Your search keyword '"Stephens NB"' showing total 27 results

1. Program of the 88th Annual Meeting of the American Association of Physical Anthropologists

Author

Figus C, Stephens NB, Sorrentino R, Bortolini E, Scalise LM, Gabanini G, Romandini M, Lugli F, Arrighi S, Badino F, Marciani G, Oxilia G, Panetta D, Belcastro MG, Harcourt-Smith W, Ryan TM, and Benazzi S.

Subjects

060303 religions & theology, 0303 health sciences, 03 medical and health sciences, Geography, 030310 physiology, Anthropology, Ethnology, Morphology (biology), 06 humanities and the arts, Anatomy, Diversification (marketing strategy), 16. Peace & justice, 0603 philosophy, ethics and religion

Abstract

Fil: Menendez, Lumila Paula. Konrad Lorenz Institute; Austria. Consejo Nacional de Investigaciones Cientificas y Tecnicas; Argentina

Published

2019

2. Exploring age-related variations during calcaneal growth

Author

Gabanini G, Figus C, Sorrentino R, Stephens NB, Belcastro MG, Harcourt-Smith W, Ryan TM, Benazzi S., and Gabanini G, Figus C, Sorrentino R, Stephens NB, Belcastro MG, Harcourt-Smith W, Ryan TM, Benazzi S.

Subjects

calcaneus, calcaneal growth, ontogeny, geometric morphometrics

Abstract

Methods for age estimation in juvenile osteological samples are highly accurate compared to those of adults, but little is known about the variation of the foot bones during growth. This study explores the age-related morphological changes of the calcaneus, which is often well preserved even in the case of multiple or damaged burials, using Geometric Morphometric Methods. A sample of 33 modern human juvenile calcanei (known age/sex= 22; unknown sex/age= 11) was 3D scanned using an Artec3D Space Scanner. 5 age categories (0-15 years) were defined; unknown sex/age specimens were classified as ND. A template of 15 landmarks and 209 semi-landmarks was applied to the digital models. The (semi)landmark configurations were superimposed by Generalized Procrustes Analysis. A form space Principal Component Analysis (PCA) was computed using the known sample to explore variation during growth, while ND specimens were projected within it. The analysis shows that PC1 (ca. 93%) is highly correlated with size and accounts for ontogenetic allometry. Negative scores (youngest individuals) are characterized by a compact morphology while positive scores (oldest individuals) show both a greater definition of the sustentaculum talii and sinus tarsii and more pronounced edges for the talar and cuboid articular facets. The projected sample follows the trajectory of the known sample, which means that our ND specimens can be aged in the 5 categories after being projected. Our results suggest that age-related morphological changes of the calcaneus during growth may be used to estimate the general age of juvenile skeletal remains.

Published

2019

3. Exploring age-related variations during talar growth

Author

Figus C, Stephens NB, Sorrentino R, Bortolini E, Scalise LM, Gabanini G, Romandini M, Lugli F, Arrighi S, Badino F, Marciani G, Oxilia G, Panetta D, Belcastro MG, Harcourt-Smith W, Ryan TM, Benazzi S., and Figus C, Stephens NB, Sorrentino R, Bortolini E, Scalise LM, Gabanini G, Romandini M, Lugli F, Arrighi S, Badino F, Marciani G, Oxilia G, Panetta D, Belcastro MG, Harcourt-Smith W, Ryan TM, Benazzi S.

Subjects

talus, ontogeny, geometric morphometrics, talar growth

Abstract

Age estimation is a fundamental aspect in juvenile osteological studies and, as such, there are many methods that rely on ontogenetic-related changes to bone morphology. The talus, being a small and compact bone, is generally well preserved in archaeological contexts, but little is known about its morphological trajectory during growth. To better nderstand this we apply a (semi)landmark-based approach to an ontogenetic sample of 26 modern human juvenile tali (known age/sex = 12; unknown age/sex = 14), grouped by 5 age categories ranging from 0 to 15 years. A template of 11 landmarks and 205 semilandmarks were applied to 26 microCT-based digital models of the juvenile tali. These were superimposed by Generalized Procrustes Analysis with the semilandmarks freely sliding against recursive updates of the Procrustes consensus. Finally, individuals of unknown age/sex were projected into the form-space determined from a Principal Component Analysis of the known sample. Our results show that most of the morphometric variation is explained by PC1 (⁓91%), which is highly correlated with size and accounts for ontogenetic allometry. Negative scores (i.e., youngest) are related to a small and globular morphology. The positive scores (i.e., oldest) account for an elongation of the talar body, which is mainly related to the development of the neck and growth of the lateral malleolar facet. Overall, our preliminary results suggest that age-related morphological variations of the talus may be used to determine the general age of juvenile skeletal remains, which could be valuable to many archaeological and forensic researchers.

