid marsupials, and two species of American rodents were measured in the laboratory and compared with data compiled from the literature. Our values are greater than, or equivalent to, those reported previously. Marsupials and placentals do not differ in maximal running speeds (nor do Australian rodents differ from non- Australian rodents). Within these groups, however, species and families may differ considerably. Some of the interspecific variation in maximal running speeds is related to differences in habitat: species inhabiting open habitats (e.g. deserts) tend to be faster than are species from habitats with more cover, or arboreal species. Maximal aerobic speeds (compiled from the literature) were higher in large species than in small species.
    [Show full text]
  • Gait Analysis in Uner Tan Syndrome Cases with Key Symptoms of Quadrupedal Locomotion, Mental Impairment, and Dysarthric Or No Speech
    Article ID: WMC005017 ISSN 2046-1690 Gait Analysis in Uner Tan Syndrome Cases with Key Symptoms of Quadrupedal Locomotion, Mental Impairment, and Dysarthric or No Speech Peer review status: No Corresponding Author: Submitting Author: Prof. Uner Tan, Senior Researcher, Cukurova University Medical School , Cukurova University, Medical School, Adana, 01330 - Turkey Article ID: WMC005017 Article Type: Research articles Submitted on: 09-Nov-2015, 01:39:27 PM GMT Published on: 10-Nov-2015, 08:43:08 AM GMT Article URL: http://www.webmedcentral.com/article_view/5017 Subject Categories: NEUROSCIENCES Keywords: Uner Tan syndrome, quadrupedal locomotion, ataxia, gait, lateral sequence, diagonal sequence, evolution, primates How to cite the article: Tan U. Gait Analysis in Uner Tan Syndrome Cases with Key Symptoms of Quadrupedal Locomotion, Mental Impairment, and Dysarthric or No Speech. WebmedCentral NEUROSCIENCES 2015;6(11):WMC005017 Copyright: This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC-BY), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Source(s) of Funding: None Competing Interests: None Additional Files: Illustration 1 ILLUSTRATION 2 ILLUSTRATION 3 ILLUSTRATION 4 ILLUSTRATION 5 ILLUSTRATION 6 WebmedCentral > Research articles Page 1 of 14 WMC005017 Downloaded from http://www.webmedcentral.com on 10-Nov-2015, 08:43:10 AM Gait Analysis in Uner Tan Syndrome Cases with Key Symptoms of Quadrupedal Locomotion, Mental Impairment, and Dysarthric or No Speech Author(s): Tan U Abstract sequence, on the lateral and on the diagonals.” This child typically exhibited straight legs during quadrupedal standing. Introduction: Uner Tan syndrome (UTS) consists of A man with healthy legs walking on all fours was quadrupedal locomotion (QL), impaired intelligence discovered by Childs [3] in Turkey, 1917.
    [Show full text]
  • Rethinking the Evolution of the Human Foot: Insights from Experimental Research Nicholas B
    © 2018. Published by The Company of Biologists Ltd | Journal of Experimental Biology (2018) 221, jeb174425. doi:10.1242/jeb.174425 REVIEW Rethinking the evolution of the human foot: insights from experimental research Nicholas B. Holowka* and Daniel E. Lieberman* ABSTRACT presumably owing to their lack of arches and mobile midfoot joints Adaptive explanations for modern human foot anatomy have long for enhanced prehensility in arboreal locomotion (see Glossary; fascinated evolutionary biologists because of the dramatic differences Fig. 1B) (DeSilva, 2010; Elftman and Manter, 1935a). Other studies between our feet and those of our closest living relatives, the great have documented how great apes use their long toes, opposable apes. Morphological features, including hallucal opposability, toe halluces and mobile ankles for grasping arboreal supports (DeSilva, length and the longitudinal arch, have traditionally been used to 2009; Holowka et al., 2017a; Morton, 1924). These observations dichotomize human and great ape feet as being adapted for bipedal underlie what has become a consensus model of human foot walking and arboreal locomotion, respectively. However, recent evolution: that selection for bipedal walking came at the expense of biomechanical models of human foot function and experimental arboreal locomotor capabilities, resulting in a dichotomy between investigations of great ape locomotion have undermined this simple human and great ape foot anatomy and function. According to this dichotomy. Here, we review this research, focusing on the way of thinking, anatomical features of the foot characteristic of biomechanics of foot strike, push-off and elastic energy storage in great apes are assumed to represent adaptations for arboreal the foot, and show that humans and great apes share some behavior, and those unique to humans are assumed to be related underappreciated, surprising similarities in foot function, such as to bipedal walking.
