Your search keyword '"VISCOELASTICITY"' showing total 40 results

1. Targeted fluorescence lifetime probes reveal responsive organelle viscosity and membrane fluidity.

Author

Steinmark, Ida Emilie, James, Arjuna L., Chung, Pei-Hua, Morton, Penny E., Parsons, Maddy, Dreiss, Cécile A., Lorenz, Christian D., Yahioglu, Gokhan, and Suhling, Klaus

Subjects

*VISCOUS flow, *PROPERTIES of fluids, *NEWTON'S law for fluids, *VISCOELASTICITY, *TRANSPORT theory

Abstract

The only way to visually observe cellular viscosity, which can greatly influence biological reactions and has been linked to several human diseases, is through viscosity imaging. Imaging cellular viscosity has allowed the mapping of viscosity in cells, and the next frontier is targeted viscosity imaging of organelles and their microenvironments. Here we present a fluorescent molecular rotor/FLIM framework to image both organellar viscosity and membrane fluidity, using a combination of chemical targeting and organelle extraction. For demonstration, we image matrix viscosity and membrane fluidity of mitochondria, which have been linked to human diseases, including Alzheimer’s Disease and Leigh’s syndrome. We find that both are highly dynamic and responsive to small environmental and physiological changes, even under non-pathological conditions. This shows that neither viscosity nor fluidity can be assumed to be fixed and underlines the need for single-cell, and now even single-organelle, imaging. [ABSTRACT FROM AUTHOR]

Published

2019

2. Viscoelastic parameters as discriminators of breast masses: Initial human study results.

Author

Kumar, Viksit, Denis, Max, Gregory, Adriana, Bayat, Mahdi, Mehrmohammadi, Mohammad, Fazzio, Robert, Fatemi, Mostafa, and Alizad, Azra

Subjects

*SHEAR waves, *ELASTOGRAPHY, *BREAST cancer diagnosis, *SOFT tissue tumors, *VISCOELASTICITY

Abstract

Shear wave elastography is emerging as a clinically valuable diagnostic tool to differentiate between benign and malignant breast masses. Elastography techniques assume that soft tissue can be modelled as a purely elastic medium. However, this assumption is often violated as soft tissue exhibits viscoelastic properties. In order to explore the role of viscoelastic parameters in suspicious breast masses, a study was conducted on a group of patients using shear wave dispersion ultrasound vibrometry in the frequency range of 50–400 Hz. A total of 43 female patients with suspicious breast masses were recruited before their scheduled biopsy. Of those, 15 patients did not meet the data selection criteria. Voigt model based shear elasticity showed a significantly (p = 7.88x10-6) higher median value for the 13 malignant masses (16.76±13.10 kPa) compared to 15 benign masses (1.40±1.12 kPa). Voigt model based shear viscosity was significantly different (p = 4.13x10-5) between malignant (8.22±3.36 Pa-s) and benign masses (2.83±1.47 Pa-s). Moreover, the estimated time constant from the Voigt model, which is dependent on both shear elasticity and viscosity, differed significantly (p = 6.13x10-5) between malignant (0.68±0.33 ms) and benign masses (3.05±1.95 ms). Results suggest that besides elasticity, viscosity based parameters like shear viscosity and time constant can also be used to differentiate between malignant and benign breast masses. [ABSTRACT FROM AUTHOR]

Published

2018

3. Transient viscous response of the human cornea probed with the Surface Force Apparatus.

Author

Zappone, Bruno, Patil, Navinkumar J., Lombardo, Marco, and Lombardo, Giuseppe

Subjects

*CORNEA diseases, *CORNEA surgery, *SURFACE forces, *VISCOELASTICITY, *ELASTIC modulus

Abstract

Knowledge of the biomechanical properties of the human cornea is crucial for understanding the development of corneal diseases and impact of surgical treatments (e.g., corneal laser surgery, corneal cross-linking). Using a Surface Force Apparatus we investigated the transient viscous response of the anterior cornea from donor human eyes compressed between macroscopic crossed cylinders. Corneal biomechanics was analyzed using linear viscoelastic theory and interpreted in the framework of a biphasic model of soft hydrated porous tissues, including a significant contribution from the pressurization and viscous flow of fluid within the corneal tissue. Time-resolved measurements of tissue deformation and careful determination of the relaxation time provided an elastic modulus in the range between 0.17 and 1.43 MPa, and fluid permeability of the order of 10−13 m4/(N∙s). The permeability decreased as the deformation was increased above a strain level of about 10%, indicating that the interstitial space between fibrils of the corneal stromal matrix was reduced under the effect of strong compression. This effect may play a major role in determining the observed rate-dependent non-linear stress-strain response of the anterior cornea, which underlies the shape and optical properties of the tissue. [ABSTRACT FROM AUTHOR]

Published

2018

4. Cardinal features of involuntary force variability can arise from the closed-loop control of viscoelastic afferented muscles.

Author

Nagamori, Akira, Laine, Christopher M., and Valero-Cuevas, Francisco J.

Subjects

*BIOMECHANICS, *CLOSED loop systems, *VISCOELASTICITY, *MUSCULOSKELETAL system, *PROPRIOCEPTION, *NERVOUS system

Abstract

Involuntary force variability below 15 Hz arises from, and is influenced by, many factors including descending neural drive, proprioceptive feedback, and mechanical properties of muscles and tendons. However, their potential interactions that give rise to the well-structured spectrum of involuntary force variability are not well understood due to a lack of experimental techniques. Here, we investigated the generation, modulation, and interactions among different sources of force variability using a physiologically-grounded closed-loop simulation of an afferented muscle model. The closed-loop simulation included a musculotendon model, muscle spindle, Golgi tendon organ (GTO), and a tracking controller which enabled target-guided force tracking. We demonstrate that closed-loop control of an afferented musculotendon suffices to replicate and explain surprisingly many cardinal features of involuntary force variability. Specifically, we present 1) a potential origin of low-frequency force variability associated with co-modulation of motor unit firing rates (i.e.,‘common drive’), 2) an in-depth characterization of how proprioceptive feedback pathways suffice to generate 5-12 Hz physiological tremor, and 3) evidence that modulation of those feedback pathways (i.e., presynaptic inhibition of Ia and Ib afferents, and spindle sensitivity via fusimotor drive) influence the full spectrum of force variability. These results highlight the previously underestimated importance of closed-loop neuromechanical interactions in explaining involuntary force variability during voluntary ‘isometric’ force control. Furthermore, these results provide the basis for a unifying theory that relates spinal circuitry to various manifestations of altered involuntary force variability in fatigue, aging and neurological disease. [ABSTRACT FROM AUTHOR]

Published

2018

5. Evaluating the Significance of Viscoelasticity in Diagnosing Early-Stage Liver Fibrosis with Transient Elastography.

Author

Zhao, Jingxin, Zhai, Fei, Cheng, Jun, He, Qiong, Luo, Jianwen, Yang, Xueping, Shao, Jinhua, and Xing, Huichun

Subjects

*VISCOELASTICITY, *FIBROSIS, *LIVER biopsy, *ELASTOGRAPHY, *SHEAR waves, *DIAGNOSIS

Abstract

Transient elastography quantifies the propagation of a mechanically generated shear wave within a soft tissue, which can be used to characterize the elasticity and viscosity parameters of the tissue. The aim of our study was to combine numerical simulation and clinical assessment to define a viscoelastic index of liver tissue to improve the quality of early diagnosis of liver fibrosis. This is clinically relevant, as early fibrosis is reversible. We developed an idealized two-dimensional axisymmetric finite element model of the liver to evaluate the effects of different viscoelastic values on the propagation characteristics of the shear wave. The diagnostic value of the identified viscoelastic index was verified against the clinical data of 99 patients who had undergone biopsy and routine blood tests for staging of liver disease resulting from chronic hepatitis B infection. Liver stiffness measurement (LSM) and the shear wave attenuation fitting coefficient (AFC) were calculated from the ultrasound data obtained by performing transient elastography. Receiver operating curve analysis was used to evaluate the reliability and diagnostic accuracy of LSM and AFC. Compared to LSM, the AFC provided a higher diagnostic accuracy to differentiate early stages of liver fibrosis, namely F1 and F2 stages, with an overall specificity of 81.48%, sensitivity of 83.33% and diagnostic accuracy of 81.82%. AFC was influenced by the level of LSM, ALT. However, there are no correlation between AFC and Age, BMI, TBIL or DBIL. Quantification of the viscoelasticity of liver tissue provides reliable measurement to identify and differentiate early stages of liver fibrosis. [ABSTRACT FROM AUTHOR]