Published

2019

4. Unravelling morphological changes of the human talus during growth

Author

Figus C, Stephens NB, Sorrentino R, Panetta D, Belcastro MG, Ryan TM, Benazzi S, Figus C, Stephens NB, Sorrentino R, Panetta D, Belcastro MG, Ryan TM, and Benazzi S

Subjects

ERC SUCCESS, ontogeny, growth: human talus: GMM

Abstract

The human talus, being located between the lower limb and foot, plays an essential role in distributing the weight of the body during locomotion. One of its most important functions during this process is in allowing for foot movements while efficiently dividing weight between its anterior and posterior portions, where it articulates with the navicular and calcaneus, respectively [1]. As such, the talus plays a pivotal role in the different stages of human locomotion, from crawling, to initial bipedal acquisition, to full striding bipedalism at age 8 [1]. Unfortunately, little is known about the morphological changes of the talus during the first years of life, when infants acquire upright posture and gait maturation. Using a (semi)landmark based approach we analyse an ontogenetic sample of modern human tali with the aim of exploring the morphological variation of the talus during growth. From this we assess if the variation may then be related to the acquisition and transition to full bipedal locomotion, which might ultimately provide insight into the evolution of hominin bipedalism. The sample consists of 21 juvenile tali aged between 1.5 years and 11 years: 12 individuals from the Collection of Bologna, Italy (sex and age at death known) [2]; five from the archaeological sample of Roccapelago (Italy) [3]; four from the archaeological sample of Norris Farms #36 (Illinois, USA). All specimens were microCT scanned with a resolution of 20-40 µm. Avizo 9.3® (Visualization Sciences Group, SAS) was used to evaluate the quality of and pre-process the reconstructed scan data (e.g. crop or resample). Segmentation of the image data was performed using the MIA-clustering method [4] and then processed in Medtool 4.2 (Dr. Pahr Ingenieurs.e.U) to obtain 3D meshes of each talus. A template of 11 landmarks, 61 curve semilandmarks and 144 surface semilandmarks was created in Viewbox (dHAL Software) and applied to the 21 tali. The (semi)landmark configuration was superimposed by Generalized Procrustes Analysis, and semilandmarks were allowed to slide against recursive updates of the Procrustes consensus [5]. Finally, a form space Principal Component Analysis was carried out to explore talar shape variation during growth. Data were processed in R 3.4.3 (The R Foundation for Statistical Computing, 2017). The first three PCs explain 92.9% of the total variation. Most of the morphometric variation is explained by PC1 (89.8%), i.e. ontogenetic allometry, where negative scores account for small, sub-parallelepiped talar morphology (the youngest individuals), while positive scores account for an elongation of the entire body of the talus, due to the development of the neck, and a clear growth of the lateral malleolar facet, while the posterior side of the trochlear facet is not well defined yet. The anterior calcaneal facet is well developed since the youngest phases (negative scores), while the posterior calcaneal facet becomes larger, less triangular, and more concave towards PC1 positive. PC2 (1.7%) and PC3 (1.4%) describe only subtle morphological differences. Negative values of PC2 account for a longer lateral ridge, that shortens along positive values, due to the growth of the talar head, development of the neck, trochlea, and lateral malleolar facet, with a more concave aspect of the lateral side. It is also possible to discern a narrowing of the sulcus tali and a clear medial rotation of the talar head. PC3 negative scores show a more compact shape, that becomes higher along positive values with the development of the posterior calcaneal facet and head. This study is part of an ongoing project focusing on ontogenetic changes. Here we present preliminary results showing how external talar morphology varies during the early stages of human bipedalism. Future analyses will combine external morphological analyses with an assessment of trabecular bone architecture, thus providing a more holistic vision of these changes during development. Acknowledgements This project is funded by the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement No 724046 - SUCCESS); website: http://www.erc-success.eu/. We are grateful to Dr Mirko Traversari for his willingness on the use of the Roccapelago sample. References: [1] Hellier, C.A., & Jeffery, N. 2006. Morphological plasticity in the juvenile talus. Foot and Ankle surgery, 12(3), 139-147. [2] Belcastro, M.G., Bonfiglioli, B., Pedrosi, M.E., Zuppello, M., Tanganelli, V., & Mariotti, V. 2017. The history and composition of the identified human skeletal collection of the Certosa Cemetery (Bologna, Italy, 19th‐20th century). International Journal of Osteoarchaeology. DOI: 10.1002/oa.2605 [3] Figus, C., Traversari M., Scalise L. M., Oxilia G., Vazzana A., Buti L., Sorrentino R., Gruppioni G., Benazzi, S. 2017. The study of commingled non-adult human remains: Insights from the 16th-18th centuries community of Roccapelago (Italy). Journal of Archaeological Science: Reports, 14:382-391 [4] Dunmore C.J., Wollny G., Skinner M.M. (2018) MIA-Clustering: a novel method for segmentation of paleontological material. PeerJ 6:e4374 [5] Rohlf, F.J., Slice, D. 1990. Extensions of the Procrustes method for the optimal superimposition of landmarks. Syst. Biol. 39, 40-59.

Published

2018

5. Trabecular Analysis of the Distal Radial Metaphysis during the Acquisition of Crawling and Bipedal Walking in Childhood: A Preliminary Study

Author

Colombo A, Stephens NB, Tsegai ZJ, Bettuzzi M, Morigi MP, Belcastro MG, Hublin J-J, and Colombo A, Stephens NB, Tsegai ZJ, Bettuzzi M, Morigi MP, Belcastro MG, Hublin J-J

Subjects

sense organs, Trabecular bone microarchitecture / Ontogeny / Bipedal walking / Biomechanics / Cancellous bone

