Your search keyword '"Olga Panagiotopoulou"' showing total 67 results

1. Cranial Bone Changes Induced by Mild Traumatic Brain Injuries: A Neglected Player in Concussion Outcomes?

Author

Bridgette D. Semple and Olga Panagiotopoulou

Subjects

biomechanics, bone, calvarium, fracture, pathology, traumatic brain injury, Medical emergencies. Critical care. Intensive care. First aid, RC86-88.9

Abstract

Mild traumatic brain injuries (TBIs), particularly when repetitive in nature, are increasingly recognized to have a range of significant negative implications for brain health. Much of the ongoing research in the field is focused on the neurological consequences of these injuries and the relationship between TBIs and long-term neurodegenerative conditions such as chronic traumatic encephalopathy and Alzheimer's disease. However, our understanding of the complex relationship between applied mechanical force at impact, brain pathophysiology, and neurological function remains incomplete. Past research has shown that mild TBIs, even below the threshold that results in cranial fracture, induce changes in cranial bone structure and morphology. These structural and physiological changes likely have implications for the transmission of mechanical force into the underlying brain parenchyma. Here, we review this evidence in the context of the current understanding of bone mechanosensitivity and the consequences of TBIs or concussions. We postulate that heterogeneity of the calvarium, including differing bone thickness attributable to past impacts, age, or individual variability, may be a modulator of outcomes after subsequent TBIs. We advocate for greater consideration of cranial responses to TBI in both experimental and computer modeling of impact biomechanics, and raise the hypothesis that calvarial bone thickness represents a novel biomarker of brain injury vulnerability post-TBI.

Published

2023

2. COVID-19 in congenital heart disease (COaCHeD) study

Author

Ashish Chikermane, Konstantinos Dimopoulos, Michael A Gatzoulis, Sonya V Babu-Narayan, Zdenka Reinhardt, Natali AY Chung, Paul F Clift, Dirk Wilson, Petra Jenkins, Rachel Knowles, Bernadette Khodaghalian, Benjamin Smith, Owen Miller, Umar Mahmood, Heba Nashat, Aoife Cleary, John M Simpson, Clive Lewis, Catherine Head, Sian Chivers, Tara Bharucha, Dominic Hares, Piers EF Daubeney, Caroline B Jones, Milos Prica, James Anthony, Victoria Jowett, Antonia Hardiman, Frances A Bu'Lock, Tristan KW Ramcharan, Jennifer Shortland, Andrew Tometzki, David S Crossland, Leila Rittey, Olga Panagiotopoulou, and Muhammad Najih L

Subjects

Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Background COVID-19 has caused significant worldwide morbidity and mortality. Congenital heart disease (CHD) is likely to increase vulnerability and understanding the predictors of adverse outcomes is key to optimising care.Objective Ascertain the impact of COVID-19 on people with CHD and define risk factors for adverse outcomes.Methods Multicentre UK study undertaken 1 March 2020–30 June 2021 during the COVID-19 pandemic. Data were collected on CHD diagnoses, clinical presentation and outcomes. Multivariable logistic regression with multiple imputation was performed to explore predictors of death and hospitalisation.Results There were 405 reported cases (127 paediatric/278 adult). In children (age

Published

2023

3. The biomechanics of chewing and suckling in the infant: A potential mechanism for physiologic metopic suture closure.

Author

Pranav N Haravu, Miguel Gonzalez, Shelby L Nathan, Callum F Ross, Olga Panagiotopoulou, and Russell R Reid

Subjects

Biology (General), QH301-705.5

Abstract

Craniosynostosis is a condition with neurologic and aesthetic sequelae requiring invasive surgery. Understanding its pathobiology requires familiarity with the processes underlying physiologic suture closure. Animal studies have shown that cyclical strain from chewing and suckling influences the closure of cranial vault sutures, especially the metopic, an important locus of craniosynostosis. However, there are no human data correlating strain patterns during chewing and suckling with the physiologically early closure pattern of the metopic suture. Furthermore, differences in craniofacial morphology make it challenging to directly extrapolate animal findings to humans. Eight finite-element analysis (FEA) models were built from craniofacial computer tomography (CT) scans at varying stages of metopic suture closure, including two with isolated non-syndromic metopic craniosynostosis. Muscle forces acting on the cranium during chewing and suckling were simulated using subject-specific jaw muscle cross-sectional areas. Chewing and suckling induced tension at the metopic and sagittal sutures, and compressed the coronal, lambdoid, and squamous sutures. Relative to other cranial vault sutures, the metopic suture experienced larger magnitudes of axial strain across the suture and a lower magnitude of shear strain. Strain across the metopic suture decreased during suture closure, but other sutures were unaffected. Strain patterns along the metopic suture mirrored the anterior to posterior sequence of closure: strain magnitudes were highest at the glabella and decreased posteriorly, with minima at the nasion and the anterior fontanelle. In models of physiologic suture closure, increased degree of metopic suture closure correlated with higher maximum principal strains across the frontal bone and mid-face, a strain regime not observed in models of severe metopic craniosynostosis. In summary, our work provides human evidence that bone strain patterns from chewing and suckling correlate with the physiologically early closure pattern of the metopic suture, and that deviations from physiologic strain regimes may contribute to clinically observed craniofacial dysmorphism.

Published

2023

4. Macaca mulatta is a good model for human mandibular fixation research

Author

Pranav N. Haravu, Hyab Mehari Abraha, Michelle Shang, Jose Iriarte-Diaz, Andrea B. Taylor, Russell R. Reid, Callum F. Ross, and Olga Panagiotopoulou

Subjects

mandible angle fracture, Champy fixation, biplanar fixation, chewing, rhesus macaque, finite-element model, Science

Abstract

Biomechanical and clinical studies have yet to converge on the optimal fixation technique for angle fractures, one of the most common and controversial fractures in terms of fixation approach. Prior pre-clinical studies have used a variety of animal models and shown abnormal strain environments exacerbated by less rigid (single-plate) Champy fixation and chewing on the side opposite the fracture (contralateral chewing). However, morphological differences between species warrant further investigation to ensure that these findings are translational. Here we present the first study to use realistically loaded finite-element models to compare the biomechanical behaviour of human and macaque mandibles pre- and post-fracture and fixation. Our results reveal only small differences in deformation and strain regimes between human and macaque mandibles. In the human model, more rigid biplanar fixation better approximated physiologically healthy global bone strains and moments around the mandible, and also resulted in less interfragmentary strain than less rigid Champy fixation. Contralateral chewing exacerbated deviations in strain, moments and interfragmentary strain, especially under Champy fixation. Our pre- and post-fracture fixation findings are congruent with those from macaques, confirming that rhesus macaques are excellent animal models for biomedical research into mandibular fixation. Furthermore, these findings strengthen the case for rigid biplanar fixation over less rigid one-plate fixation in the treatment of isolated mandibular angle fractures.

Published

2022

5. Taking a stab at modelling canine tooth biomechanics in mammalian carnivores with beam theory and finite-element analysis

Author

Tahlia I. Pollock, Olga Panagiotopoulou, David P. Hocking, and Alistair R. Evans

Subjects

tooth morphology, feeding ecology, biomechanics, Carnivora, form-function, Science

Abstract

Canine teeth are vital to carnivore feeding ecology, facilitating behaviours related to prey capture and consumption. Forms vary with specific feeding ecologies; however, the biomechanics that drive these relationships have not been comprehensively investigated. Using a combination of beam theory analysis (BTA) and finite-element analysis (FEA) we assessed how aspects of canine shape impact tooth stress, relating this to feeding ecology. The degree of tooth lateral compression influenced tolerance of multidirectional loads, whereby canines with more circular cross-sections experienced similar maximum stresses under pulling and shaking loads, while more ellipsoid canines experienced higher stresses under shaking loads. Robusticity impacted a tooth's ability to tolerate stress and appears to be related to prey materials. Robust canines experience lower stresses and are found in carnivores regularly encountering hard foods. Slender canines experience higher stresses and are associated with carnivores biting into muscle and flesh. Curvature did not correlate with tooth stress; however, it did impact bending during biting. Our simulations help identify scenarios where canine forms are likely to break and pinpoint areas where this breakage may occur. These patterns demonstrate how canine shape relates to tolerating the stresses experienced when killing and feeding, revealing some of the form–function relationships that underpin mammalian carnivore ecologies.

Published

2022

6. Fracture Fixation Technique and Chewing Side Impact Jaw Mechanics in Mandible Fracture Repair

Author

Hyab Mehari Abraha, José Iriarte‐Diaz, Russell R Reid, Callum F Ross, and Olga Panagiotopoulou

Subjects

FINITE ELEMENT ANALYSIS, IMPLANTS, MANDIBLE, MASTICATION, MAXILLOFACIAL SURGERY, RHESUS MONKEY, Orthopedic surgery, RD701-811, Diseases of the musculoskeletal system, RC925-935

Abstract

ABSTRACT Lower jaw (mandible) fractures significantly impact patient health and well‐being due to pain and difficulty eating, but the best technique for repairing the most common subtype—angle fractures—and rehabilitating mastication is unknown. Our study is the first to use realistic in silico simulation of chewing to quantify the effects of Champy and biplanar techniques of angle fracture fixation. We show that more rigid, biplanar fixation results in lower strain magnitudes in the miniplates, the bone around the screws, and in the fracture zone, and that the mandibular strain regime approximates the unfractured condition. Importantly, the strain regime in the fracture zone is affected by chewing laterality, suggesting that both fixation type and the patient's post‐fixation masticatory pattern—ipsi‐ or contralateral to the fracture— impact the bone healing environment. Our study calls for further investigation of the impact of fixation technique on chewing behavior. Research that combines in vivo and in silico approaches can link jaw mechanics to bone healing and yield more definitive recommendations for fixation, hardware, and postoperative rehabilitation to improve outcomes. © 2021 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research.

