Your search keyword '"hind limb"' showing total 9 results

1. Geckos decouple fore- and hind limb kinematics in response to changes in incline.

Author

Birn-Jeffery, Aleksandra V. and Higham, Timothy E.

Subjects

*HINDLIMB, *GECKOS, *MUSCULOSKELETAL system, *FORELIMB, *BODY movement

Abstract

Background: Terrestrial animals regularly move up and down surfaces in their natural habitat, and the impacts of moving uphill on locomotion are commonly examined. However, if an animal goes up, it must go down. Many morphological features enhance locomotion on inclined surfaces, including adhesive systems among geckos. Despite this, it is not known whether the employment of the adhesive system results in altered locomotor kinematics due to the stereotyped motions that are necessary to engage and disengage the system. Using a generalist pad-bearing gecko, Chondrodactylus bibronii, we determined whether changes in slope impact body and limb kinematics. Results: Despite the change in demand, geckos did not change speed on any incline. This constant speed was achieved by adjusting stride frequency, step length and swing time. Hind limb, but not forelimb, kinematics were altered on steep downhill conditions, thus resulting in significant de-coupling of the limbs. Conclusions: Unlike other animals on non-level conditions, the geckos in our study only minimally alter the movements of distal limb elements, which is likely due to the constraints associated with the need for rapid attachment and detachment of the adhesive system. This suggests that geckos may experience a trade-off between successful adhesion and the ability to respond dynamically to locomotor perturbations. [ABSTRACT FROM AUTHOR]

Published

2016

2. A pressure plate study on fore and hindlimb loading and the association with hoof contact area in sound ponies at the walk and trot.

Author

Oosterlinck, M., Pille, F., Back, W., Dewulf, J., and Gasthuys, F.

Subjects

*FORELIMB, *PONIES, *ANIMAL mechanics, *SYMMETRY (Biology), *HOOFS, *MUSCULOSKELETAL system

Abstract

The aim of this study was to evaluate the association between fore- and hind-hoof contact area and limb loading. Data from a previous study on forelimb loading and symmetry were compared with data on hindlimb kinetics, and the fore- and hind-hoof contact area at the walk and trot was evaluated. Five sound ponies, selected for symmetrical feet, were walked and trotted over a pressure plate embedded in a custom-made runway. The hindlimb peak vertical force (PVF) and vertical impulse (VI) were found to be significantly lower than in the forelimb, whereas their high symmetry ratios (>95%) did not show a significant difference from forelimb data. Hindlimb PVF in ponies was found to be slightly higher when compared to data reported for horses even though the ponies moved at a similar or lower relative velocity. The contact area had low intra-individual variability and was significantly smaller in the hind- than in the fore-hooves. A larger contact area was significantly associated with lower peak vertical pressure (PVP) but higher PVF and VI. No significant differences between left and right sides were found for contact area or loading variables. Pressure plate measurements demonstrated a significant association between hoof contact area and limb loading, in addition to intrinsic differences between fore and hindlimb locomotor function. The pressure plate provides the clinician with a tool to quantify simultaneously contralateral differences in hoof contact area and limb loading. [ABSTRACT FROM AUTHOR]

Published

2011

3. DIFFERENCES IN THE TIMING OF PRECHONDROGENIC LIMB DEVELOPMENT IN MAMMALS: THE MARSUPIAL–PLACENTAL DICHOTOMY RESOLVED.

Author

Sears, Karen E.

Subjects

*MARSUPIALS, *PREGNANCY in animals, *BIOLOGICAL evolution, *EXTREMITIES (Anatomy), *GENETICS

Abstract

In contrast to placentals, marsupials are born with forelimbs that are greatly developmentally advanced relative to their hind limbs. Despite significant interest, we still do not know why this is the case, or how this difference is achieved developmentally. Studies of prechondrogenic and chondrogenic limbs have supported the traditional hypothesis that marsupial forelimb development is accelerated in response to the functional requirements of the newborn's crawl to the teat. However, limb ossification studies have concluded that, rather than the forelimb being accelerated, hind limb development is delayed. By increasing the taxonomic coverage and number of prechondrogenic events relative to previous studies, and combining traditional phylogenetic analyses of event sequences with novel analyses of relative developmental rates, this study demonstrates that the timing of limb development in marsupials is more complex than commonly thought. The marsupial phenotype was derived through two independent evolutionary changes in developmental rate: (1) an acceleration of the forelimb's first appearance and (2) a delay of hind limb development from the bud stage onward. Surprisingly, this study also provides some support for an evolutionary acceleration of the marsupial hind limb's first appearance. Further study is needed on the developmental and genetic mechanisms driving these major evolutionary transitions. [ABSTRACT FROM AUTHOR]

Published

2009

4. Choosing the correct functional assay: A comprehensive assessment of functional tests in the rat

Author

Nichols, Chris M., Myckatyn, Terence M., Rickman, Susan R., Fox, Ida K., Hadlock, Tessa, and Mackinnon, Susan E.

