Your search keyword '"Eva C. Herbst"' showing total 12 results

1. A toolbox for the retrodeformation and muscle reconstruction of fossil specimens in Blender

Author

Eva C. Herbst, Luke E. Meade, Stephan Lautenschlager, Niccolo Fioritti, and Torsten M. Scheyer

Subjects

blender, reconstruction, retrodeformation, modelling, fossils, muscles, Science

Abstract

Accurate muscle reconstructions can offer new information on the anatomy of fossil organisms and are also important for biomechanical analysis (multibody dynamics and finite-element analysis (FEA)). For the sake of simplicity, muscles are often modelled as point-to-point strands or frustra (cut-off cones) in biomechanical models. However, there are cases in which it is useful to model the muscle morphology in three dimensions, to better examine the effects of muscle shape and size. This is especially important for fossil analyses, where muscle force is estimated from the reconstructed muscle morphology (rather than based on data collected in vivo). The two main aims of this paper are as follows. First, we created a new interactive tool in the free open access software Blender to enable interactive three-dimensional modelling of muscles. This approach can be applied to both palaeontological and human biomechanics research to generate muscle force magnitudes and lines of action for FEA. Second, we provide a guide on how to use existing Blender tools to reconstruct distorted or incomplete specimens. This guide is aimed at palaeontologists but can also be used by anatomists working with damaged specimens or to test functional implication of hypothetical morphologies.

Published

2022

2. Modeling tooth enamel in FEA comparisons of skulls: Comparing common simplifications with biologically realistic models

Author

Eva C. Herbst, Stephan Lautenschlager, Dylan Bastiaans, Feiko Miedema, and Torsten M. Scheyer

Subjects

paleontology, biophysics, biomechanics, biomaterials, Science

Abstract

Summary: Palaeontologists often use finite element analyses, in which forces propagate through objects with specific material properties, to investigate feeding biomechanics. Teeth are usually modeled with uniform properties (all bone or all enamel). In reality, most teeth are composed of pulp, dentine, and enamel. We tested how simplified teeth compare to more realistic models using mandible models of three reptiles. For each, we created models representing enamel thicknesses found in extant taxa, as well as simplified models (bone, dentine or enamel). Our results suggest that general comparisons of stress distribution among distantly related taxa do not require representation of dental tissues, as there was no noticeable effect on heatmap representations of stress. However, we find that representation of dental tissues impacts bite force estimates, although magnitude of these effects may differ depending on constraints. Thus, as others have shown, the detail necessary in a biomechanical model relates to the questions being examined.

Published

2021

3. A new straightforward method for semi-automated segmentation of trabecular bone from cortical bone in diverse and challenging morphologies

Author

Eva C. Herbst, Alessandro A. Felder, Lucinda A. E. Evans, Sara Ajami, Behzad Javaheri, and Andrew A. Pitsillides

Subjects

trabecular segmentation, automatic segmentation, cortical bone, trabecular bone, thresholding, Avizo, Science

Abstract

Many physiological, biomechanical, evolutionary and clinical studies that explore skeletal structure and function require successful separation of trabecular from cortical compartments of a bone that has been imaged by X-ray micro-computed tomography (micro-CT) prior to analysis. Separation often involves manual subdivision of these two similarly radio-opaque compartments, which can be time-consuming and subjective. We have developed an objective, semi-automated protocol which reduces user bias and enables straightforward, user-friendly segmentation of trabecular from the cortical bone without requiring sophisticated programming expertise. This method can conveniently be used as a ‘recipe’ in commercial programmes (Avizo herein) and applied to a variety of datasets. Here, we characterize and share this recipe, and demonstrate its application to a range of murine and human bone types, including normal and osteoarthritic specimens, and bones with distinct embryonic origins and spanning a range of ages. We validate the method by testing inter-user bias during the scan preparation steps and confirm utility in the architecturally challenging analysis of growing murine epiphyses. We also report details of the recipe, so that other groups can readily re-create a similar method in open access programmes. Our aim is that this method will be adopted widely to create a reproducible and time-efficient method of segmenting trabecular and cortical bone.