Published

2022

7. Individual variation of the masticatory system dominates 3D skull shape in the herbivory-adapted marsupial wombats

Author

Vera Weisbecker, Thomas Guillerme, Cruise Speck, Emma Sherratt, Hyab Mehari Abraha, Alana C. Sharp, Claire E. Terhune, Simon Collins, Stephen Johnston, and Olga Panagiotopoulou

Subjects

Marsupial, Mastication, Constraint, Cranium, Mandible, Geometric morphometrics, Zoology, QL1-991

Abstract

Abstract Background Within-species skull shape variation of marsupial mammals is widely considered low and strongly size-dependent (allometric), possibly due to developmental constraints arising from the altricial birth of marsupials. However, species whose skulls are impacted by strong muscular stresses – particularly those produced through mastication of tough food items – may not display such intrinsic patterns very clearly because of the known plastic response of bone to muscle activity of the individual. In such cases, allometry may not dominate within-species shape variation, even if it is a driver of evolutionary shape divergence; ordination of shape in a geometric morphometric context through principal component analysis (PCA) should reveal main variation in areas under masticatory stress (incisor region/zygomatic arches/mandibular ramus); but this main variation should emerge from high individual variability and thus have low eigenvalues. Results We assessed the evidence for high individual variation through 3D geometric morphometric shape analysis of crania and mandibles of three species of grazing-specialized wombats, whose diet of tough grasses puts considerable strain on their masticatory system. As expected, we found little allometry and low Principal Component 1 (PC1) eigenvalues within crania and mandibles of all three species. Also as expected, the main variation was in the muzzle, zygomatic arches, and masticatory muscle attachments of the mandibular ramus. We then implemented a new test to ask if the landmark variation reflected on PC1 was reflected in individuals with opposite PC1 scores and with opposite shapes in Procrustes space. This showed that correspondence between individual and ordinated shape variation was limited, indicating high levels of individual variability in the masticatory apparatus. Discussion Our results are inconsistent with hypotheses that skull shape variation within marsupial species reflects a constraint pattern. Rather, they support suggestions that individual plasticity can be an important determinant of within-species shape variation in marsupials (and possibly other mammals) with high masticatory stresses, making it difficult to understand the degree to which intrinsic constraints act on shape variation at the within-species level. We conclude that studies that link micro- and macroevolutionary patterns of shape variation might benefit from a focus on species with low-impact mastication, such as carnivorous or frugivorous species.

Published

2019

8. A New Pipeline to Automatically Segment and Semi-Automatically Measure Bone Length on 3D Models Obtained by Computed Tomography

Author

Santiago Beltran Diaz, Chee Ho H’ng, Xinli Qu, Michael Doube, John Tan Nguyen, Michael de Veer, Olga Panagiotopoulou, and Alberto Rosello-Diez

Subjects

bone growth and development, micro-CT (computed tomography), BoneJ, MIMICS, skeletal phenotype analysis, limb evolution, Biology (General), QH301-705.5

Abstract

The characterization of developmental phenotypes often relies on the accurate linear measurement of structures that are small and require laborious preparation. This is tedious and prone to errors, especially when repeated for the multiple replicates that are required for statistical analysis, or when multiple distinct structures have to be analyzed. To address this issue, we have developed a pipeline for characterization of long-bone length using X-ray microtomography (XMT) scans. The pipeline involves semi-automated algorithms for automatic thresholding and fast interactive isolation and 3D-model generation of the main limb bones, using either the open-source ImageJ plugin BoneJ or the commercial Mimics Innovation Suite package. The tests showed the appropriate combination of scanning conditions and analysis parameters yields fast and comparable length results, highly correlated with the measurements obtained via ex vivo skeletal preparations. Moreover, since XMT is not destructive, the samples can be used afterward for histology or other applications. Our new pipelines will help developmental biologists and evolutionary researchers to achieve fast, reproducible and non-destructive length measurement of bone samples from multiple animal species.

Published

2021

9. The Mechanical Effect of the Periodontal Ligament on Bone Strain Regimes in a Validated Finite Element Model of a Macaque Mandible

Author

Hyab Mehari Abraha, Jose Iriarte-Diaz, Callum F. Ross, Andrea B. Taylor, and Olga Panagiotopoulou

Subjects

finite element analysis, in vivo validation, biomechanics, mastication, rhesus monkey, sensitivity analysis, Biotechnology, TP248.13-248.65

Abstract

The primary anatomical function of the periodontal ligament (PDL) is to attach teeth to their sockets. However, theoretical and constitutive mechanical models have proposed that during mastication the PDL redistributes local occlusal loads and reduces the jaw's resistance to torsional deformations. These hypotheses imply that accurately modeling the PDL's material properties and geometry in finite element analysis (FEA) is a prerequisite to obtaining precise strain and deformation data. Yet, many finite element studies of the human and non-human primate masticatory apparatus exclude the PDL or model it with simplicity, in part due to limitations in μCT/CT scan resolution and material property assignment. Previous studies testing the sensitivity of finite element models (FEMs) to the PDL have yielded contradictory results, however a major limitation of these studies is that FEMs were not validated against in vivo bone strain data. Hence, this study uses a validated and subject specific FEM to assess the effect of the PDL on strain and deformation regimes in the lower jaw of a rhesus macaque (Macaca mulatta) during simulated unilateral post-canine chewing. Our findings demonstrate that the presence of the PDL does influence local and global surface strain magnitudes (principal and shear) in the jaw. However, the PDL's effect is limited (diff. ~200–300 με) in areas away from the alveoli. Our results also show that varying the PDL's Young's Modulus within the range of published values (0.07–1750 MPa) has very little effect on global surface strains. These findings suggest that the mechanical importance of the PDL in FEMs of the mandible during chewing is dependent on the scope of the hypotheses being tested. If researchers are comparing strain gradients across species/taxa, the PDL may be excluded with minimal effect on results, but, if researchers are concerned with absolute strain values, sensitivity analysis is required.

Published

2019

10. Foot pressure distribution in White Rhinoceroses (Ceratotherium simum) during walking

Author

Olga Panagiotopoulou, Todd C. Pataky, and John R. Hutchinson

Subjects

Perissodactyla, Biomechanics, Osteopathology, Gait, Mechanobiology, Locomotion, Medicine, Biology (General), QH301-705.5

Abstract

White rhinoceroses (Ceratotherium simum) are odd-toed ungulates that belong to the group Perissodactyla. Being second only to elephants in terms of large body mass amongst extant tetrapods, rhinoceroses make fascinating subjects for the study of how large land animals support and move themselves. Rhinoceroses often are kept in captivity for protection from ivory poachers and for educational/touristic purposes, yet a detrimental side effect of captivity can be foot disease (i.e., enthesopathies and osteoarthritis around the phalanges). Foot diseases in large mammals are multifactorial, but locomotor biomechanics (e.g., pressures routinely experienced by the feet) surely can be a contributing factor. However, due to a lack of in vivo experimental data on rhinoceros foot pressures, our knowledge of locomotor performance and its links to foot disease is limited. The overall aim of this study was to characterize peak pressures and center of pressure trajectories in white rhinoceroses during walking. We asked two major questions. First, are peak locomotor pressures the lowest around the fat pad and its lobes (as in the case of elephants)? Second, are peak locomotor pressures concentrated around the areas with the highest reported incidence of pathologies? Our results show a reduction of pressures around the fat pad and its lobes, which is potentially due to the material properties of the fat pad or a tendency to avoid or limit “heel” contact at impact. We also found an even and gradual concentration of foot pressures across all digits, which may be a by-product of the more horizontal foot roll-off during the stance phase. While our exploratory, descriptive sample precluded hypothesis testing, our study provides important new data on rhinoceros locomotion for future studies to build on, and thus impetus for improved implementation in the care of captive/managed rhinoceroses.

Published

2019

11. Congenital Heart Disease in Asymptomatic Neonates with Extra-Cardiac Malformations and Genetic Disorders

Author

Ageliki A. Karatza, Olga Panagiotopoulou, Despoina Gkentzi, and Gabriel Dimitriou

Subjects

Medicine

Published

2019

12. A preliminary case study of the effect of shoe-wearing on the biomechanics of a horse’s foot

Author

Olga Panagiotopoulou, Jeffery W. Rankin, Stephen M. Gatesy, and John R. Hutchinson

Subjects

Equine biomechanics, Farriery, Finite element analysis, Inverse dynamics, XROMM, Locomotion, Medicine, Biology (General), QH301-705.5

Abstract

Horse racing is a multi-billion-dollar industry that has raised welfare concerns due to injured and euthanized animals. Whilst the cause of musculoskeletal injuries that lead to horse morbidity and mortality is multifactorial, pre-existing pathologies, increased speeds and substrate of the racecourse are likely contributors to foot disease. Horse hooves have the ability to naturally deform during locomotion and dissipate locomotor stresses, yet farriery approaches are utilised to increase performance and protect hooves from wear. Previous studies have assessed the effect of different shoe designs on locomotor performance; however, no biomechanical study has hitherto measured the effect of horseshoes on the stresses of the foot skeleton in vivo. This preliminary study introduces a novel methodology combining three-dimensional data from biplanar radiography with inverse dynamics methods and finite element analysis (FEA) to evaluate the effect of a stainless steel shoe on the function of a Thoroughbred horse’s forefoot during walking. Our preliminary results suggest that the stainless steel shoe shifts craniocaudal, mediolateral and vertical GRFs at mid-stance. We document a similar pattern of flexion-extension in the PIP (pastern) and DIP (coffin) joints between the unshod and shod conditions, with slight variation in rotation angles throughout the stance phase. For both conditions, the PIP and DIP joints begin in a flexed posture and extend over the entire stance phase. At mid-stance, small differences in joint angle are observed in the PIP joint, with the shod condition being more extended than the unshod horse, whereas the DIP joint is extended more in the unshod than the shod condition. We also document that the DIP joint extends more than the PIP after mid-stance and until the end of the stance in both conditions. Our FEA analysis, conducted solely on the bones, shows increased von Mises and Maximum principal stresses on the forefoot phalanges in the shod condition at mid-stance, consistent with the tentative conclusion that a steel shoe might increase mechanical loading. However, because of our limited sample size none of these apparent differences have been tested for statistical significance. Our preliminary study illustrates how the shoe may influence the dynamics and mechanics of a Thoroughbred horse’s forefoot during slow walking, but more research is needed to quantify the effect of the shoe on the equine forefoot during the whole stance phase, at faster speeds/gaits and with more individuals as well as with a similar focus on the hind feet. We anticipate that our preliminary analysis using advanced methodological approaches will pave the way for new directions in research on the form/function relationship of the equine foot, with the ultimate goal to minimise foot injuries and improve animal health and welfare.