Abstract

In modern day populations, children following a normal pattern of development acquire independent bipedal locomotion between the ages of 9 and 18 months. Variability in the timing of this psychomotor developmental milestone depends on various factors, including cultural influences. It is well known that trabecular bone adapts to changes in biomechanical loading and that this can be influenced by alternative locomotor modes, such as crawling, which may be adopted before the acquisition of bipedal locomotion. With the onset of crawling, increased loading of the distal metaphysis of the radius, a component of the wrist, may lead to changes in trabecular bone architecture. To test this hypothesis, eight distal metaphyses of the radius of nonpathological children aged 0 to 3 years from the Bologna collection of identified skeletons were μCT-scanned at a resolution of 10.7 μm. The microarchitectural parameters of the trabecular bone (trabecular bone volume fraction, trabecular thickness, trabecular spacing, and trabecular ellipsoid factor) were quantified for the entire metaphysis and 3D morphometric maps of the distribution of the bone volume fraction were generated. Analysis of these microarchitectural parameters and the 3D morphometric maps show changes in the trabecular bone structure between 6 and 15 months, the period during which both crawling and bipedalism are acquired. This preliminary study analyzed the trabecular structure of the growing radius in three dimensions for the first time, and suggests that ontogenetic changes in the trabecular structure of the radial metaphysis may be related to changes in the biomechanical loading of the wrist during early locomotor transitions, i.e. the onset of crawling. Moreover, microarchitectural analysis could supply important information on the developmental timing of locomotor transitions, which would facilitate interpretations of locomotor development in past populations.

Published

2018

6. Unravelling morphological changes of the human talus during growth

Author

Carla Figus, Stephens, Nb, Rita Sorrentino, Panetta, D., MARIA GIOVANNA BELCASTRO, Ryan, Tm, and Stefano Benazzi

7. Morphologies in-between: The impact of the first steps on the human talus.

Author

Figus C, Stephens NB, Sorrentino R, Bortolini E, Arrighi S, Higgins OA, Lugli F, Marciani G, Oxilia G, Romandini M, Silvestrini S, Baruffaldi F, Belcastro MG, Bernardini F, Festa A, Hajdu T, Mateovics-László O, Pap I, Szeniczey T, Tuniz C, Ryan TM, and Benazzi S

Subjects

Humans, X-Ray Microtomography, Walking

Abstract

Objective: The development of bipedalism is a very complex activity that contributes to shaping the anatomy of the foot. The talus, which starts ossifying in utero, may account for the developing stages from the late gestational phase onwards. Here, we explore the early development of the talus in both its internal and external morphology to broaden the knowledge of the anatomical changes that occur during early development., Materials and Methods: The sample consists of high-resolution microCT scans of 28 modern juvenile tali (from 36 prenatal weeks to 2 years), from a broad chronological range from the Late Roman period to the 20th century. We applied geometric morphometric and whole-bone trabecular analysis to investigate the early talar morphological changes., Results: In the youngest group (<6 postnatal months), the immature external shell is accompanied by an isotropic internal structure, with thin and densely packed trabeculae. After the initial attempts of locomotion, bone volume fraction decreases, while anisotropy and trabecular thickness increase. These internal changes correspond to the maturation of the external shell, which is now more defined and shows the development of the articular surfaces., Discussion: The internal and external morphology of the human talus reflects the diverse load on the foot during the initial phases of the bipedal locomotion, with the youngest group potentially reflecting the lack of readiness of the human talus to bear forces and perform bipedal walking. These results highlight the link between mechanical loading and bone development in the human talus during the acquisition of bipedalism, providing new insight into the early phases of talar development., (© 2022 The Authors. The Anatomical Record published by Wiley Periodicals LLC on behalf of American Association for Anatomy.)

Published

2023

8. Unique foot posture in Neanderthals reflects their body mass and high mechanical stress.

Author

Sorrentino R, Stephens NB, Marchi D, DeMars LJD, Figus C, Bortolini E, Badino F, Saers JPP, Bettuzzi M, Boschin F, Capecchi G, Feletti F, Guarnieri T, May H, Morigi MP, Parr W, Ricci S, Ronchitelli A, Stock JT, Carlson KJ, Ryan TM, Belcastro MG, and Benazzi S

Subjects

Animals, Fossils, Humans, Phylogeny, Posture, Stress, Mechanical, Neanderthals, Talus anatomy & histology

Abstract

Neanderthal foot bone proportions and morphology are mostly indistinguishable from those of Homo sapiens, with the exception of several distinct Neanderthal features in the talus. The biomechanical implications of these distinct talar features remain contentious, fueling debate around the adaptive meaning of this distinctiveness. With the aim of clarifying this controversy, we test phylogenetic and behavioral factors as possible contributors, comparing tali of 10 Neanderthals and 81 H. sapiens (Upper Paleolithic and Holocene hunter-gatherers, agriculturalists, and postindustrial group) along with the Clark Howell talus (Omo, Ethiopia). Variation in external talar structures was assessed through geometric morphometric methods, while bone volume fraction and degree of anisotropy were quantified in a subsample (n = 45). Finally, covariation between point clouds of site-specific trabecular variables and surface landmark coordinates was assessed. Our results show that although Neanderthal talar external and internal morphologies were distinct from those of H. sapiens groups, shape did not significantly covary with either bone volume fraction or degree of anisotropy, suggesting limited covariation between external and internal talar structures. Neanderthal external talar morphology reflects ancestral retentions, along with various adaptations to high levels of mobility correlated to their presumably unshod hunter-gatherer lifestyle. This pairs with their high site-specific trabecular bone volume fraction and anisotropy, suggesting intense and consistently oriented locomotor loading, respectively. Relative to H.sapiens, Neanderthals exhibit differences in the talocrural joint that are potentially attributable to cultural and locomotor behavior dissimilarity, a talonavicular joint that mixes ancestral and functional traits, and a derived subtalar joint that suggests a predisposition for a pronated foot during stance phase. Overall, Neanderthal talar variation is attributable to mobility strategy and phylogenesis, while H. sapiens talar variation results from the same factors plus footwear. Our results suggest that greater Neanderthal body mass and/or higher mechanical stress uniquely led to their habitually pronated foot posture., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