Published

2017

6. Fabrication of Artificial Food Bolus for Evaluation of Swallowing.

Author

Hosotsubo, Miyu, Magota, Tetsuro, Egusa, Masahiko, Miyawaki, Takuya, and Matsumoto, Takuya

Subjects

*MASTICATION disorders, *ARTIFICIAL foods, *GELATIN, *MICROFABRICATION, *VISCOELASTICITY, *THERAPEUTICS

Abstract

Simple and easy methods to evaluate swallowing are required because of the recently increased need of rehabilitation for dysphagia. "Artificial food bolus", but not "artificial food", would be a valuable tool for swallowing evaluation without considering the mastication effect which is altered according to the individual's oral condition. Thus, this study was carried out to fabricate artificial bolus resembling natural food bolus. The mechanical property and the volume change of food bolus in normal people were firstly investigated. Thirty healthy adults without dysphagia were selected and asked to chew four sample foods (rice cake, peanut, burdock, and gummy candy). The results indicated that Young’s modulus of bolus before swallowing was below 150 kPa. The bolus volume before swallowing was below 400 mm3. In addition, the saliva component ratio of each bolus was approximately 30wt%, and the average saliva viscosity of research participants was approximately 10 mPa•s. Based on the obtained data, artificial food bolus was designed and fabricated by using alginate hydrogel as a visco-elastic material and gelatin solution as a viscotic material with a ratio of 7:3 based on weight. Consequently, the swallowing time of fabricated artificial food bolus was measured among the same participants. The results indicated the participants swallowed fabricated food bolus with similar manner reflecting their mechanical property and volume. Thus, this artificial food bolus would be a promising tool for evaluation of swallowing. [ABSTRACT FROM AUTHOR]

Published

2016

7. Stress generation, relaxation and size control in confined tumor growth

Author

Huaming Yan, Daniel Ramirez-Guerrero, John Lowengrub, and Min Wu

Subjects

01 natural sciences, 0302 clinical medicine, Neoplasms, Tumor Cells, Cultured, Stress relaxation, Medicine and Health Sciences, Cell Cycle and Cell Division, Biology (General), Anisotropy, 0303 health sciences, Ecology, Physics, Compression, Stiffness, Classical Mechanics, Mechanics, Biomechanical Phenomena, Computational Theory and Mathematics, Oncology, Cell Processes, Modeling and Simulation, Physical Sciences, Mechanical Stress, medicine.symptom, Research Article, Materials science, QH301-705.5, Materials Science, Material Properties, Geometry, Viscoelasticity, Stress (mechanics), Cellular and Molecular Neuroscience, 03 medical and health sciences, Malignant Tumors, Position (vector), Cell Line, Tumor, Spheroids, Cellular, 0103 physical sciences, Genetics, medicine, Tumor Expansion, Humans, 010306 general physics, Molecular Biology, Relaxation (Physics), Ecology, Evolution, Behavior and Systematics, Cell Proliferation, 030304 developmental biology, Computational Biology, Cancers and Neoplasms, Biology and Life Sciences, Cell Biology, Elasticity, Radii, Relaxation (physics), Stress, Mechanical, 030217 neurology & neurosurgery, Mathematics

Abstract

Experiments on tumor spheroids have shown that compressive stress from their environment can reversibly decrease tumor expansion rates and final sizes. Stress release experiments show that nonuniform anisotropic elastic stresses can be distributed throughout. The elastic stresses are maintained by structural proteins and adhesive molecules, and can be actively relaxed by a variety of biophysical processes. In this paper, we present a new continuum model to investigate how the growth-induced elastic stresses and active stress relaxation, in conjunction with cell size control feedback machinery, regulate the cell density and stress distributions within growing tumors as well as the tumor sizes in the presence of external physical confinement and gradients of growth-promoting chemical fields. We introduce an adaptive reference map that relates the current position with the reference position but adapts to the current position in the Eulerian frame (lab coordinates) via relaxation. This type of stress relaxation is similar to but simpler than the classical Maxwell model of viscoelasticity in its formulation. By fitting the model to experimental data from two independent studies of tumor spheroid growth and their cell density distributions, treating the tumors as incompressible, neo-Hookean elastic materials, we find that the rates of stress relaxation of tumor tissues can be comparable to volumetric growth rates. Our study provides insight on how the biophysical properties of the tumor and host microenvironment, mechanical feedback control and diffusion-limited differential growth act in concert to regulate spatial patterns of stress and growth. When the tumor is stiffer than the host, our model predicts tumors are more able to change their size and mechanical state autonomously, which may help to explain why increased tumor stiffness is an established hallmark of malignant tumors., Author summary The mechanical state of cells can modulate their growth and division dynamics via mechanotransduction, which affects both the cell size distribution and the tissue size as a whole. Experiments on tumor spheroids have shown that compressive stress from their environment can reversibly decrease tumor expansion rates and final sizes. Besides external confinement and compression on the tumor border, a heterogeneous stress field can be generated inside the tumor by nutrient-driven differential growth. Such growth-induced mechanical stresses can be relaxed by tissue rearrangement, which happens during cell neighbor exchanges, cell divisions, and extracellular matrix renewal. In this study, we have developed a continuum model that describes the above mechanical interactions and the dynamics of tissue rearrangement explicitly. Motivated by published experimental data, we consider mechanotransduction where the local compressive stress slows down cell growth and cell size reduction limits cell division. We have analyzed how external mechanical stimuli and internal processes influence the outcome of cell-and-tissue sizes and spatial patterns of cell density and mechanical stress in growing tumors.

Published

2021

8. Numerical and Analytical Study of Two-Layered Unsteady Blood Flow through Catheterized Artery.

Author

Zaman, Akbar, Ali, Nasir, Sajid, M., and Hayat, Tasawar

Subjects

*BLOOD flow, *NON-Newtonian fluids, *VISCOELASTICITY, *LAPLACE transformation, *NUMERICAL analysis

Abstract

The pulsatile flow of blood in a catheterized blood vessel is analyzed. The flow of blood in vessel is modeled as the flow of two immiscible fluids. The fluid in the core region is characterized as a non-Newtonian viscoelastic fluid satisfying the constitutive equation of an Oldroyd-B fluid. The fluid in the peripheral region is treated as a Newtonian fluid. The catheter inside the vessel is modeled as a rigid tube of very small radius. The resulting differential system for velocity in each region is computed numerically by finite-difference scheme and analytically by Laplace transform. A comparison of numerical solution with Laplace transform solution is carried out. Various physical quantities of interest through the computed velocity are also analyzed. [ABSTRACT FROM AUTHOR]

Published

2016

9. Functional Properties of Glutinous Rice Flour by Dry-Heat Treatment.

Author

Qin, Yang, Liu, Chengzhen, Jiang, Suisui, Cao, Jinmiao, Xiong, Liu, and Sun, Qingjie

Subjects

*RICE starch, *HEAT treatment, *FOOD industry, *VISCOELASTICITY, *ENDOTHERMIC reactions

Abstract

Glutinous rice flour (GRF) and glutinous rice starch (GRS) were modified by dry-heat treatment and their rheological, thermal properties and freeze-thaw stability were evaluated. Compared with the native GRF and GRS, the water-holding ability of modified GRF and GRS were enhanced. Both the onset and peak temperatures of the modified samples increased while the endothermic enthalpy change decreased significantly (p < 0.05). Meanwhile, dry heating remarkably increased the apparent viscosities of both GRF and GRS. Importantly, compared with GRS samples, the storage modulus (G') and loss modulus (G") values of modified GRF increased more greatly and the tanδ values decreased more remarkably, indicating that the dry-heat treatment showed more impact on the GRF and a higher viscoelasticity compared with GRS. Our results suggest the dry-heat treatment of GRF is a more effective method than that of GRS, which omits the complex and tedious process for purifying GRS, and thereby has more practical applications in the food industry. [ABSTRACT FROM AUTHOR]

Published

2016

10. Dopaminergic Neurodegeneration in the Mouse Is Associated with Decrease of Viscoelasticity of Substantia Nigra Tissue.

