Your search keyword '"Fiber architecture"' showing total 324 results

1. Muscle fiber strain rates in the lower leg during ankle dorsi‐/plantarflexion exercise.

Author

Hooijmans, Melissa T., Veeger, Thom T. J., Mazzoli, Valentina, van Assen, Hans C., de Groot, Jurriaan H., Gottwald, Lukas M., Nederveen, Aart J., Strijkers, Gustav J., and Kan, Hermien E.

Subjects

STRAIN rate, MUSCLE contraction, LEG muscles, MAGNETIC resonance imaging, SKELETAL muscle

Abstract

Static quantitative magnetic resonance imaging (MRI) provides readouts of structural changes in diseased muscle, but current approaches lack the ability to fully explain the loss of contractile function. Muscle contractile function can be assessed using various techniques including phase‐contrast MRI (PC‐MRI), where strain rates are quantified. However, current two‐dimensional implementations are limited in capturing the complex motion of contracting muscle in the context of its three‐dimensional (3D) fiber architecture. The MR acquisitions (chemical shift‐encoded water–fat separation scan, spin echo‐echoplanar imaging with diffusion weighting, and two time‐resolved 3D PC‐MRI) wereperformed at 3 T. PC‐MRI acquisitions and performed with and without load at 7.5% of the maximum voluntary dorsiflexion contraction force. Acquisitions (3 T, chemical shift‐encoded water–fat separation scan, spin echo‐echo planar imaging with diffusion weighting, and two time‐resolved 3D PC‐MRI) were performed with and without load at 7.5% of the maximum voluntary dorsiflexion contraction force. Strain rates and diffusion tensors were calculated and combined to obtain strain rates along and perpendicular to the muscle fibers in seven lower leg muscles during the dynamic dorsi‐/plantarflexion movement cycle. To evaluate strain rates along the proximodistal muscle axis, muscles were divided into five equal segments. t‐tests were used to test if cyclic strain rate patterns (amplitude > 0) were present along and perpendicular to the muscle fibers. The effects of proximal‐distal location and load were evaluated using repeated measures ANOVAs. Cyclic temporal strain rate patterns along and perpendicular to the fiber were found in all muscles involved in dorsi‐/plantarflexion movement (p < 0.0017). Strain rates along and perpendicular to the fiber were heterogeneously distributed over the length of most muscles (p < 0.003). Additional loading reduced strain rates of the extensor digitorum longus and gastrocnemius lateralis muscle (p < 0.001). In conclusion, the lower leg muscles involved in cyclic dorsi‐/plantarflexion exercise showed cyclic fiber strain rate patterns with amplitudes that varied between muscles and between the proximodistal segments within the majority of muscles. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mechanical and tribological properties of C/C–SiC ceramic composites with different preforms

Author

Peng Yuqing, Li Zhiwei, Li Aijun, Wang Qifan, Bai Ruicheng, and Zhang Fangzhou

Subjects

c/c–sic, tribological properties, liquid silicon infiltration, chemical vapor infiltration, fiber architecture, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The C/C–SiC composites were fabricated by the liquid silicon infiltration method. The mechanical and tribological properties of C/C–SiC composites were assessed and compared based on different C/C densities and the carbon fiber textile architecture. The results demonstrated that the bending and shear strengths of C/C–SiC were lower than those of C/C composites, which resulted from the carbon fibers being corroded during the process of infiltration of liquid silicon. In contrast to C/C composites, the compressive strength of C/C–SiC exhibited higher values due to the presence of SiC ceramics. Moreover, the mechanical strength of C/C composites increased gradually with the increase of the C/C preform density. The tribological properties of various C/C–SiC composites showed a stable friction phase at an intermediate braking stage. When the density of C/C preforms was around 1.78 g/cm3, the C/C–SiC composites exhibited excellent friction coefficients (0.438 and 0.465), and low wear rates (linear and weight wear rates were 0.450 µm/time and 0.123 g/cycle, respectively). Furthermore, the C/C–SiC composites fabricated with non-woven carbon fiber needling preforms showed relatively a higher friction value and wear rate than those of C/C–SiC with PANOF integral C/C preforms. Therefore, C/C–SiC composites have been considered promising friction materials for braking system applications.

Published

2023

3. Diffusion Tensor Cardiac Magnetic Resonance Reveals Exosomes From Cardiosphere-Derived Cells Preserve Myocardial Fiber Architecture After Myocardial Infarction

Author

Nguyen, Christopher T, Dawkins, James, Bi, Xiaoming, Marbán, Eduardo, and Li, Debiao

Subjects

Biomedical and Clinical Sciences, Cardiovascular Medicine and Haematology, Cardiovascular, Heart Disease - Coronary Heart Disease, Clinical Trials and Supportive Activities, Clinical Research, Heart Disease, Regenerative Medicine, Evaluation of treatments and therapeutic interventions, 6.1 Pharmaceuticals, diffusion tensor MRI, exosomes, fiber architecture, regeneration, myocardial infarction, Cardiorespiratory Medicine and Haematology, Clinical Sciences, Cardiovascular medicine and haematology

Abstract

The object of the study was to reveal the fiber microstructural response with diffusion tensor cardiac magnetic resonance after intramyocardial exosomes secreted by cardiosphere-derived cells (CDCEXO) in chronic porcine myocardial infarction. Porcine with myocardial infarction underwent intramyocardial delivery of human CDCEXO and placebo in a randomized placebo-controlled study. Four weeks after injection, viability improved in the CDCEXO group, whereas myocardial fiber architecture and cardiac function were preserved. In the placebo group, fiber architecture and cardiac function declined. Myocardial regeneration by CDCEXO is not tumor-like; instead, details of tissue architecture are faithfully preserved, which may foster physiological excitation and contraction.

Published

2018

4. KURBAĞA BALDIRININ İZOMETRİK KASILMASINDA APONEVROZ VE LİF YÖNELİMİNİN KUVVET VE SAYISAL KARARLIK ÜZERİNDEKİ ETKİLERİ

Author

Ali Fethi Okyar and Şükrü Furkan Taşdemir

Subjects

sonlu elemanlar yöntemi, kasılma mekaniği, aponevroz, lif mimarisi, lif-takviyeli kompozit, finite element method, contractile mechanics, aponeurosis, fiber architecture, fiber-reinforced composites, Technology, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Bu çalışmada, kurbağa gastrocnemius (plantaris longus olarak da bilinmektedir) kasının sayısal modelini oluşturarak sonlu elemanlar yöntemi (SEY) ile kasılma davranışı incelenmiştir. Bu amaçla sonlu elemanlar yöntemi ile çalışan bir fiziksel gerçeklik benzetim senaryosu oluşturulmuştur. Bu senaryo dahilinde, çapraz-bağ kinetik modelini dağıtık-moment yaklaşımını kullanarak çözen sonlu elemanlar yöntemi ile oluşturulmuş kas modeli, kas üzerinde ince bir zar şeklinde bulunan aponevroz örtüsünün açısal yerleşiminin, kasılma sonucunda oluşan toplam çekme kuvveti üzerindeki etkisini incelemek üzere kullanılmıştır. Bununla birlikte, kas modelinde lif yöneliminin etkisinin incelenmesi amacıyla yönelim eksenel (sabit eksen yönünde) ve fusiform (kas geometrisini takip eden) olarak iki tipte örneklenerek üretilen çekme kuvveti ve yakınsama üzerindeki etkileri değerlendirilmiştir. Ayrıca, elde edilen veriler, gerçek bir kurbağa kasından laboratuvar ortamında elde edilmiş verilerle karşılaştırılmıştır. Sonuç olarak, aponevroz örtüsünün şeklinin ve lif yöneliminin kas modeli üzerinde üretilen çekme kuvveti ve yakınsama özellikleri bakımından ayırt edici ve önemli etkileri olduğu deneyimlenmiş, kullanılan modelin 3 boyutlu kas modellemesine uygun olabileceği görülmüştür.