    [Show full text]
  • Conference Main Sponsors-2018
    Anatomical variation of habitat related changes in scapular morphology C. Luziga1 and N. Wada2 1Department of Veterinary Anatomy and Pathology, College of Veterinary and Biomedical Sciences, Sokoine University of Agriculture, Morogoro, Tanzania 2Laboratory Physiology, Department of Veterinary Sciences, School of Veterinary Medicine, Yamaguchi University, Yamaguchi 753-8558, Japan E-mail: [email protected] SUMMARY The mammalian forelimb is adapted to different functions including postural, locomotor, feeding, exploratory, grooming and defense. Comparative studies on morphology of the mammalian scapula have been performed in an attempt to establish the functional differences in the use of the forelimb. In this study, a total of 102 scapulae collected from 66 species of animals, representatives of all major taxa from rodents, sirenians, marsupials, pilosa, cetaceans, carnivores, ungulates, primates and apes were analyzed. Parameters measured included scapular length, width, position, thickness, area, angles and index. Structures included supraspinous and infraspinous fossae, scapular spine, glenoid cavity, acromium and coracoid processes. Images were taken using computed tomographic (CT) scanning technology (CT-Aquarium, Toshiba and micro CT- LaTheta, Hotachi, Japan) and measurement values acquired and processed using Avizo computer software and CanvasTM 11 ACD systems. Statistical analysis was performed using Microsoft Excel 2013. Results obtained showed that there were similar morphological characteristics of scapula in mammals with arboreal locomotion and living in forest and mountainous areas but differed from those with leaping and terrestrial locomotion living in open habitat or savannah. The cause for the statistical grouping of the animals signifies presence of the close relationship between habitat and scapular morphology and in a way that corresponds to type of locomotion and speed.
    [Show full text]
  • Orangutan Positional Behavior and the Nature of Arboreal Locomotion in Hominoidea Susannah K.S
    AMERICAN JOURNAL OF PHYSICAL ANTHROPOLOGY 000:000–000 (2006) Orangutan Positional Behavior and the Nature of Arboreal Locomotion in Hominoidea Susannah K.S. Thorpe1* and Robin H. Crompton2 1School of Biosciences, University of Birmingham, Edgbaston, Birmingham B15 2TT, UK 2Department of Human Anatomy and Cell Biology, University of Liverpool, Liverpool L69 3GE, UK KEY WORDS Pongo pygmaeus; posture; orthograde clamber; forelimb suspend ABSTRACT The Asian apes, more than any other, are and orthograde compressive locomotor modes are ob- restricted to an arboreal habitat. They are consequently an served more frequently. Given the complexity of orangu- important model in the interpretation of the morphological tan positional behavior demonstrated by this study, it is commonalities of the apes, which are locomotor features likely that differences in positional behavior between associated with arboreal living. This paper presents a de- studies reflect differences in the interplay between the tailed analysis of orangutan positional behavior for all age- complex array of variables, which were shown to influence sex categories and during a complete range of behavioral orangutan positional behavior (Thorpe and Crompton [2005] contexts, following standardized positional mode descrip- Am. J. Phys. Anthropol. 127:58–78). With the exception tions proposed by Hunt et al. ([1996] Primates 37:363–387). of pronograde suspensory posture and locomotion, orang- This paper shows that orangutan positional behavior is utan positional behavior is similar to that of the African highly complex, representing a diverse spectrum of posi- apes, and in particular, lowland gorillas. This study sug- tional modes. Overall, all orthograde and pronograde sus- gests that it is orthogrady in general, rather than fore- pensory postures are exhibited less frequently in the pres- limb suspend specifically, that characterizes the posi- ent study than previously reported.