Author

Hain, Elisabeth G., Klein, Charlotte, Munder, Tonia, Braun, Juergen, Riek, Kerstin, Mueller, Susanne, Sack, Ingolf, and Steiner, Barbara

Subjects

*NEURODEGENERATION, *DOPAMINERGIC neurons, *VISCOELASTICITY, *SUBSTANTIA nigra, *TISSUE mechanics, *HISTOPATHOLOGY, *LABORATORY mice

Abstract

The biomechanical properties of brain tissue are altered by histopathological changes due to neurodegenerative diseases like Parkinson's disease (PD). Such alterations can be measured by magnetic resonance elastography (MRE) as a non-invasive technique to determine viscoelastic parameters of the brain. Until now, the correlation between histopathological mechanisms and observed alterations in tissue viscoelasticity in neurodegenerative diseases is still not completely understood. Thus, the objective of this study was to evaluate (1) the validity of MRE to detect viscoelastic changes in small and specific brain regions: the substantia nigra (SN), midbrain and hippocampus in a mouse model of PD, and (2) if the induced dopaminergic neurodegeneration and inflammation in the SN is reflected by local changes in viscoelasticity. Therefore, MRE measurements of the SN, midbrain and hippocampus were performed in adult female mice before and at five time points after 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridin hydrochloride (MPTP) treatment specifically lesioning dopaminergic neurons in the SN. At each time point, additional mice were utilized for histological analysis of the SN. After treatment cessation, we observed opposed viscoelastic changes in the midbrain, hippocampus and SN with the midbrain showing a gradual rise and the hippocampus a distinct transient increase of viscous and elastic parameters, while viscosity and–to a lesser extent—elasticity in the SN decreased over time. The decrease in viscosity and elasticity in the SN was paralleled by a reduced number of neurons due to the MPTP-induced neurodegeneration. In conclusion, MRE is highly sensitive to detect local viscoelastic changes in specific and even small brain regions. Moreover, we confirmed that neuronal cells likely constitute the backbone of the adult brain mainly accounting for its viscoelasticity. Therefore, MRE could be established as a new potential instrument for clinical evaluation and diagnostics of neurodegenerative diseases. [ABSTRACT FROM AUTHOR]

Published

2016

11. Platelet Rich Plasma and Hyaluronic Acid Blend for the Treatment of Osteoarthritis: Rheological and Biological Evaluation.

Author

Russo, Fabrizio, D’Este, Matteo, Vadalà, Gianluca, Cattani, Caterina, Papalia, Rocco, Alini, Mauro, and Denaro, Vincenzo

Subjects

*HYALURONIC acid, *OSTEOARTHRITIS treatment, *ECOLOGICAL assessment, *CARTILAGE, *VISCOELASTICITY

Abstract

Introduction: Osteoarthritis (OA) is the most common musculoskeletal disease. Current treatments for OA are mainly symptomatic and inadequate since none results in restoration of fully functional cartilage. Hyaluronic Acid (HA) intra-articular injections are widely accepted for the treatment of pain associated to OA. The goal of HA viscosupplementation is to reduce pain and improve viscoelasticity of synovial fluid. Platelet-rich plasma (PRP) has been also employed to treat OA to possibly induce cartilage regeneration. The combination of HA and PRP could supply many advantages for tissue repair. Indeed, it conjugates HA viscosupplementation with PRP regenerative properties. The aim of this study was to evaluate the rheological and biological properties of different HA compositions in combination with PRP in order to identify (i) the viscoelastic features of the HA-PRP blends, (ii) their biological effect on osteoarthritic chondrocytes and (iii) HA formulations suitable for use in combination with PRP. Materials and Methods: HA/PRP blends have been obtained mixing human PRP and three different HA at different concentrations: 1) Sinovial, 0.8% (SN); 2) Sinovial Forte 1.6% (SF); 3) Sinovial HL 3.2% (HL); 4) Hyalubrix 1.5% (HX). Combinations of phosphate buffered saline (PBS) and the four HA types were used as control. Rheological measurements were performed on an Anton PaarMCR-302 rheometer. Amplitude sweep, frequency sweep and rotational measurements were performed and viscoelastic properties were evaluated. The rheological data were validated performing the tests in presence of Bovine Serum Albumin (BSA) up to ultra-physiological concentration (7%). Primary osteoarthritic chondrocytes were cultured in vitro with the HA and PRP blends in the culture medium for one week. Cell viability, proliferation and glycosaminoglycan (GAG) content were assessed. Results: PRP addition to HA leads to a decrease of viscoelastic shear moduli and increase of the crossover point, due to a pure dilution effect. For viscosupplements with HA concentration below 1% the viscoelasticity is mostly lost. Results were validated also in presence of proteins, which in synovial fluid are more abundant than HA. Chondrocytes proliferated overtime in all different culture conditions. The proliferation rate was higher in chondrocytes cultured in the media containing PRP compared to the cultures with different HA alone. GAG content was significantly higher in chondrocytes cultured in PRP and HL blend. Discussion: We investigated the rheological and biological properties of four different HA concentrations when combined with PRP giving insights on viscoelastic and biological properties of a promising approach for future OA therapy. Our data demonstrate that PRP addition is not detrimental to the viscosupplementation effect of HA. Viscosupplements containing low HA concentration are not indicated for combination with PRP, as the viscoelastic properties are lost. Although having the same rheological behavior of SF and HX, HL was superior in stimulating extracellular matrix production in vitro. [ABSTRACT FROM AUTHOR]

Published

2016

12. Influence of Age on Ocular Biomechanical Properties in a Canine Glaucoma Model with ADAMTS10 Mutation.

Author

Palko, Joel R., Morris, Hugh J., Pan, Xueliang, Harman, Christine D., Koehl, Kristin L., Gelatt, Kirk N., Plummer, Caryn E., Komáromy, András M., and Liu, Jun

Subjects

*GLAUCOMA, *CANIDAE, *BIOMECHANICS, *GENETIC mutation, *DISEASES in older people, *EXTRACELLULAR matrix, *VISCOELASTICITY, *GENETICS, *DISEASES

Abstract

Soft tissue often displays marked age-associated stiffening. This study aims to investigate how age affects scleral biomechanical properties in a canine glaucoma model with ADAMTS10 mutation, whose extracellular matrix is concomitantly influenced by the mutation and an increased mechanical load from an early age. Biomechanical data was acquired from ADAMTS10-mutant dogs (n = 10, 21 to 131 months) and normal dogs (n = 5, 69 to 113 months). Infusion testing was first performed in the whole globes to measure ocular rigidity. After infusion experiments, the corneas were immediately trephined to prepare scleral shells that were mounted on a pressurization chamber to measure strains in the posterior sclera using an inflation testing protocol. Dynamic viscoelastic mechanical testing was then performed on dissected posterior scleral strips and the data were combined with those reported earlier by our group from the same animal model (Palko et al, IOVS 2013). The association between age and scleral biomechanical properties was evaluated using multivariate linear regression. The relationships between scleral properties and the mean and last measured intraocular pressure (IOP) were also evaluated. Our results showed that age was positively associated with complex modulus (p<0.001) and negatively associated with loss tangent (p<0.001) in both the affected and the normal groups, suggesting an increased stiffness and decreased mechanical damping with age. The regression slopes were not different between the groups, although the complex modulus was significantly lower in the affected group (p = 0.041). The posterior circumferential tangential strain was negatively correlated with complex modulus (R = -0.744, p = 0.006) showing consistent mechanical evaluation between the testing methods. Normalized ocular rigidity was negatively correlated with the last IOP in the affected group (p = 0.003). Despite a mutation that affects the extracellular matrix and a chronic IOP elevation in the affected dogs, age-associated scleral stiffening and loss of mechanical damping were still prominent and had a similar rate of change as in the normal dogs. [ABSTRACT FROM AUTHOR]

Published

2016

13. Evidence for ACTN3 as a Speed Gene in Isolated Human Muscle Fibers.

Author

Broos, Siacia, Malisoux, Laurent, Theisen, Daniel, van Thienen, Ruud, Ramaekers, Monique, Jamart, Cécile, Deldicque, Louise, Thomis, Martine A., and Francaux, Marc

Subjects

*MUSCLE contraction, *ACTININ, *HOMOZYGOSITY, *VISCOELASTICITY, *CROSS-sectional method, *IMMUNOHISTOCHEMISTRY