9. High-throughput phenotyping methods for quantifying hair fiber morphology.

Author

Lasisi T, Zaidi AA, Webster TH, Stephens NB, Routch K, Jablonski NG, and Shriver MD

Subjects

Cross-Sectional Studies, Humans, Hair anatomy & histology, Image Processing, Computer-Assisted, Scalp

Abstract

Quantifying the continuous variation in human scalp hair morphology is of interest to anthropologists, geneticists, dermatologists and forensic scientists, but existing methods for studying hair form are time-consuming and not widely used. Here, we present a high-throughput sample preparation protocol for the imaging of both longitudinal (curvature) and cross-sectional scalp hair morphology. Additionally, we describe and validate a new Python package designed to process longitudinal and cross-sectional hair images, segment them, and provide measurements of interest. Lastly, we apply our methods to an admixed African-European sample (n = 140), demonstrating the benefit of quantifying hair morphology over classification, and providing evidence that the relationship between cross-sectional morphology and curvature may be an artefact of population stratification rather than a causal link.

Published

2021

10. Automated resolution independent method for comparing in vivo and dry trabecular bone.

Author

Saers JPP, DeMars LJ, Stephens NB, Jashashvili T, Carlson KJ, Gordon AD, Ryan TM, and Stock JT

Subjects

Adaptation, Physiological physiology, Adult, Anatomy, Cross-Sectional, Animals, Archaeology, Female, Humans, Male, Phantoms, Imaging, Swine, X-Ray Microtomography methods, Cancellous Bone diagnostic imaging, Tibia diagnostic imaging, Tomography, X-Ray Computed methods

Abstract

Objectives: Variation in human trabecular bone morphology can be linked to habitual behavior, but it is difficult to investigate in vivo due to the radiation required at high resolution. Consequently, functional interpretations of trabecular morphology remain inferential. Here we introduce a method to link low- and high-resolution CT data from dry and fresh bone, enabling bone functional adaptation to be studied in vivo and results compared to the fossil and archaeological record., Materials and Methods: We examine 51 human dry bone distal tibiae from Nile Valley and UK and two pig tibiae containing soft tissues. We compare low-resolution peripheral quantitative computed tomography (pQCT) parameters and high-resolution micro CT (μCT) in homologous single slices at 4% bone length and compare results to our novel Bone Ratio Predictor (BRP) method., Results: Regression slopes between linear attenuation coefficients of low-resolution pQCT images and bone area/total area (BA/TA) of high-resolution μCT scans differ substantially between geographical subsamples, presumably due to diagenesis. BRP accurately predicts BA/TA (R 2 = .97) and eliminates the geographic clustering. BRP accurately estimates BA/TA in pigs containing soft tissues (R 2 = 0.98) without requiring knowledge of true density or phantom calibration of the scans., Discussion: BRP allows automated comparison of image data from different image modalities (pQCT, μCT) using different energy settings, in archeological bone and wet specimens. The method enables low-resolution data generated in vivo to be compared with the fossil and archaeological record. Such experimental approaches would substantially improve behavioral inferences based on trabecular bone microstructure., (© 2020 Wiley Periodicals LLC.)

Published

2021

11. Combinations of trabecular and cortical bone properties distinguish various loading modalities between athletes and controls.

Author

Saers JPP, DeMars LJ, Stephens NB, Jashashvili T, Carlson KJ, Gordon AD, Shaw CN, Ryan TM, and Stock JT

Subjects

Adult, Anthropology, Physical, Athletes, Bayes Theorem, Cancellous Bone diagnostic imaging, Cortical Bone diagnostic imaging, Humans, Male, Tibia diagnostic imaging, Tibia physiology, Young Adult, Cancellous Bone physiology, Cortical Bone physiology, Sports physiology, Weight-Bearing physiology

Abstract

Objectives: Variation in trabecular and cortical bone properties is often used to infer habitual behavior in the past. However, the structures of both types of bone are rarely considered together and may even contradict each other in functional interpretations. We examine trabecular and cortical bone properties in various athletes and sedentary controls to clarify the associations between combinations of cortical and trabecular bone properties and various loading modalities., Materials and Methods: We compare trabecular and cortical bone properties using peripheral quantitative computed tomography scans of the tibia between groups of 83 male athletes (running, hockey, swimming, cricket) and sedentary controls using Bayesian multilevel models. We quantify midshaft cortical bone rigidity and area (J, CA), midshaft shape index (Imax/Imin), and mean trabecular bone mineral density (BMD) in the distal tibia., Results: All groups show unique combinations of biomechanical properties. Cortical bone rigidity is high in sports that involve impact loading (cricket, running, hockey) and low in nonimpact loaded swimmers and controls. Runners have more anteroposteriorly elliptical midshafts compared to other groups. Interestingly, all athletes have greater trabecular BMD compared to controls, but do not differ credibly among each other., Discussion: Results suggest that cortical midshaft hypertrophy is associated with impact loading while trabecular BMD is positively associated with both impact and nonimpact loading. Midshaft shape is associated with directionality of loading. Individuals from the different categories overlap substantially, but group means differ credibly, suggesting that nuanced group-level inferences of habitual behavior are possible when combinations of trabecular and cortical bone are analyzed., (© 2020 Wiley Periodicals LLC.)

