Your search keyword '"Jonas Rubenson"' showing total 20 results

1. Running birds reveal secrets for legged robot design

Author

Gregory Sawicki and Jonas Rubenson

Subjects

Birds, Control and Optimization, Artificial Intelligence, Mechanical Engineering, Animals, Robotics, Gait, Locomotion, Computer Science Applications, Running

Abstract

Recapitulating avian locomotion opens the door for simple and economical control of legged robots without sensory feedback systems.

Published

2022

2. American Society of Biomechanics Journal of Biomechanics Award 2017: High-acceleration training during growth increases optimal muscle fascicle lengths in an avian bipedal model

Author

Matthew Q. Salzano, Suzanne M. Cox, Stephen J. Piazza, and Jonas Rubenson

Subjects

Sarcomeres, 030110 physiology, 0301 basic medicine, Muscle fascicle, Movement, Acceleration, Biomedical Engineering, Biophysics, Strain (injury), Isometric exercise, Biology, Muscle mass, Article, Running, Birds, 03 medical and health sciences, Isometric Contraction, Physical Conditioning, Animal, medicine, Animals, Orthopedics and Sports Medicine, Muscle, Skeletal, High acceleration, Hip, Rehabilitation, Biomechanics, Anatomy, Fascicle, medicine.disease, Biomechanical Phenomena, medicine.anatomical_structure, Body Composition, Muscle architecture, Muscle Contraction

Abstract

Sprinters have been found to possess longer muscle fascicles than non-sprinters, which is thought to be beneficial for high-acceleration movements based on muscle force-length-velocity properties. However, it is unknown if their morphology is a result of genetics or training during growth. To explore the influence of training during growth, thirty guinea fowl (Numida meleagris) were split into exercise and sedentary groups. Exercise birds were housed in a large pen and underwent high-acceleration training during their growth period (age 4–14 weeks), while sedentary birds were housed in small pens to restrict movement. Morphological analyses (muscle mass, PCSA, optimal fascicle length, pennation angle) of a hip extensor muscle (ILPO) and plantarflexor muscle (LG), which differ in architecture and function during running, were performed post-mortem. Muscle mass for both ILPO and LG was not different between the two groups. Exercise birds were found to have ∼12% and ∼14% longer optimal fascicle lengths in ILPO and LG, respectively, than the sedentary group despite having ∼3% shorter limbs. From this study we can conclude that optimal fascicle lengths can increase as a result of high-acceleration training during growth. This increase in optimal fascicle length appears to occur irrespective of muscle architecture and in the absence of a change in muscle mass. Our findings suggest high-acceleration training during growth results in muscles that prioritize adaptations for lower strain and shortening velocity over isometric strength. Thus, the adaptations observed suggest these muscles produce higher force during dynamic contractions, which is beneficial for movements requiring large power outputs.

Published

2018

3. Three dimensional microstructural network of elastin, collagen, and cells in Achilles tendons

Author

Jianping Wu, Jonas Rubenson, Jiake Xu, Allan Wang, Xin Pang, Garry T. Allison, Minghao Zheng, David Lloyd, Bruce S. Gardiner, and Thomas Brett Kirk

Subjects

0301 basic medicine, Fibrillar Collagens, Confocal, 0206 medical engineering, 02 engineering and technology, Fibril, Achilles Tendon, Extracellular matrix, 03 medical and health sciences, medicine, Animals, Orthopedics and Sports Medicine, Achilles tendon, Fourier Analysis, biology, Chemistry, Anatomy, Elastic Tissue, 020601 biomedical engineering, Elastin, Extracellular Matrix, Tendon, Tenocytes, 030104 developmental biology, medicine.anatomical_structure, Close relationship, Biophysics, biology.protein, Rabbits, Type I collagen

Abstract

Similar to most biological tissues, the biomechanical, and functional characteristics of the Achilles tendon are closely related to its composition and microstructure. It is commonly reported that type I collagen is the predominant component of tendons and is mainly responsible for the tissue's function. Although elastin has been found in varying proportions in other connective tissues, previous studies report that tendons contain very small quantities of elastin. However, the morphology and the microstructural relationship among the elastic fibres, collagen, and cells in tendon tissue have not been well examined. We hypothesize the elastic fibres, as another fibrillar component in the extracellular matrix, have a unique role in mechanical function and microstructural arrangement in Achilles tendons. It has been shown that elastic fibres present a close connection with the tenocytes. The close relationship of the three components has been revealed as a distinct, integrated and complex microstructural network. Notably, a "spiral" structure within fibril bundles in Achilles tendons was observed in some samples in specialized regions. This study substantiates the hierarchical system of the spatial microstructure of tendon, including the mapping of collagen, elastin and tenocytes, with 3-dimensional confocal images. © 2017 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 35:1203-1214, 2017.