Abstract

Purpose: To examine the effect of α-actinin-3 deficiency due to homozygosity for the ACTN3 577X-allele on contractile and morphological properties of fast muscle fibers in non-athletic young men. Methods: A biopsy was taken from the vastus lateralis of 4 RR and 4 XX individuals to test for differences in morphologic and contractile properties of single muscle fibers. The cross-sectional area of the fiber and muscle fiber composition was determined using standard immunohistochemistry analyses. Skinned single muscle fibers were subjected to active tests to determine peak normalized force (P0), maximal unloading velocity (V0) and peak power. A passive stretch test was performed to calculate Young’s Modulus and hysteresis to assess fiber visco-elasticity. Results: No differences were found in muscle fiber composition. The cross-sectional area of type IIa and IIx fibers was larger in RR compared to XX individuals (P<0.001). P0 was similar in both groups over all fiber types. A higher V0 was observed in type IIa fibers of RR genotypes (P<0.001) but not in type I fibers. The visco-elasticity as determined by Young’s Modulus and hysteresis was unaffected by fiber type or genotype. Conclusion: The greater V0 and the larger fast fiber CSA in RR compared to XX genotypes likely contribute to enhanced whole muscle performance during high velocity contractions. [ABSTRACT FROM AUTHOR]

Published

2016

14. Supramolecular dynamic binary complexes with pH and salt-responsive properties for use in unconventional reservoirs

Author

Yu-Ting Lin, Shuhao Liu, Martin L. Sentmanat, Mustafa Akbulut, Bhargavi Bhat, and Joseph Sang-Il Kwon

Subjects

Salinity, Marine and Aquatic Sciences, Sodium Chloride, Physical Chemistry, Biochemistry, Extraction and Processing Industry, Viscosity, chemistry.chemical_compound, Hydraulic fracturing, Materials Physics, Polyamines, Medicine and Health Sciences, Oil and Gas Fields, Fluids, Multidisciplinary, Aqueous solution, Hydraulic Fracking, Physics, Fatty Acids, dBc, Viscoelasticity, Hydrogen-Ion Concentration, Lipids, Shear (sheet metal), Chemistry, Diethylenetriamine, Physical Sciences, Medicine, Rheology, Research Article, States of Matter, Materials science, Science, Materials Science, Material Properties, Supramolecular chemistry, Natural Gas, Settling, Sea Water, Nutrition, Ecology and Environmental Sciences, Chemical Compounds, Biology and Life Sciences, Aquatic Environments, Marine Environments, Diet, chemistry, Chemical engineering, Chemical Properties, Earth Sciences, Salts, Oleic Acid

Abstract

Hydraulic fracturing of unconventional reservoirs has seen a boom in the last century, as a means to fulfill the growing energy demand in the world. The fracturing fluid used in the process plays a substantial role in determining the results. Hence, several research and development efforts have been geared towards developing more sustainable, efficient, and improved fracturing fluids. Herein, we present a dynamic binary complex (DBC) solution, with potential to be useful in the hydraulic fracturing domain. It has a supramolecular structure formed by the self-assembly of low molecular weight viscosifiers (LMWVs) oleic acid and diethylenetriamine into an elongated entangled network under alkaline conditions. With less than 2 wt% constituents dispersed in aqueous solution, a viscous gel that exhibits high viscosities even under shear was formed. Key features include responsiveness to pH and salinity, and a zero-shear viscosity that could be tuned by a factor of ~280 by changing the pH. Furthermore, its viscous properties were more pronounced in the presence of salt. Sand settling tests revealed its potential to hold up sand particles for extended periods of time. In conclusion, this DBC solution system has potential to be utilized as a smart salt-responsive, pH-switchable hydraulic fracturing fluid.

Published

2021

15. Impairment in facial expression generation in patients with repaired unilateral cleft lip: Effects of the physical properties of facial soft tissues

Author

Takashi Yamashiro, Donghoon Lee, and Chihiro Tanikawa

Subjects

Male, Muscle Physiology, Physiology, Lower lip, Cleft Lip and Palate, Epithelium, 0302 clinical medicine, Medical Conditions, Medicine and Health Sciences, Morphogenesis, Medicine, Biomechanics, 030212 general & internal medicine, Orthodontics, Measurement, Multidisciplinary, Physics, Scars, Soft tissue, Treatment options, Viscoelasticity, Surface displacement, Cleft Palate, Facial Expression, Physical Sciences, Engineering and Technology, Female, Anatomy, Anatomic Landmarks, Research Article, Adult, Soft Tissues, Adolescent, Facial motion, Science, Cleft Lip, Materials Science, Material Properties, 03 medical and health sciences, Young Adult, Imaging, Three-Dimensional, Congenital Disorders, Humans, Displacement (orthopedic surgery), In patient, Birth Defects, Facial expression, business.industry, Biology and Life Sciences, 030206 dentistry, Physical Properties, stomatognathic diseases, Biological Tissue, Otorhinolaryngology, Facial Asymmetry, Face, Case-Control Studies, business, Musculoskeletal Mechanics, Head, Developmental Biology

Abstract

Patients with repaired unilateral cleft lip with palate (UCLP) often show dysmorphology and distorted facial motion clinically, which can cause psychological issues. However, no report has clarified the details concerning distorted facial motion and the corresponding possible causative factors. In this study, we hypothesized that the physical properties of the scar and surrounding facial soft tissue might affect facial displacement while smiling in patients with UCLP (Cleft group). We thus examined the three-dimensional (3D) facial displacement while smiling in the Cleft and Control groups in order to determine whether or not the physical properties of facial soft tissues differ between the Cleft and Control groups and to examine the relationship between the physical properties of facial soft tissues on 3D facial displacement while smiling. Three-dimensional images at rest and while smiling as well as the facial physical properties (e.g. viscoelasticity) of both groups were recorded. Differences in terms of physical properties and facial displacement while smiling between the two groups were examined. To examine the relationship between facial surface displacement while smiling and physical properties, a canonical correlation analysis (CCA) was conducted. As a result, three typical abnormal features of smiling in the Cleft group compared with the Control group were noted: less upward and backward displacement on the scar area, downward movement of the lower lip, and a greater asymmetric displacement, including greater lateral displacement of the subalar on the cleft side while smiling and greater alar backward displacement on the non-cleft side. The Cleft group also showed greater elastic modulus at the upper lip on the cleft side, suggesting hardened soft tissue at the scar. The CCA showed that this hard scar significantly affected facial displacement, inducing less upward and backward displacement on the scar area and downward movement of the lower lip in patients with UCLP (correlation coefficient = 0.82, p = 0.04); however, there was no significant relationship between greater nasal alar lateral movement and physical properties of the skin at the scar. Based on these results, personalizing treatment options for dysfunction in facial expression generation may require quantification of the 3D facial morphology and physical properties of facial soft tissues.

Published

2021

16. Impact of axisymmetric deformation on MR elastography of a nonlinear tissue-mimicking material and implications in peri-tumour stiffness quantification

Author

Myrianthi Hadjicharalambous, Marco Fiorito, Jack Lee, Ralph Sinkus, Daniel Fovargue, Adela Capilnasiu, David Nordsletten, King‘s College London, Laboratoire de Recherche Vasculaire Translationnelle (LVTS (UMR_S_1148 / U1148)), Institut National de la Santé et de la Recherche Médicale (INSERM)-Université de Paris (UP)-Université Sorbonne Paris Nord, Ralph, Sinkus, and Institut National de la Santé et de la Recherche Médicale (INSERM)-Université Paris Cité (UPCité)-Université Sorbonne Paris Nord

Subjects

Shear waves, [SDV.IB.IMA]Life Sciences [q-bio]/Bioengineering/Imaging, Physics::Medical Physics, 030218 nuclear medicine & medical imaging, Quantitative Biology::Cell Behavior, 0302 clinical medicine, Biomimetic Materials, [SPI.MECA.BIOM] Engineering Sciences [physics]/Mechanics [physics.med-ph]/Biomechanics [physics.med-ph], Neoplasms, Breast Tumors, Medicine and Health Sciences, Multidisciplinary, medicine.diagnostic_test, Phantoms, Imaging, Physics, Stiffness, Classical Mechanics, [SPI.MECA.BIOM]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Biomechanics [physics.med-ph], Viscoelasticity, Mechanics, Magnetic Resonance Imaging, Deformation, Oncology, Physical Sciences, Elasticity Imaging Techniques, Medicine, Elastography, medicine.symptom, Deformation (engineering), Anatomy, Research Article, Materials science, Soft Tissues, Quantitative Biology::Tissues and Organs, Science, Materials Science, Material Properties, [SDV.CAN]Life Sciences [q-bio]/Cancer, Shear modulus, 03 medical and health sciences, [SDV.CAN] Life Sciences [q-bio]/Cancer, Breast Cancer, medicine, Humans, Damage Mechanics, Cancers and Neoplasms, Biology and Life Sciences, Elasticity (physics), Elasticity, [SDV.IB.IMA] Life Sciences [q-bio]/Bioengineering/Imaging, Biological Tissue, Hyperelastic material, Waves, Anisotropy, Stress, Mechanical, Wave Propagation, 030217 neurology & neurosurgery