Published

2016

13. Architecture of the sperm whale forehead facilitates ramming combat

Author

Olga Panagiotopoulou, Panagiotis Spyridis, Hyab Mehari Abraha, David R. Carrier, and Todd C. Pataky

Subjects

Sperm whale, Spermaceti junk, Ramming impact, Finite element analysis, Probabilistic simulation, Connective tissue partitions, Medicine, Biology (General), QH301-705.5

Abstract

Herman Melville’s novel Moby Dick was inspired by historical instances in which large sperm whales (Physeter macrocephalus L.) sank 19th century whaling ships by ramming them with their foreheads. The immense forehead of sperm whales is possibly the largest, and one of the strangest, anatomical structures in the animal kingdom. It contains two large oil-filled compartments, known as the “spermaceti organ” and “junk,” that constitute up to one-quarter of body mass and extend one-third of the total length of the whale. Recognized as playing an important role in echolocation, previous studies have also attributed the complex structural configuration of the spermaceti organ and junk to acoustic sexual selection, acoustic prey debilitation, buoyancy control, and aggressive ramming. Of these additional suggested functions, ramming remains the most controversial, and the potential mechanical roles of the structural components of the spermaceti organ and junk in ramming remain untested. Here we explore the aggressive ramming hypothesis using a novel combination of structural engineering principles and probabilistic simulation to determine if the unique structure of the junk significantly reduces stress in the skull during quasi-static impact. Our analyses indicate that the connective tissue partitions in the junk reduce von Mises stresses across the skull and that the load-redistribution functionality of the former is insensitive to moderate variation in tissue material parameters, the thickness of the partitions, and variations in the location and angle of the applied load. Absence of the connective tissue partitions increases skull stresses, particularly in the rostral aspect of the upper jaw, further hinting of the important role the architecture of the junk may play in ramming events. Our study also found that impact loads on the spermaceti organ generate lower skull stresses than an impact on the junk. Nevertheless, whilst an impact on the spermaceti organ would reduce skull stresses, it would also cause high compressive stresses on the anterior aspect of the organ and the connective tissue case, possibly making these structures more prone to failure. This outcome, coupled with the facts that the spermaceti organ houses sensitive and essential sonar producing structures and the rostral portion of junk, rather than the spermaceti organ, is frequently a site of significant scarring in mature males suggest that whales avoid impact with the spermaceti organ. Although the unique structure of the junk certainly serves multiple functions, our results are consistent with the hypothesis that the structure also evolved to function as a massive battering ram during male-male competition.

Published

2016

14. Foot pressure distributions during walking in African elephants (Loxodonta africana)

Author

Olga Panagiotopoulou, Todd C. Pataky, Madeleine Day, Michael C. Hensman, Sean Hensman, John R. Hutchinson, and Christofer J. Clemente

Subjects

biomechanics, welfare, proboscidea, locomotion, centre of pressure, elephant feet, Science

Abstract

Elephants, the largest living land mammals, have evolved a specialized foot morphology to help reduce locomotor pressures while supporting their large body mass. Peak pressures that could cause tissue damage are mitigated passively by the anatomy of elephants' feet, yet this mechanism does not seem to work well for some captive animals. This study tests how foot pressures vary among African and Asian elephants from habitats where natural substrates predominate but where foot care protocols differ. Variations in pressure patterns might be related to differences in husbandry, including but not limited to trimming and the substrates that elephants typically stand and move on. Both species' samples exhibited the highest concentration of peak pressures on the lateral digits of their feet (which tend to develop more disease in elephants) and lower pressures around the heel. The trajectories of the foot's centre of pressure were also similar, confirming that when walking at similar speeds, both species load their feet laterally at impact and then shift their weight medially throughout the step until toe-off. Overall, we found evidence of variations in foot pressure patterns that might be attributable to husbandry and other causes, deserving further examination using broader, more comparable samples.

Published

2016

15. Size-related changes in foot impact mechanics in hoofed mammals.

Author

Sharon Elaine Warner, Phillip Pickering, Olga Panagiotopoulou, Thilo Pfau, Lei Ren, and John Richard Hutchinson

Subjects

Medicine, Science

Abstract

Foot-ground impact is mechanically challenging for all animals, but how do large animals mitigate increased mass during foot impact? We hypothesized that impact force amplitude scales according to isometry in animals of increasing size through allometric scaling of related impact parameters. To test this, we measured limb kinetics and kinematics in 11 species of hoofed mammals ranging from 18-3157 kg body mass. We found impact force amplitude to be maintained proportional to size in hoofed mammals, but that other features of foot impact exhibit differential scaling patterns depending on the limb; forelimb parameters typically exhibit higher intercepts with lower scaling exponents than hind limb parameters. Our explorations of the size-related consequences of foot impact advance understanding of how body size influences limb morphology and function, foot design and locomotor behaviour.

Published

2013

16. Cranial Bone Changes Induced by Mild Head Impacts: A Neglected Player in Concussion Outcomes?

Author

Bridgette Semple and Olga Panagiotopoulou

Abstract

Mild impacts to the head, particularly when repetitive in nature, are increasingly recognized to have a range of significant negative implications for brain health. Much of the ongoing research in the field is focused on the neurological consequences of these injuries, and the relationship between head impacts and long-term neurodegenerative conditions such as chronic traumatic encephalopathy and Alzheimer’s disease. However, our understanding of the complex relationship between applied mechanical force at impact, brain pathophysiology, and neurological function, remains incomplete. Past research has shown that mild head impacts, even below the threshold that results in cranial fracture, induce changes in cranial bone structure and morphology. These structural and physiological changes likely have implications for the transmission of mechanical force into the underlying brain parenchyma. Here, we review this evidence in the context of the current understanding of bone mechanosensitivity and the consequences of traumatic brain injuries or concussions. We postulate that heterogeneity of the calvarium including differing bone thickness due to prior impacts, age, or individual variability, may be a modulator of outcomes following subsequent head impacts. We advocate for greater consideration of cranial responses to head injury in both experimental and computer modeling of impact biomechanics, and raise the hypothesis that calvarial bone thickness represents a novel biomarker of brain injury vulnerability after head trauma.

Published

2023

17. Does the model reflect the system? When two-dimensional biomechanics is not ‘good enough’

Author

Amanda L. Smith, Julian Davis, Olga Panagiotopoulou, Andrea B. Taylor, Chris Robinson, Carol V. Ward, William H. Kimbel, Zeresenay Alemseged, and Callum F. Ross

Subjects

Biomaterials, Biomedical Engineering, Biophysics, Bioengineering, Biochemistry, Biotechnology

Abstract

Models are mathematical representations of systems, processes or phenomena. In biomechanics, finite-element modelling (FEM) can be a powerful tool, allowing biologists to test form–function relationships in silico , replacing or extending results of in vivo experimentation. Although modelling simplifications and assumptions are necessary, as a minimum modelling requirement the results of the simplified model must reflect the biomechanics of the modelled system. In cases where the three-dimensional mechanics of a structure are important determinants of its performance, simplified two-dimensional modelling approaches are likely to produce inaccurate results. The vertebrate mandible is one among many three-dimensional anatomical structures routinely modelled using two-dimensional FE analysis. We thus compare the stress regimes of our published three-dimensional model of the chimpanzee mandible with a published two-dimensional model of the chimpanzee mandible and identify several fundamental differences. We then present a series of two-dimensional and three-dimensional FE modelling experiments that demonstrate how three key modelling parameters, (i) dimensionality, (ii) symmetric geometry, and (iii) constraints, affect deformation and strain regimes of the models. Our results confirm that, in the case of the primate mandible (at least), two-dimensional FEM fails to meet this minimum modelling requirement and should not be used to draw functional, ecological or evolutionary conclusions.

Published

2023

18. Corrigendum to 'Biomechanics of the mandible of Macaca mulatta during the power stroke of mastication: Loading, deformation, and strain regimes and the impact of food type' [Journal of Human Evolution 147 (2020) 102865]

Author

Olga Panagiotopoulou, Jose Iriarte-Diaz, Hyab Mehari Abraha, Andrea B. Taylor, Simon Wilshin, Paul C. Dechow, and Callum F. Ross

Subjects

Anthropology, Ecology, Evolution, Behavior and Systematics

Published

2023

19. Ultra-High-Field Diffusion Tensor Imaging Identifies Discrete Patterns of Concussive Injury in the Rodent Brain

Author

Joseph Benetatos, Xuan Vinh To, Hyab Mehari Abraha, Olga Panagiotopoulou, Wenyi Yan, Dedao Liu, Neha Soni, and Fatima A. Nasrallah

Subjects

Male, 030506 rehabilitation, Finite Element Analysis, Mice, Reflex, Righting, 03 medical and health sciences, 0302 clinical medicine, Nuclear magnetic resonance, Ultra high field, Concussion, medicine, Animals, Brain Concussion, Physics, medicine.diagnostic_test, Brain, food and beverages, Concussive injury, Magnetic resonance imaging, medicine.disease, Mice, Inbred C57BL, Diffusion Tensor Imaging, Neurology (clinical), 0305 other medical science, 030217 neurology & neurosurgery, Diffusion MRI

Abstract

Although concussions can result in persistent neurological post-concussion symptoms, they are typically invisible on routine magnetic resonance imaging (MRI) scans. Our study aimed to investigate the use of ultra-high-field diffusion tensor imaging (UHF-DTI) in discerning severity-dependent microstructural changes in the mouse brain following a concussion. Twenty-three C57BL/6 mice were randomly allocated into three groups: the low concussive (LC

Published

2021

20. Softening the steps to gigantism in sauropod dinosaurs through the evolution of a pedal pad

Author

Andréas Jannel, Olga Panagiotopoulou, and Steven Salisbury

Subjects

Multidisciplinary

Abstract

How sauropod dinosaurs were able to withstand the forces associated with their immense size represents one of the most challenging biomechanical scenarios in the evolution of terrestrial tetrapods, but also one lacking robust biomechanical testing. Here, we use finite element analyses to quantify the biomechanical effects of foot skeletal postures with and without the presence of a soft tissue pad in sauropodomorphs. We find that none of the models can maintain bone stresses that fall within optimal bone safety factors in the absence of a soft tissue pad. Our findings suggest that a soft tissue pad in sauropods would have reduced bone stresses by combining the mechanical advantages of a functionally plantigrade foot with the plesiomorphic skeletally digitigrade saurischian condition. The acquisition of a developed soft tissue pad by the Late Triassic–Early Jurassic may represent one of the key adaptations for the evolution of gigantism that has become emblematic of these dinosaurs.