Published

2021

5. Microstructural characterization of myocardial infarction with optical coherence tractography and two-photon microscopy.

Author

Goergen, Craig J, Chen, Howard H, Sakadžić, Sava, Srinivasan, Vivek J, and Sosnovik, David E

Subjects

Myofibrils, Animals, Humans, Mice, Myocardial Infarction, Collagen, Image Interpretation, Computer-Assisted, Diffusion Magnetic Resonance Imaging, Tomography, Optical Coherence, Models, Animal, Multimodal Imaging, Fiber architecture, Myocardium, myocardial infarction, optical coherence tomography, tractography, two‐photon microscopy, Image Interpretation, Computer-Assisted, Models, Animal, Tomography, Optical Coherence, Physiology, Clinical Sciences, Medical Physiology

Abstract

Myocardial infarction leads to complex changes in the fiber architecture of the heart. Here, we present a novel optical approach to characterize these changes in intact hearts in three dimensions. Optical coherence tomography (OCT) was used to derive a depth-resolved field of orientation on which tractography was performed. Tractography of healthy myocardium revealed a smooth linear transition in fiber inclination or helix angle from the epicardium to endocardium. Conversely, in infarcted hearts, no coherent microstructure could be identified in the infarct with OCT Additional characterization of the infarct was performed by the measurement of light attenuation and with two-photon microscopy. Myofibers were imaged using autofluorescence and collagen fibers using second harmonic generation. This revealed the presence of two distinct microstructural patterns in areas of the infarct with high light attenuation. In the presence of residual myofibers, the surrounding collagen fibers were aligned in a coherent manner parallel to the myofibers. In the absence of residual myofibers, the collagen fibers were randomly oriented and lacked any microstructural coherence. The presence of residual myofibers thus exerts a profound effect on the microstructural properties of the infarct scar and consequently the risk of aneurysm formation and arrhythmias. Catheter-based approaches to segment and image myocardial microstructure in humans are feasible and could play a valuable role in guiding the development of strategies to improve infarct healing.

Published

2016

6. A comparison study of water diffusion in unidirectional and 2D woven carbon/epoxy composites.

Author

Almudaihesh, Faisel, Holford, Karen, Pullin, Rhys, and Eaton, Mark

Subjects

*EPOXY resins, *WEAVING patterns, *DIFFUSION coefficients, *THERMOPLASTIC composites, *MICROCRACKS

Abstract

The use of CFRP composites is significantly increasing in the aerospace, automotive, and marine industries, particularly in safety critical primary structures. This work presents a newly developed experimental approach to investigate the directional diffusion of water in CFRP composites with the use of Fick's law. The approach is used to study the effect of fiber architecture on directional diffusion rates, with a particular focus on the role of fiber waviness in the diffusion process. A comparison of water diffusion is made in three different fiber architectures: Unidirectional (UD), plain weave, and twill weave. The specimens were fully immersed in 90°C purified water until their maximum moisture saturation was achieved, with some specimens being selectively exposed from the edges only to obtain the directional diffusion coefficients. The water penetration process into the CFRP structure initiate from the micro‐cracks and defects. The experimental work of this study shows sharp mass increases within the first stage followed by an equilibrium stage where saturation is present. The interfacial region is found to be a critical parameter where detachment of the interfacial fiber/matrix bonding is observed further demonstrating the potential effect of different fiber architecture in this region. UD fiber architecture showed ~20% higher diffusion coefficient in the Dx,y direction compared with plain and twill woven architectures. The weave patterns in 2D woven fiber architectures are therefore believed to play a key role on the moisture ingress mechanism and subsequently contributed in slowing down the capillary process in the interfacial region. This has implications for materials development and selection for CFRP composites used in moist environments. [ABSTRACT FROM AUTHOR]

Published

2022

7. Experimental and statistical analysis of strength of glass fiber reinforced polymer composite for different fiber architecture.

Author

Jariwala, Hitesh, Jain, Piyush, and Maisuriya, Vatsal

Subjects

*FIBROUS composites, *GLASS analysis, *STATISTICS, *WOVEN composites, *GOODNESS-of-fit tests, *GLASS fibers

Abstract

In the present study, the effect of fiber architecture on mechanical properties of E‐glass fiber reinforced polymer composite has been investigated experimentally. The influence of fiber volume fraction on strength of composite has also been predicted using second order polynomial regression models. The glass fibers were arranged in different architecture like unidirectional continuous, unidirectional discontinuous, short randomly oriented, transversely aligned, and woven for preparation of composites. The tensile and flexural tests were performed as per ASTM D3039 and ASTM D790, respectively. The experimental results of tensile and flexural properties of composites have been discussed. Results predicted by the regression models are in good agreement with experimental results which indicate the goodness of fit and the models are statistically significant. [ABSTRACT FROM AUTHOR]

Published

2021

8. Diffusion Tensor Cardiac Magnetic Resonance Reveals Exosomes From Cardiosphere-Derived Cells Preserve Myocardial Fiber Architecture After Myocardial Infarction

Author

Christopher T. Nguyen, PhD, James Dawkins, DVM, Xiaoming Bi, PhD, Eduardo Marbán, MD, PhD, and Debiao Li, PhD

Subjects

diffusion tensor MRI, exosomes, fiber architecture, regeneration, myocardial infarction, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

The object of the study was to reveal the fiber microstructural response with diffusion tensor cardiac magnetic resonance after intramyocardial exosomes secreted by cardiosphere-derived cells (CDCEXO) in chronic porcine myocardial infarction. Porcine with myocardial infarction underwent intramyocardial delivery of human CDCEXO and placebo in a randomized placebo-controlled study. Four weeks after injection, viability improved in the CDCEXO group, whereas myocardial fiber architecture and cardiac function were preserved. In the placebo group, fiber architecture and cardiac function declined. Myocardial regeneration by CDCEXO is not tumor-like; instead, details of tissue architecture are faithfully preserved, which may foster physiological excitation and contraction.

Published

2018

9. Experimental Investigation on the Shear Properties and Failure Mechanism of 3D MWK Glass/Epoxy Composites under Compressive Loading.