Abstract

International audience; Solid tumour growth is often associated with the accumulation of mechanical stresses acting on the surrounding host tissue. Due to tissue nonlinearity, the shear modulus of the peri-tumoural region inherits a signature from the tumour expansion which depends on multiple factors, including the soft tissue constitutive behaviour and its stress/strain state. Shear waves used in MR-elastography (MRE) sense the apparent change in shear modulus along their propagation direction, thereby probing the anisotropic stiffness field around the tumour. We developed an analytical framework for a heterogeneous shear modulus distribution using a thick-shelled sphere approximation of the tumour and soft tissue ensemble. A hyperelastic material (plastisol) was identified to validate the proposed theory in a phantom setting. A balloon-catheter connected to a pressure sensor was used to replicate the stress generated from tumour pressure and growth while MRE data were acquired. The shear modulus anisotropy retrieved from the reconstructed elastography data confirmed the analytically predicted patterns at various levels of inflation. An alternative measure, combining the generated deformation and the local wave direction and independent of the reconstruction strategy, was also proposed to correlate the analytical findings with the stretch probed by the waves. Overall, this work demonstrates that MRE in combination with non-linear mechanics, is able to identify the apparent shear modulus variation arising from the strain generated by a growth within tissue, such as an idealised model of tumour. Investigation in real tissue represents the next step to further investigate the implications of endogenous forces in tissue characterisation through MRE

Published

2021

17. Longitudinal stability of a multimodal visco-elastic polyacrylamide gel phantom for magnetic resonance and ultrasound shear-wave elastography

Author

Eika Hotta, Mikio Suga, Jeff Kershaw, Masashi Usumura, Riwa Kishimoto, Koki Ishii, Tatsuya Higashi, and Takayuki Obata

Subjects

Glycerol, Polymers, Acrylic Resins, Biochemistry, Stiffness, Polymerization, 030218 nuclear medicine & medical imaging, 0302 clinical medicine, Medicine and Health Sciences, Longitudinal Studies, Magnetic Resonance, Materials, Multidisciplinary, medicine.diagnostic_test, Phantoms, Imaging, Viscosity, Liver Diseases, Physics, Monomers, Ultrasound, Magnetism, Chemical Reactions, Viscoelasticity, Condensed Matter Physics, Magnetic Resonance Imaging, Chemistry, Macromolecules, 030220 oncology & carcinogenesis, Physical Sciences, Elasticity Imaging Techniques, Liver Fibrosis, Medicine, Elastography, Polyacrylamides, Research Article, Materials science, Science, Materials Science, Material Properties, Gastroenterology and Hepatology, Imaging phantom, 03 medical and health sciences, medicine, Mechanical Properties, Shear wave elastography, business.industry, Longitudinal static stability, Biology and Life Sciences, Magnetic resonance imaging, Polymer Chemistry, Elasticity, Magnetic resonance elastography, business, Gels, Biomarkers, Biomedical engineering

Abstract

We evaluated the long-term stability of a newly developed viscoelastic phantom made of polyacrylamide (PAAm) gel for magnetic resonance elastography (MRE) and ultrasound-based shear-wave elastography (US SWE). The stiffness of the cylindrical phantom was measured at 0, 13 and 18 months. Storage and loss moduli were measured with MRE, and shear-wave speed (SWS) was measured with US SWE. Long-term stability was evaluated in accordance with the Quantitative Imaging Biomarker Alliance (QIBA) profiles for each modality. The initial storage and loss moduli of the phantom were 5.01±0.22 and 1.11±0.15 respectively, and SWS was 2.57±0.04 m/s. The weight of the phantom decreased by 0.6% over the 18 months. When measured with MRE, the stiffness of the phantom decreased and changes to the storage and loss moduli were -3.0% and -4.6% between 0 and 13 months, and -4.3% and 0.0% between 0 and 18 months. The US measurements found that SWS decreased by 2.4% over the first 13 months and 3.6% at 18 months. These changes were smaller than the tolerances specified in the QIBA profiles, so the viscoelastic PAAm gel phantom fulfilled the condition for long-term stability. This new phantom has the potential to be used as a quality assurance and quality control phantom for MRE and US SWE.

Published

2021

18. Finite element analysis of the performance of additively manufactured scaffolds for scapholunate ligament reconstruction

Author

David Lloyd, Maria Gomez Cerezo, Kevin M. Moerman, Jayishni N. Maharaj, Randy Bindra, Nataliya Perevoshchikova, Bardiya Akhbari, David J. Saxby, Cedryck Vaquette, and Amelia Carr

Subjects

Wrist Joint, Scaffold, Critical Care and Emergency Medicine, Kinematics, bepress|Engineering, Electronics engineering, Engineering and technology, Wrist, Medicine and Health Sciences, Orthopedic Procedures, Lunate Bone, Trauma Medicine, Fixation (histology), Multidisciplinary, engrXiv|Engineering|Biomedical Engineering and Bioengineering, Applied Mathematics, Physics, bepress|Engineering|Biomedical Engineering and Bioengineering|Biomechanics and Biotransport, Classical Mechanics, Viscoelasticity, 3D printing, Scapholunate ligament, Tendon, Biomechanical Phenomena, Arms, medicine.anatomical_structure, engrXiv|Engineering, Terminal (electronics), Connective Tissue, Bone Fracture, Ligaments, Articular, Physical Sciences, Ligament, Medicine, Anatomy, Traumatic Injury, Research Article, Optimization, Materials science, Movement, Science, Finite Element Analysis, Materials Science, Material Properties, bepress|Engineering|Biomedical Engineering and Bioengineering, Models, Biological, medicine, Humans, Scaphoid Bone, Ligaments, engrXiv|Engineering|Biomedical Engineering and Bioengineering|Biomechanics and Biotransport, Biology and Life Sciences, Bone fracture, Plastic Surgery Procedures, medicine.disease, Biological Tissue, Body Limbs, Mathematics, Biomedical engineering

Abstract

Rupture of the scapholunate interosseous ligament can cause the dissociation of scaphoid and lunate bones, resulting in impaired wrist function. Current treatments (e.g., tendon-based surgical reconstruction, screw-based fixation, fusion, or carpectomy) may restore wrist stability, but do not address regeneration of the ruptured ligament, and may result in wrist functional limitations and osteoarthritis. Recently a novel multiphasic bone-ligament-bone scaffold was proposed, which aims to reconstruct the ruptured ligament, and which can be 3D-printed using medical-grade polycaprolactone. This scaffold is composed of a central ligament-scaffold section and features a bone attachment terminal at either end. Since the ligament-scaffold is the primary load bearing structure during physiological wrist motion, its geometry, mechanical properties, and the surgical placement of the scaffold are critical for performance optimisation. This study presents a patient-specific computational biomechanical evaluation of the effect of scaffold length, and positioning of the bone attachment sites. Through segmentation and image processing of medical image data for natural wrist motion, detailed 3D geometries as well as patient-specific physiological wrist motion could be derived. This data formed the input for detailed finite element analysis, enabling computational of scaffold stress and strain distributions, which are key predictors of scaffold structural integrity. The computational analysis demonstrated that longer scaffolds present reduced peak scaffold stresses and a more homogeneous stress state compared to shorter scaffolds. Furthermore, it was found that scaffolds attached at proximal sites experience lower stresses than those attached at distal sites. However, scaffold length, rather than bone terminal location, most strongly influences peak stress. For each scaffold terminal placement configuration, a basic metric was computed indicative of bone fracture risk. This metric was the minimum distance from the bone surface to the internal scaffold bone terminal. Analysis of this minimum bone thickness data confirmed further optimisation of terminal locations is warranted.