    [Show full text]
  • The Biodynamics of Arboreal Locomotion in the Gray Short
    THE BIODYNAMICS OF ARBOREAL LOCOMOTION IN THE GRAY SHORT- TAILED OPOSSUM (MONODELPHIS DOMESTICA) A dissertation presented to the faculty of the College of Arts and Sciences of Ohio University In partial fulfillment of the requirements for the degree Doctor of Philosophy Andrew R. Lammers August 2004 This dissertation entitled THE BIODYNAMICS OF ARBOREAL LOCOMOTION IN THE GRAY SHORT- TAILED OPOSSUM (MONODELPHIS DOMESTICA) BY ANDREW R. LAMMERS has been approved for the Department of Biological Sciences and the College of Arts and Sciences by Audrone R. Biknevicius Associate Professor of Biomedical Sciences Leslie A. Flemming Dean, College of Arts and Sciences LAMMERS, ANDREW R. Ph.D. August 2004. Biological Sciences The biodynamics of arboreal locomotion in the gray short-tailed opossum (Monodelphis domestica). (147 pp.) Director of Dissertation: Audrone R. Biknevicius Most studies of animal locomotor biomechanics examine movement on a level, flat trackway. However, small animals must negotiate heterogenerous terrain that includes changes in orientation and diameter. Furthermore, animals which are specialized for arboreal locomotion may solve the biomechanical problems that are inherent in substrates that are sloped and/or narrow differently from animals which are considered terrestrial. Thus I studied the effects of substrate orientation and diameter on locomotor kinetics and kinematics in the gray short-tailed opossum (Monodelphis domestica). The genus Monodelphis is considered the most terrestrially adapted member of the family Didelphidae, but nevertheless these opossums are reasonably skilled at climbing. The first study (Chapter 2) examines the biomechanics of moving up a 30° incline and down a 30° decline. Substrate reaction forces (SRFs), limb kinematics, and required coefficient of friction were measured.
    [Show full text]
  • Linking Gait Dynamics to Mechanical Cost of Legged Locomotion
    REVIEW published: 17 October 2018 doi: 10.3389/frobt.2018.00111 Linking Gait Dynamics to Mechanical Cost of Legged Locomotion David V. Lee 1* and Sarah L. Harris 2 1 School of Life Sciences, University of Nevada Las Vegas, Las Vegas, NV, United States, 2 Department of Electrical and Computer Engineering, University of Nevada Las Vegas, Las Vegas, NV, United States For millenia, legged locomotion has been of central importance to humans for hunting, agriculture, transportation, sport, and warfare. Today, the same principal considerations of locomotor performance and economy apply to legged systems designed to serve, assist, or be worn by humans in urban and natural environments. Energy comes at a premium not only for animals, wherein suitably fast and economical gaits are selected through organic evolution, but also for legged robots that must carry sufficient energy in their batteries. Although a robot’s energy is spent at many levels, from control systems to actuators, we suggest that the mechanical cost of transport is an integral energy expenditure for any legged system—and measuring this cost permits the most direct comparison between gaits of legged animals and robots. Although legged robots have matched or even improved upon total cost of transport of animals, this is typically achieved by choosing extremely slow speeds or by using regenerative mechanisms. Legged robots have not yet reached the low mechanical cost of transport achieved at speeds used by bipedal and quadrupedal animals. Here we consider approaches Edited by: used to analyze gaits and discuss a framework, termed mechanical cost analysis, that Monica A. Daley, can be used to evaluate the economy of legged systems.