Author

Li, Dian-sen, Dang, Ming-guang, and Jiang, Lei

Abstract

This paper reports the effects of temperature and fiber architecture on the shear properties and failure mechanism of 3D MWK composites under compressive loading at room and elevated temperatures. The shear experiments of composites with three fiber architectures were performed at five different temperatures. Macro-fracture and SEM micrographs were examined to understand the deformation and shear failure mechanism. The results show that shear stress-strain curves show non-linearity and plastic fracture feature, and exhibit plastic platform at elevated temperatures. The temperature has significant effects on the shear properties which decrease significantly with increasing the temperature due to degradation of matrix properties, especially after 75 oC. The shear properties can be affected greatly by the fiber architecture and these increase significantly with the increase of 45 o direction fiber at different temperatures. The results also show that the damage and failure patterns of composites vary with the fiber architecture and temperature. At room temperature, the interfacial adhesion between fibers and matrix is high, the local delaminating and shear failure feature are prominent. At elevated temperatures, the composites become more softened, cracked and attain plasticity. The damage of matrix plastic and cracking, interface debonding, and fiber layer delaminating change significantly. [ABSTRACT FROM AUTHOR]

Published

2020

10. Towards Large-Scale Fiber Orientation Models of the Brain – Automation and Parallelization of a Seeded Region Growing Segmentation of High-Resolution Brain Section Images

Author

Lührs, Anna, Bücker, Oliver, Axer, Markus, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Amunts, Katrin, editor, Grandinetti, Lucio, editor, Lippert, Thomas, editor, and Petkov, Nicolai, editor

Published

2016

11. A comparative study on the low velocity impact behavior of UD, woven, and hybrid UD/woven FRP composite laminates.

Author

Ma, Binlin, Cao, Xiaofei, Feng, Yu, Song, Yujian, Yang, Fei, Li, Ying, Zhang, Deyue, Wang, Yipeng, and He, Yuting

Subjects

*WOVEN composites, *LAMINATED materials, *IMPACT response, *VELOCITY, *INSPECTION & review, *COMPARATIVE studies

Abstract

This study is aimed at comparing the response and damage of unidirectional (UD), woven fabric (WF) and hybrid UD/WF fiber reinforced polymer (FRP) laminates subjected to low velocity impact. The unidirectional tape and/or woven fabric (plain weave) carbon/epoxy prepregs are laminated and hot-pressed to produce UD, WF and sandwich-like hybrid UD/WF specimens. Impact responses of specimens are determined through low velocity impact (LVI) tests with impact energies of 10 J, 17 J and 25 J. After the LVI tests, the damage of specimens is characterized and analyzed using a combination of visual inspection, ultrasonic phased-array inspection, micro-computed tomography (CT) inspection, cross-sectional microscopic observation, and thermal de-ply test. Also, the LVI damage mechanisms of the three types of specimens are quantitatively compared by using the inter fiber crack volume ratio, total delamination area and fiber fracture length. It is concluded that the fiber architecture plays an important role in determining low velocity impact behavior of composite laminates. Especially, for the sandwich-like hybrid UD/WF laminates whose surface is a WF layer and the core is a UD layer, the WF layer on the surface plays an important role in reducing matrix cracking, delamination and fiber fracture, thus improving its LVI resistance. [Display omitted] • The LVI performance of three types of laminates, UD, WF and hybrid UD/WF laminates, was experimentally compared. • The LVI damage mechanisms of laminates were quantitatively compared by using the IFCVR, TDA and FFL. • The impact damage was characterized and analyzed by combining several NDT and DT methods. [ABSTRACT FROM AUTHOR]

Published

2024

12. Mechanical Investigation of Basalt/S-Glass Fiber Reinforced Epoxy Hybrid Composites for High Temperature Application

Author

Sandeep B., Dr. Naveed Anjum, Suraj T.G., Abhishek S., Bharath S., Ravikumar B.G., and Sandeep B.

Subjects

Epoxy, Fiber architecture, S-glass, Temperature, Polymer matrix, Basalt, Hybrid, Reinforcement

Abstract

The work presents the mechanical investigation of composite materials that are meant to perform under different temperature condition with the application of tensile loading. The composite under study is developed using reinforcement materials made out of basalt and S-glass fiber reinforced with polymer matrix composite (epoxy resin) by hand layup technique with different compositions by changing the fiber layer sequence starting with pure form to hybrid once (fiber architecture). The test results reveals, that the tensile properties of the hybrid composites with fiber architecture of 2/2 basalt mixed S-glass fiber reinforced with epoxy composites are at its optimal level in both normal and elevated temperature conditions. Basalt fiber being good temperature resistant and S-glass fiber having high strength, with this hybrid combination, the material has out played under tensile force being applied when compared with other samples under test.

Published

2023

13. Towards a Multiscale, High-Resolution Model of the Human Brain

Author

Amunts, Katrin, Bücker, Oliver, Axer, Markus, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Grandinetti, Lucio, editor, Lippert, Thomas, editor, and Petkov, Nicolai, editor

Published

2014

14. A Muscle Model Incorporating Fiber Architecture Features for the Estimation of Joint Stiffness During Dynamic Movement

Author

Cop, Christopher P., Schouten, A.C., Koopman, Bart F.J.M., Sartori, M., Torricelli, Diego, Akay, Metin, Pons, Jose L., TechMed Centre, and Biomechanical Engineering

Subjects

musculoskeletal diseases, animal structures, Computer science, Generalization, Movement (music), Computation, System identification, Stiffness, macromolecular substances, equipment and supplies, musculoskeletal system, Control theory, Joint stiffness, 2023 OA procedure, medicine, Fiber architecture, medicine.symptom, Joint (geology)

Abstract

Quantifying human joint stiffness in vivo during movement remains challenging. Well established stiffness estimation methods include system identification and the notion of quasi-stiffness, with experimental and conceptual limitations, respectively. Joint stiffness computation via biomechanical models is an emerging solution to overcome such limitations. However, these models make assumptions that hamper their generalization across muscle architectures. Here we present a stiffness formulation that considers the muscle’s pennation angle, and its comparison to a simpler formulation that does not. Model-based stiffness estimates are evaluated against joint-perturbation-based system identification. Results on muscles with different pennation angle show that our formulation seamlessly adjusts the muscle-tendon units’ stiffness depending on their architecture. At the joint level, our new model improved the stiffness estimations. Our study’s relevance is the creation and validation of a modeling formulation that does not require joint perturbation. This will enable better estimations and understanding of stiffness properties and human movement.

Published

2022

15. Modeling of the Optical Behavior of Myocardial Fibers in Polarized Light Imaging

Author

Desrosiers, Paul Audain, Michalowicz, Gabrielle, Jouk, Pierre-Simon, Usson, Yves, Zhu, Yuemin, Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Sudan, Madhu, editor, Terzopoulos, Demetri, editor, Tygar, Doug, editor, Vardi, Moshe Y., editor, Weikum, Gerhard, editor, Camara, Oscar, editor, Mansi, Tommaso, editor, Pop, Mihaela, editor, Rhode, Kawal, editor, Sermesant, Maxime, editor, and Young, Alistair, editor

Published

2013

16. Derivation of Fiber Orientations From Oblique Views Through Human Brain Sections in 3D-Polarized Light Imaging

Author

Daniel Schmitz, Sascha E. A. Muenzing, Martin Schober, Nicole Schubert, Martina Minnerop, Thomas Lippert, Katrin Amunts, and Markus Axer

Subjects

neuroimaging, modeling, 3D-PLI, white matter anatomy, fiber architecture, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Human anatomy, QM1-695

Abstract

3D-Polarized Light Imaging (3D-PLI) enables high-resolution three-dimensional mapping of the nerve fiber architecture in unstained histological brain sections based on the intrinsic birefringence of myelinated nerve fibers. The interpretation of the measured birefringent signals comes with conjointly measured information about the local fiber birefringence strength and the fiber orientation. In this study, we present a novel approach to disentangle both parameters from each other based on a weighted least squares routine (ROFL) applied to oblique polarimetric 3D-PLI measurements. This approach was compared to a previously described analytical method on simulated and experimental data obtained from a post mortem human brain. Analysis of the simulations revealed in case of ROFL a distinctly increased level of confidence to determine steep and flat fiber orientations with respect to the brain sectioning plane. Based on analysis of histological sections of a human brain dataset, it was demonstrated that ROFL provides a coherent characterization of cortical, subcortical, and white matter regions in terms of fiber orientation and birefringence strength, within and across sections. Oblique measurements combined with ROFL analysis opens up new ways to determine physical brain tissue properties by means of 3D-PLI microscopy.