Published

2022

21. A functional analysis of Carabelli trait in Australian aboriginal dentition

Author

Luca Fiorenza, Sarah Fung, Jinyoung Lee, John A. Kaidonis, Robin Yong, Varsha Pilbrow, Sarbin Ranjitkar, and Olga Panagiotopoulou

Subjects

Adult, Male, 0106 biological sciences, Molar, Native Hawaiian or Other Pacific Islander, Adolescent, Wear pattern, Biology, 010603 evolutionary biology, 01 natural sciences, Anthropology, Physical, stomatognathic system, Occlusal plane, Humans, 0601 history and archaeology, Child, Mastication, 2. Zero hunger, Orthodontics, 060101 anthropology, Dentition, Australia, 06 humanities and the arts, 15. Life on land, Adaptation, Physiological, Anthropology, Trait, Cusp (anatomy), Female, Tooth Wear, Anatomy, Adaptation

Abstract

Objectives Carabelli is a nonmetric dental trait variably expressed as a small pit to a prominent cusp in the maxillary molars of modern humans. Investigations on the occurrence and expression rates of this trait have been conducted extensively, tracing its origin to genetic sources. However, there remains a lack of understanding about its potential role in chewing. In this study, we examine molar macrowear with the aim of reconstructing Carabelli trait occlusal dynamics occurring during chewing. Methods We have examined 96 deciduous and permanent maxillary molars of children and young adults from Yuendumu, an Australian Aboriginal population that was at an early stage of transition from a nomadic and hunter-gatherer way of life to a more settled existence. We apply a well-established method, called Occlusal Fingerprint Analysis, which is a digital approach for analyzing dental macrowear allowing the reconstruction of jaw movements required to produce wear pattern specific to each tooth. Results Carabelli trait slightly enlarges the surface functional area, especially in those molars where this feature is expressed in its cuspal form and it is closer to the occlusal plane. Moreover, the highly steep contact planes would also indicate that Carabelli wear areas contribute to increasing the shearing abilities of the occluded teeth, which are particularly important when processing fibrous and tough foods. Conclusions The macrowear analysis suggests that Carabelli trait in the Aboriginal people from Yuendumu slightly enhanced occlusion and probably played some functional role during mastication. Future biomechanical and microwear analyses could provide additional information on the mechanical adaptation of Carabelli trait in modern human dentition.

Published

2020

22. Dyslipidaemias and Cardiovascular Disease: Focus on the Role of PCSK9 Inhibitors

Author

Scott T Chiesa, Dimitrios Tousoulis, Marietta Charakida, and Olga Panagiotopoulou

Subjects

Oncology, medicine.medical_specialty, medicine.drug_class, Phases of clinical research, Disease, 030204 cardiovascular system & hematology, Antibodies, Monoclonal, Humanized, Monoclonal antibody, Biochemistry, 03 medical and health sciences, 0302 clinical medicine, Internal medicine, Drug Discovery, medicine, Humans, 030212 general & internal medicine, Dyslipidemias, Alirocumab, Pharmacology, business.industry, PCSK9, Organic Chemistry, Cholesterol, LDL, Proprotein convertase, Evolocumab, Cardiovascular Diseases, Molecular Medicine, Kexin, Hydroxymethylglutaryl-CoA Reductase Inhibitors, Proprotein Convertase 9, business

Abstract

Genetic, experimental and clinical studies have consistently confirmed that inhibition of Proprotein Convertase Subtilisin/Kexin type 9 (PCSK9) can result in significant lowering of LDL-C and two fully human PCSK9 monoclonal antibodies have received regulatory approval for use in highrisk patients. Co-administration of PCSK9 with statins has resulted in extremely low LDL-C levels with excellent short-term safety profiles. While results from Phase III clinical trials provided significant evidence about the role of PCSK9 inhibitors in reducing cardiovascular event rates, their impact on mortality remains less clear. PCSK9 inhibitor therapy can be considered for high-risk patients who are likely to experience significant cardiovascular risk reduction.

Published

2020

23. Fracture Fixation Technique and Chewing Side Impact Jaw Mechanics in Mandible Fracture Repair

Author

Hyab Mehari Abraha, Callum F. Ross, Olga Panagiotopoulou, Russell R. Reid, and Jose Iriarte-Diaz

Subjects

Orthodontics, Orthopedic surgery, Side impact, business.industry, Mandible Fracture, Endocrinology, Diabetes and Metabolism, Mandible, Diseases of the musculoskeletal system, Original Articles, IMPLANTS, RHESUS MONKEY, MAXILLOFACIAL SURGERY, MASTICATION, RC925-935, Fracture fixation, FINITE ELEMENT ANALYSIS, Medicine, Orthopedics and Sports Medicine, Original Article, business, Mastication, RD701-811, MANDIBLE, TRAUMA

Abstract

Lower jaw (mandible) fractures significantly impact patient health and well‐being due to pain and difficulty eating, but the best technique for repairing the most common subtype—angle fractures—and rehabilitating mastication is unknown. Our study is the first to use realistic in silico simulation of chewing to quantify the effects of Champy and biplanar techniques of angle fracture fixation. We show that more rigid, biplanar fixation results in lower strain magnitudes in the miniplates, the bone around the screws, and in the fracture zone, and that the mandibular strain regime approximates the unfractured condition. Importantly, the strain regime in the fracture zone is affected by chewing laterality, suggesting that both fixation type and the patient's post‐fixation masticatory pattern—ipsi‐ or contralateral to the fracture— impact the bone healing environment. Our study calls for further investigation of the impact of fixation technique on chewing behavior. Research that combines in vivo and in silico approaches can link jaw mechanics to bone healing and yield more definitive recommendations for fixation, hardware, and postoperative rehabilitation to improve outcomes. © 2021 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research.

Published

2021

24. 'Keep your feet on the ground': Simulated range of motion and hind foot posture of the Middle Jurassic sauropodRhoetosaurus browneiand its implications for sauropod biology

Author

Anthony Romilio, Steven W. Salisbury, Andréas Jannel, Jay P. Nair, and Olga Panagiotopoulou

Subjects

0106 biological sciences, 0301 basic medicine, Plantigrade, Posture, Plantar surface, 010603 evolutionary biology, 01 natural sciences, Dinosaurs, 03 medical and health sciences, Rhoetosaurus, Animals, Range of Motion, Articular, Phylogeny, Osteology, biology, Foot, Fossils, Biomechanics, Digitigrade, Anatomy, biology.organism_classification, Biological Evolution, Hindlimb, body regions, 030104 developmental biology, Animal Science and Zoology, Range of motion, Interphalangeal Joint, human activities, Locomotion, Developmental Biology

Abstract

The biomechanics of the sauropod dinosaur pes is poorly understood, particularly among the earliest members of the group. To date, reasonably complete and articulated pedes in Early Middle Jurassic sauropods are rare, limited to a handful of taxa. Of these, Rhoetosaurus brownei, from eastern Australia, is currently the only one from the Gondwanan Middle Jurassic that preserves an articulated pes. Using Rhoetosaurus brownei as a case exemplar, we assessed its paleobiomechanical capabilities and pedal posture. Physical and virtual manipulations of the pedal elements were undertaken to evaluate the range of motion between the pedal joints, under both bone-to-bone and cartilaginous scenarios. Using the results as constraints, virtual reconstructions of all possible pedal postures were generated. We show that Rhoetosaurus brownei was capable of significant digital mobility at the osteological metatarsophalangeal and distal interphalangeal joints. We assume these movements would have been restricted by soft tissue in life but that their presence would have helped in the support of the animal. Further insights based on anatomy and theoretical mechanical constraints restricted the skeletal postures to a range encompassing digitigrade to subunguligrade stances. The approach was extended to additional sauropodomorph pedes, and some validation was provided via the bone data of an African elephant pes. Based on the resulting pedal configurations, the in-life plantar surface of the sauropod pes is inferred to extend caudally from the digits, with a soft tissue pad supporting the elevated metatarsus. The plantar pad is inferred to play a role in the reduction of biomechanical stresses, and to aid in support and locomotion. A pedal pad may have been a key biomechanical innovation in early sauropods, ultimately resulting in a functionally plantigrade pes, which may have arisen during the Early to Middle Jurassic. Further mechanical studies are ultimately required to permit validation of this long-standing hypothesis.

Published

2019

25. Author response for 'Fracture fixation technique and chewing side impact jaw mechanics in mandible fracture repair'

Author

Olga Panagiotopoulou, Jose Iriarte-Diaz, Hyab Mehari Abraha, Russell R. Reid, and Callum F. Ross

Subjects

Orthodontics, Side impact, business.industry, Mandible Fracture, Fracture fixation, Medicine, business

Published

2021

26. A New Pipeline to Automatically Segment and Semi-Automatically Measure Bone Length on 3D Models Obtained by Computed Tomography

Author

Xinli Qu, Alberto Roselló-Díez, John Tan Nguyen, Michael Doube, Chee Ho H’ng, Olga Panagiotopoulou, Santiago Beltran Diaz, Michael John de Veer, Rosello-Diez, Alberto [0000-0002-5550-9846], and Apollo - University of Cambridge Repository

Subjects

Computer science, QH301-705.5, Pipeline (computing), 3d model, Computed tomography, bone growth and development, Measure (mathematics), micro-CT (computed tomography), Cell and Developmental Biology, Length measurement, MIMICS, Methods, medicine, Biology (General), Measure (data warehouse), medicine.diagnostic_test, business.industry, Pattern recognition, Histology, Cell Biology, skeletal phenotype analysis, Thresholding, Bone length, Pipeline transport, BoneJ, limb evolution, Artificial intelligence, business, Ex vivo, Developmental Biology

Abstract

The characterization of developmental phenotypes often relies on the accurate linear measurement of structures that are small and require laborious preparation. This is tedious and prone to errors, especially when repeated for the multiple replicates that are required for statistical analysis, or when multiple distinct structures have to be analysed. To address this issue, we have developed a pipeline for characterization of long-bone length and inter-vertebral distance using X-ray microtomography (XMT) scans. The pipeline involves semi-automated algorithms for automatic thresholding and fast interactive isolation and 3D-model generation of the main limb bones, using either the open-source ImageJ plugin BoneJ or the commercial Mimics Innovation Suite package. The tests showed the appropriate combination of scanning conditions and analysis parameters yields fast and comparable length results, highly correlated with the measurements obtained via ex vivo skeletal preparations. Moreover, since XMT is not destructive, the samples can be used afterwards for histology or other applications. Our new pipelines will help developmental biologists and evolutionary researchers to achieve fast, reproducible and non-destructive length measurement of bone samples from multiple animal species.Summary statementBeltran Diaz et al. present a semi-automated pipeline for fast and versatile characterization of bone length from micro-CT images of mouse developmental samples.