Subjects

*NERVOUS system regeneration, *EXTREMITIES (Anatomy), *PERIPHERAL nervous system, *NERVOUS system

Abstract

Abstract: While there are several ways to quantify peripheral nerve regeneration; the true measure of successful outcome is functional recovery. Functional tests are relatively easily conducted in human subjects; however it is more difficult in a laboratory animal. The laboratory rat is an excellent animal model of peripheral nerve injury and has been used extensively in the field of peripheral nerve research. Due to the intense interest in the rat as an experimental model, functional assays have been reported. In an effort to provide a resource to which investigators can refer when considering the most appropriate functional assay for a given experiment, the authors have compiled and tabulated the available functional tests applicable to various models of rat nerve injury. [Copyright &y& Elsevier]

Published

2005

5. Angular Displacement Patterns of Leading and Trailing Limb Joints During Galloping in Monkeys.

Author

Vilensky, Joel A., Moore-Kuhns, Marsha, and Moore, Ann M.

Subjects

*CERCOPITHECUS aethiops, *SQUIRREL monkeys, *GALLOPING, *ANIMAL locomotion, *ANIMAL behavior, *PRIMATES

Abstract

The movement patterns of the joints of the right hind limbs and forelimbs of four vervet and one squirrel monkey were compared during right- and left-lead gallops. Although the overall displacement patterns were similar under both conditions, comparisons of the inflection points in the curves yielded consistent differences in the joints at various phases in the cycle. Some of these differences appear to reflect differing mechanical conditions, whereas others seem to represent variation in muscle activation patterns. Although some of the differences in the joints under the two conditions were consistent with those reported previously for other quadrupeds, others were not. This may reflect that different quadrupeds are slightly different biomechanical strategies during galloping. [ABSTRACT FROM AUTHOR]

Published

1990

6. Osteology and Functional Morphology of the Hind Limb of the Marine Sloth Thalassocnus (Mammalia, Tardigrada)

Author

Eli Amson, H. Gregory McDonald, Christine Argot, Christian de Muizon, Centre de recherche sur la Paléobiodiversité et les Paléoenvironnements (CR2P), Muséum national d'Histoire naturelle (MNHN)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS), Park Museum Management Program, National Park Service, AG Morphologie und Formengeschichte & Institut für Biologie [Berlin], Humboldt-Universität zu Berlin, Centre National de la Recherche Scientifique (CNRS)-Muséum national d'Histoire naturelle (MNHN)-Université Pierre et Marie Curie - Paris 6 (UPMC), Centre de Recherche en Paléontologie - Paris (CR2P), and Muséum national d'Histoire naturelle (MNHN)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)

Subjects

0106 biological sciences, 010506 paleontology, animal structures, Hind limb, Marine mammal, 010603 evolutionary biology, 01 natural sciences, biology.animal, Pisco Formation, medicine, 14. Life underwater, Thalassocnus, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, biology, Osteology, Aquatic adaptation, Xenarthra, Anatomy, Sloth, biology.organism_classification, Functional anatomy, Skull, medicine.anatomical_structure, Forelimb, [SDU.STU.PG]Sciences of the Universe [physics]/Earth Sciences/Paleontology

Abstract

International audience; The anatomy of the skeletal elements of the hind limb of Thalassocnus is described. This genus of "ground sloth" comprises five species represented by Neogene specimens from the coast of Peru and Chile, mostly found in the Pisco Formation. The hind limb of the genus Thalassocnus as a whole is characterized by a small iliac wing, a gracile femur with well-formed femoral neck, teardrop shaped patella, long and slender tibia, triangular tuber calcis, and proximal development of the lateral process of the Mt V. The comparison of the species of Thalassocnus with each other suggests a progressive shift to a particular ecology from the earliest to the latest species of the genus, a conclusion in agreement with those of the studies of craniomandibular, dental, and forelimb gross morphology, and bone internal microstructure. The pedolateral stance, which involves the bearing of the weight on the lateral side of the foot, was practiced by the earliest species of Thalassocnus, as was the case for other Megatheria. This stance was apparently forsaken by the late species of the genus in favor of the acquisition of a secondary plantigrady. A plantigrade hind limb may have been more efficient for paddling and for bottom-walking. Additionally, the late species of Thalassocnus differ from the early ones in the morphology of the pelvis and the slight overall reduction of the hind limb. This suggests the decrease of the support function of the hind limb of these species when compared to that of the early species of Thalassocnus.