Published

2018

17. Characterizing Tissue Remodeling and Mechanical Heterogeneity in Cerebral Aneurysms

Author

Elizabeth D. Shih, Colleen M. Witzenburg, Victor H. Barocas, Andrew W. Grande, Paolo P. Provenzano, and Patrick W. Alford

Subjects

Materials science, Computed Tomography Angiography, Physiology, Aortic Rupture, Fibrillar Collagens, Models, Cardiovascular, Biomechanics, Intracranial Aneurysm, Blood flow, Cerebral Arteries, Biomechanical Phenomena, Cerebral Angiography, Extracellular Matrix, Tissue remodeling, Immune infiltration, Cerebrovascular Circulation, Humans, Fiber architecture, Stress, Mechanical, Tissue mechanics, Cardiology and Cardiovascular Medicine, Biological system, Magnetic Resonance Angiography, Dilatation, Pathologic

Abstract

Accurately assessing the complex tissue mechanics of cerebral aneurysms (CAs) is critical for elucidating how CAs grow and whether that growth will lead to rupture. The factors that have been implicated in CA progression – blood flow dynamics, immune infiltration, and extracellular matrix remodeling – all occur heterogeneously throughout the CA. Thus, it stands to reason that the mechanical properties of CAs are also spatially heterogeneous. Here, we present a new method for characterizing the mechanical heterogeneity of human CAs using generalized anisotropic inverse mechanics, which uses biaxial stretching experiments and inverse analyses to determine the local Kelvin moduli and principal alignments within the tissue. Using this approach, we find that there is significant mechanical heterogeneity within a single acquired human CA. These results were confirmed using second harmonic generation imaging of the CA’s fiber architecture and a correlation was observed. This approach provides a single-step method for determining the complex heterogeneous mechanics of CAs, which has important implications for future identification of metrics that can improve accuracy in prediction risk of rupture.

Published

2021

18. The glial framework reveals white matter fiber architecture in human and primate brains

Author

Aviv Mezer and Roey Schurr

Subjects

Physics, Multidisciplinary, Staining and Labeling, biology, Resolution (electron density), Brain, Macaca mulatta, White Matter, Axons, Corpus Callosum, White matter, Diffusion Magnetic Resonance Imaging, medicine.anatomical_structure, nervous system, biology.animal, Chlorocebus aethiops, Image Processing, Computer-Assisted, medicine, Animals, Humans, Fiber architecture, Primate, Neuroglia, Neuroscience

Abstract

How to quantify local axonal orientations Mapping the axonal trajectories of the brain’s white matter at cellular resolution is a long-standing goal of neuroscience. However, existing methods for mapping the axons are either limited to animal studies or require highly specialized equipment for data acquisition and processing. Nissl staining identifies cell nuclei and has been used extensively to investigate parcellations of the cortical gray matter, but the white matter has largely been neglected with this technique. Schurr and Mezer now show that Nissl staining, together with structure tensor analysis, can be used to study white matter architecture and the organization of the glial cell framework around axons over the whole brain. This technique greatly advances our knowledge regarding the organization of glial cells and the fine-grained organization of axonal projections in the brain. —PRS

Published

2021

19. A comparison study of water diffusion in unidirectional and <scp>2D</scp> woven carbon/epoxy composites

Author

Faisel Almudaihesh, Mark Jonathan Eaton, Karen Margaret Holford, and Rhys Pullin

Subjects

Materials science, Absorption of water, Polymers and Plastics, chemistry.chemical_element, General Chemistry, Epoxy, Moisture diffusion, chemistry, visual_art, Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium, Comparison study, Fiber architecture, Water diffusion, Composite material, Carbon

Abstract

he use of CFRP composites is significantly increasing in the aerospace, automotive, and marine industries, particularly in safety critical primary structures. This work presents a newly developed experimental approach to investigate the directional diffusion of water in CFRP composites with the use of Fick's law. The approach is used to study the effect of fiber architecture on directional diffusion rates, with a particular focus on the role of fiber waviness in the diffusion process. A comparison of water diffusion is made in three different fiber architectures: Unidirectional (UD), plain weave, and twill weave. The specimens were fully immersed in 90°C purified water until their maximum moisture saturation was achieved, with some specimens being selectively exposed from the edges only to obtain the directional diffusion coefficients. The water penetration process into the CFRP structure initiate from the micro-cracks and defects. The experimental work of this study shows sharp mass increases within the first stage followed by an equilibrium stage where saturation is present. The interfacial region is found to be a critical parameter where detachment of the interfacial fiber/matrix bonding is observed further demonstrating the potential effect of different fiber architecture in this region. UD fiber architecture showed ~20% higher diffusion coefficient in the Dx,y direction compared with plain and twill woven architectures. The weave patterns in 2D woven fiber architectures are therefore believed to play a key role on the moisture ingress mechanism and subsequently contributed in slowing down the capillary process in the interfacial region. This has implications for materials development and selection for CFRP composites used in moist environments.

Published

2021

20. Shear Buckling of GFRP Beam Webs

Author

Manshadi, Behzad D., Vassilopoulos, Anastasios P., Keller, Thomas, Ye, Lieping, editor, Feng, Peng, editor, and Yue, Qingrui, editor

Published

2011

21. A Computational Framework for Patient-Specific Multi-Scale Cardiac Modeling

Author

Aguado-Sierra, Jazmin, Kerckhoffs, Roy C. P., Lionetti, Fred, Hunt, Darlene, Villongco, Chris, Gonzales, Matt, Campbell, Stuart G., McCulloch, Andrew D., and Kerckhoffs, Roy C.P., editor

Published

2010

22. Exploration of male urethral sphincter complex using diffusion tensor imaging (DTI)-based fiber-tracking.

Author

Sinha, Shantanu, Sinha, Usha, Malis, Vadim, Bhargava, Valmik, Sakamoto, Kyoko, and Rajasekaran, Mahadevan

Abstract

Background: Urinary incontinence is a major clinical problem arising primarily from age-related degenerative changes to the sphincter muscles. However, the precise anatomy of the normal male sphincter muscles has yet to be established. Diffusion tensor imaging (DTI) may offer a unique insight into muscle microstructure and fiber architecture.Purpose: To explore the anatomy of the urethral sphincter muscles pertinent to urinary continence function using DT-MRI.Study Type: Prospective cohort study.Subjects: Eleven normal male subjects (mean age: 25.4 years); two subjects were scanned in three separate sessions to assess reproducibility.Field Strength/sequence: 3T; using a diffusion-weighted spin echo planar sequence.Assessment: DT parameters including fractional anisotropy (FA), primary (λ1 ), secondary (λ2 ), and tertiary (λ3 ) eigenvalues, Apparent diffusion coefficient and radial diffusivity were analyzed statistically, while tracked muscle fibers were assessed visually.Statistical Tests: Regional differences (sphincters and longitudinal muscle of the urethra) in the DTI indices were assessed by one-way analysis of variance. A Tukey post-hoc test was used to identify significant differences between muscle regions.Results: Two sphincter muscles, one proximal near the base of the bladder, corresponding to the lisso-sphincter, and the other distal to the end of the prostate corresponding to the rhabdo-sphincter, surrounding a central urethral muscle fiber bundle, were clearly identified. FA was higher and λ3 lower in the proximal sphincter muscle compared to the central urethral muscle and the distal sphincter (P < 0.05). The average coefficient of variation ranged from 5-12% for the DTI indices.Data Conclusion: Since DTI values are known to reflect underlying tissue microarchitecture, significant differences in DTI indices identified here between the muscles of the urethral complex may potentially arise from differences in tissue microarchitecture that may in turn be related to the specific function of the sphincter and other muscles.Level Of Evidence: 1 Technical Efficacy: Stage 2 J. Magn. Reson. Imaging 2018;48:1002-1011. [ABSTRACT FROM AUTHOR]