Published

2017

4. Eliminating high-intensity activity during growth reduces mechanical power capacity but not submaximal metabolic cost in a bipedal animal model

Author

Suzanne M. Cox, Stephen J. Piazza, Matthew Q. Salzano, and Jonas Rubenson

Subjects

0301 basic medicine, Physiology, High intensity, 030229 sport sciences, Biology, medicine.disease_cause, Metabolic cost, Biomechanical Phenomena, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Jumping, Animal model, Physiology (medical), Physical Conditioning, Animal, Models, Animal, medicine, Animals, Biochemical engineering, Galliformes, Muscle, Skeletal, Mechanical energy, Locomotion, Research Article

Abstract

Decreases in activity levels in children worldwide are feared to have long-term health repercussions. Yet, because of the difficulty of performing controlled long-term studies in humans, we do not yet understand how decreases in childhood activity influence adult functional capacity. Here, in an avian bipedal model, we evaluated the elimination of all high-intensity activity during growth on adult performance. We evaluated three alternative hypotheses: Elimination of high-intensity activity 1) does not influence adult function, 2) results in task-specific deficits in adulthood, or 3) results in deficits that generalize across locomotor tasks. We found that animals restricted from jumping and sprinting during growth showed detriments as adults in maximal jump performance in comparison to controls, but did not require more metabolic energy during steady-state running or standing. From this, we conclude that functional deficits from elimination of high-intensity exercise are task specific and do not generalize across all locomotor functions.NEW & NOTEWORTHY Decreasing childhood activity levels are feared to have long-term health repercussions, but testing this hypothesis is hampered by restrictions of human experimentation. Here, in a bipedal animal model, we examine how the elimination of high-intensity activity during all of maturation influences adult locomotor capacity. We found restricted activity during growth reduced mechanical power capacity but not submaximal metabolic cost. This suggests that reduced childhood activity may result in task-specific, rather than generalized locomotor deficits.

Published

2019

5. The influence of speed and size on avian terrestrial locomotor biomechanics: Predicting locomotion in extinct theropod dinosaurs

Author

Jonas Rubenson, J A Hancock, David Lloyd, Peter J. Bishop, Christofer J. Clemente, Dorothy Graham, Scott A. Hocknull, Rod Barrett, John R. Hutchinson, Robbie S. Wilson, and L. P. Lamas

Subjects

0106 biological sciences, 0301 basic medicine, Male, Kinematics, Muscle Physiology, Range (biology), Physiology, lcsh:Medicine, Walking, 01 natural sciences, Dinosaurs, Extant taxon, Medicine and Health Sciences, Biomechanics, lcsh:Science, Musculoskeletal System, Archosauria, Multidisciplinary, Saurischia, biology, Physics, Eukaryota, Classical Mechanics, Prehistoric Animals, Biomechanical Phenomena, Theropoda, Vertebrates, Physical Sciences, Legs, Female, Anatomy, Locomotion, Research Article, Adult, Vertebrate Paleontology, Extinction, Biological, 010603 evolutionary biology, Pelvis, Birds, 03 medical and health sciences, Animals, Humans, Ground reaction force, Paleozoology, Extinction, Hip, Biological Locomotion, lcsh:R, Limbs (Anatomy), Organisms, Biology and Life Sciences, Paleontology, Terrestrial locomotion, biology.organism_classification, 030104 developmental biology, Evolutionary biology, Amniotes, Earth Sciences, lcsh:Q, Paleobiology, Musculoskeletal Mechanics

Abstract

How extinct, non-avian theropod dinosaurs moved is a subject of considerable interest and controversy. A better understanding of non-avian theropod locomotion can be achieved by better understanding terrestrial locomotor biomechanics in their modern descendants, birds. Despite much research on the subject, avian terrestrial locomotion remains little explored in regards to how kinematic and kinetic factors vary together with speed and body size. Here, terrestrial locomotion was investigated in twelve species of ground-dwelling bird, spanning a 1,780-fold range in body mass, across almost their entire speed range. Particular attention was devoted to the ground reaction force (GRF), the force that the feet exert upon the ground. Comparable data for the only other extant obligate, striding biped, humans, were also collected and studied. In birds, all kinematic and kinetic parameters examined changed continuously with increasing speed, while in humans all but one of those same parameters changed abruptly at the walk-run transition. This result supports previous studies that show birds to have a highly continuous locomotor repertoire compared to humans, where discrete 'walking' and 'running' gaits are not easily distinguished based on kinematic patterns alone. The influences of speed and body size on kinematic and kinetic factors in birds are developed into a set of predictive relationships that may be applied to extinct, non-avian theropods. The resulting predictive model is able to explain 79-93% of the observed variation in kinematics and 69-83% of the observed variation in GRFs, and also performs well in extrapolation tests. However, this study also found that the location of the whole-body centre of mass may exert an important influence on the nature of the GRF, and hence some caution is warranted, in lieu of further investigation.