Published

2021

12. Using point clouds to investigate the relationship between trabecular bone phenotype and behavior: An example utilizing the human calcaneus.

Author

DeMars LJD, Stephens NB, Saers JPP, Gordon A, Stock JT, and Ryan TM

Subjects

Agriculture, Archaeology, Humans, Illinois, Anthropometry methods, Calcaneus physiology, Cancellous Bone physiology, Life Style, Phenotype

Abstract

Objectives: The objective of this study is to demonstrate a new method for analyzing trabecular bone volume fraction and degree of anisotropy in three dimensions., Methods: We use a combination of automatic mesh registration, point-cloud correspondence registration, and P-value corrected univariate statistical tests to compare bone volume fraction and degree of anisotropy on a point by point basis across the entire calcaneus of two human groups with different subsistence strategies., Results: We found that the patterns of high and low bone volume fraction and degree of anisotropy distribution between the Black Earth (hunter-gatherers) and Norris Farms (mixed-strategy agriculturalists) are very similar, but differ in magnitude. The hunter-gatherers exhibit higher levels of bone volume fraction and less anisotropic trabecular bone organization. Additionally, patterns of bone volume fraction and degree of anisotropy in the calcaneus correspond well with biomechanical expectations of relative forces experienced during walking and running., Conclusions: We conclude that comparing site-specific, localized differences in trabecular bone variables such as bone volume fraction and degree of anisotropy in three-dimensions is a powerful analytical tool. This method makes it possible to determine where similarities and differences between groups are located within the whole skeletal element of interest. The visualization of multiple variables also provides a way for researchers to see how the trabecular bone variables interact within the morphology, and allows for a more nuanced understanding of how they relate to one another and the broader mechanical environment., (© 2020 Wiley Periodicals LLC.)

Published

2021

13. The position of Australopithecus sediba within fossil hominin hand use diversity.

Author

Dunmore CJ, Skinner MM, Bardo A, Berger LR, Hublin JJ, Pahr DH, Rosas A, Stephens NB, and Kivell TL

Subjects

Animals, Biological Evolution, Fossils, Humans, Locomotion, Hominidae

Abstract

The human lineage is marked by a transition in hand use, from locomotion towards increasingly dexterous manipulation, concomitant with bipedalism. The forceful precision grips used by modern humans probably evolved in the context of tool manufacture and use, but when and how many times hominin hands became principally manipulative remains unresolved. We analyse metacarpal trabecular and cortical bone, which provide insight into behaviour during an individual's life, to demonstrate previously unrecognized diversity in hominin hand use. The metacarpals of the palm in Australopithecus sediba have trabecular morphology most like orangutans and consistent with locomotor power-grasping with the fingers, while that of the thumb is consistent with human-like manipulation. This internal morphology is the first record of behaviour consistent with a hominin that used its hand for both arboreal locomotion and human-like manipulation. This hand use is distinct from other fossil hominins in this study, including A. afarensis and A. africanus.

Published

2020

14. The influence of mobility strategy on the modern human talus.

Author

Sorrentino R, Stephens NB, Carlson KJ, Figus C, Fiorenza L, Frost S, Harcourt-Smith W, Parr W, Saers J, Turley K, Wroe S, Belcastro MG, Ryan TM, and Benazzi S

Subjects

Adult, Africa, Aged, Archaeology, Europe, Female, History, 17th Century, History, 18th Century, History, 19th Century, History, 20th Century, Humans, Male, Middle Aged, North America, Young Adult, Feeding Behavior, Motor Activity, Shoes history, Talus anatomy & histology

Abstract

Objectives: The primate talus is known to have a shape that varies according to differences in locomotion and substrate use. While the modern human talus is morphologically specialized for bipedal walking, relatively little is known on how its morphology varies in relation to cultural and environmental differences across time. Here we compare tali of modern human populations with different subsistence economies and lifestyles to explore how cultural practices and environmental factors influence external talar shape., Materials and Methods: The sample consists of digital models of 142 tali from 11 archaeological and post-industrial modern human groups. Talar morphology was investigated through 3D (semi)landmark based geometric morphometric methods., Results: Our results show distinct differences between highly mobile hunter-gatherers and more sedentary groups belonging to a mixed post-agricultural/industrial background. Hunter-gatherers exhibit a more "flexible" talar shape, everted posture, and a more robust and medially oriented talar neck/head, which we interpret as reflecting long-distance walking strictly performed barefoot, or wearing minimalistic footwear, along uneven ground. The talus of the post-industrial population exhibits a "stable" profile, neutral posture, and a less robust and orthogonally oriented talar neck/head, which we interpret as a consequence of sedentary lifestyle and use of stiff footwear., Discussion: We suggest that talar morphological variation is related to the adoption of constraining footwear in post-industrial society, which reduces ankle range of motion. This contrasts with hunter-gatherers, where talar shape shows a more flexible profile, likely resulting from a lack of footwear while traversing uneven terrain. We conclude that modern human tali vary with differences in locomotor and cultural behavior., (© 2019 Wiley Periodicals, Inc.)