    [Show full text]
  • Hand Pressures During Arboreal Locomotion in Captive Bonobos (Pan Paniscus) Diana S
    © 2018. Published by The Company of Biologists Ltd | Journal of Experimental Biology (2018) 221, jeb170910. doi:10.1242/jeb.170910 RESEARCH ARTICLE Hand pressures during arboreal locomotion in captive bonobos (Pan paniscus) Diana S. Samuel1, Sandra Nauwelaerts2,3, Jeroen M. G. Stevens3,4 and Tracy L. Kivell1,5,* ABSTRACT of both manipulation and locomotion. Although there has been much Evolution of the human hand has undergone a transition from use research into the potential changes in manipulative abilities during locomotion to use primarily for manipulation. Previous throughout human evolution, from both morphological (e.g. comparative morphological and biomechanical studies have Napier, 1955; Marzke, 1997; Marzke et al., 1999; Skinner et al., focused on potential changes in manipulative abilities during 2015) and biomechanical (e.g. Marzke et al., 1998; Rolian et al., human hand evolution, but few have focused on functional signals 2011; Williams et al., 2012; Key and Dunmore, 2014) perspectives, for arboreal locomotion. Here, we provide this comparative context comparatively little research has been done that may help us infer though the first analysis of hand loading in captive bonobos during how our ancestors may have used their hands for arboreal arboreal locomotion. We quantify pressure experienced by the locomotion, particularly climbing and suspension. Many fossil fingers, palm and thumb in bonobos during vertical locomotion, hominins show features of the hand (e.g. curved fingers) and upper suspension and arboreal knuckle-walking. The results show that limb (e.g. superiorly oriented shoulder joint) (e.g. Stern, 2000; pressure experienced by the fingers is significantly higher during Larson, 2007; Churchill et al., 2013; Kivell et al., 2011, 2015; Kivell, knuckle-walking compared with similar pressures experienced by the 2015) that suggest arboreal locomotion may still have been an fingers and palm during suspensory and vertical locomotion.
    [Show full text]
  • Fleagle and Lieberman 2015F.Pdf
    15 Major Transformations in the Evolution of Primate Locomotion John G. Fleagle* and Daniel E. Lieberman† Introduction Compared to other mammalian orders, Primates use an extraordinary diversity of locomotor behaviors, which are made possible by a complementary diversity of musculoskeletal adaptations. Primate locomotor repertoires include various kinds of suspension, bipedalism, leaping, and quadrupedalism using multiple pronograde and orthograde postures and employing numerous gaits such as walking, trotting, galloping, and brachiation. In addition to using different locomotor modes, pri- mates regularly climb, leap, run, swing, and more in extremely diverse ways. As one might expect, the expansion of the field of primatology in the 1960s stimulated efforts to make sense of this diversity by classifying the locomotor behavior of living primates and identifying major evolutionary trends in primate locomotion. The most notable and enduring of these efforts were by the British physician and comparative anatomist John Napier (e.g., Napier 1963, 1967b; Napier and Napier 1967; Napier and Walker 1967). Napier’s seminal 1967 paper, “Evolutionary Aspects of Primate Locomotion,” drew on the work of earlier comparative anatomists such as LeGros Clark, Wood Jones, Straus, and Washburn. By synthesizing the anatomy and behavior of extant primates with the primate fossil record, Napier argued that * Department of Anatomical Sciences, Health Sciences Center, Stony Brook University † Department of Human Evolutionary Biology, Harvard University 257 You are reading copyrighted material published by University of Chicago Press. Unauthorized posting, copying, or distributing of this work except as permitted under U.S. copyright law is illegal and injures the author and publisher. fig. 15.1 Trends in the evolution of primate locomotion.
    [Show full text]
  • 1 Early Evolution of the Foot
    1 Early Evolution of the Foot The history of life can be best understood using the analogy of a tree. All living things, be they animals, plants, fungi, bacteria, or viruses are on the outside of the tree, but they are all descended from a common ancestor at its base. The evolu- tionary history of all these living forms is represented by the branches within the tree. Modern humans are at the end of a relatively short twig. There is reliable genetic evidence to suggest that our nearest neighbor on the Tree of Life is the chimpanzee, with another African ape, the gorilla, being the next closest neigh- bour. The combined chimp/human twig is part of a small higher primate branch, which is part of a larger primate branch, which is just a small component of the bough of the Tree of Life that includes all animals (Figure 1.1). This chapter looks into the branches of the Tree of Life to reconstruct the ‘deep’ evolutionary history of modern human feet. Our feet are unique. No other living animal has feet like ours, but as we show in the next chapter some of our extinct ancestors and cousins had feet that were like those of modern humans. What type of animals showed the first signs of appendages that eventually gave rise to primate feet? What can we tell about these distant ancestors and cousins that will help us make sense of the more recent evolutionary history of modern human feet? We trace the emergence of simple, primitive, paired limbs and then examine how selective forces have resulted in the various types of foot structures we see in some of the major groups of living mammals.