Published

2018

23. Derivation of Fiber Orientations From Oblique Views Through Human Brain Sections in 3D-Polarized Light Imaging.

Author

Schmitz, Daniel, Muenzing, Sascha E. A., Schober, Martin, Schubert, Nicole, Minnerop, Martina, Lippert, Thomas, Amunts, Katrin, and Axer, Markus

Subjects

FIBER orientation, OPTICAL polarization, THREE-dimensional imaging, NERVE fibers, BIREFRINGENT filters

Abstract

3D-Polarized Light Imaging (3D-PLI) enables high-resolution three-dimensional mapping of the nerve fiber architecture in unstained histological brain sections based on the intrinsic birefringence of myelinated nerve fibers. The interpretation of the measured birefringent signals comes with conjointly measured information about the local fiber birefringence strength and the fiber orientation. In this study, we present a novel approach to disentangle both parameters from each other based on a weighted least squares routine (ROFL) applied to oblique polarimetric 3D-PLI measurements. This approach was compared to a previously described analytical method on simulated and experimental data obtained from a post mortem human brain. Analysis of the simulations revealed in case of ROFL a distinctly increased level of confidence to determine steep and flat fiber orientations with respect to the brain sectioning plane. Based on analysis of histological sections of a human brain dataset, it was demonstrated that ROFL provides a coherent characterization of cortical, subcortical, and white matter regions in terms of fiber orientation and birefringence strength, within and across sections. Oblique measurements combined with ROFL analysis opens up new ways to determine physical brain tissue properties by means of 3D-PLI microscopy. [ABSTRACT FROM AUTHOR]

Published

2018

24. The Functional Significance of Jaw-Muscle Fiber Architecture in Tree-Gouging Marmosets

Author

Taylor, Andrea B., Eng, Carolyn M., Anapol, Fred C., Vinyard, Christopher J., Ford, Susan M., editor, Porter, Leila M., editor, and Davis, Lesa C., editor

Published

2009

25. The effect of the adherends' thickness on static ultrasonic welding of thermoplastic composites

Author

Guevara Sotelo, Natalia Sofia (author) and Guevara Sotelo, Natalia Sofia (author)

Abstract

Fiber-reinforced polymer composites have gained relevance in the aerospace industry due to their great potential for weight reduction. This, thanks to their outstanding specific properties and ability to be tailored to different applications. Developing efficient composite joining techniques is a challenge that requires great attention as it is key to a more sustainable industry. Thermoplastic composites present the great advantage that they can be joined via fusion bonding, a joining technique in which the interface is virtually erased and is generally faster than other available techniques such as mechanical fastening and adhesion bonding. A fusion bonding technology that stands out for its short processing times and cost-efficiency is ultrasonic welding, a process in which the joint is developed via low-amplitude and high-frequency mechanical vibrations that heat up the interface. Although the effect of different parameters is well known, the particular effect of the part -commonly referred to as adherend- thickness is yet not fully understood. This thesis investigated the effect of the adherends’ thickness on the process response and weld evolution on static ultrasonic welding of CF/LMPAEK thermoplastic composites. Different characterization techniques were used to assess the latter, such as the output from the welding equipment (power and displacement), temperature readings, microscopy analysis, high-speed camera recordings, and numerical models. The results showed that increasing only the top adherend’s thickness gradually increases the heating in this adherend up to a point where significant fiber squeeze-out is observed at early stages of the process. This overheating was associated with hammering and the differences in compliance when increasing the thickness. It is hypothesized that this hammering may contribute to overheating. Welding with a higher force significantly decreased the overheating in the top adherend as hammering is reduced, whereas, Aerospace Engineering

Published

2022

26. Titanium Matrix Composites

Author

Lütjering, Gerd and Williams, James C.

Published

2007

27. Three‐dimensional Integrated Functional, Structural, and Computational Mapping to Define the Structural 'Fingerprints' of Heart‐Specific Atrial Fibrillation Drivers in Human Heart Ex Vivo

Author

Jichao Zhao, Brian J. Hansen, Yufeng Wang, Thomas A. Csepe, Lidiya V. Sul, Alan Tang, Yiming Yuan, Ning Li, Anna Bratasz, Kimerly A. Powell, Ahmet Kilic, Peter J. Mohler, Paul M. L. Janssen, Raul Weiss, Orlando P. Simonetti, John D. Hummel, and Vadim V. Fedorov

Subjects

3D computer model, atrial fibrillation, atrial structure, computer‐based model, fiber architecture, fibrosis, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

BackgroundStructural remodeling of human atria plays a key role in sustaining atrial fibrillation (AF), but insufficient quantitative analysis of human atrial structure impedes the treatment of AF. We aimed to develop a novel 3‐dimensional (3D) structural and computational simulation analysis tool that could reveal the structural contributors to human reentrant AF drivers. Methods and ResultsHigh‐resolution panoramic epicardial optical mapping of the coronary‐perfused explanted intact human atria (63‐year‐old woman, chronic hypertension, heart weight 608 g) was conducted during sinus rhythm and sustained AF maintained by spatially stable reentrant AF drivers in the left and right atrium. The whole atria (107×61×85 mm3) were then imaged with contrast‐enhancement MRI (9.4 T, 180×180×360‐μm3 resolution). The entire 3D human atria were analyzed for wall thickness (0.4–11.7 mm), myofiber orientations, and transmural fibrosis (36.9% subendocardium; 14.2% midwall; 3.4% subepicardium). The 3D computational analysis revealed that a specific combination of wall thickness and fibrosis ranges were primarily present in the optically defined AF driver regions versus nondriver tissue. Finally, a 3D human heart–specific atrial computer model was developed by integrating 3D structural and functional mapping data to test AF induction, maintenance, and ablation strategies. This 3D model reproduced the optically defined reentrant AF drivers, which were uninducible when fibrosis and myofiber anisotropy were removed from the model. ConclusionsOur novel 3D computational high‐resolution framework may be used to quantitatively analyze structural substrates, such as wall thickness, myofiber orientation, and fibrosis, underlying localized AF drivers, and aid the development of new patient‐specific treatments.