Published

2020

15. Exploring sexual dimorphism of the modern human talus through geometric morphometric methods.

Author

Sorrentino R, Belcastro MG, Figus C, Stephens NB, Turley K, Harcourt-Smith W, Ryan TM, and Benazzi S

Subjects

Discriminant Analysis, Female, Humans, Image Processing, Computer-Assisted, Male, Principal Component Analysis, Sex Characteristics, Forensic Anthropology methods, Sex Determination by Skeleton methods, Talus anatomy & histology

Abstract

Sex determination is a pivotal step in forensic and bioarchaeological fields. Generally, scholars focus on metric or qualitative morphological features, but in the last few years several contributions have applied geometric-morphometric (GM) techniques to overcome limitations of traditional approaches. In this study, we explore sexual dimorphism in modern human tali from three early 20th century populations (Sassari and Bologna, Italy; New York, USA) at intra- and interspecific population levels using geometric morphometric (GM) methods. Statistical analyses were performed using shape, form, and size variables. Our results do not show significant differences in shape between males and females, either considering the pooled sample or the individual populations. Differences in talar morphology due to sexual dimorphism are mainly related to allometry, i.e. size-related changes of morphological traits. Discriminant function analysis using form space Principal Components and centroid size correctly classify between 87.7% and 97.2% of the individuals. The result is similar using the pooled sample or the individual population, except for a diminished outcome for the New York group (from 73.9% to 78.2%). Finally, a talus from the Bologna sample (not included in the previous analysis) with known sex was selected to run a virtual resection, followed by two digital reconstructions based on the mean shape of both the pooled sample and the Bologna sample, respectively. The reconstructed talus was correctly classified with a Ppost between 99.9% and 100%, demonstrating that GM is a valuable tool to cope with fragmentary tali, which is a common occurrence in forensic and bioarchaeological contexts., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

16. Three-dimensional geometric morphometric analysis of the first metacarpal distal articular surface in humans, great apes and fossil hominins.

Author

Galletta L, Stephens NB, Bardo A, Kivell TL, and Marchi D

Subjects

Animals, Biological Evolution, Biomechanical Phenomena, Humans, Metacarpal Bones physiology, Neanderthals anatomy & histology, Hand Strength, Hominidae anatomy & histology, Metacarpal Bones anatomy & histology, Range of Motion, Articular

Abstract

Understanding the manual abilities of fossil hominins has been a focus of palaeoanthropological research for decades. Of interest are the morphological characteristics of the thumb due to its fundamental role in manipulation, particularly that of the trapeziometacarpal joint. Considerably less attention has been given to the thumb metacarpophalangeal (MCP) joint, which plays a role in stabilizing the thumb during forceful grasps and precision pinching. In this study we use a three-dimensional geometric morphometric approach to quantify the shape of the first metacarpal head in extant hominids (Homo, Pan, Gorilla and Pongo) and six fossil hominin species (Homo neanderthalensis Tabun C1 and La Chappelle-aux-Saints, Homo naledi U.W. 101-1282, Australopithecus sediba MH2, Paranthropus robustus/early Homo SK84, Australopithecus africanus StW 418, Australopithecus afarensis A.L. 333w-39), with the aims of identifying shapes that may be correlated with human-like forceful opposition and determining if similar morphologies are present in fossil hominins. Results show that humans differ from extant great apes by having a distally flatter articular surface, larger epicondyle surface area, and a larger radial palmar condyle. We suggest that this suite of features is correlated with a lower range of motion at the MCP joint, which would enhance the thumbs ability to resist the elevated loads associated with the forceful precision grips typical of humans. Great ape genera are each differentiated by distinctive morphological features, each of which is consistently correlated with the predicted biomechanical demands of their particular locomotor and/or manipulatory habits. Neanderthals and U.W. 101-1282 fall within the modern human range of variation, StW 418, SK 84 and U.W. 88-119 fall in between humans and great apes, and A.L. 333w-39 falls within Pan variation. These results agree with those of traditional linear analyses while providing a more comprehensive quantitative basis from which to interpret the hand functional morphology of extinct hominins., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

17. Mandibular dysmorphology due to abnormal embryonic osteogenesis in FGFR2-related craniosynostosis mice.

Author

Motch Perrine SM, Wu M, Stephens NB, Kriti D, van Bakel H, Jabs EW, and Richtsmeier JT

Subjects

Animals, Cell Proliferation, Chondrocytes pathology, Diphosphates metabolism, Disease Models, Animal, Embryo, Mammalian pathology, Mandible pathology, Mice, Models, Biological, Osteoblasts pathology, Craniosynostoses embryology, Craniosynostoses pathology, Embryo, Mammalian abnormalities, Mandible abnormalities, Mandible embryology, Osteogenesis, Receptor, Fibroblast Growth Factor, Type 2 genetics