Published

2021

4. Natural barriers: waterfall transit by small flying animals

Author

Victor M. Ortega-Jimenez, Eva C. Herbst, Michelle S. Leung, and Robert Dudley

Subjects

two-phase flows, flight, hummingbirds, insect, swifts, Science

Abstract

Waterfalls are conspicuous geomorphological features with heterogeneous structure, complex dynamics and multiphase flows. Swifts, dippers and starlings are well-known to nest behind waterfalls, and have been reported to fly through them. For smaller fliers, by contrast, waterfalls seem to represent impenetrable barriers, but associated physical constraints and the kinematic responses of volant animals during transit are unknown. Here, we describe the flight behaviour of hummingbirds (the sister group to the swifts) and of various insect taxa as they fly through an artificial sheet waterfall. We additionally launched plastic balls at different speeds at the waterfall so as to assess the inertial dependence of sheet penetration. Hummingbirds were able to penetrate the waterfall with reductions in both their translational speed, and stroke amplitude. The body tilted more vertically and exhibited greater rotations in roll, pitch and yaw, along with increases in tail spread and pitch. The much smaller plastic balls and some flies moving at speeds greater than 2.3 m s−1 and 1.6 m s−1, respectively, also overcame effects of surface tension and water momentum and passed through the waterfall; objects with lower momentum, by contrast, entered the sheet but then fell along with the moving water. Waterfalls can thus represent impenetrable physical barriers for small and slow animal fliers, and may also serve to exclude both predators and parasites from nests of some avian taxa.

Published

2020

5. <scp>3D</scp> profiling of mouse epiphyses across ages reveals new potential imaging biomarkers of early spontaneous osteoarthritis

Author

Eva C. Herbst, Lucinda A. E. Evans, Alessandro A. Felder, Behzad Javaheri, and Andrew A. Pitsillides

Subjects

Histology, Cell Biology, Anatomy, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Developmental Biology

Published

2023

6. Spherical frame projections for visualising joint range of motion, and a complementary method to capture mobility data

Author

Eva C. Herbst, Enrico A. Eberhard, John R. Hutchinson, Christopher T. Richards, University of Zurich, and Herbst, Eva C

Subjects

Histology, hip, Evolution, Movement, system, 10125 Paleontological Institute and Museum, 2722 Histology, range of motion, 1309 Developmental Biology, 1307 Cell Biology, Behavior and Systematics, morphology, 1312 Molecular Biology, spherical frame projection, Animals, Range of Motion, Articular, joint mobility, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Ecology, Cell Biology, 2702 Anatomy, Biomechanical Phenomena, movement visualisation, automatic-determination, 1105 Ecology, Evolution, Behavior and Systematics, 560 Fossils & prehistoric life, soft-tissues, freedom, Anatomy, Developmental Biology

Abstract

Quantifying joint range of motion (RoM), the reachable poses at a joint, has many applications in research and clinical care. Joint RoM measurements can be used to investigate the link between form and function in extant and extinct animals, to diagnose musculoskeletal disorders and injuries or monitor rehabilitation progress. However, it is difficult to visually demonstrate how the rotations of the joint axes interact to produce joint positions. Here, we introduce the spherical frame projection (SFP), which is a novel 3D visualisation technique, paired with a complementary data collection approach. SFP visualisations are intuitive to interpret in relation to the joint anatomy because they 'trace' the motion of the coordinate system of the distal bone at a joint relative to the proximal bone. Furthermore, SFP visualisations incorporate the interactions of degrees of freedom, which is imperative to capture the full joint RoM. For the collection of such joint RoM data, we designed a rig using conventional motion capture systems, including live audio-visual feedback on torques and sampled poses. Thus, we propose that our visualisation and data collection approach can be adapted for wide use in the study of joint function.

Published

2022

7. Multi-Joint Analysis of Pose Viability Supports the Possibility of Salamander-Like Hindlimb Configurations in the Permian Tetrapod Eryops megacephalus

Author

Armita Manafzadeh, Eva C. Herbst, and John Hutchinson

Subjects

Amphibians, Animals, Urodela, Extremities, Animal Science and Zoology, Plant Science, Locomotion, Hindlimb

Abstract

Synopsis Salamanders are often used as analogs for early tetrapods in paleontological reconstructions of locomotion. However, concerns have been raised about whether this comparison is justifiable, necessitating comparisons of a broader range of early tetrapods with salamanders. Here, we test whether the osteological morphology of the hindlimb in the early tetrapod (temnospondyl amphibian) Eryops megacephalus could have facilitated the sequence of limb configurations used by salamanders during terrestrial locomotion. To do so, we present a new method that enables the examination of full limb configurations rather than isolated joint poses. Based on this analysis, we conclude that E. megacephalus may indeed have been capable of salamander-like hindlimb kinematics. Our method facilitates the holistic visual comparison of limb configurations between taxa without reliance on the homology of coordinate system definitions, and can thus be applied to facilitate various comparisons between extinct and extant taxa, spanning the diversity of locomotion both past and present.