Published

2018

6. Using step width to compare locomotor biomechanics between extinct, non-avian theropod dinosaurs and modern obligate bipeds

Author

Christofer J. Clemente, John R. Hutchinson, Scott A. Hocknull, Dorothy Graham, R. E. Weems, David Lloyd, Peter J. Bishop, Robbie S. Wilson, L. P. Lamas, Jonas Rubenson, and Rod Barrett

Subjects

Male, 0106 biological sciences, 0301 basic medicine, animal structures, Biomedical Engineering, Biophysics, Bioengineering, Walking, Biology, Models, Biological, 010603 evolutionary biology, 01 natural sciences, Biochemistry, Dinosaurs, Birds, Biomaterials, 03 medical and health sciences, Paleontology, Animals, Obligate, Biomechanics, Life Sciences–Physics interface, Terrestrial locomotion, Stride length, Biomechanical Phenomena, 030104 developmental biology, Evolutionary biology, Female, Locomotion, Biotechnology

Abstract

How extinct, non-avian theropod dinosaurs locomoted is a subject of considerable interest, as is the manner in which it evolved on the line leading to birds. Fossil footprints provide the most direct evidence for answering these questions. In this study, step width—the mediolateral (transverse) distance between successive footfalls—was investigated with respect to speed (stride length) in non-avian theropod trackways of Late Triassic age. Comparable kinematic data were also collected for humans and 11 species of ground-dwelling birds. Permutation tests of the slope on a plot of step width against stride length showed that step width decreased continuously with increasing speed in the extinct theropods (p< 0.001), as well as the five tallest bird species studied (p< 0.01). Humans, by contrast, showed an abrupt decrease in step width at the walk–run transition. In the modern bipeds, these patterns reflect the use of either a discontinuous locomotor repertoire, characterized by distinct gaits (humans), or a continuous locomotor repertoire, where walking smoothly transitions into running (birds). The non-avian theropods are consequently inferred to have had a continuous locomotor repertoire, possibly including grounded running. Thus, features that characterize avian terrestrial locomotion had begun to evolve early in theropod history.

Published

2017

7. A conceptual framework for computational models of Achilles tendon homeostasis

Author

David Smith, Justin Fernandez, David Lloyd, Thor F. Besier, Jonas Rubenson, Minghao Zheng, Jiake Xu, and Bruce S. Gardiner

Subjects

Computer science, media_common.quotation_subject, Medicine (miscellaneous), Molecular Dynamics Simulation, Achilles Tendon, Biochemistry, Genetics and Molecular Biology (miscellaneous), Biomechanical Phenomena, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Humans, Tissue homeostasis, 030304 developmental biology, media_common, 0303 health sciences, Achilles tendon, Computational model, Models, Theoretical, musculoskeletal system, Experimental research, Tendon, medicine.anatomical_structure, Conceptual framework, Risk analysis (engineering), Conceptual model, Collagen, Stress, Mechanical, 030217 neurology & neurosurgery

Abstract

Computational modeling of tendon lags the development of computational models for other tissues. A major bottleneck in the development of realistic computational models for Achilles tendon is the absence of detailed conceptual and theoretical models as to how the tissue actually functions. Without the conceptual models to provide a theoretical framework to guide the development and integration of multiscale computational models, modeling of the Achilles tendon to date has tended to be piecemeal and focused on specific mechanical or biochemical issues. In this paper, we present a new conceptual model of Achilles tendon tissue homeostasis, and discuss this model in terms of existing computational models of tendon. This approach has the benefits of structuring the research on relevant computational modeling to date, while allowing us to identify new computational models requiring development. The critically important functional issue for tendon is that it is continually damaged during use and so has to be repaired. From this follows the centrally important issue of homeostasis of the load carrying collagen fibrils within the collagen fibers of the Achilles tendon. Collagen fibrils may be damaged mechanically-by loading, or damaged biochemically-by proteases. Upon reviewing existing computational models within this conceptual framework of the Achilles tendon structure and function, we demonstrate that a great deal of theoretical and experimental research remains to be done before there are reliably predictive multiscale computational model of Achilles tendon in health and disease.

Published

2013

8. Bioreactor Design for Tendon/Ligament Engineering

Author

David Smith, Jonas Rubenson, Zhen Lin, Bruce S. Gardiner, Tao Wang, Jiake Xu, Ming H. Zheng, David Lloyd, Thomas Brett Kirk, and Allan Wang

Subjects

musculoskeletal diseases, Engineering, Biomedical Engineering, Bioengineering, Clinical settings, complex mixtures, Biochemistry, Tendons, Biomaterials, Bioreactors, medicine, Bioreactor, Animals, Humans, Regeneration, Ligament injury, Review Articles, Ligaments, Tissue Engineering, business.industry, Culture environment, technology, industry, and agriculture, Treatment options, Equipment Design, equipment and supplies, musculoskeletal system, Tendon, medicine.anatomical_structure, Tendon ligament, Ligament, business, Biomedical engineering

Abstract

Tendon and ligament injury is a worldwide health problem, but the treatment options remain limited. Tendon and ligament engineering might provide an alternative tissue source for the surgical replacement of injured tendon. A bioreactor provides a controllable environment enabling the systematic study of specific biological, biochemical, and biomechanical requirements to design and manufacture engineered tendon/ligament tissue. Furthermore, the tendon/ligament bioreactor system can provide a suitable culture environment, which mimics the dynamics of the in vivo environment for tendon/ligament maturation. For clinical settings, bioreactors also have the advantages of less-contamination risk, high reproducibility of cell propagation by minimizing manual operation, and a consistent end product. In this review, we identify the key components, design preferences, and criteria that are required for the development of an ideal bioreactor for engineering tendons and ligaments.