Abstract

One diagnostic feature of craniosynostosis syndromes is mandibular dysgenesis. Using three mouse models of Apert, Crouzon and Pfeiffer craniosynostosis syndromes, we investigated how embryonic development of the mandible is affected by fibroblast growth factor receptor 2 ( Fgfr2 ) mutations. Quantitative analysis of skeletal form at birth revealed differences in mandibular morphology between mice carrying Fgfr2 mutations and their littermates that do not carry the mutations. Murine embryos with the mutations associated with Apert syndrome in humans ( Fgfr2 +/S252W and Fgfr2 +/P253R ) showed an increase in the size of the osteogenic anlagen and Meckel's cartilage (MC). Changes in the microarchitecture and mineralization of the developing mandible were visualized using histological staining. The mechanism for mandibular dysgenesis in the Apert Fgfr2 +/S252W mouse resulting in the most severe phenotypic effects was further analyzed in detail and found to occur to a lesser degree in the other craniosynostosis mouse models. Laser capture microdissection and RNA-seq analysis revealed transcriptomic changes in mandibular bone at embryonic day 16.5 (E16.5), highlighting increased expression of genes related to osteoclast differentiation and dysregulated genes active in bone mineralization. Increased osteoclastic activity was corroborated by TRAP assay and in situ hybridization of Csf1r and Itgb3 Upregulated expression of Enpp1 and Ank was validated in the mandible of Fgfr2 +/S252W embryos, and found to result in elevated inorganic pyrophosphate concentration. Increased proliferation of osteoblasts in the mandible and chondrocytes forming MC was identified in Fgfr2 +/S252W embryos at E12.5. These findings provide evidence that FGFR2 gain-of-function mutations differentially affect cartilage formation and intramembranous ossification of dermal bone, contributing to mandibular dysmorphogenesis in craniosynostosis syndromes.This article has an associated First Person interview with the joint first authors of the paper., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2019. Published by The Company of Biologists Ltd.)

Published

2019

18. CMA quits global medical body over plagiarism row.

Author

Owens B

Subjects

Canada, Ethics, Medical, Humans, Plagiarism, Societies, Medical

Published

2018

19. Doctors call for change in union tactics in health care strikes.

Author

Owens B

Subjects

Allied Health Personnel, Canada, Health Facility Administrators, Health Services Accessibility, Humans, Nurses, Physicians, Health Personnel, Labor Unions, Strikes, Employee

Published

2018

20. Trabecular bone patterning across the human hand.

Author

Stephens NB, Kivell TL, Pahr DH, Hublin JJ, and Skinner MM

Subjects

Archaeology, Biomechanical Phenomena, Cancellous Bone physiology, Hand Bones physiology, Humans, Cancellous Bone anatomy & histology, Hand Bones anatomy & histology, Life Style

Abstract

Hand bone morphology is regularly used to link particular hominin species with behaviors relevant to cognitive/technological progress. Debates about the functional significance of differing hominin hand bone morphologies tend to rely on establishing phylogenetic relationships and/or inferring behavior from epigenetic variation arising from mechanical loading and adaptive bone modeling. Most research focuses on variation in cortical bone structure, but additional information about hand function may be provided through the analysis of internal trabecular structure. While primate hand bone trabecular structure is known to vary in ways that are consistent with expected joint loading differences during manipulation and locomotion, no study exists that has documented this variation across the numerous bones of the hand. We quantify the trabecular structure in 22 bones of the human hand (early/extant modern Homo sapiens) and compare structural variation between two groups associated with post-agricultural/industrial (post-Neolithic) and foraging/hunter-gatherer (forager) subsistence strategies. We (1) establish trabecular bone volume fraction (BV/TV), modulus (E), degree of anisotropy (DA), mean trabecular thickness (Tb.Th) and spacing (Tb.Sp); (2) visualize the average distribution of site-specific BV/TV for each bone; and (3) examine if the variation in trabecular structure is consistent with expected joint loading differences among the regions of the hand and between the groups. Results indicate similar distributions of trabecular bone in both groups, with those of the forager sample presenting higher BV/TV, E, and lower DA, suggesting greater and more variable loading during manipulation. We find indications of higher loading along the ulnar side of the forager sample hand, with high site-specific BV/TV distributions among the carpals that are suggestive of high loading while the wrist moves through the 'dart-thrower's' motion. These results support the use of trabecular structure to infer behavior and have direct implications for refining our understanding of human hand evolution and fossil hominin hand use., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

21. CMA phasing out annual General Council meeting.

Author

Owens B

Subjects

Canada, Congresses as Topic organization & administration, Humans, Organizational Policy, Societies, Medical organization & administration

Published

2018

22. Organ donations from overdose deaths on the rise but stigma remains.

Author

Owens B

Subjects

Canada, Health Education, Humans, Social Stigma, Tissue and Organ Procurement statistics & numerical data, Drug Overdose mortality, Substance Abuse, Intravenous mortality, Tissue Donors, Tissue and Organ Procurement organization & administration

Published

2018

23. Homo sapiens in Arabia by 85,000 years ago.

Author

Groucutt HS, Grün R, Zalmout IAS, Drake NA, Armitage SJ, Candy I, Clark-Wilson R, Louys J, Breeze PS, Duval M, Buck LT, Kivell TL, Pomeroy E, Stephens NB, Stock JT, Stewart M, Price GJ, Kinsley L, Sung WW, Alsharekh A, Al-Omari A, Zahir M, Memesh AM, Abdulshakoor AJ, Al-Masari AM, Bahameem AA, Al Murayyi KMS, Zahrani B, Scerri ELM, and Petraglia MD