Published

2021

27. Comparative biomechanics of the

Author

Amanda L, Smith, Chris, Robinson, Andrea B, Taylor, Olga, Panagiotopoulou, Julian, Davis, Carol V, Ward, William H, Kimbel, Zeresenay, Alemseged, and Callum F, Ross

Subjects

Articles

Abstract

The mechanical behaviour of the mandibles of Pan and Macaca during mastication was compared using finite element modelling. Muscle forces were calculated using species-specific measures of physiological cross-sectional area and scaled using electromyographic estimates of muscle recruitment in Macaca. Loading regimes were compared using moments acting on the mandible and strain regimes were qualitatively compared using maps of principal, shear and axial strains. The enlarged and more vertically oriented temporalis and superficial masseter muscles of Pan result in larger sagittal and transverse bending moments on both working and balancing sides, and larger anteroposterior twisting moments on the working side. The mandible of Pan experiences higher principal strain magnitudes in the ramus and mandibular prominence, higher transverse shear strains in the top of the symphyseal region and working-side corpus, and a predominance of sagittal bending-related strains in the balancing-side mandible. This study lays the foundation for a broader comparative study of Hominidae mandibular mechanics in extant and fossil hominids using finite element modelling. Pan's larger and more vertical masseter and temporalis may make it a more suitable model for hominid mandibular biomechanics than Macaca.

Published

2021

28. In vivo bone strain and finite element modeling of a rhesus macaque mandible during mastication

Author

Sharifah F. Aljunid, Olga Panagiotopoulou, Andrea B. Taylor, Paul C. Dechow, Jose Iriarte-Diaz, Simon Wilshin, Hyab Mehari Abraha, and Callum F. Ross

Subjects

0301 basic medicine, Accuracy and precision, Strain (injury), Mandible, Biology, Models, Biological, Article, Bone and Bones, 03 medical and health sciences, stomatognathic system, medicine, Animals, Electromyography, Isotropy, Biomechanics, Anatomy, medicine.disease, Macaca mulatta, Finite element method, Biomechanical Phenomena, Temporomandibular joint, 030104 developmental biology, medicine.anatomical_structure, Mastication, Female, Animal Science and Zoology, Material properties, Biomedical engineering

Abstract

Finite element analysis (FEA) is a commonly used tool in musculoskeletal biomechanics and vertebrate paleontology. The accuracy and precision of finite element models (FEMs) are reliant on accurate data on bone geometry, muscle forces, boundary conditions and tissue material properties. Simplified modeling assumptions, due to lack of in vivo experimental data on material properties and muscle activation patterns, may introduce analytical errors in analyses where quantitative accuracy is critical for obtaining rigorous results. A subject-specific FEM of a rhesus macaque mandible was constructed, loaded and validated using in vivo data from the same animal. In developing the model, we assessed the impact on model behavior of variation in (i) material properties of the mandibular trabecular bone tissue and teeth; (ii) constraints at the temporomandibular joint and bite point; and (iii) the timing of the muscle activity used to estimate the external forces acting on the model. The best match between the FEA simulation and the in vivo experimental data resulted from modeling the trabecular tissue with an isotropic and homogeneous Young’s modulus and Poisson’s value of 10 GPa and 0.3, respectively; constraining translations along X,Y, Z axes in the chewing (left) side temporomandibular joint, the premolars and the m1; constraining the balancing (right) side temporomandibular joint in the anterior-posterior and superior-inferior axes, and using the muscle force estimated at time of maximum strain magnitude in the lower lateral gauge. The relative strain magnitudes in this model were similar to those recorded in vivo for all strain locations. More detailed analyses of mandibular strain patterns during the power stroke at different times in the chewing cycle are needed.

Published

2017

29. Biomechanical implications of cortical elastic properties of the macaque mandible

Author

Olga Panagiotopoulou, Poorva Gharpure, and Paul C. Dechow

Subjects

0301 basic medicine, Bone density, Mandible, Macaque, 03 medical and health sciences, biology.animal, Cortical Bone, medicine, Animals, 0601 history and archaeology, Elastic modulus, 060101 anthropology, biology, business.industry, Ultrasound, Stiffness, 06 humanities and the arts, Anatomy, biology.organism_classification, Biomechanical Phenomena, Rhesus macaque, 030104 developmental biology, medicine.anatomical_structure, Macaca, Female, Animal Science and Zoology, Cortical bone, medicine.symptom, business

Abstract

Knowledge of the variation in the elastic properties of mandibular cortical bone is essential for modeling bone function. Our aim was to characterize the elastic properties of rhesus macaque mandibular cortical bone and compare these to the elastic properties from mandibles of dentate humans and baboons. Thirty cylindrical samples were harvested from each of six adult female rhesus monkey mandibles. Assuming orthotropy, axes of maximum stiffness in the plane of the cortical plate were derived from ultrasound velocity measurements. Further velocity measurements with longitudinal and transverse ultrasonic transducers along with measurements of bone density were used to compute three-dimensional cortical elastic properties using equations based on Hooke's law. Results showed regional variations in the elastic properties of macaque mandibular cortical bone that have both similarities and differences with that of humans and baboons. So far, the biological and structural basis of these differences is poorly understood.

Published

2017

30. Individual variation of the masticatory system dominates 3D skull shape in the herbivory-adapted marsupial wombats

Author

Claire E. Terhune, Olga Panagiotopoulou, S.N. Collins, Alana C. Sharp, Vera Weisbecker, Hyab Mehari Abraha, Thomas Guillerme, Emma Sherratt, Cruise Speck, and Steve Johnston

Subjects

0301 basic medicine, 0106 biological sciences, Mandible, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, lcsh:Zoology, medicine, Marsupial, lcsh:QL1-991, Mastication, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Geometric morphometrics, 0303 health sciences, Crania, biology, Research, biology.organism_classification, Masticatory force, Altricial, Skull, Constraint, 030104 developmental biology, medicine.anatomical_structure, Evolutionary biology, Animal Science and Zoology, Cranium, Allometry, Shape analysis (digital geometry)

Abstract

BackgroundWithin-species skull shape variation of marsupial mammals is widely considered low and strongly size-dependent (allometric), possibly due to developmental constraints arising from the altricial birth of marsupials. However, species whose skulls are impacted by strong muscular stresses – particularly those produced through mastication of tough food items – may not display such intrinsic patterns very clearly because of the known plastic response of bone to muscle activity of the individual. In such cases, allometry may not dominate within-species shape variation, even if it is a driver of evolutionary shape divergence; ordination of shape in a geometric morphometric context through principal component analysis (PCA) should reveal main variation in areas under masticatory stress (incisor region/zygomatic arches/mandibular ramus); but this main variation should emerge from high individual variability and thus have low eigenvalues.ResultsWe assessed the evidence for high individual variation through 3D geometric morphometric shape analysis of crania and mandibles of three species of grazing-specialized wombats, whose diet of tough grasses puts considerable strain on their masticatory system. As expected, we found little allometry and low Principal Component 1 (PC1) eigenvalues within crania and mandibles of all three species. Also as expected, the main variation was in the muzzle, zygomatic arches, and masticatory muscle attachments of the mandibular ramus. We then implemented a new test to ask if the landmark variation reflected on PC1 was reflected in individuals with opposite PC1 scores and with opposite shapes in Procrustes space. This showed that correspondence between individual and ordinated shape variation was limited, indicating high levels of individual variability in the masticatory apparatus.DiscussionOur results are inconsistent with hypotheses that skull shape variation within marsupial species reflects a constraint pattern. Rather, they support suggestions that individual plasticity can be an important determinant of within-species shape variation in marsupials (and possibly other mammals) with high masticatory stresses, making it difficult to understand the degree to which intrinsic constraints act on shape variation at the within-species level. We conclude that studies that link micro- and macroevolutionary patterns of shape variation might benefit from a focus on species with low-impact mastication, such as carnivorous or frugivorous species.