Published

2022

8. In vivo and ex vivo range of motion in the fire salamander Salamandra salamandra

Author

Eva C. Herbst, Enrico A. Eberhard, Christopher T. Richards, John R. Hutchinson, University of Zurich, and Herbst, Eva C

Subjects

Histology, Evolution, rotoscoping, Urodela, Walking, 10125 Paleontological Institute and Museum, gait, 2722 Histology, range of motion, 1309 Developmental Biology, 1307 Cell Biology, Behavior and Systematics, perspectives, motion capture, 1312 Molecular Biology, Animals, Salamandra, Range of Motion, Articular, joint mobility, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Ecosystem, Ecology, Cell Biology, 2702 Anatomy, salamander, mobility, 1105 Ecology, Evolution, Behavior and Systematics, 560 Fossils & prehistoric life, freedom, Anatomy, terrestrial locomotion, Developmental Biology

Abstract

Joint range of motion (RoM) analyses are fundamental to our understanding of how an animal moves throughout its ecosystem. Recent technological advances allow for more detailed quantification of this RoM (e.g. including interaction of degrees of freedom) both in ex vivo joints and in vivo experiments. Both types of data have been used to draw comparisons with fossils to reconstruct locomotion. Salamanders are often used as analogues for early tetrapod locomotion; testing such hypotheses requires an in-depth analysis of salamander joint RoM. Here, we provide a detailed dataset of the ex vivo ligamentous rotational joint RoM in the hindlimb of the fire salamander Salamandra salamandra, using a new method for collecting and visualising joint RoM. We also characterise in vivo joint RoM used during walking, via scientific rotoscoping and compare the in vivo and ex vivo data. In summary, we provide (1) a new method for joint RoM data experiments and (2) a detailed analysis of both in vivo and ex vivo data of salamander hindlimbs, which can be used for comparative studies.

Published

2022

9. A New Straightforward Method for Automated Segmentation of Trabecular Bone from Cortical Bone in Diverse and Challenging Morphologies

Author

Eva C. Herbst, Alessandro Felder, Andrew A. Pitsillides, S Ajami, Behzad Javaheri, Lucinda A. E. Evans, and University of Zurich

Subjects

Protocol (science), business.industry, Computer science, Automated segmentation, Human bone, Pattern recognition, 10125 Paleontological Institute and Museum, Trabecular bone, medicine.anatomical_structure, 560 Fossils & prehistoric life, medicine, Segmentation, Cortical bone, Tomography, Artificial intelligence, business

Abstract

Many physiological, biomechanical, evolutionary and clinical studies that explore skeletal structure and function require successful separation of trabecular from cortical compartments of a bone that has been imaged by X-ray micro-computed tomography (microCT) prior to analysis. Separation is often time-consuming, involves user bias and needs manual sub-division of these two similarly radio-opaque compartments. We have developed an objective, automated protocol which reduces user bias and enables straightforward, user-friendly segmentation of trabecular from cortical bone without requiring sophisticated programming expertise. This method can conveniently be used as a “recipe” in commercial programmes (Avizo herein) and applied to a variety of datasets. Here, we characterise and share this recipe, and demonstrate its application to a range of murine and human bone types, including normal and osteoarthritic specimens, and bones with distinct embryonic origins and spanning a range of ages. We validate the method by testing inter-user bias during the scan preparation steps and confirm utility in the architecturally challenging analysis of growing murine epiphyses. We also report details of the recipe, so that other groups can readily re-create a similar method in open access programs. Our aim is that this method will be adopted widely to create a more standardized and time efficient method of segmenting trabecular and cortical bone.

Published

2021

10. Natural barriers: waterfall transit by small flying animals

Author

Eva C. Herbst, Victor Manuel Ortega-Jimenez, Michelle S. Leung, Robert Dudley, University of Zurich, and Ortega-Jimenez, Victor M

Subjects

0106 biological sciences, 10125 Paleontological Institute and Museum, Waterfall, 010603 evolutionary biology, 01 natural sciences, Natural (archaeology), two-phase flows, 03 medical and health sciences, Nest, Transit (astronomy), swifts, lcsh:Science, 030304 developmental biology, hummingbirds, 1000 Multidisciplinary, Ecology, Conservation, and Global Change Biology, 0303 health sciences, geography, Multidisciplinary, geography.geographical_feature_category, Ecology, Complex dynamics, flight, 560 Fossils & prehistoric life, lcsh:Q, insect, Geology, Research Article

Abstract

Waterfalls are conspicuous geomorphological features with heterogeneous structure, complex dynamics and multiphase flows. Swifts, dippers and starlings are well-known to nest behind waterfalls, and have been reported to fly through them. For smaller fliers, by contrast, waterfalls seem to represent impenetrable barriers, but associated physical constraints and the kinematic responses of volant animals during transit are unknown. Here, we describe the flight behaviour of hummingbirds (the sister group to the swifts) and of various insect taxa as they fly through an artificial sheet waterfall. We additionally launched plastic balls at different speeds at the waterfall so as to assess the inertial dependence of sheet penetration. Hummingbirds were able to penetrate the waterfall with reductions in both their translational speed, and stroke amplitude. The body tilted more vertically and exhibited greater rotations in roll, pitch and yaw, along with increases in tail spread and pitch. The much smaller plastic balls and some flies moving at speeds greater than 2.3 m s−1and 1.6 m s−1, respectively, also overcame effects of surface tension and water momentum and passed through the waterfall; objects with lower momentum, by contrast, entered the sheet but then fell along with the moving water. Waterfalls can thus represent impenetrable physical barriers for small and slow animal fliers, and may also serve to exclude both predators and parasites from nests of some avian taxa.