Subjects

Archaeology, Environment, Humans, Saudi Arabia, Fossils, Human Migration

Abstract

Understanding the timing and character of the expansion of Homo sapiens out of Africa is critical for inferring the colonization and admixture processes that underpin global population history. It has been argued that dispersal out of Africa had an early phase, particularly ~130-90 thousand years ago (ka), that reached only the East Mediterranean Levant, and a later phase, ~60-50 ka, that extended across the diverse environments of Eurasia to Sahul. However, recent findings from East Asia and Sahul challenge this model. Here we show that H. sapiens was in the Arabian Peninsula before 85 ka. We describe the Al Wusta-1 (AW-1) intermediate phalanx from the site of Al Wusta in the Nefud desert, Saudi Arabia. AW-1 is the oldest directly dated fossil of our species outside Africa and the Levant. The palaeoenvironmental context of Al Wusta demonstrates that H. sapiens using Middle Palaeolithic stone tools dispersed into Arabia during a phase of increased precipitation driven by orbital forcing, in association with a primarily African fauna. A Bayesian model incorporating independent chronometric age estimates indicates a chronology for Al Wusta of ~95-86 ka, which we correlate with a humid episode in the later part of Marine Isotope Stage 5 known from various regional records. Al Wusta shows that early dispersals were more spatially and temporally extensive than previously thought. Early H. sapiens dispersals out of Africa were not limited to winter rainfall-fed Levantine Mediterranean woodlands immediately adjacent to Africa, but extended deep into the semi-arid grasslands of Arabia, facilitated by periods of enhanced monsoonal rainfall.

Published

2018

24. Trabecular architecture in the thumb of Pan and Homo: implications for investigating hand use, loading, and hand preference in the fossil record.

Author

Stephens NB, Kivell TL, Gross T, Pahr DH, Lazenby RA, Hublin JJ, Hershkovitz I, and Skinner MM

Subjects

Animals, Anthropology, Physical, Biological Evolution, Biomechanical Phenomena physiology, Fossils, Humans, Metacarpal Bones diagnostic imaging, Thumb diagnostic imaging, X-Ray Microtomography, Functional Laterality physiology, Metacarpal Bones anatomy & histology, Pan troglodytes anatomy & histology, Thumb anatomy & histology

Abstract

Objectives: Humans display an 85-95% cross-cultural right-hand bias in skilled tasks, which is considered a derived behavior because such a high frequency is not reported in wild non-human primates. Handedness is generally considered to be an evolutionary byproduct of selection for manual dexterity and augmented visuo-cognitive capabilities within the context of complex stone tool manufacture/use. Testing this hypothesis requires an understanding of when appreciable levels of right dominant behavior entered the fossil record. Because bone remodels in vivo, skeletal asymmetries are thought to reflect greater mechanical loading on the dominant side, but incomplete preservation of external morphology and ambiguities about past loading environments complicate interpretations. We test if internal trabecular bone is capable of providing additional information by analyzing the thumb of Homo sapiens and Pan., Materials and Methods: We assess trabecular structure at the distal head and proximal base of paired (left/right) first metacarpals using micro-CT scans of Homo sapiens (n = 14) and Pan (n = 9). Throughout each epiphysis we quantify average and local bone volume fraction (BV/TV), degree of anisotropy (DA), and elastic modulus (E) to address bone volume patterning and directional asymmetry., Results: We find a right directional asymmetry in H. sapiens consistent with population-level handedness, but also report a left directional asymmetry in Pan that may be the result of postural and/or locomotor loading., Conclusion: We conclude that trabecular bone is capable of detecting right/left directional asymmetry, but suggest coupling studies of internal structure with analyses of other skeletal elements and cortical bone prior to applications in the fossil record., (© 2016 Wiley Periodicals, Inc.)

Published

2016

25. CMAJ gets interim editor amid governance shake-up.

Author

Owens B

Subjects

Canada, Humans, Editorial Policies, Journalism, Medical standards, Periodicals as Topic standards

Published

2016

26. Human evolution. Response to Comment on "Human-like hand use in Australopithecus africanus".

Author

Skinner MM, Stephens NB, Tsegai ZJ, Foote AC, Nguyen NH, Gross T, Pahr DH, Hublin JJ, and Kivell TL

Subjects

Animals, Humans, Biological Evolution, Metacarpal Bones anatomy & histology, Metacarpus anatomy & histology, Thumb anatomy & histology

Abstract

Almécija and colleagues claim that we apply a simplified understanding of bone functional adaptation and that our results of human-like hand use in Australopithecus africanus are not novel. We argue that our results speak to actual behavior, rather than potential behaviors, and our functional interpretation is well supported by our methodological approach, comparative sample, and previous experimental data., (Copyright © 2015, American Association for the Advancement of Science.)

Published

2015

27. Human evolution. Human-like hand use in Australopithecus africanus.

Author

Skinner MM, Stephens NB, Tsegai ZJ, Foote AC, Nguyen NH, Gross T, Pahr DH, Hublin JJ, and Kivell TL

Subjects

Animals, Archaeology, Hominidae anatomy & histology, Humans, Metacarpus physiology, Neanderthals anatomy & histology, Posture, Thumb physiology, Biological Evolution, Metacarpal Bones anatomy & histology, Metacarpus anatomy & histology, Thumb anatomy & histology

Abstract

The distinctly human ability for forceful precision and power "squeeze" gripping is linked to two key evolutionary transitions in hand use: a reduction in arboreal climbing and the manufacture and use of tools. However, it is unclear when these locomotory and manipulative transitions occurred. Here we show that Australopithecus africanus (~3 to 2 million years ago) and several Pleistocene hominins, traditionally considered not to have engaged in habitual tool manufacture, have a human-like trabecular bone pattern in the metacarpals consistent with forceful opposition of the thumb and fingers typically adopted during tool use. These results support archaeological evidence for stone tool use in australopiths and provide morphological evidence that Pliocene hominins achieved human-like hand postures much earlier and more frequently than previously considered., (Copyright © 2015, American Association for the Advancement of Science.)

Published

2015