Published

2017

28. Relating Advanced Electrospun Fiber Architectures to the Temporal Release of Active Agents to Meet the Needs of Next-Generation Intravaginal Delivery Applications

Author

Kevin M. Tyo, Farnaz Minooei, Keegan C. Curry, Sarah M. NeCamp, Danielle L. Graves, Joel R. Fried, and Jill M. Steinbach-Rankins

Subjects

electrospun fibers, fiber architecture, drug delivery, intravaginal delivery, delivery vehicle, Pharmacy and materia medica, RS1-441

Abstract

Electrospun fibers have emerged as a relatively new delivery platform to improve active agent retention and delivery for intravaginal applications. While uniaxial fibers have been explored in a variety of applications including intravaginal delivery, the consideration of more advanced fiber architectures may offer new options to improve delivery to the female reproductive tract. In this review, we summarize the advancements of electrospun coaxial, multilayered, and nanoparticle-fiber architectures utilized in other applications and discuss how different material combinations within these architectures provide varied durations of release, here categorized as either transient (within 24 h), short-term (24 h to one week), or sustained (beyond one week). We seek to systematically relate material type and fiber architecture to active agent release kinetics. Last, we explore how lessons derived from these architectures may be applied to address the needs of future intravaginal delivery platforms for a given prophylactic or therapeutic application. The overall goal of this review is to provide a summary of different fiber architectures that have been useful for active agent delivery and to provide guidelines for the development of new formulations that exhibit release kinetics relevant to the time frames and the diversity of active agents needed in next-generation multipurpose applications.

Published

2019

29. Titanium Matrix Composites

Author

Lütjering, Gerd, Williams, James C., Derby, Brain, editor, Lütjering, Gerd, and Williams, James C.

Published

2003

30. Knowledge Management for the Strategie Design and Manufacture of Polymer Composite Products

Author

Lenz, Timothy J., McDowell, James K., and Roy, Rajkumar, editor

Published

2001

31. High-Strength Hybrid Textile Composites with Carbon, Kevlar, and E-Glass Fibers for Impact-Resistant Structures. A Review.

Author

Priyanka, P., Dixit, A., and Mali, H.

Subjects

*TEXTILES, *FINITE element method, *HYBRID materials, *COMPUTER simulation, *COMPOSITE materials

Abstract

The paper reviews the characterization of high-performance hybrid textile composites and their hybridization effects of composite's behavior. Considered are research works based on the finite-element modeling, simulation, and experimental characterization of various mechanical properties of such composites. [ABSTRACT FROM AUTHOR]

Published

2017

32. A functionally graded material model for the transmural stress distribution of the aortic valve leaflet.

Author

Rego, Bruno V. and Sacks, Michael S.

Subjects

*STRESS concentration, *AORTIC valve, *HEART physiology, *MICROELECTROMECHANICAL systems, *DISEASE progression

Abstract

Heterogeneities in structure and stress within heart valve leaflets are of significant concern to their functional physiology, as they affect how the tissue constituents remodel in response to pathological and non-pathological (e.g. exercise, pregnancy) alterations in cardiac function. Indeed, valve interstitial cells (VICs) are known to synthesize and degrade leaflet extracellular matrix (ECM) components in a manner specific to their local micromechanical environment. Quantifying local variations in ECM structure and stress is thus necessary to understand homeostatic valve maintenance as well as to develop predictive models of disease progression and post-surgical outcomes. In the aortic valve (AV), transmural variations in stress have previously been investigated by modeling the leaflet as a composite of contiguous but mechanically distinct layers. Based on previous findings about the bonded nature of these layers ( Buchanan and Sacks, BMMB, 2014 ), we developed a more generalized structural constitutive model by treating the leaflet as a functionally graded material (FGM), whose properties vary continuously over the thickness. We informed the FGM model using high-resolution morphological measurements, which demonstrated that the composition and fiber structure change gradually over the thickness of the AV leaflet. For validation, we fit the model against an extensive database of whole-leaflet and individual-layer mechanical responses. The FGM model predicted large stress variations both between and within the leaflet layers at end-diastole, with low-collagen regions bearing significant radial stress. These novel results suggest that the continually varying structure of the AV leaflet has an important purpose with regard to valve function and tissue homeostasis. [ABSTRACT FROM AUTHOR]

Published

2017

33. Influence of temperature on the bending properties and failure mechanism of 3D needle-punched carbon/epoxy composites.

Author

Jiang, Nan, Li, Dian-sen, Yao, Qian-qian, and Jiang, Lei

Abstract

This paper presents the three-point bending properties of 3D needle-punched composites with two fiber architectures at room and elevated temperatures. The influences of temperature and fiber architectures on the load/deflection curves, bending strength and bending stiffness are analyzed. Macro-Fracture morphology and SEM micrographs are examined to understand the damage and failure mechanism. The results show that the bending properties of plain structure needle-punched composites are superior to those with non-woven structure. Meanwhile, the bending properties of composites decrease significantly with the increase of testing temperature. Moreover, the damage and failure patterns of composites vary with fiber architecture and testing temperatures. For the plain structure, 90 ° and 0 ° fiber bundles can bear the load together. At room temperature, the composite shows brittle fracture feature and exhibits local damage with matrix cracking, breakage and tearing of the fibers. While at a higher temperature, the composite shows less fracture and becomes more softened and plastic. It damages with matrix cracking, falling off and plastic deformation, fiber layer/web delaminating, and interface debonding. [ABSTRACT FROM AUTHOR]

Published

2017

34. Estimating fiber orientation distribution functions in 3D-Polarized Light Imaging

Author

Markus eAxer, Sven eStrohmer, David eGräßel, Oliver eBücker, Melanie eDohmen, Julia eReckfort, Karl eZilles, and Katrin eAmunts

Subjects

human brain, connectome, Polarized light imaging, Fiber architecture, 3D-PLI, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Human anatomy, QM1-695

Abstract

Research of the human brain connectome requires multiscale approaches derived from independent imaging methods ideally applied to the same object. Hence, comprehensible strategies for data integration across modalities and across scales are essential. We have successfully established a concept to bridge the spatial scales from microscopic fiber orientation measurements based on 3D-Polarized Light Imaging (3D-PLI) to meso- or macroscopic dimensions. By creating orientation distribution functions (pliODFs) from high-resolution vector data via series expansion with spherical harmonics utilizing high performance computing and supercomputing technologies, data fusion with Diffusion Magnetic Resonance Imaging has become feasible, even for a large-scale dataset such as the human brain. Validation of our approach was done effectively by means of two types of datasets that were transferred from fiber orientation maps into pliODFs: simulated 3D-PLI data showing artificial, but clearly defined fiber patterns and real 3D-PLI data derived from sections through the human brain and the brain of a hooded seal.

Published

2016

35. Experimental and statistical analysis of strength of glass fiber reinforced polymer composite for different fiber architecture

Author

Piyush Jain, Hitesh Jariwala, and Vatsal Maisuriya

Subjects

Materials science, Polymers and Plastics, Composite number, Materials Chemistry, Ceramics and Composites, Glass fiber reinforced polymer, Fiber architecture, Statistical analysis, General Chemistry, Composite material

Published

2020

36. Experimental Investigation on the Shear Properties and Failure Mechanism of 3D MWK Glass/Epoxy Composites under Compressive Loading

Author

Dian-sen Li, Ming-guang Dang, and Lei Jiang

Subjects

Materials science, Polymers and Plastics, General Chemical Engineering, Glass epoxy, Interfacial adhesion, Failure mechanism, 02 engineering and technology, General Chemistry, Plasticity, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Compressive load, Cracking, Shear (geology), Fiber architecture, Composite material, 0210 nano-technology

Abstract

This paper reports the effects of temperature and fiber architecture on the shear properties and failure mechanism of 3D MWK composites under compressive loading at room and elevated temperatures. The shear experiments of composites with three fiber architectures were performed at five different temperatures. Macro-fracture and SEM micrographs were examined to understand the deformation and shear failure mechanism. The results show that shear stress-strain curves show non-linearity and plastic fracture feature, and exhibit plastic platform at elevated temperatures. The temperature has significant effects on the shear properties which decrease significantly with increasing the temperature due to degradation of matrix properties, especially after 75 oC. The shear properties can be affected greatly by the fiber architecture and these increase significantly with the increase of 45 o direction fiber at different temperatures. The results also show that the damage and failure patterns of composites vary with the fiber architecture and temperature. At room temperature, the interfacial adhesion between fibers and matrix is high, the local delaminating and shear failure feature are prominent. At elevated temperatures, the composites become more softened, cracked and attain plasticity. The damage of matrix plastic and cracking, interface debonding, and fiber layer delaminating change significantly.