Published

2020

11. Bony lesions in early tetrapods and the evolution of mineralized tissue repair

Author

Michael Doube, Jennifer A. Clack, Timothy R. Smithson, John R. Hutchinson, Eva C. Herbst, University of Zurich, and Herbst, Eva C

Subjects

0106 biological sciences, Mineralized tissues, Evolution, Context (language use), Bone healing, 1100 General Agricultural and Biological Sciences, Biology, 10125 Paleontological Institute and Museum, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, stomatognathic system, Behavior and Systematics, biology.animal, medicine, Tetrapod (structure), Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Ecology, Cartilage, Palaeontology, Paleontology, Crassigyrinus, Vertebrate, Anatomy, biology.organism_classification, 1911 Paleontology, medicine.anatomical_structure, 1105 Ecology, Evolution, Behavior and Systematics, 560 Fossils & prehistoric life, Cortical bone, General Agricultural and Biological Sciences, 2303 Ecology

Abstract

Bone healing is an important survival mechanism, allowing vertebrates to recover from injury and disease. Here we describe newly recognized paleopathologies in the hindlimbs of the early tetrapodsCrassigyrinus scoticusandEoherpeton watsonifrom the early Carboniferous of Cowdenbeath, Scotland. These pathologies are among the oldest known instances of bone healing in tetrapod limb bones in the fossil record (about 325 Ma). X-ray microtomographic imaging of the internal bone structure of these lesions shows that they are characterized by a mass of trabecular bone separated from the shaft's trabeculae by a layer of cortical bone. We frame these paleopathologies in an evolutionary context, including additional data on bone healing and its pathways across extinct and extant sarcopterygians. These data allowed us to synthesize information on cell-mediated repair of bone and other mineralized tissues in all vertebrates, to reconstruct the evolutionary history of skeletal tissue repair mechanisms. We conclude that bone healing is ancestral for sarcopterygians. Furthermore, other mineralized tissues (aspidin and dentine) were also capable of healing and remodeling early in vertebrate evolution, suggesting that these repair mechanisms are synapomorphies of vertebrate mineralized tissues. The evidence for remodeling and healing in all of these tissues appears concurrently, so in addition to healing, these early vertebrates had the capacity to restore structure and strength by remodeling their skeletons. Healing appears to be an inherent property of these mineralized tissues, and its linkage to their remodeling capacity has previously been underappreciated.

Published

2019

12. A new straightforward method for semi-automated segmentation of trabecular bone from cortical bone in diverse and challenging morphologies

Author

Andrew A. Pitsillides, Eva C. Herbst, S Ajami, Behzad Javaheri, Lucinda A. E. Evans, Alessandro Felder, University of Zurich, and Herbst, Eva C

Subjects

Computer science, Science, cortical bone, Automated segmentation, thresholding, 030209 endocrinology & metabolism, 10125 Paleontological Institute and Museum, 03 medical and health sciences, automatic segmentation, 0302 clinical medicine, trabecular segmentation, medicine, Research Articles, 030304 developmental biology, 1000 Multidisciplinary, 0303 health sciences, Multidisciplinary, Thresholding, Structure and function, Trabecular bone, medicine.anatomical_structure, 560 Fossils & prehistoric life, trabecular bone, Organismal and Evolutionary Biology, Automatic segmentation, Cortical bone, Avizo, Biomedical engineering

Abstract

Many physiological, biomechanical, evolutionary and clinical studies that explore skeletal structure and function require successful separation of trabecular from cortical compartments of a bone that has been imaged by X-ray micro-computed tomography (micro-CT) prior to analysis. Separation often involves manual subdivision of these two similarly radio-opaque compartments, which can be time-consuming and subjective. We have developed an objective, semi-automated protocol which reduces user bias and enables straightforward, user-friendly segmentation of trabecular from the cortical bone without requiring sophisticated programming expertise. This method can conveniently be used as a ‘recipe’ in commercial programmes (Avizo herein) and applied to a variety of datasets. Here, we characterize and share this recipe, and demonstrate its application to a range of murine and human bone types, including normal and osteoarthritic specimens, and bones with distinct embryonic origins and spanning a range of ages. We validate the method by testing inter-user bias during the scan preparation steps and confirm utility in the architecturally challenging analysis of growing murine epiphyses. We also report details of the recipe, so that other groups can readily re-create a similar method in open access programmes. Our aim is that this method will be adopted widely to create a reproducible and time-efficient method of segmenting trabecular and cortical bone.