Published

2014

7. The Effects of Inclination (Up and Down) of the Treadmill on the Electromyogram Activities of the Forelimb and Hind limb Muscles at a Walk and a Trot in Thoroughbred Horses

Author

Atsushi Hiraga, Hiroko Aida, Toshiyuki Takahashi, Kazutaka Mukai, Akira Matsui, and Hajime Ohmura

Subjects

inclination, animal structures, biology, Equine, business.industry, electromyogram, Anatomy, Hindlimb, Thoroughbred, biology.organism_classification, Biceps, forelimb, body regions, hind limb, Medius, medicine.anatomical_structure, medicine, Original Article, Forelimb, Treadmill, business, Longissimus dorsi

Abstract

It is important to know the effects of the inclination of a slope on the activity of each muscle, because training by running on a sloped track is commonly used for Thoroughbred racehorses. The effects of incline (from −6 to +6%) on the forelimbs and hind limbs during walking and trotting on a treadmill were evaluated by an integrated electromyogram (iEMG). The muscle activities in the forelimbs (5 horses) and hind limbs (4 horses) were measured separately. Two stainless steel wires were inserted into each of the brachiocephalicus (Bc), biceps brachii (BB), splenius (Sp), and pectoralis descendens (PD) in the forelimb experiment and into the longissimus dorsi (LD), vastus lateralis (VL), gluteus medius (GM), and biceps femoris (BF) in the hind limb experiment. The EMG recordings were taken at a sampling rate of 1,000 Hz. At a walk, the iEMG values for the forelimb were not significantly different under any of the inclinations. In the hind limb, the iEMG values for the GM and BF significantly decreased as the inclination decreased. At a trot, the iEMG values for the Bc in the forelimb significantly decreased as the inclination of the treadmill decreased. In the hind limb, the iEMG values for the LD, GM, and BF significantly decreased as the inclination decreased. Uphill exercise increased the iEMG values for the Bc, LD, GM, and BF, while downhill exercise resulted in little increase in the iEMG values. It was concluded that the effects of inclination on the muscle activities were larger for the uphill exercises, and for the hind limb muscles compared with the forelimb muscles.

Published

2014

8. Strength properties of extant hominoid hallucal and pollical metapodials.

Author

Patel, Biren A., Orr, Caley M., and Jashashvili, Tea

Subjects

*APES, *COMPACT bone, *HOMINIDS, *CHIMPANZEES, *ORANGUTANS, *BONES

Abstract

Functional comparisons of cortical bone strength properties between hominoid hallucal and pollical metapodials (Mt1 and Mc1, respectively) are lacking. Determining which of these two elements is stronger, and by how much, could be informative because the hallux and pollex are used differently both within and among extant hominoids during locomotion and manipulation (i.e., functional differentiation between autopod pairs). Here, we compare Mt1 and Mc1 midshaft cortical area, polar section modulus, and polar second moment of area, calculated from high-resolution computed tomography images in humans (n = 21), chimpanzees (n = 47), gorillas (n = 24), orangutans (n = 20), siamangs (n = 8), and gibbons (n = 21). Intraindividual comparisons between bones within species were made using paired t-tests. Log 10 -transformed Mt1:Mc1 ratios were created to assess relative strength asymmetry between bones, and interspecific comparisons of these proportions were made using analyses of variance. Absolute strength differences between the Mt1 and Mc1 for all variables were significantly larger in the Mt1 for all species (p < 0.05). Significant differences across species in Mt1:Mc1 proportions were also found, thereby demonstrating that strength asymmetry between bones differs among taxa (p < 0.05); asymmetry was lowest in orangutans, intermediate in gorillas, and greatest in humans, chimpanzees, siamangs, and gibbons. These findings support the hypothesis that the Mt1 is better adapted structurally than the Mc1 for bearing mechanical loads during weight support of locomotion in all extant hominoids and that pedal hallucal grasping likely engenders higher loads than manual pollical grasping in nonhuman hominoids. Thus, functional differentiation in autopod use within and among hominoids is reflected in hallucal and pollical metapodial strength properties. [ABSTRACT FROM AUTHOR]

Published

2020

9. Geckos decouple fore- and hind limb kinematics in response to changes in incline

Author

Aleksandra V. Birn-Jeffery and Timothy E. Higham

Subjects

030110 physiology, 0301 basic medicine, medicine.medical_specialty, Hind limb, STRIDE, Hindlimb, Kinematics, 03 medical and health sciences, Physical medicine and rehabilitation, Decline, Adhesive system, Forelimb, medicine, Gecko, Incline, Ecology, Evolution, Behavior and Systematics, biology, Research, Anatomy, Stride length, biology.organism_classification, Distal limb, body regions, medicine.anatomical_structure, Animal Science and Zoology

Abstract

Background Terrestrial animals regularly move up and down surfaces in their natural habitat, and the impacts of moving uphill on locomotion are commonly examined. However, if an animal goes up, it must go down. Many morphological features enhance locomotion on inclined surfaces, including adhesive systems among geckos. Despite this, it is not known whether the employment of the adhesive system results in altered locomotor kinematics due to the stereotyped motions that are necessary to engage and disengage the system. Using a generalist pad-bearing gecko, Chondrodactylus bibronii, we determined whether changes in slope impact body and limb kinematics. Results Despite the change in demand, geckos did not change speed on any incline. This constant speed was achieved by adjusting stride frequency, step length and swing time. Hind limb, but not forelimb, kinematics were altered on steep downhill conditions, thus resulting in significant de-coupling of the limbs. Conclusions Unlike other animals on non-level conditions, the geckos in our study only minimally alter the movements of distal limb elements, which is likely due to the constraints associated with the need for rapid attachment and detachment of the adhesive system. This suggests that geckos may experience a trade-off between successful adhesion and the ability to respond dynamically to locomotor perturbations.