Published

2021

19. Effects of moisture content and tillage methods on creep properties of paddy soil

Author

Xia Junfang, Liu Guoyang, Cheng Jian, Li Dong, Zheng Kan, and Du Jun

Subjects

0106 biological sciences, business.product_category, Compaction, Physical Chemistry, Polynomials, 01 natural sciences, Plough, Soil, Materials Physics, Agricultural Soil Science, Relaxation Time, Water content, Multidisciplinary, Moisture, Viscosity, Physics, Classical Mechanics, Eukaryota, Agriculture, Viscoelasticity, 04 agricultural and veterinary sciences, Plants, Deformation, Tillage, Chemistry, Experimental Organism Systems, Agricultural soil science, Physical Sciences, Medicine, Research Article, Science, Materials Science, Material Properties, Soil Science, Soil science, Research and Analysis Methods, Rivers, Plant and Algal Models, Grasses, Relaxation (Physics), Damage Mechanics, Organisms, Biology and Life Sciences, Water, Elasticity, Algebra, Chemical Properties, Models, Chemical, Soil water, Earth Sciences, Animal Studies, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Rice, business, Mathematics, 010606 plant biology & botany

Abstract

The rheological properties parameters of paddy soil affect the interaction between the tillage tools and soil, thus influencing the operation quality and power consumption. In order to study the effects of tillage methods and moisture content on the rheological properties parameters of paddy soil in the middle and lower reaches of the Yangtze River, uniaxial compression creep tests of paddy soils with four moisture contents under no tillage (moisture contents: 26.71%, 24.52%, 23.26%, 21.28%) and plough tillage (moisture contents: 26.77%, 25.55%, 23.40%, 20.56%) were carried out using a TMS-PRO texture analyzer. The creep properties curves obtained from the tests, and the rheological constitutive equation of paddy soil under compression was established by Burgers viscoelastic model. Respectively, the quantitative change rules of creep properties of paddy soil with different moisture contents under different tillage methods and the correlation between these parameters were explored. The results showed that the moisture content under the three-year plough tillage and no tillage methods had significant influence on the rheological properties parameters of paddy soil (P < 0.05). The instantaneous elastic modulus, delay elastic modulus, and viscosity coefficient of the two paddy soils (no tillage and plough tillage soils) decreased with the increase of moisture content. However, the variation rules of relaxation time and delay viscosity coefficient with moisture content differed between these two paddy soils. Specifically, the strain rate of the two paddy soils decreased as moisture content decreased, where the total strain combines elastic strain, viscous strain, and viscoelastic strain. The initial strain rate and steady strain rate of the plough tillage paddy soils were lower than that of the no tillage paddy soils. The established creep model equation could be used to obtain viscoelastic rheological parameters of paddy soil in a wide range. The fitting equations between rheological parameters and moisture content were introduced into Burgers model, and the coupling equations between creep deformation and moisture content and time were derived, which could be used to predict the creep properties and deformation behavior of paddy soil in a certain range of no tillage and ploughed field. Overall, this study has a certain theoretical significance for the development and improvement of paddy soil rheology theory, and can also provide theoretical basis and technical support for the research of agricultural machinery design optimization, field water, soil conservation, soil tillage and compaction related simulation analysis in the middle and lower reaches of the Yangtze River.

Published

2021

20. Experimental and mathematical characterization of coronary polyamide-12 balloon catheter membranes

Author

Jakob D Eckmann, Dominik Maier, Gerhard Sommer, Gerhard Holzapfel, Patrick Szabo, Emmanouil Agrafiotis, Daniel Ch Haspinger, Thomas Schratzenstaller, and Markus A Geith

Subjects

Polymers, Cardiovascular Procedures, Constitutive equation, 02 engineering and technology, Balloon, Polynomials, Cardiac Catheters, Medicine and Health Sciences, Composite material, Angioplasty, Balloon, Coronary, Materials, 0303 health sciences, Multidisciplinary, Physics, Applied Mathematics, Classical Mechanics, Heart, Condensed Matter Physics, Finite element method, Clamping, Deformation, Biomechanical Phenomena, Chemistry, Membrane, Macromolecules, Physical Sciences, Medicine, Engineering and Technology, Research Article, Biotechnology, Materials science, Catheters, Coronary Stenting, Science, 0206 medical engineering, Finite Element Analysis, Materials Science, Material Properties, Bioengineering, Surgical and Invasive Medical Procedures, Models, Biological, Viscoelasticity, 03 medical and health sciences, Tensile Strength, Adhesives, 030304 developmental biology, Damage Mechanics, Membranes, Myocardium, Isotropy, Balloon catheter, Biology and Life Sciences, Polymer Chemistry, 020601 biomedical engineering, Nylons, Algebra, Stent Implantation, Anisotropy, Medical Devices and Equipment, Stress, Mechanical, Mathematics

Abstract

The experimental quantification and modeling of the multiaxial mechanical response of polymer membranes of coronary balloon catheters have not yet been carried out. Due to the lack of insights, it is not shown whether isotropic material models can describe the material response of balloon catheter membranes expanded with nominal or higher, supra-nominal pressures. Therefore, for the first time, specimens of commercial polyamide-12 balloon catheters membranes were investigated during uniaxial and biaxial loading scenarios. Furthermore, the influence of kinematic effects on the material response was observed by comparing results from quasi-static and dynamic biaxial extension tests. Novel clamping techniques are described, which allow to test even tiny specimens taken from the balloon membranes. The results of this study reveal the semi-compliant, nonlinear, and viscoelastic character of polyamide-12 balloon catheter membranes. Above nominal pressure, the membranes show a pronounced anisotropic mechanical behavior with a stiffer response in the circumferential direction. The anisotropic feature intensifies with an increasing strain-rate. A modified polynomial model was applied to represent the realistic mechanical response of the balloon catheter membranes during dynamic biaxial extension tests. This study also includes a compact set of constitutive model parameters for the use of the proposed model in future finite element analyses to perform more accurate simulations of expanding balloon catheters.

Published

2020

21. On the accuracy of displacement-based wave intensity analysis: Effect of vessel wall viscoelasticity and nonlinearity

Author

Jingyi Kang, Niema M. Pahlevan, and Arian Aghilinejad

Subjects

Reflection, Blood Pressure, 02 engineering and technology, 030204 cardiovascular system & hematology, Pathology and Laboratory Medicine, Vascular Medicine, Physical Chemistry, law.invention, 0302 clinical medicine, law, Materials Physics, Fluid dynamics, Medicine and Health Sciences, Aorta, Physics, Stenosis, Multidisciplinary, Viscosity, Classical Mechanics, Mechanics, Arteries, Finite element method, Deformation, Vasodilation, Chemistry, Pressure measurement, Carotid Arteries, Pulsatile Flow, Physical Sciences, Medicine, Anatomy, Aneurysms, Blood Flow Velocity, Research Article, Science, 0206 medical engineering, Materials Science, Fluid Mechanics, Continuum Mechanics, Viscoelasticity, 03 medical and health sciences, Signs and Symptoms, Diagnostic Medicine, Waveform, Humans, Vascular Diseases, Fluid Flow, Damage Mechanics, Linear elasticity, Biology and Life Sciences, Reproducibility of Results, Fluid Dynamics, 020601 biomedical engineering, Elasticity, Nonlinear system, Chemical Properties, Cardiovascular Anatomy, Dilation (morphology), Blood Vessels

Abstract

Recent studies showed that wave intensity analysis (WIA) provides clinically valuable information about local and global cardiovascular function. Wave intensity (WI) is computed as the product of the pressure change and the velocity change during short time intervals. The major limitation of WIA in clinical practice is the need for invasive pressure measurement. Since vessel wall displacement can be measured non-invasively, the usage of WI will be expanded if the vessel wall dilation is used instead of pressure in derivation of WI waveform. Our goal in this study is to investigate the agreement between wall displacement-based WI and the pressure-based WI for different vessel wall models including linear elastic, nonlinear and viscoelastic cases. The arbitrary Eulerian Lagrangian finite element method is employed to solve the coupled fluid-structure interaction (FSI). Our computational models also include two types of vascular disease-related cases with geometrical irregularities, aneurysm and stenosis. Our results show that for vessels with linear elastic wall, the displacement-based WI is almost identical to the pressure-based WI. The existence of vessel irregularities does not impact the accuracy of displacement-based WI. However, in a viscoelastic wall where there is a phase difference between pressure and vessel wall dilation, displacement-based WI deviated from pressure-based WI. The error associated with this phase difference increased nonlinearly with increasing viscosity. This results in a maximum error of 6.8% and 7.13% for a regular viscoelastic vessel wall and an irregular viscoelastic vessel wall, respectively. A separate analysis has also been performed on the agreement of backward and forward running waves extracted from a decomposition of the displacement-based and pressure-based WI. Our findings suggest that displacement-based WI is a reliable method of WIA for large central arteries that do not show viscoelastic behaviors. This can be clinically significant since the required information can be measured non-invasively.