Published

2020

37. Carbon Fiber Architecture

Author

Fitzer, E., Manocha, Lalit M., Fitzer, E., and Manocha, Lalit M.

Published

1998

38. Textile Preforming

Author

Ko, Frank K., Du, George W., and Peters, S. T., editor

Published

1998

39. Ultrasonic NDE Techniques and the Effects of Flaws on Mechanical Performance in Multi-Directionally Reinforced Textile Composites

Author

Hale, R. D., Hsu, D. K., Adams, D. O., Thompson, Donald O., editor, and Chimenti, Dale E., editor

Published

1996

40. Implementation of skeletal muscle model with advanced activation control

Author

Kocková H. and Cimrman R.

Subjects

Skeletal muscle, Cross-bridge distribution, Calcium activation, Fiber architecture, Composite model, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

The paper summarizes main principles of an advanced skeletal muscle model. The proposed mathematical model is suitable for a 3D muscle representation. It respects the microstructure of the muscle which is represented by three basic components: active fibers, passive fibers and a matrix. For purposes of presented work the existing material models suitable for the matrix and passive fibers are used and a new active fiber model is proposed. The active fiber model is based on the sliding cross-bridge theory of contraction. This theory is often used in modeling of skeletal and cardiac muscle contractions. In this work, a certain simplification of the cross-bridge distribution function is proposed, so that the 3D computer implementation becomes feasible. The new active fiber model is implemented into our research finite element code. A simple 3D muscle bundle-like model is created and the implemented composite model (involving the matrix, passive and active fibers) is used to perform the isometric, concentric and excentric muscle contraction simulations.

Published

2009

41. Ultrasonic NDE of Three-Dimensional Textile Composites

Author

Hale, R. D., Hsu, D. K., Thompson, Donald O., editor, and Chimenti, Dale E., editor

Published

1995

42. Textile Composites

Author

Post, Daniel, Han, Bongtae, Ifju, Peter, Ling, Frederick F., editor, Post, Daniel, Han, Bongtae, and Ifju, Peter

Published

1994

43. Brain atlas of the Mongolian gerbil ( Meriones unguiculatus) in CT/MRI-aided stereotaxic coordinates.

Author

Radtke-Schuller, Susanne, Schuller, Gerd, Angenstein, Frank, Grosser, Oliver, Goldschmidt, Jürgen, and Budinger, Eike

Subjects

*BRAIN tomography, *MAGNETIC resonance imaging of the brain, *STEREOTAXIC techniques, *MONGOLIAN gerbil, *HISTOLOGY, *MYELINATION

Abstract

A new stereotaxic brain atlas of the Mongolian gerbil ( Meriones unguiculatus), an important animal model in neurosciences, is presented. It combines high-quality histological material for identification of brain structures with reliable stereotaxic coordinates. The atlas consists of high-resolution images of frontal sections alternately stained for cell bodies (Nissl) and myelinated fibers (Gallyas) of 62 rostro-caudal levels at intervals of 350 μm. Brain structures were named according to the Paxinos nomenclature for rodents. The accuracy of the stereotaxic coordinate system was improved substantially by comparing and matching the series of histological sections to in vivo brain images of the gerbil obtained by magnetic resonance imaging (MRI). The skull outlines corresponding to the MR images were acquired using X-ray computerized tomography (CT) and were used to establish the relationship between coordinates of brain structures and skull. Landmarks such as lambda, bregma, ear canals and occipital crest can be used to line up skull and brain in standard atlas coordinates. An easily reproducible protocol allows sectioning of experimental brains in the standard frontal plane of the atlas. [ABSTRACT FROM AUTHOR]

Published

2016

44. Study of myocardial cell inhomogeneity of the human heart: Simulation and validation using polarized light imaging.

Author

Desrosiers, Paul Audain, Michalowicz, Gabrielle, Jouk, Pierre Simon, Usson, Yves, and Zhu, Yuemin

Subjects

*CARDIOMYOPATHIES, *POLARIZATION microscopy, *HEART diseases, *MYOCARDIUM, *MICROSTRUCTURE

Abstract

Purpose: The arrangement or architecture of myocardial cells plays a fundamental role in the heart's function and its change was shown to be directly linked to heart diseases. Inhomogeneity level is an important index of myocardial cell arrangements in the human heart. The authors propose to investigate the inhomogeneity level of myocardial cells using polarized light imaging simulations and experiments. Methods: The idea is based on the fact that the myosin filaments in myocardial cells have the same properties as those of a uniaxial birefringent crystal. The method then consists in modeling the myosin filaments of myocardial cells as uniaxial birefringent crystal, simulating the behavior of the latter by means of the Mueller matrix, and measuring the final intensity of polarized light and consequently the inhomogeneity level of myocardial cells in each voxel through the use of crossed polarizers. The method was evaluated on both simulated and real tissues and under various myocardial cell configurations including parallel cells, crossed cells, and cells with random orientations. Results: When myocardial cells run perfectly parallel to each other, all the polarized light was blocked by those parallel myocardial cells, and a high homogeneity level was observed. However, if myocardial cells were not parallel to each other, some leakage of the polarized light was observed, thus causing the decrease of the polarized light amplitude and homogeneity level. The greater the crossing angle between myocardial cells, the smaller the amplitude of the polarized light and the greater the inhomogeneity level. For two populations of myocardial cell crossing at an angle, the resulting azimuth angle of the voxel was the bisector of this angle. Moreover, the value of the inhomogeneity level began to decrease from a nonzero value when the voxel was not totally homogeneous, containing for example cell crossing. Conclusions: The proposed method enables the physical information of myocardial tissues to be estimated and the inhomogeneity level of a volume or voxel to be quantified, which opens new ways to study the microstructures of the human myocardium and helps understanding how heart diseases modify myocardial cells and change their mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2016

45. Effect of temperature on bending properties and failure mechanism of three-dimensional multiaxial warp-knitted carbon/epoxy composites.