    [Show full text]
  • The Biodynamics of Arboreal Locomotion: the Effects of Substrate Diameter on Locomotor Kinetics in the Gray Short-Tailed Opossum (Monodelphis Domestica) Andrew R
    The Journal of Experimental Biology 207, 4325-4336 4325 Published by The Company of Biologists 2004 doi:10.1242/jeb.01231 The biodynamics of arboreal locomotion: the effects of substrate diameter on locomotor kinetics in the gray short-tailed opossum (Monodelphis domestica) Andrew R. Lammers1,* and Audrone R. Biknevicius2 1Department of Biological Sciences, Ohio University, Athens, OH 45701, USA and 2Department of Biomedical Sciences, Ohio University College of Osteopathic Medicine, Athens, OH 45701, USA *Author for correspondence at present address: Department of Health Sciences, Cleveland State University, Cleveland, OH 44115, USA (e-mail: [email protected]) Accepted 9 August 2004 Summary Effects of substrate diameter on locomotor biodynamics segregated between limbs on the terrestrial trackway, fore were studied in the gray short-tailed opossum limbs were dominant both in braking and in propulsion on (Monodelphis domestica). Two horizontal substrates were the arboreal trackway. Both fore and hind limbs exerted used: a flat ‘terrestrial’ trackway with a force platform equivalently strong, medially directed limb forces on the integrated into the surface and a cylindrical ‘arboreal’ arboreal trackway and laterally directed limb forces on the trackway (20.3·mm diameter) with a force-transducer terrestrial trackway. We propose that the modifications in instrumented region. On both terrestrial and arboreal substrate reaction force on the arboreal trackway are due substrates, fore limbs exhibited higher vertical impulse and to the differential placement of the limbs about the peak vertical force than hind limbs. Although vertical limb dorsolateral aspect of the branch. Specifically, the pes impulses were lower on the terrestrial substrate than on typically made contact with the branch lower and more the arboreal support, this was probably due to speed laterally than the manus, which may explain the effects because the opossums refused to move as quickly on significantly lower required coefficient of friction in the the arboreal trackway.
    [Show full text]
  • Analyzing the Form and Function of the Hominoid Scapula Using Geometric Morphometrics and Finite Element Analysis
    AMERICAN JOURNAL OF PHYSICAL ANTHROPOLOGY 159:325–341 (2016) Standing on the Shoulders of Apes: Analyzing the Form and Function of the Hominoid Scapula Using Geometric Morphometrics and Finite Element Analysis Thomas A. Puschel*€ and William I. Sellers Computational and Evolutionary Biology Group, Faculty of Life Sciences, University of Manchester, Manchester, M13 9PT, UK KEY WORDS shape; biomechanical performance; scapulae; hominoidea ABSTRACT Objective: The aim was to analyze the relationship between scapular form and function in hominoids by using geometric morphometrics (GM) and finite element analysis (FEA). Methods: FEA was used to analyze the biomechanical performance of different hominoid scapulae by simulating static postural scenarios. GM was used to quantify scapular shape differences and the relationship between form and function was analyzed by applying both multivariate-multiple regressions and phylogenetic generalized least- squares regressions (PGLS). Results: Although it has been suggested that primate scapular morphology is mainly a product of function rather than phylogeny, our results showed that shape has a significant phylogenetic signal. There was a significant rela- tionship between scapular shape and its biomechanical performance; hence at least part of the scapular shape varia- tion is due to non-phylogenetic factors, probably related to functional demands. Discussion: This study has shown that a combined approach using GM and FEA was able to cast some light regarding the functional and phylogenetic contributions in hominoid scapular morphology, thus contributing to a better insight of the association between scapular form and function. Am J Phys Anthropol 159:325–341, 2016. VC 2015 Wiley Periodicals, Inc. Primates live in diverse environments, mastering both using knuckle-walking when travelling (Hunt, 2004), life in trees and in terrestrial locations (Fleagle, 1998).
    [Show full text]