Published

2013

9. Programmable mechanical stimulation influences tendon homeostasis in a bioreactor system

Author

Euphemie Landao-Bassonga, David Lloyd, Zhen Lin, Thomas Brett Kirk, Allan Wang, Bruce S. Gardiner, Robert E. Day, Ming H. Zheng, Qiujian Zheng, Tao Wang, Gerard Hardisty, Jonas Rubenson, and David Smith

Subjects

Apoptosis, Cell Count, Bioengineering, Stimulation, Matrix (biology), Achilles Tendon, Applied Microbiology and Biotechnology, Extracellular matrix, Bioreactors, Tensile Strength, Ultimate tensile strength, medicine, Animals, Humans, Cell Shape, Analysis of Variance, Tissue Engineering, Histocytochemistry, Chemistry, Regeneration (biology), medicine.disease, Biomechanical Phenomena, Extracellular Matrix, Tendon, Collagen Type III, medicine.anatomical_structure, Eccentric training, Female, Rabbits, Stress, Mechanical, Tendinopathy, Biotechnology, Biomedical engineering

Abstract

Identification of functional programmable mechanical stimulation (PMS) on tendon not only provides the insight of the tendon homeostasis under physical/pathological condition, but also guides a better engineering strategy for tendon regeneration. The aims of the study are to design a bioreactor system with PMS to mimic the in vivo loading conditions, and to define the impact of different cyclic tensile strain on tendon. Rabbit Achilles tendons were loaded in the bioreactor with/without cyclic tensile loading (0.25 Hz for 8 h/day, 0-9% for 6 days). Tendons without loading lost its structure integrity as evidenced by disorientated collagen fiber, increased type III collagen expression, and increased cell apoptosis. Tendons with 3% of cyclic tensile loading had moderate matrix deterioration and elevated expression levels of MMP-1, 3, and 12, whilst exceeded loading regime of 9% caused massive rupture of collagen bundle. However, 6% of cyclic tensile strain was able to maintain the structural integrity and cellular function. Our data indicated that an optimal PMS is required to maintain the tendon homeostasis and there is only a narrow range of tensile strain that can induce the anabolic action. The clinical impact of this study is that optimized eccentric training program is needed to achieve maximum beneficial effects on chronic tendinopathy management.

Published

2013

10. Inferring muscle functional roles of the ostrich pelvic limb during walking and running using computer optimization

Author

John R. Hutchinson, Jonas Rubenson, and Jeffery W. Rankin

Subjects

0301 basic medicine, Computer science, Biomedical Engineering, Biophysics, Bioengineering, inverse dynamics, Electromyography, Walking, musculoskeletal model, Biochemistry, Cursorial, Models, Biological, Inverse dynamics, Pelvis, Running, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Computer Simulation, OpenSim, Muscle, Skeletal, Simulation, Life Sciences–Engineering interface, static optimization, Struthioniformes, medicine.diagnostic_test, Work (physics), Pelvic limb, Swing, Gait, Hindlimb, 030104 developmental biology, computed muscle control, forward dynamics, Computer optimization, human activities, 030217 neurology & neurosurgery, Biotechnology, Research Article

Abstract

Owing to their cursorial background, ostriches (Struthio camelus) walk and run with high metabolic economy, can reach very fast running speeds and quickly execute cutting manoeuvres. These capabilities are believed to be a result of their ability to coordinate muscles to take advantage of specialized passive limb structures. This study aimed to infer the functional roles of ostrich pelvic limb muscles during gait. Existing gait data were combined with a newly developed musculoskeletal model to generate simulations of ostrich walking and running that predict muscle excitations, force and mechanical work. Consistent with previous avian electromyography studies, predicted excitation patterns showed that individual muscles tended to be excited primarily during only stance or swing. Work and force estimates show that ostrich gaits are partially hip-driven with the bi-articular hip–knee muscles driving stance mechanics. Conversely, the knee extensors acted as brakes, absorbing energy. The digital extensors generated large amounts of both negative and positive mechanical work, with increased magnitudes during running, providing further evidence that ostriches make extensive use of tendinous elastic energy storage to improve economy. The simulations also highlight the need to carefully consider non-muscular soft tissues that may play a role in ostrich gait.

Published

2016

11. Mechanisms producing coordinated function across the breadth of a large biarticular thigh muscle

Author

Jonas Rubenson, Richard L. Marsh, David J. Ellerby, and Jennifer A. Carr

Subjects

musculoskeletal diseases, Bundle of His, Physiology, Strain (injury), Electromyography, Aquatic Science, Thigh, Biology, Models, Biological, Running, medicine, Animals, Aponeurosis, Galliformes, Muscle, Skeletal, Molecular Biology, Research Articles, Ecology, Evolution, Behavior and Systematics, Analysis of Variance, Hip, medicine.diagnostic_test, Anatomy, medicine.disease, Ischium, Biomechanical Phenomena, Hindlimb, Tendon, Sonomicrometry, medicine.anatomical_structure, Insect Science, Joints, Animal Science and Zoology, medicine.symptom, Muscle Contraction, Muscle contraction