Author

Li, Dian-sen, Zhao, Chuang-qi, Jiang, Nan, and Jiang, Lei

Subjects

*TEMPERATURE effect, *EPOXY compounds, *CRYSTAL morphology, *SCANNING electron microscopes, *FIBERS

Abstract

The three-point bending experiments on three-dimensional multiaxial warp-knitted carbon/epoxy composites with two fiber architectures are performed at room and elevated temperatures. Macro-fracture morphology and scanning electron microscopic micrographs are examined to understand the deformation and failure mechanism. The results show that the load–deflection curves are significantly different for different temperatures and the bending properties decrease significantly with increasing the temperature. Meanwhile, bending properties can be affected greatly by the fiber architecture and these increase significantly with the decrease of the fiber orientation angle at different temperatures. The results also show that the damage and failure patterns of composites vary with the test temperature. At room temperature, the composite exhibits brittle feature, and it damages with the breakage and tearing of fibers. At elevated temperature, the composite becomes more softened and exhibits plasticity. The damage of matrix plastic and cracking, interface debonding, and fiber layer delaminating become prominent. Moreover, the failure mechanism at room and elevated temperatures can be significantly affected by the fiber architecture. [ABSTRACT FROM AUTHOR]

Published

2016

46. Experimental study on the bending properties and failure mechanism of 3D multi-axial warp knitted composites at room and liquid nitrogen temperatures.

Author

Li, Dian-sen, Jiang, Nan, Jiang, Lei, and Lu, Na

Subjects

*WARP knitting, *SCANNING electron microscopes, *LIQUID nitrogen, *DEFORMATIONS (Mechanics), *CRYOGENICS

Abstract

Three-point bending experiments on 3D multi-axial warp knitted composites with four fiber architectures are performed at room and liquid nitrogen temperatures. Macro-fracture morphology and scanning electron microscope micrographs are examined to understand the deformation and failure mechanism. The results show that the load–deflection curves are significantly different for four types of composites and the bending properties decrease with the increase of fiber orientation angle at room and liquid nitrogen temperatures. Meanwhile, the bending properties at liquid nitrogen temperature have been improved significantly than that of at room temperature. Moreover, the damage and failure patterns of composites vary with the test temperature. At liquid nitrogen temperature, the interfacial adhesion strength is enhanced significantly and the brittle failure feature becomes more obvious. In addition, the failure mechanism at room and liquid nitrogen temperatures can be significantly affected by the fiber architecture. [ABSTRACT FROM AUTHOR]

Published

2016

47. Classification of Meniscal Tears Associated with Lesions of the Anterior Cruciate Ligament

Author

Müller, We., Jakob, R. P., editor, and Stäubli, H.-U., editor

Published

1990

48. Digital Design and Automated Fabrication of Bespoke Collagen Microfiber Scaffolds

Author

Kareen L.K. Coulombe, Rajeev J. Kant, Jessica Anna Bellows, and Nicholas J. Kaiser

Subjects

business.product_category, Materials science, Fabrication, Cell Survival, Induced Pluripotent Stem Cells, Biomedical Engineering, regenerative medicine, Medicine (miscellaneous), Bioengineering, Nanotechnology, Regenerative medicine, fiber architecture, Rats, Sprague-Dawley, Extracellular matrix, Automation, automated fabrication, Tensile Strength, Soft tissue engineering, Microfiber, Methods Article, Animals, Humans, Bespoke, mechanical anisotropy, Calorimetry, Differential Scanning, Tissue Engineering, Tissue Scaffolds, Natural polymers, Synthetic polymer, Cross-Linking Reagents, Anisotropy, Collagen, business, collagen scaffolds, biomaterials

Abstract

A great variety of natural and synthetic polymer materials have been utilized in soft tissue engineering as extracellular matrix (ECM) materials. Natural polymers, such as collagen and fibrin hydrogels, have experienced especially broad adoption due to the high density of cell adhesion sites compared to their synthetic counterparts, ready availability, and ease of use. However, these and other hydrogels lack the structural and mechanical anisotropy that define the ECM in many tissues, such as skeletal and cardiac muscle, tendon, and cartilage. Herein, we present a facile, low-cost, and automated method of preparing collagen microfibers, organizing these fibers into precisely controlled mesh designs, and embedding these meshes in a bulk hydrogel, creating a composite biomaterial suitable for a wide variety of tissue engineering and regenerative medicine applications. With the assistance of custom software tools described herein, mesh patterns are designed by a digital graphical user interface and translated into protocols that are executed by a custom mesh collection and organization device. We demonstrate a high degree of precision and reproducibility in both fiber and mesh fabrication, evaluate single fiber mechanical properties, and provide evidence of collagen self-assembly in the microfibers under standard cell culture conditions. This work offers a powerful, flexible platform for the study of tissue engineering and cell material interactions, as well as the development of therapeutic biomaterials in the form of custom collagen microfiber patterns that will be accessible to all through the methods and techniques described here. Impact Statement Collagen microfiber meshes have immediate and broad applications in tissue engineering research and show high potential for later use in clinical therapeutics due to their compositional similarities to native extracellular matrix and tunable structural and mechanical characteristics. Physical and biological characterizations of these meshes demonstrate physiologically relevant mechanical properties, native-like collagen structure, and cytocompatibility. The methods presented herein not only describe a process through which custom collagen microfiber meshes can be fabricated but also provide the reader with detailed device plans and software tools to produce their own bespoke meshes through a precise, consistent, and automated process.

Published

2019

49. A rule-based method for predicting the electrical activation of the heart with cardiac resynchronization therapy from non-invasive clinical data

Subjects

Cardiac resynchronization therapy, VENTRICULAR LEAD PLACEMENT, HISTOLOGICAL VALIDATION, PACING SITE, DIFFUSION TENSOR MRI, Patient-specific simulations, Electrophysiology, MODEL, FIBER ARCHITECTURE, TRABECULAR MUSCLE, Computational models, QRS DURATION, OPTIMIZATION, CONDUCTION-VELOCITY

Abstract

Background: Cardiac Resynchronization Therapy (CRT) is one of the few effective treatments for heart failure patients with ventricular dyssynchrony. The pacing location of the left ventricle is indicated as a determinant of CRT outcome. Objective: Patient specific computational models allow the activation pattern following CRT implant to be predicted and this may be used to optimize CRT lead placement. Methods: In this study, the effects of heterogeneous cardiac substrate (scar, fast endocardial conduction, slow septal conduction, functional block) on accurately predicting the electrical activation of the LV epicardium were tested to determine the minimal detail required to create a rule based model of cardiac electrophysiology. Non-invasive clinical data (CT or CMR images and 12 lead ECG) from eighteen patients from two centers were used to investigate the models. Results: Validation with invasive electro-anatomical mapping data identified that computer models with fast endocardial conduction were able to predict the electrical activation with a mean distance errors of 9.2 +/- 0.5 mm (CMR data) or (CT data) 7.5 +/- 0.7 mm. Conclusion: This study identified a simple rule-based fast endocardial conduction model, built using non-invasive clinical data that can be used to rapidly and robustly predict the electrical activation of the heart. Pre-procedural prediction of the latest electrically activating region to identify the optimal LV pacing site could potentially be a useful clinical planning tool for CRT procedures. (C) 2019 The Authors. Published by Elsevier B.V.

Published

2019

50. Experimental investigation of composite leaf spring reinforced with various fiber architecture

Author

Vikas Khatkar and B. K. Behera

Subjects

010302 applied physics, Materials science, business.industry, Mechanical Engineering, Composite number, Automotive industry, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Relaxation behavior, Mechanics of Materials, Energy absorption, Leaf spring, 0103 physical sciences, Ceramics and Composites, Fiber architecture, Composite material, 0210 nano-technology, business, Aerospace

Abstract

Fiber-reinforced composites are the materials of choice in numerous advanced applications in the fields such as automotive, aerospace, and marine as compared to conventional engineering materials. ...

Published

2019