Published

2019

31. Metformin use in obese mothers is associated with improved cardiovascular profile in the offspring

Author

Kypros H. Nicolaides, John M. Simpson, Argyro Syngelaki, Olga Panagiotopoulou, Marietta Charakida, Georgios Georgiopoulos, Ranjit Akolekar, and Hassan Shehata

Subjects

Adult, Leptin, Male, medicine.medical_specialty, Offspring, Hemodynamics, Blood Pressure, Pulse Wave Analysis, Obesity, Maternal, 03 medical and health sciences, 0302 clinical medicine, Insulin resistance, Vascular Stiffness, Pregnancy, medicine, Humans, Hypoglycemic Agents, Arterial Pressure, 030212 general & internal medicine, Adverse effect, Triglycerides, 030219 obstetrics & reproductive medicine, Obstetrics, business.industry, Cholesterol, HDL, Obstetrics and Gynecology, Cholesterol, LDL, medicine.disease, Obesity, Metformin, Cholesterol, Echocardiography, Child, Preschool, Prenatal Exposure Delayed Effects, Arterial stiffness, Body Composition, Female, Adiponectin, business, medicine.drug, Follow-Up Studies

Abstract

Maternal obesity increases the risk for pregnancy complications and adverse neonatal outcome and has been associated with long-lasting adverse effects in the offspring, including increased body fat mass, insulin resistance, and increased risk for premature cardiovascular disease. Lifestyle interventions in pregnancy have produced no or modest effects in the reduction of adverse pregnancy outcomes in obese mothers. The Metformin in Obese Pregnant Women trial was associated with reduced adverse pregnancy outcomes and had no effect on birthweight. However, the long-term implications of metformin on the health of offspring remain unknown.The purpose of this study was to assess whether prenatal exposure to metformin can improve the cardiovascular profile and body composition in the offspring of obese mothers.In 151 children from the Metformin in Obese Pregnant Women trial, body composition, peripheral blood pressure, and arterial pulse wave velocity were measured. Central hemodynamics (central blood pressure and augmentation index) were estimated with the use of an oscillometric device. Left ventricular cardiac function and structure were assessed by echocardiography.Children were 3.9±1.0 years old, and 77 of them had been exposed to metformin prenatally. There was no significant difference in peripheral blood pressure, arterial stiffness, and body composition apart from gluteal and tricep circumferences, which were lower in the metformin group (P.05). The metformin group, compared with the placebo group, had lower central hemodynamics (mean adjusted decrease, -0.707 mm Hg for aortic systolic blood pressure, -1.65 mm Hg for aortic pulse pressure, and -2.68% for augmentation index; P.05 for all) and lower left ventricular diastolic function (adjusted difference in left atrial area, -0.525 cmChildren of obese mothers who were exposed prenatally to metformin, compared with those who were exposed to placebo, had lower central hemodynamic and cardiac diastolic indices. These results suggest that the administration of metformin in obese pregnant women potentially may have a beneficial cardiovascular effect for their offspring.

Published

2019

32. The Mechanical Effect of the Periodontal Ligament on Bone Strain Regimes in a Validated Finite Element Model of a Macaque Mandible

Author

Jose Iriarte-Diaz, Callum F. Ross, Hyab Mehari Abraha, Olga Panagiotopoulou, and Andrea B. Taylor

Subjects

0301 basic medicine, Materials science, Histology, lcsh:Biotechnology, mastication, Biomedical Engineering, Modulus, rhesus monkey, Strain (injury), Bioengineering, 02 engineering and technology, finite element analysis, biomechanics, 03 medical and health sciences, stomatognathic system, sensitivity analysis, lcsh:TP248.13-248.65, medicine, Periodontal fiber, Original Research, Biomechanics, Mandible, Bioengineering and Biotechnology, 021001 nanoscience & nanotechnology, medicine.disease, Finite element method, Masticatory force, 030104 developmental biology, in vivo validation, Deformation (engineering), 0210 nano-technology, Biomedical engineering, Biotechnology

Abstract

The primary anatomical function of the periodontal ligament (PDL) is to attach teeth to their sockets. However, theoretical and constitutive mechanical models have proposed that during mastication the PDL redistributes local occlusal loads and reduces the jaw’s resistance to torsional deformations. These hypotheses imply that accurately modelling the PDL’s material properties and geometry in finite element analysis (FEA) is a prerequisite to obtaining precise strain and deformation data. Yet, many finite element studies of the human and non-human primate masticatory apparatus exclude the PDL or model it with simplicity, in part due to limitations in µCT/CT scan resolution and material property assignment. Previous studies testing the sensitivity of finite element models (FEMs) to the PDL have yielded contradictory results, however a major limitation of these studies is that FEMs were not validated against in vivo bone strain data. Hence, this study uses a validated and subject specific FEM to assess the effect of the PDL on strain and deformation regimes in the lower jaw of a rhesus macaque (Macaca mulatta) during simulated unilateral post-canine chewing. Our findings demonstrate that the presence of the PDL does influence local and global surface strain magnitudes (principal and shear) in the jaw. However, the PDL’s effect is limited (diff. ~200-300µe) in areas away from the alveoli. Our results also show that varying the PDL’s Young’s Modulus within the range of published values (0.07-1750 MPa) has very little effect on global surface strains. These findings suggest that the mechanical importance of the PDL in FE models of the mandible during chewing is dependent on the scope of the hypotheses being tested. If researchers are comparing strain gradients across species/taxa, the PDL may be excluded with minimal effect on results, but, if researchers are concerned with absolute strain values, sensitivity analysis is required.

Published

2019

33. Biomechanical insights into the role of foot pads during locomotion in camelid species

Author

Olga Panagiotopoulou, Christopher L. Glen, Taylor J. M. Dick, and Christofer J. Clemente

Subjects

0106 biological sciences, 0301 basic medicine, endocrine system, Camelus, Zoology, lcsh:Medicine, Walking, Biology, 010603 evolutionary biology, 01 natural sciences, Fat pad, Article, 03 medical and health sciences, Animal physiology, Pressure, Animals, Humans, Biomechanics, lcsh:Science, Multidisciplinary, Foot, Vertical ground reaction force, lcsh:R, biology.organism_classification, 030104 developmental biology, lcsh:Q, Camelids, New World, Foot (unit), Camelid

Abstract

From the camel’s toes to the horse’s hooves, the diversity in foot morphology among mammals is striking. One distinguishing feature is the presence of fat pads, which may play a role in reducing foot pressures, or may be related to habitat specialization. The camelid family provides a useful paradigm to explore this as within this phylogenetically constrained group we see prominent (camels) and greatly reduced (alpacas) fat pads. We found similar scaling of vertical ground reaction force with body mass, but camels had larger foot contact areas, which increased with velocity, unlike alpacas, meaning camels had relatively lower foot pressures. Further, variation between specific regions under the foot was greater in alpacas than camels. Together, these results provide strong evidence for the role of fat pads in reducing relative peak locomotor foot pressures, suggesting that the fat pad role in habitat specialization remains difficult to disentangle.

Published

2019

34. Comparative biomechanics of the Pan and Macaca mandibles during mastication: finite element modelling of loading, deformation and strain regimes

Author

Zeresenay Alemseged, William H. Kimbel, Carol V. Ward, Chris Robinson, Julian L. Davis, Olga Panagiotopoulou, Andrea B. Taylor, Amanda L. Smith, and Callum F. Ross

Subjects

Materials science, Biomedical Engineering, Biophysics, Biomechanics, Bioengineering, Strain (injury), Deformation (meteorology), medicine.disease, Biochemistry, Finite element method, Biomaterials, stomatognathic system, medicine, Composite material, Mastication, Biotechnology

Abstract

The mechanical behaviour of the mandibles of Pan and Macaca during mastication was compared using finite element modelling. Muscle forces were calculated using species-specific measures of physiological cross-sectional area and scaled using electromyographic estimates of muscle recruitment in Macaca . Loading regimes were compared using moments acting on the mandible and strain regimes were qualitatively compared using maps of principal, shear and axial strains. The enlarged and more vertically oriented temporalis and superficial masseter muscles of Pan result in larger sagittal and transverse bending moments on both working and balancing sides, and larger anteroposterior twisting moments on the working side. The mandible of Pan experiences higher principal strain magnitudes in the ramus and mandibular prominence, higher transverse shear strains in the top of the symphyseal region and working-side corpus, and a predominance of sagittal bending-related strains in the balancing-side mandible. This study lays the foundation for a broader comparative study of Hominidae mandibular mechanics in extant and fossil hominids using finite element modelling. Pan 's larger and more vertical masseter and temporalis may make it a more suitable model for hominid mandibular biomechanics than Macaca .

Published

2021

35. Congenital heart disease in twins: The contribution of type of conception and chorionicity

Author

Xenophon Sinopidis, Olga Panagiotopoulou, Sotirios Fouzas, Ageliki A. Karatza, Stefanos Mantagos, and Gabriel Dimitriou

Subjects

Adult, Heart Defects, Congenital, Male, medicine.medical_specialty, Reproductive Techniques, Assisted, Heart disease, Offspring, medicine.medical_treatment, 030204 cardiovascular system & hematology, 03 medical and health sciences, 0302 clinical medicine, Pregnancy, Diseases in Twins, Twins, Dizygotic, medicine, Humans, 030219 obstetrics & reproductive medicine, Assisted reproductive technology, In vitro fertilisation, Obstetrics, business.industry, Incidence (epidemiology), Pregnancy Outcome, medicine.disease, Cohort, Pregnancy, Twin, Gestation, Female, Monochorionic twins, Cardiology and Cardiovascular Medicine, business, Maternal Age

Abstract

Increased incidence of congenital heart disease (CHD) has been reported in the offspring of monochorionic twin gestations. Assisted reproductive technology (ART), which is related to increased rates of twinning, has also been associated with higher risk of birth defects. We studied the incidence of CHD in a cohort of twins to clarify the contribution of type of conception and chorionicity.Data concerning 874 live-born twins of which at least one was admitted in our Neonatal Unit during 1995-2012 were analysed. Forty-five % (N=197) of the gestations resulted from ART (in vitro fertilisation or intracytoplasmic sperm insertion).In the ART group 32/389 (8.2%) had CHD compared to 21/485 (4.3%) infants conceived naturally (OR 1.90, 95%CI 1.08-3.34, p=0.024). Spontaneous-conception gestations had higher incidence of monochorionic placentation (47/245 versus 4/197, p0.001), and included younger mothers (29.1±5.2 versus 33.9±5.5years, p0.001) who had higher parity (median 2 [range 1-7] versus 1 Pinborg (2005), Blondel and Kaminski (2002), Knopman et al. (2014), Kyvik and Derom (2006) ; p0.001). Multivariable logistic regression analysis showed that ART (OR 2.60, 95% CI 1.24-5.45) and monochorionicity (OR 3.49, 95% CI 1.57-7.77) were significant determinants of CHD, independently of maternal age, parity, and the gender of the offspring.We confirmed that monochorionic twins have increased risk of CHD and we documented a higher incidence of CHD in ART twins independently of chorionicity. We suggest improvement of echocardiographic skills of health care professionals involved in prenatal screening and foetal cardiology referral of ART dichorionic twins with suspicious findings at screening, in addition to all monochorionic gestations.