Abstract

SUMMARY We examined the hypothesis that structural features of the iliotibialis lateralis pars postacetabularis (ILPO) in guinea fowl allow this large muscle to maintain equivalent function along its anterior–posterior axis. The ILPO, the largest muscle in the hindlimb of the guinea fowl, is a hip and knee extensor. The fascicles of the ILPO originate across a broad region of the ilium and ischium posterior to the hip. Its long posterior fascicles span the length of the thigh and insert directly on the patellar tendon complex. However, its anterior fascicles are shorter and insert on a narrow aponeurosis that forms a tendinous band along the anterior edge of the muscle and is connected distally to the patellar tendon. The biarticular ILPO is actively lengthened and then actively shortened during stance. The moment arm of the fascicles at the hip increases along the anterior to posterior axis, whereas the moment arm at the knee is constant for all fascicles. Using electromyography and sonomicrometry, we examined the activity and strain of posterior and anterior fascicles of the ILPO. The activation was not significantly different in the anterior and posterior fascicles. Although we found significant differences in active lengthening and shortening strain between the anterior and posterior fascicles, the differences were small. The majority of shortening strain is caused by hip extension and the inverse relationship between hip moment arm and fascicle length along the anterior–posterior axis was found to have a major role in ensuring similar shortening strain. However, because the knee moment arm is the same for all fascicles, knee flexion in early stance was predicted to produce much larger lengthening strains in the short anterior fascicles than our measured values at this location. We propose that active lengthening of the anterior fascicles was lower than predicted because the aponeurotic tendon of insertion of the anterior fascicles was stretched and only a portion of the lengthening had to be accommodated by the active muscle fascicles.

Published

2011

12. Gait-specific energetics contributes to economical walking and running in emus and ostriches

Author

Lisa Coder, Richard L. Marsh, Rebecca R. Watson, Jonas Rubenson, Donald F. Hoyt, and Matthew W. G. Propert

Subjects

Male, Cost of transport, Walking, California, General Biochemistry, Genetics and Molecular Biology, Running, Transition from walking to running, Control theory, Animals, Gait, Human locomotion, Research Articles, Simulation, General Environmental Science, Mathematics, Struthioniformes, Dromaiidae, General Immunology and Microbiology, Energetics, General Medicine, Energy budget, Metabolic rate, Linear relation, Female, Energy Metabolism, General Agricultural and Biological Sciences

Abstract

A widely held assumption is that metabolic rate (Ėmet) during legged locomotion is linked to the mechanics of different gaits and this linkage helps explain the preferred speeds of animals in nature. However, despite several prominent exceptions,Ėmetof walking and running vertebrates has been nearly uniformly characterized as increasing linearly with speed across all gaits. This description of locomotor energetics does not predict energetically optimal speeds for minimal cost of transport (Ecot). We tested whether large bipedal ratite birds (emus and ostriches) have gait-specific energetics during walking and running similar to those found in humans. We found that during locomotion, emus showed a curvilinear relationship betweenĖmetand speed during walking, and both emus and ostriches demonstrated an abrupt change in the slope ofĖmetversus speed at the gait transition with a linear increase during running. Similar to human locomotion, the minimum netEcotcalculated after subtracting resting metabolism was lower in walking than in running in both species. However, the difference in netEcotbetween walking and running was less than is found in humans because of a greater change in the slope ofĖmetversus speed at the gait transition, which lowers the cost of running for the avian bipeds. For emus, we also show that animals moving freely overground avoid a range of speeds surrounding the gait-transition speed within which theEcotis large. These data suggest that deviations from a linear relation of metabolic rate and speed and variations in transport costs with speed are more widespread than is often assumed, and provide new evidence that locomotor energetics influences the choice of speed in bipedal animals. The low cost of transport for walking is probably ecologically important for emus and ostriches because they spend the majority of their active day walking, and thus the energy used for locomotion is a large part of their daily energy budget.

Published

2010

13. Mechanical efficiency of limb swing during walking and running in guinea fowl (Numida meleagris)

Author

Richard L. Marsh and Jonas Rubenson

Subjects

Male, medicine.medical_specialty, Physiology, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Energy metabolism, Walking, Biology, Models, Biological, Running, Physical medicine and rehabilitation, Physiology (medical), medicine, Animals, Galliformes, Muscle, Skeletal, ComputingMethodologies_COMPUTERGRAPHICS, Guinea fowl, Articles, Anatomy, Swing, Metabolic cost, Hindlimb, body regions, Energy cost, Female, Energy Metabolism, human activities

Abstract

Understanding the mechanical determinants of the energy cost of limb swing is crucial for refining our models of locomotor energetics, as well as improving treatments for those suffering from impaired limb-swing mechanics. In this study, we use guinea fowl ( Numida meleagris) as a model to explore whether mechanical work at the joints explains limb-swing energy use by combining inverse dynamic modeling and muscle-specific energetics from blood flow measurements. We found that the overall efficiencies of the limb swing increased markedly from walking (3%) to fast running (17%) and are well below the usually accepted maximum efficiency of muscle, except at the fastest speeds recorded. The estimated efficiency of a single muscle used during ankle flexion (tibialis cranialis) parallels that of the total limb-swing efficiency (3% walking, 15% fast running). Taken together, these findings do not support the hypothesis that joint work is the major determinant of limb-swing energy use across the animal's speed range and warn against making simple predictions of energy use based on joint mechanical work. To understand limb-swing energy use, mechanical functions other than accelerating the limb segments need to be explored, including isometric force production and muscle work arising from active and passive antagonist muscle forces.