Published

2019

22. Simulations of dynamically cross-linked actin networks: Morphology, rheology, and hydrodynamic interactions

Author

Aleksandar Donev, Raúl P. Peláez, Alex Mogilner, and Ondrej Maxian

Subjects

Actin Filaments, Physical Chemistry, Protein filament, Viscosity, Materials Physics, Biology (General), Physics, Fluids, Deformation (mechanics), Ecology, Classical Mechanics, Viscoelasticity, Mechanics, Deformation, Drag, Actin Cytoskeleton, Chemistry, Cell Motility, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Dynamic Actin Filaments, Rheology, Research Article, States of Matter, QH301-705.5, Materials Science, Material Properties, Fluid Mechanics, Molecular Dynamics Simulation, Continuum Mechanics, Quantitative Biology::Subcellular Processes, Cellular and Molecular Neuroscience, Slender-body theory, Elastic Modulus, Genetics, Elasticity (economics), Molecular Biology, Ecology, Evolution, Behavior and Systematics, Damage Mechanics, Steady state, Computational Biology, Biology and Life Sciences, Fluid Dynamics, Cell Biology, Actins, Elasticity, Chemical Properties, Hydrodynamics

Abstract

Cross-linked actin networks are the primary component of the cell cytoskeleton and have been the subject of numerous experimental and modeling studies. While these studies have demonstrated that the networks are viscoelastic materials, evolving from elastic solids on short timescales to viscous fluids on long ones, questions remain about the duration of each asymptotic regime, the role of the surrounding fluid, and the behavior of the networks on intermediate timescales. Here we perform detailed simulations of passively cross-linked non-Brownian actin networks to quantify the principal timescales involved in the elastoviscous behavior, study the role of nonlocal hydrodynamic interactions, and parameterize continuum models from discrete stochastic simulations. To do this, we extend our recent computational framework for semiflexible filament suspensions, which is based on nonlocal slender body theory, to actin networks with dynamic cross linkers and finite filament lifetime. We introduce a model where the cross linkers are elastic springs with sticky ends stochastically binding to and unbinding from the elastic filaments, which randomly turn over at a characteristic rate. We show that, depending on the parameters, the network evolves to a steady state morphology that is either an isotropic actin mesh or a mesh with embedded actin bundles. For different degrees of bundling, we numerically apply small-amplitude oscillatory shear deformation to extract three timescales from networks of hundreds of filaments and cross linkers. We analyze the dependence of these timescales, which range from the order of hundredths of a second to the actin turnover time of several seconds, on the dynamic nature of the links, solvent viscosity, and filament bending stiffness. We show that the network is mostly elastic on the short time scale, with the elasticity coming mainly from the cross links, and viscous on the long time scale, with the effective viscosity originating primarily from stretching and breaking of the cross links. We show that the influence of nonlocal hydrodynamic interactions depends on the network morphology: for homogeneous meshworks, nonlocal hydrodynamics gives only a small correction to the viscous behavior, but for bundled networks it both hinders the formation of bundles and significantly lowers the resistance to shear once bundles are formed. We use our results to construct three-timescale generalized Maxwell models of the networks., Author summary The cytoskeleton is composed of semiflexible, inextensible actin filaments, dynamic cross linkers, and molecular motors, and makes the primary contribution to the structural properties of the cell. Despite its being so fundamental to cell biology, the biological complexity of the cytoskeleton hinders our ability to understand its mechanical properties through in vitro experiments. In this paper, we perform microscopic simulations of actin fibers and transient cross linkers to quantify the principle timescales involved in the network, study how these timescales influence the morphology and rheology of the system, and examine the role of hydrodynamic interactions in cytoskeletal networks. We find three principle timescales which we associate with fiber flexibility, cross linker detachment, and network remodeling, respectively. We show that the morphology of the network is more important on longer timescales, where the viscosity of links inside of fiber bundles is enhanced. We also show that hydrodynamic interactions reduce the stress inside of bundles because of entrainment flows. Finally, we propose a continuum model which can be used to coarse-grain our agent-based simulations and enable modeling of larger systems.

Published

2021

23. The role of actin protrusion dynamics in cell migration through a degradable viscoelastic extracellular matrix: Insights from a computational model

Author

Tommy Heck, Diego A. Vargas, Bart Smeets, Paul Van Liedekerke, Hans Van Oosterwyck, Herman Ramon, Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven), Modelling and Analysis for Medical and Biological Applications (MAMBA), Inria de Paris, Institut National de Recherche en Informatique et en Automatique (Inria)-Institut National de Recherche en Informatique et en Automatique (Inria)-Laboratoire Jacques-Louis Lions (LJLL (UMR_7598)), Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), SImulations en Médecine, BIOtechnologie et ToXicologie de systèmes multicellulaires (SIMBIOTX ), Inria Saclay - Ile de France, Institut National de Recherche en Informatique et en Automatique (Inria)-Institut National de Recherche en Informatique et en Automatique (Inria), H.V.O. acknowledges that the research leading to these results has received funding from the European Research Council under the European Union’s Seventh Framework Programme (FP7/ 2007–2013)/ ERC Grant Agreement No. 308223)(https://ec.europa.eu/research/fp7/index_en.cfm). P.V.L would like to acknowledge the support by BMBF -LiSym (https://www.bmbf.de/), INSERM –PhysiCancer (https://www.inserm.fr/), ITMO –INVADE (https://itcancer.aviesan.fr/), EU 7th Framework Programme (NOTOX) (https://ec. europa.eu/research/fp7/index_en.cfm) and ANR –iLite, Université Paris Diderot - Paris 7 (UPD7)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), and Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP)

Subjects

0301 basic medicine, Cell, Biochemistry, Stiffness, Extracellular matrix, LIMITS, Contractile Proteins, 0302 clinical medicine, Cell Movement, Myosin, Biology (General), 0303 health sciences, stiffness, actin polymerization, anisotropy, cell migration, viscoelasticity, cancer cell migration, collagens, actins, Ecology, Chemistry, Viscosity, Physics, Dynamics (mechanics), Strain stiffening, Cell migration, STIFFNESS, Adhesion, Condensed Matter Physics, Extracellular Matrix, Cell Motility, medicine.anatomical_structure, Computational Theory and Mathematics, Cell Processes, Modeling and Simulation, Physical Sciences, symbols, Life Sciences & Biomedicine, Research Article, 3D, Biochemistry & Molecular Biology, PROTEINS, QH301-705.5, [PHYS.PHYS.PHYS-BIO-PH]Physics [physics]/Physics [physics]/Biological Physics [physics.bio-ph], Materials Science, Material Properties, Motor Proteins, Actin Motors, [SDV.BC]Life Sciences [q-bio]/Cellular Biology, Myosins, Models, Biological, Viscoelasticity, Biochemical Research Methods, 03 medical and health sciences, Cellular and Molecular Neuroscience, symbols.namesake, Molecular Motors, Genetics, medicine, Mechanical Properties, Actin polymerization, Computer Simulation, [PHYS.MECA.BIOM]Physics [physics]/Mechanics [physics]/Biomechanics [physics.med-ph], PROTEOLYSIS, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Actin, 030304 developmental biology, Science & Technology, Regeneration (biology), Biology and Life Sciences, Proteins, Cancer cell migration, Computational Biology, Cell Biology, Actins, Elasticity, Cytoskeletal Proteins, 030104 developmental biology, Biophysics, Anisotropy, Mathematical & Computational Biology, Collagens, 030217 neurology & neurosurgery, Lagrangian, Developmental Biology

Abstract

Actin protrusion dynamics plays an important role in the regulation of three-dimensional (3D) cell migration. Cells form protrusions that adhere to the surrounding extracellular matrix (ECM), mechanically probe the ECM and contract in order to displace the cell body. This results in cell migration that can be directed by the mechanical anisotropy of the ECM. However, the subcellular processes that regulate protrusion dynamics in 3D cell migration are difficult to investigate experimentally and therefore not well understood. Here, we present a computational model of cell migration through a degradable viscoelastic ECM. This model is a 2D representation of 3D cell migration. The cell is modeled as an active deformable object that captures the viscoelastic behavior of the actin cortex and the subcellular processes underlying 3D cell migration. The ECM is regarded as a viscoelastic material, with or without anisotropy due to fibrillar strain stiffening, and modeled by means of the meshless Lagrangian smoothed particle hydrodynamics (SPH) method. ECM degradation is captured by local fluidization of the material and permits cell migration through the ECM. We demonstrate that changes in ECM stiffness and cell strength affect cell migration and are accompanied by changes in number, lifetime and length of protrusions. Interestingly, directly changing the total protrusion number or the average lifetime or length of protrusions does not affect cell migration. A stochastic variability in protrusion lifetime proves to be enough to explain differences in cell migration velocity. Force-dependent adhesion disassembly does not result in faster migration, but can make migration more efficient. We also demonstrate that when a number of simultaneous protrusions is enforced, the optimal number of simultaneous protrusions is one or two, depending on ECM anisotropy. Together, the model provides non-trivial new insights in the role of protrusions in 3D cell migration and can be a valuable contribution to increase the understanding of 3D cell migration mechanics., Author summary The ability of cells to migrate through a tissue in the human body is vital for many processes such as tissue development, growth and regeneration. At the same time, abnormal cell migration is also playing an important role in many diseases such as cancer. If we want to be able to explain the origin of these abnormalities and develop new treatment strategies, we have to understand how cells are able to regulate their migration. Since it is challenging to investigate cell migration through a biological tissue in experiments, computational modeling can provide a valuable contribution. We have developed a computational model of cell migration through a deformable and degradable material that describes both mechanics of the cell and the surrounding material and subcellular processes underlying cell migration. This model captures the formation of long and thin protrusions that adhere to the surrounding material and that pull the cell forward. It provides new non-trivial insights in the role of these protrusions in cell migration and the regulation of protrusion dynamics by cell strength and anisotropic mechanical properties of the surrounding material. Therefore, we believe that this model can be a valuable tool to further improve the understanding of cell migration.