Published

2016

36. Expression of Listeria monocytogenes key virulence genes during growth in liquid medium, on rocket and melon at 4, 10 and 30 °C

Author

Christina Molfeta, Eleftherios H. Drosinos, Agni Hadjilouka, Olga Panagiotopoulou, Spiros Paramithiotis, and Marios Mataragas

Subjects

0301 basic medicine, Virulence Factors, Melon, 030106 microbiology, Virulence, Biology, medicine.disease_cause, Microbiology, 03 medical and health sciences, Bacterial Proteins, Listeria monocytogenes, Gene expression, medicine, Gene, Incubation, Inoculation, Temperature, RNA, Gene Expression Regulation, Bacterial, Culture Media, Cucurbitaceae, Barbarea, Fruit, Food Science

Abstract

The aim of the present study was to assess the expression of key virulence genes, during growth of a Listeria monocytogenes isolate in liquid medium, on melon and rocket at different temperatures and time. For that purpose, BHI broth, rocket and melon were inoculated at 7.0-7.5 log CFU mL(-1) or g(-1)and stored at 4, 10 and 30 °C. Sampling took place upon inoculation and after 0.5, 6 and 24 h of incubation. The RNA was stabilized and the expression of hly, plcA, plcB, sigB, inlA, inlB, inlC, inlJ, lmo2672 and lmo2470 was assessed by RT-qPCR. The results obtained were summarized into two observations; the first one referring to the interactive effect of incubation temperature and type of substrate and the second one to the effect of time on gene expression. Regarding the latter, nearly all genes were regulated upon inoculation and exhibited differential expression in the subsequent sampling times indicating the existence of additional regulatory mechanisms yet to be explored.

Published

2016

37. Biomechanics of the mandible of Macaca mulatta during the power stroke of mastication: Loading, deformation, and strain regimes and the impact of food type

Author

Callum F. Ross, Hyab Mehari Abraha, Paul C. Dechow, Simon Wilshin, Olga Panagiotopoulou, Jose Iriarte-Diaz, and Andrea B. Taylor

Subjects

010506 paleontology, Dried fruit, Shear force, Mandible, 01 natural sciences, Article, medicine, Shear stress, Animals, 0601 history and archaeology, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Orthodontics, 060101 anthropology, 06 humanities and the arts, Macaca mulatta, Sagittal plane, Biomechanical Phenomena, Diet, Transverse plane, medicine.anatomical_structure, Anthropology, Bending moment, Mastication, Stress, Mechanical, Deformation (engineering), Geology

Abstract

Mandible morphology has yet to yield definitive information on primate diet, probably because of poor understanding of mandibular loading and strain regimes, and overreliance on simple beam models of mandibular mechanics. We used a finite element model of a macaque mandible to test hypotheses about mandibular loading and strain regimes and relate variation in muscle activity during chewing on different foods to variation in strain regimes. The balancing-side corpus is loaded primarily by sagittal shear forces and sagittal bending moments. On the working side, sagittal bending moments, anteroposterior twisting moments, and lateral transverse bending moments all reach similar maxima below the bite point; sagittal shear is the dominant loading regime behind the bite point; and the corpus is twisted such that the mandibular base is inverted. In the symphyseal region, the predominant loading regimes are lateral transverse bending and negative twisting about a mediolateral axis. Compared with grape and dried fruit chewing, nut chewing is associated with larger sagittal and transverse bending moments acting on balancing- and working-side mandibles, larger sagittal shear on the working side, and larger twisting moments about vertical and transverse axes in the symphyseal region. Nut chewing is also associated with higher minimum principal strain magnitudes in the balancing-side posterior ramus; higher sagittal shear strain magnitudes in the working-side buccal alveolar process and the balancing-side oblique line, recessus mandibulae, and endocondylar ridge; and higher transverse shear strains in the symphyseal region, the balancing-side medial prominence, and the balancing-side endocondylar ridge. The largest food-related differences in maximum principal and transverse shear strain magnitudes are in the transverse tori and in the balancing-side medial prominence, extramolar sulcus, oblique line, and endocondylar ridge. Food effects on the strain regime are most salient in areas not traditionally investigated, suggesting that studies seeking dietary effects on mandible morphology might be looking in the wrong places.

Published

2020

38. Cardiometabolic Follow Up of the Offspring From the Metformin in Obese Non-Diabetic Pregnant (MOP) Women Trial

Author

Argyro Syngelaki, George Georgiopoulos, Hassan Shehata, Marietta Charakida, Olga Panagiotopoulou, John M. Simpson, Ranjit Akolekar, and Kypros H. Nicolaides

Subjects

medicine.medical_specialty, Offspring, business.industry, Hemodynamics, medicine.disease, Placebo, Metformin, Blood pressure, Internal medicine, medicine, Cardiology, Arterial stiffness, Aortic Pulse Pressure, Isovolumic relaxation time, business, medicine.drug

Abstract

Background: Maternal obesity is associated with adverse cardiometabolic outcome in the offspring. We aimed to assess whether prenatal exposure to metformin can improve the cardiovascular profile and body composition in the offspring of obese mothers. Methods: In 151 children from the MOP trial we measured body composition, peripheral blood pressure and arterial pulse wave velocity. Central haemodynamics (central blood pressure and augmentation index) were estimated using the Vicorder device. Left ventricular cardiac function and structure were assessed by echocardiography. In 39 children from each group the metabolic profile was assessed. Findings: Children were 3.9±1.0 years of age and 77 were exposed to metformin prenatally. There was no significant difference in peripheral blood pressure, arterial stiffness and body composition apart from gluteal and tricep circumferences which were lower in the metformin group (p

Published

2019

39. Editorial: Determinants of mammalian feeding system design

Author

Jose Iriarte-Diaz and Olga Panagiotopoulou

Subjects

Mammals, Interdisciplinary Research, Systems design, Animals, Animal Science and Zoology, Computational biology, Biology, Animal Husbandry, Housing, Animal

Published

2017

40. Surgical anomalies in twins: The role of assisted reproductive technology and chorionicity: RE: 'Congenital malformations associated with assisted reproductive technology: A California statewide analysis' by Kelley-Quon LI et al. J Pediatr Surg 2013; 48; 1218-1224

Author

Sotirios, Fouzas, Olga, Panagiotopoulou, Xenophon, Sinopidis, Chrysanthi, Papadopoulou, Gabriel, Dimitriou, and Ageliki A, Karatza

Published

2017

41. Congenital Heart Disease in Asymptomatic Neonates with Extra-Cardiac Malformations and Genetic Disorders

Author

Gabriel Dimitriou, Ageliki A. Karatza, Despoina Gkentzi, and Olga Panagiotopoulou

Subjects

Chromosome Aberrations, Heart Defects, Congenital, Pediatrics, medicine.medical_specialty, Heart disease, Heart Murmurs, business.industry, Incidence (epidemiology), Incidence, lcsh:R, MEDLINE, Infant, Newborn, lcsh:Medicine, General Medicine, medicine.disease, Asymptomatic, Cardiac malformations, medicine, Humans, medicine.symptom, business, Letter to the Editor

Published

2019

42. Incidental Identification of Left Atrial Appendage Aneurysm in a Ten Month Old Infant

Author

Asimoula Maroutsou, Olga Panagiotopoulou, Nicoleta Oikonomou, Maria Kiaffas, and Ageliki A. Karatza

Subjects

Psychiatry and Mental health, medicine.medical_specialty, business.industry, Medicine, Identification (biology), Radiology, business, Left atrial appendage aneurysm

Published

2016

43. Statistical parametric mapping of the regional distribution and ontogenetic scaling of foot pressures during walking in Asian elephants (Elephas maximus)

Author

Zoe Hill, John R. Hutchinson, Todd C. Pataky, and Olga Panagiotopoulou

Subjects

Heel, Physiology, Elephants, Walking, Aquatic Science, medicine.disease_cause, Statistical parametric mapping, Weight-bearing, Weight-Bearing, Elephas, Osteoarthritis, Image Processing, Computer-Assisted, Pressure, medicine, Animals, Foot pressure, Molecular Biology, Scaling, Ecology, Evolution, Behavior and Systematics, Models, Statistical, biology, Foot, Viscosity, Body Weight, Reproducibility of Results, Anatomy, biology.organism_classification, Elasticity, Biomechanical Phenomena, body regions, medicine.anatomical_structure, Data Interpretation, Statistical, Insect Science, Animal Science and Zoology, Palmar surface, Software, Foot (unit), Geology

Abstract

SUMMARY Foot pressure distributions during locomotion have causal links with the anatomical and structural configurations of the foot tissues and the mechanics of locomotion. Elephant feet have five toes bound in a flexible pad of fibrous tissue (digital cushion). Does this specialized foot design control peak foot pressures in such giant animals? And how does body size, such as during ontogenetic growth, influence foot pressures? We addressed these questions by studying foot pressure distributions in elephant feet and their correlation with body mass and centre of pressure trajectories, using statistical parametric mapping (SPM), a neuro-imaging technology. Our results show a positive correlation between body mass and peak pressures, with the highest pressures dominated by the distal ends of the lateral toes (digits 3, 4 and 5). We also demonstrate that pressure reduction in the elephant digital cushion is a complex interaction of its viscoelastic tissue structure and its centre of pressure trajectories, because there is a tendency to avoid rear ‘heel’ contact as an elephant grows. Using SPM, we present a complete map of pressure distributions in elephant feet during ontogeny by performing statistical analysis at the pixel level across the entire plantar/palmar surface. We hope that our study will build confidence in the potential clinical and scaling applications of mammalian foot pressures, given our findings in support of a link between regional peak pressures and pathogenesis in elephant feet.