Published

2009

14. Running in ostriches (Struthio camelus): three-dimensional joint axes alignment and joint kinematics

Author

Denham B. Heliams, Paul A. Fournier, David Lloyd, Jonas Rubenson, and Thor F. Besier

Subjects

Models, Anatomic, musculoskeletal diseases, Physiology, STRIDE, Kinematics, Aquatic Science, Running, medicine, Animals, Displacement (orthopedic surgery), Bipedalism, Pelvic Bones, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Mathematics, Struthioniformes, biology, Biomechanics, Motor control, Anatomy, biology.organism_classification, Biomechanical Phenomena, Hindlimb, body regions, Valgus, medicine.anatomical_structure, Insect Science, Joints, Animal Science and Zoology, Ankle

Abstract

SUMMARY Although locomotor kinematics in walking and running birds have been examined in studies exploring many biological aspects of bipedalism, these studies have been largely limited to two-dimensional analyses. Incorporating a five-segment, 17 degree-of-freedom (d.f.) kinematic model of the ostrich hind limb developed from anatomical specimens, we quantified the three-dimensional(3-D) joint axis alignment and joint kinematics during running (at ∼3.3 m s–1) in the largest avian biped, the ostrich. Our analysis revealed that the majority of the segment motion during running in the ostrich occurs in flexion/extension. Importantly, however, the alignment of the average flexion/extension helical axes of the knee and ankle are rotated externally to the direction of travel (37° and 21°, respectively) so that pure flexion and extension at the knee will act to adduct and adbuct the tibiotarsus relative to the plane of movement, and pure flexion and extension at the ankle will act to abduct and adduct the tarsometatarsus relative to the plane of movement. This feature of the limb anatomy appears to provide the major lateral (non-sagittal) displacement of the lower limb necessary for steering the swinging limb clear of the stance limb and replaces what would otherwise require greater adduction/abduction and/or internal/external rotation, allowing for less complex joints, musculoskeletal geometry and neuromuscular control. Significant rotation about the joints'non-flexion/extension axes nevertheless occurs over the running stride. In particular, hip abduction and knee internal/external and varus/valgus motion may further facilitate limb clearance during the swing phase, and substantial non-flexion/extension movement at the knee is also observed during stance. Measurement of 3-D segment and joint motion in birds will be aided by the use of functionally determined axes of rotation rather than assumed axes, proving important when interpreting the biomechanics and motor control of avian bipedalism.

Published

2007

15. Cyclic mechanical stimulation rescues achilles tendon from degeneration in a bioreactor system

Author

Tao, Wang, Zhen, Lin, Ming, Ni, Christine, Thien, Robert E, Day, Bruce, Gardiner, Jonas, Rubenson, Thomas B, Kirk, David W, Smith, Allan, Wang, David G, Lloyd, Yan, Wang, Qiujian, Zheng, and Ming H, Zheng

Subjects

Cell Survival, Apoptosis, In Vitro Techniques, Real-Time Polymerase Chain Reaction, Achilles Tendon, Biomechanical Phenomena, Extracellular Matrix, Disease Models, Animal, Bioreactors, Collagen Type III, Tensile Strength, Tendinopathy, In Situ Nick-End Labeling, Animals, Female, Collagen, Rabbits, Stress, Mechanical

Abstract

Physiotherapy is one of the effective treatments for tendinopathy, whereby symptoms are relieved by changing the biomechanical environment of the pathological tendon. However, the underlying mechanism remains unclear. In this study, we first established a model of progressive tendinopathy-like degeneration in the rabbit Achilles. Following ex vivo loading deprivation culture in a bioreactor system for 6 and 12 days, tendons exhibited progressive degenerative changes, abnormal collagen type III production, increased cell apoptosis, and weakened mechanical properties. When intervention was applied at day 7 for another 6 days by using cyclic tensile mechanical stimulation (6% strain, 0.25 Hz, 8 h/day) in a bioreactor, the pathological changes and mechanical properties were almost restored to levels seen in healthy tendon. Our results indicated that a proper biomechanical environment was able to rescue early-stage pathological changes by increased collagen type I production, decreased collagen degradation and cell apoptosis. The ex vivo model developed in this study allows systematic study on the effect of mechanical stimulation on tendon biology.

Published

2015

16. Gait selection in the ostrich: mechanical and metabolic characteristics of walking and running with and without an aerial phase

Author

Jonas Rubenson, David Lloyd, Denham B. Heliams, and Paul A. Fournier

Subjects

medicine.medical_specialty, Power walking, Computer science, Effect of gait parameters on energetic cost, Walking, General Biochemistry, Genetics and Molecular Biology, Running, Oxygen Consumption, Physical medicine and rehabilitation, Transition from walking to running, medicine, Animals, Treadmill, Gait, Simulation, General Environmental Science, Struthioniformes, General Immunology and Microbiology, Level and incline running, Biomechanics, Western Australia, General Medicine, Carbon Dioxide, Biomechanical Phenomena, Preferred walking speed, Energy Metabolism, General Agricultural and Biological Sciences, human activities, Research Article

Abstract

It has been argued that minimization of metabolic-energy costs is a primary determinant of gait selection in terrestrial animals. This view is based predominantly on data from humans and horses, which have been shown to choose the most economical gait (walking, running, galloping) for any given speed. It is not certain whether a minimization of metabolic costs is associated with the selection of other prevalent forms of terrestrial gaits, such as grounded running (a widespread gait in birds). Using biomechanical and metabolic measurements of four ostriches moving on a treadmill over a range of speeds from 0.8 to 6.7 m s(-1), we reveal here that the selection of walking or grounded running at intermediate speeds also favours a reduction in the metabolic cost of locomotion. This gait transition is characterized by a shift in locomotor kinetics from an inverted-pendulum gait to a bouncing gait that lacks an aerial phase. By contrast, when the ostrich adopts an aerial-running gait at faster speeds, there are no abrupt transitions in mechanical parameters or in the metabolic cost of locomotion. These data suggest a continuum between grounded and aerial running, indicating that they belong to the same locomotor paradigm.

Published

2004

17. Adaptations for economical bipedal running: the effect of limb structure on three-dimensional joint mechanics

Author

David Lloyd, Denham B. Heliams, Thor F. Besier, Jonas Rubenson, and Paul A. Fournier

Subjects

Adult, Male, Biomedical Engineering, Biophysics, Bioengineering, Biochemistry, Cursorial, Running, Biomaterials, Joint mechanics, Animals, Humans, Mechanical energy, Simulation, Research Articles, Mathematics, Struthioniformes, Models, Statistical, Muscles, Biomechanics, Elastic energy, Mechanics, Elasticity, Biomechanical Phenomena, Kinetics, Limb structure, Mechanical joint, Running economy, Joints, Stress, Mechanical, Locomotion, Biotechnology

Abstract

The purpose of this study was to examine the mechanical adaptations linked to economical locomotion in cursorial bipeds. We addressed this question by comparing mass-matched humans and avian bipeds (ostriches), which exhibit marked differences in limb structure and running economy. We hypothesized that the nearly 50 per cent lower energy cost of running in ostriches is a result of: (i) lower limb-swing mechanical power, (ii) greater stance-phase storage and release of elastic energy, and (iii) lower total muscle power output. To test these hypotheses, we used three-dimensional joint mechanical measurements and a simple model to estimate the elastic and muscle contributions to joint work and power. Contradictory to our first hypothesis, we found that ostriches and humans generate the same amounts of mechanical power to swing the limbs at a similar self-selected running speed, indicating that limb swing probably does not contribute to the difference in energy cost of running between these species. In contrast, we estimated that ostriches generate 120 per cent more stance-phase mechanical joint power via release of elastic energy compared with humans. This elastic mechanical power occurs nearly exclusively at the tarsometatarso-phalangeal joint, demonstrating a shift of mechanical power generation to distal joints compared with humans. We also estimated that positive muscle fibre power is 35 per cent lower in ostriches compared with humans, and is accounted for primarily by higher capacity for storage and release of elastic energy. Furthermore, our analysis revealed much larger frontal and internal/external rotation joint loads during ostrich running than in humans. Together, these findings support the hypothesis that a primary limb structure specialization linked to economical running in cursorial species is an elevated storage and release of elastic energy in tendon. In the ostrich, energy-saving specializations may also include passive frontal and internal/external rotation load-bearing mechanisms.

Published

2010

18. Reappraisal of the comparative cost of human locomotion using gait-specific allometric analyses

Author

Paul A. Fournier, Jonas Rubenson, Philip C. Withers, Shane K. Maloney, David Lloyd, and Denham B. Heliams

Subjects

Physiology, Net energy, Walking, Aquatic Science, Running, Gait (human), Statistics, Animals, Humans, Bipedalism, Molecular Biology, Human locomotion, Gait, Ecology, Evolution, Behavior and Systematics, Mathematics, Metabolic energy, Anthropometry, Ecology, Body Weight, Metabolic cost, Regression, Insect Science, Animal Science and Zoology, Allometry, Energy Metabolism, Locomotion

Abstract

SUMMARYThe alleged high net energy cost of running and low net energy cost of walking in humans have played an important role in the interpretation of the evolution of human bipedalism and the biomechanical determinants of the metabolic cost of locomotion. This study re-explores how the net metabolic energy cost of running and walking (J kg–1m–1) in humans compares to that of animals of similar mass using new allometric analyses of previously published data. Firstly, this study shows that the use of the slope of the regression between the rate of energy expenditure and speed to calculate the net energy cost of locomotion overestimates the net cost of human running. Also, the net energy cost of human running is only 17% higher than that predicted based on their mass. This value is not exceptional given that over a quarter of the previously examined mammals and birds have a net energy cost of running that is 17% or more above their allometrically predicted value. Using a new allometric equation for the net energy cost of walking, this study also shows that human walking is 20%less expensive than predicted for their mass. Of the animals used to generate this equation, 25% have a relatively lower net cost of walking compared with their allometrically predicted value. This new walking allometric analysis also indicates that the scaling of the net energy cost of locomotion with body mass is gait dependent. In conclusion, the net costs of running and walking in humans are moderately different from those predicted from allometry and are not remarkable for an animal of its size.