Published

2012

44. Surgical anomalies in twins: The role of assisted reproductive technology and chorionicity

Author

Ageliki A. Karatza, Olga Panagiotopoulou, Sotirios Fouzas, Xenophon Sinopidis, Gabriel Dimitriou, and Chrysanthi Papadopoulou

Subjects

Gynecology, medicine.medical_specialty, 030219 obstetrics & reproductive medicine, Assisted reproductive technology, business.industry, medicine.medical_treatment, Congenital malformations, General Medicine, 030204 cardiovascular system & hematology, 03 medical and health sciences, 0302 clinical medicine, Pediatrics, Perinatology and Child Health, Medicine, Surgery, business

Published

2017

45. Balancing the spatial demands of the developing dentition with the mechanical demands of the catarrhine mandibular symphysis

Author

Olga Panagiotopoulou and Samuel N. Cobb

Subjects

Histology, Mandibular symphysis, Dentition, Symphysis, Mandible, Biomechanics, Cell Biology, Anatomy, Biology, stomatognathic diseases, Transverse plane, medicine.anatomical_structure, Biting, stomatognathic system, Incisor, medicine, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Developmental Biology

Abstract

The superior transverse torus of the catarrhine mandible has been shown to effectively reduce bending at the symphysis during unilateral postcanine biting. While the adult superior transverse torus contains trabecular bone, the juvenile one is almost entirely filled by developing permanent incisors until their eruption. This study uses finite elements analysis (FEA) to investigate whether the presence of developing incisors in the juvenile symphysis increases strains on the superior transverse torus. Two FE models of a juvenile Macaca fascicularis mandible were created: one included all the developing teeth; the second was modified to remove the incisor tooth crypts by filling them with trabecular bone. The models were loaded identically to simulate static physiological unilateral biting on dp4 and strain magnitudes, patterns and distributions of the two FE models were compared. The FEA results show a notable increase in strain magnitudes by up to 40% when the developing incisors are present. The results indicate that, in order to maintain the same symphyseal strain magnitudes during chewing, the presence of the incisors in the symphysis necessitates a larger superior transverse torus in the juvenile than would be required if the superior transverse torus did not house the developing incisors. These results highlight the adaptational balance of the symphyseal morphology throughout ontogeny between biomechanics and the spatial demands of the developing dentition. Based on the findings we therefore propose that the spatial requirements of the developing incisors during ontogeny can act as a constraint on the functional adaptation and subsequent adult morphology observed in the catarrhine mandibular symphysis.

Published

2010

46. The mechanical function of the periodontal ligament in the macaque mandible: a validation and sensitivity study using finite element analysis

Author

Samuel N. Cobb, Olga Panagiotopoulou, and Kornelius Kupczik

Subjects

Histology, Materials science, Mandible, Modulus, Strain (injury), Cell Biology, Anatomy, medicine.disease, Finite element method, Viscoelasticity, stomatognathic system, medicine, Periodontal fiber, Material properties, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Dental alveolus, Developmental Biology, Biomedical engineering

Abstract

Whilst the periodontal ligament (PDL) acts as an attachment tissue between bone and tooth, hypotheses regarding the role of the PDL as a hydrodynamic damping mechanism during intraoral food processing have highlighted its potential importance in finite element (FE) analysis. Although experimental and constitutive models have correlated the mechanical function of the PDL tissue with its anisotropic, heterogeneous, viscoelastic and non-linear elastic nature, in many FE simulations the PDL is either present or absent, and when present is variably modelled. In addition, the small space the PDL occupies and the inability to visualize the PDL tissue using μCT scans poses issues during FE model construction and so protocols for the PDL thickness also vary. In this paper we initially test and validate the sensitivity of an FE model of a macaque mandible to variations in the Young's modulus and the thickness of the PDL tissue. We then tested the validity of the FE models by carrying out experimental strain measurements on the same mandible in the laboratory using laser speckle interferometry. These strain measurements matched the FE predictions very closely, providing confidence that material properties and PDL thickness were suitably defined. The FE strain results across the mandible are generally insensitive to the absence and variably modelled PDL tissue. Differences are only found in the alveolar region adjacent to the socket of the loaded tooth. The results indicate that the effect of the PDL on strain distribution and/or absorption is restricted locally to the alveolar bone surrounding the teeth and does not affect other regions of the mandible.

Published

2010

47. RETRACTED: Modelling subcortical bone in finite element analyses: A validation and sensitivity study in the macaque mandible

Author

Neil Curtis, Olga Panagiotopoulou, Samuel N. Cobb, and P. O’ Higgins

Subjects

Materials science, Finite Element Analysis, Biomedical Engineering, Biophysics, Modulus, Mandible, Bending, Models, Biological, Sensitivity and Specificity, Bite Force, Stress (mechanics), medicine, Animals, Computer Simulation, Orthopedics and Sports Medicine, Sensitivity (control systems), Image resolution, business.industry, Rehabilitation, Reproducibility of Results, Structural engineering, Finite element method, Macaca fascicularis, medicine.anatomical_structure, Female, Cortical bone, Stress, Mechanical, Material properties, business, Biomedical engineering

Abstract

Finite element analysis (FEA) is a fundamental method to study stresses and strains in complex structures, with the accuracy of an FEA being reliant on a number of variables, not least the precision and complexity of the model's geometry. Techniques such as computed tomography (CT) allow general geometries to be derived relatively quickly; however, constraints on CT image resolution mean defining subcortical geometries can be problematic. In relation to the overall mechanical response of a complex structure during FEA, the consequence of variable subcortical modelling is not known. Here we test this sensitivity with a series of FE models of a macaque mandible with different subcortical geometries and comparing the FEA strain magnitudes and orientations. The validity of the FE models was tested by carrying out experimental strain measurements on the same mandible. These strain measurements matched the FE predictions, providing confidence that material properties and model geometry were suitably defined. Results of this study show that cortical bone alone is not as effective in resisting bending as it is when coupled with subcortical bone, and as such subcortical geometries must be modelled during an FEA. This study demonstrates that the fine detail of the mandibular subcortical structure can be adequately modelled as a solid when assigned an appropriate Young's modulus value, in this case ranging from 1 to 2 GPa. This is an important and encouraging result for the creation of FE models of materials where CT image resolution or poor preservation prevent the accurate modelling of subcortical bone.

Published

2010

48. Abstracts of Papers

Author

John Long, Olga Panagiotopoulou, Jussi Eronen, Kai Puolamäki, John Whitlock, and Mikael Fortelius

Subjects

Orthodontics, Variation (linguistics), Mandibular morphology, Paleontology, Biology, Load resistance, Masticatory force

Published

2009

49. Finite element analysis (FEA): Applying an engineering method to functional morphology in anthropology and human biology

Author

Olga Panagiotopoulou

Subjects

Aging, Sequence, Physiology, Epidemiology, Method engineering, Finite Element Analysis, Public Health, Environmental and Occupational Health, Mechanical engineering, Function (mathematics), Models, Biological, Finite element method, Imaging, Three-Dimensional, Complex geometry, Simple (abstract algebra), Anthropology, Genetics, Animals, Dentition, Humans, Limit (mathematics), Biology, Finite set, Mathematics

Abstract

A fundamental research question for morphologists is how morphological variation in the skeleton relates to function. Traditional approaches have advanced our understanding of form-function relationships considerably but have limitations. Strain gauges can only record strains on a surface, and the geometry of the structure can limit where they can be bonded. Theoretical approaches, such as geometric abstractions, work well on problems with simple geometries and material properties but biological structures typically have neither of these. Finite element analysis (FEA) is a method that overcomes these problems by reducing a complex geometry into a finite number of elements with simple geometries. In addition, FEA allows strain to be modelled across the entire surface of the structure and throughout the internal structure. With advances in the processing power of computers, FEA has become more accessible and as such is becoming an increasingly popular tool to address questions about form-function relationships in development and evolution, as well as human biology generally. This paper provides an introduction to FEA including a review of the sequence of steps needed for the generation of biologically accurate finite element models that can be used for the testing of biological and functional morphology hypotheses.

Published

2009

50. Architecture of the sperm whale forehead facilitates ramming combat

Author

Olga Panagiotopoulou, Panagiotis Spyridis, David R. Carrier, Hyab Mehari Abraha, and Todd C. Pataky

Subjects

0106 biological sciences, 0301 basic medicine, Sperm whale, lcsh:Medicine, Human echolocation, Marine Biology, Connective tissue partitions, 010603 evolutionary biology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, biology.animal, Spermaceti junk, medicine, Whaling, Probabilistic simulation, Ramming, biology, Animal Behavior, Whale, General Neuroscience, lcsh:R, Spermaceti organ, Finite element analysis, General Medicine, Anatomy, biology.organism_classification, Evolutionary Studies, Skull, 030104 developmental biology, medicine.anatomical_structure, Ramming impact, Sexual selection, General Agricultural and Biological Sciences, Zoology

Abstract

Herman Melville’s novelMoby Dickwas inspired by historical instances in which large sperm whales (Physeter macrocephalus L.) sank 19th century whaling ships by ramming them with their foreheads. The immense forehead of sperm whales is possibly the largest, and one of the strangest, anatomical structures in the animal kingdom. It contains two large oil-filled compartments, known as the “spermaceti organ” and “junk,” that constitute up to one-quarter of body mass and extend one-third of the total length of the whale. Recognized as playing an important role in echolocation, previous studies have also attributed the complex structural configuration of the spermaceti organ and junk to acoustic sexual selection, acoustic prey debilitation, buoyancy control, and aggressive ramming. Of these additional suggested functions, ramming remains the most controversial, and the potential mechanical roles of the structural components of the spermaceti organ and junk in ramming remain untested. Here we explore the aggressive ramming hypothesis using a novel combination of structural engineering principles and probabilistic simulation to determine if the unique structure of the junk significantly reduces stress in the skull during quasi-static impact. Our analyses indicate that the connective tissue partitions in the junk reduce von Mises stresses across the skull and that the load-redistribution functionality of the former is insensitive to moderate variation in tissue material parameters, the thickness of the partitions, and variations in the location and angle of the applied load. Absence of the connective tissue partitions increases skull stresses, particularly in the rostral aspect of the upper jaw, further hinting of the important role the architecture of the junk may play in ramming events. Our study also found that impact loads on the spermaceti organ generate lower skull stresses than an impact on the junk. Nevertheless, whilst an impact on the spermaceti organ would reduce skull stresses, it would also cause high compressive stresses on the anterior aspect of the organ and the connective tissue case, possibly making these structures more prone to failure. This outcome, coupled with the facts that the spermaceti organ houses sensitive and essential sonar producing structures and the rostral portion of junk, rather than the spermaceti organ, is frequently a site of significant scarring in mature males suggest that whales avoid impact with the spermaceti organ. Although the unique structure of the junk certainly serves multiple functions, our results are consistent with the hypothesis that the structure also evolved to function as a massive battering ram during male-male competition.

Published

2015