Published

2007

19. The cost of running uphill: linking organismal and muscle energy use in guinea fowl (Numida meleagris)

Author

Jonas Rubenson, Peter M. Dimoulas, Havalee T. Henry, and Richard L. Marsh

Subjects

Physiology, Physical Exertion, Muscle Energy, Aquatic Science, Biology, Running, Animal science, Blood Circulation Time, Oxygen Consumption, Animals, Galliformes, Muscle, Skeletal, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Total blood, Guinea fowl, Level and incline running, Work (physics), Anatomy, Biomechanical Phenomena, Regional Blood Flow, Insect Science, Metabolic rate, Active muscle, Animal Science and Zoology, Energy Metabolism

Abstract

SUMMARYUphill running requires more energy than level running at the same speed,largely due to the additional mechanical work of elevating the body weight. We explored the distribution of energy use among the leg muscles of guinea fowl running on the level and uphill using both organismal energy expenditure(oxygen consumption) and muscle blood flow measurements. We tested each bird under four conditions: (1) rest, (2) a moderate-speed level run at 1.5 m s–1, (3) an incline run at 1.5 m s–1 with a 15% gradient and (4) a fast level run at a speed eliciting the same metabolic rate as did running at a 15% gradient at 1.5 m s–1(2.28–2.39 m s–1). The organismal energy expenditure increased by 30% between the moderate-speed level run and both the fast level run and the incline run, and was matched by a proportional increase in total blood flow to the leg muscles. We found that blood flow increased significantly to nearly all the leg muscles between the moderate-speed level run and the incline run. However, the increase in flow was distributed unevenly across the leg muscles, with just three muscles being responsible for over 50% of the total increase in blood flow during uphill running. Three muscles showed significant increases in blood flow with increased incline but not with an increase in speed. Increasing the volume of active muscle may explain why in a previous study a higher maximal rate of oxygen consumption was measured during uphill running. The majority of the increase in energy expenditure between level and incline running was used in stance-phase muscles. Proximal stance-phase extensor muscles with parallel fibers and short tendons, which have been considered particularly well suited for doing positive work on the center of mass, increased their mass-specific energy use during uphill running significantly more than pinnate stance-phase muscles. This finding provides some evidence for a division of labor among muscles used for mechanical work production based on their muscle–tendon architecture. Nevertheless, 33% of the total increase in energy use (40% of the increase in stance-phase energy use) during uphill running was provided by pinnate stance-phase muscles. Swing-phase muscles also increase their energy expenditure during uphill running, although to a lesser extent than that required by running faster on the level. These results suggest that neither muscle–tendon nor musculoskeletal architecture appear to greatly restrict the ability of muscles to do work during locomotor tasks such as uphill running, and that the added energy cost of running uphill is not solely due to lifting the body center of mass.

Published

2006

20. The energetic costs of trunk and distal-limb loading during walking and running in guinea fowl Numida meleagris: I. Organismal metabolism and biomechanics

Author

Richard L, Marsh, David J, Ellerby, Havalee T, Henry, and Jonas, Rubenson

Subjects

Weight-Bearing, Animals, Walking, Galliformes, Energy Metabolism, Biomechanical Phenomena, Hindlimb, Running

Abstract

We examined the energetic cost of loading the trunk or distal portion of the leg in walking and running guinea fowl (Numida meleagris). These different loading regimes were designed to separately influence the energy use by muscles used during the stance and swing phases of the stride. Metabolic rate, estimated from oxygen consumption, was measured while birds locomoted on a motorized treadmill at speeds from 0.5 to 2.0 m s-1, either unloaded, or with a mass equivalent to 23% of their body mass carried on their backs, or with masses equal to approximately 2.5% of their body mass attached to each tarsometatarsal segment. In separate experiments, we also measured the duration of stance and swing in unloaded, trunk-loaded, or limb-loaded birds. In the unloaded and limb-loaded birds, we also calculated the mechanical energy of the tarsometatarsal segment throughout the stride. Trunk and limb loads caused similar increases in metabolic rate. During trunk loading, the net metabolic rate (gross metabolic rate-resting metabolic rate) increased by 17% above the unloaded value across all speeds. This percentage increase is less than has been found in most studies of humans and other mammals. The economical load carriage of guinea fowl is consistent with predictions based on the relative cost of the stance and swing phases of the stride in this species. However, the available comparative data and considerations of the factors that determine the cost of carrying extra mass lead us to the conclusion that the cost of load carrying is unlikely to be a reliable indicator of the distribution of energy use in stance and swing. Both loading regimes caused small changes in the swing and/or stance durations, but these changes were less than 10%. Loading the tarsometatarsal segment increased its segmental energy by 4.1 times and the segmental mechanical power averaged over the stride by 3.8 times. The increases in metabolism associated with limb loading appear to be linked to the increases in mechanical power. The delta efficiency (change in mechanical power divided by the change in metabolic power) of producing this power increased from 11% in walking to approximately 25% in running. Although tarsometatarsal loading was designed to increase the mechanical energy during swing phase, 40% of the increase in segmental energy occurred during late stance. Thus, the increased energy demand of distal limb loading in guinea fowl is predicted to cause increases in energy use by both stance- and swing-phase muscles.

Published

2006