Published

2019

24. Frictional characterization of injectable hyaluronic acids is more predictive of clinical outcomes than traditional rheological or viscoelastic characterization

Author

Edward D. Bonnevie, Cynthia Secchieri, Devis Galesso, and Lawrence J. Bonassar

Subjects

Tribology, 02 engineering and technology, Physical Chemistry, chemistry.chemical_compound, Viscosity, 0302 clinical medicine, Skeletal Joints, Materials Physics, Lubrication, Hyaluronic acid, Medicine and Health Sciences, Clinical efficacy, Hyaluronic Acid, Musculoskeletal System, Multidisciplinary, Physics, 021001 nanoscience & nanotechnology, Chemistry, Treatment Outcome, Connective Tissue, Physical Sciences, Engineering and Technology, Medicine, Anatomy, Rheology, 0210 nano-technology, Research Article, Materials science, Friction, Drug Compounding, Science, Materials Science, Material Properties, Viscoelasticity, Injections, 03 medical and health sciences, Rheumatology, Humans, Mechanical Properties, 030203 arthritis & rheumatology, Rheometry, Arthritis, Mechanical Engineering, Biology and Life Sciences, Elasticity, Biological Tissue, Cartilage, Chemical Properties, chemistry, Arthritis therapy, Viscosupplementation, Biomedical engineering

Abstract

Hyaluronic acid injections have been a mainstay of arthritis treatment for decades. However, much controversy remains about their clinical efficacy and their potential mechanism of action. This approach to arthritis therapy is often called viscosupplementation, a term which is rooted in the elevated viscosity of the injected solutions. This terminology also suggests a mechanical pathway of action and further implies that their efficacy is dependent on viscosity. Notably, previous studies of the relationship between viscous properties of hyaluronic acid solutions and their clinical efficacy have not been definitive. Recently we developed an experimental and analytical framework for studying cartilage lubrication that captures the Stribeck-like behavior of cartilage in an elastoviscous transition curve. Here we apply this framework to study the lubricating behavior of six hyaluronan products currently used for injectable arthritis therapy in the US. Despite the fact that the source and chemical modifications endow these products with a range of lubricating properties, we show that the lubricating effect of all of these materials can be described by this Stribeck-like elastoviscous transition. Fitting this data to the elastoviscous transition model enables the calculation of effective lubricating viscosities for each material, which differ substantially from the viscosities measured using standard rheometry. Further we show that while data from standard rheometry are poor predictors of clinical performance of these materials, measurements of friction coefficient and effective lubricating viscosity correlate well (R2 = 0.77; p < 0.005) with assessments of improved clinical function reported previously. This approach offers both a novel method that can be used to evaluate potential clinical efficacy of hyaluronic acid formulations and provide new insight on their mode of action.

Published

2019

25. Viscoelastic properties of wheat gluten in a molecular dynamics study

Author

Łukasz Mioduszewski and Marek Cieplak

Subjects

0301 basic medicine, Wheat gluten, Biochemistry, Physical Chemistry, 01 natural sciences, Molecular dynamics, Molecular level, Biochemical Simulations, Biology (General), Post-Translational Modification, Triticum, 2. Zero hunger, chemistry.chemical_classification, 0303 health sciences, 010304 chemical physics, Ecology, Viscosity, Physics, Classical Mechanics, Eukaryota, Plants, Deformation, Shear (sheet metal), Chemistry, Experimental Organism Systems, Computational Theory and Mathematics, Chemical physics, Modeling and Simulation, Physical Sciences, Disulfide Bonds, Deformation (engineering), Research Article, Nutrient and Storage Proteins, Materials science, Glutens, QH301-705.5, Materials Science, Material Properties, Molecular Dynamics Simulation, Research and Analysis Methods, Viscoelasticity, 03 medical and health sciences, Cellular and Molecular Neuroscience, Model Organisms, Plant and Algal Models, 0103 physical sciences, Genetics, Storage protein, Grasses, Elasticity (economics), Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Damage Mechanics, Response force, Chemical Bonding, Organisms, Biology and Life Sciences, Proteins, Computational Biology, Hydrogen Bonding, Gluten, Elasticity, Maize, 030104 developmental biology, chemistry, Animal Studies

Abstract

Wheat (Triticum spp.) gluten consists mainly of intrinsincally disordered storage proteins (glutenins and gliadins) that can form megadalton-sized networks. These networks are responsible for the unique viscoelastic properties of wheat dough and affect the quality of bread. These properties have not yet been studied by molecular level simulations. Here, we use a newly developed α-C-based coarse-grained model to study ∼ 4000-residue systems. The corresponding time-dependent properties are studied through shear and axial deformations. We measure the response force to the deformation, the number of entanglements and cavities, the mobility of residues, the number of the inter-chain bonds, etc. Glutenins are shown to influence the mechanics of gluten much more than gliadins. Our simulations are consistent with the existing ideas about gluten elasticity and emphasize the role of entanglements and hydrogen bonding. We also demonstrate that the storage proteins in maize and rice lead to weaker elasticity which points to the unique properties of wheat gluten., Author summary During the breadmaking process, expanding gas bubbles cause the dough to increase volume. Gluten proteins act as an elastic scaffold in that process, allowing the wheat dough to grow more than other kinds of dough. Thus, explaining the unique viscoelastic properties of gluten at the molecular level may be of great interest to the baking industry. Assessing the structural properties of gluten is difficult because its proteins are disordered. We provide the first molecular dynamics model of gluten elasticity, that is able to distinguish gluten and proteins from different plants, like maize and rice. Our model shows the structural changes the gluten proteins undergo during their deformation, which mimics the mixing of dough during kneading. It also allows for a determination of the force required to extend gluten proteins, as during baking. The data confirms existing theories about gluten, but it also provides molecular-level information about the extraordinary elasticity of gluten.

Published

2021

26. A three-dimensional phase-field model for multiscale modeling of thrombus biomechanics in blood vessels

Author

Alireza Yazdani, Jay D. Humphrey, He Li, George Em Karniadakis, and Xiaoning Zheng

Subjects

0301 basic medicine, Platelet Aggregation, Platelet aggregation, Physiology, Biochemistry, Vascular Medicine, 0302 clinical medicine, Animal Cells, Blood Flow, Medicine and Health Sciences, Biology (General), Ecology, Physics, Simulation and Modeling, Biomechanics, Classical Mechanics, Hematology, Multiscale modeling, Deformation, Body Fluids, Blood, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, cardiovascular system, Anatomy, Cellular Types, Aneurysms, Research Article, circulatory and respiratory physiology, Blood Platelets, Platelets, Materials science, Particle simulation, QH301-705.5, Materials Science, Material Properties, Biophysics, Research and Analysis Methods, Models, Biological, Permeability, Viscoelasticity, 03 medical and health sciences, Cellular and Molecular Neuroscience, Platelet Adhesiveness, Genetics, medicine, Humans, Computer Simulation, Vascular Diseases, cardiovascular diseases, Thrombus, Blood Coagulation, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Damage Mechanics, Fibrin, Blood Cells, Extramural, Biology and Life Sciences, Proteins, Thrombosis, Cell Biology, Blood flow, medicine.disease, 030104 developmental biology, Blood Vessels, 030217 neurology & neurosurgery, Biomedical engineering

Abstract

Mechanical interactions between flowing and coagulated blood (thrombus) are crucial in dictating the deformation and remodeling of a thrombus after its formation in hemostasis. We propose a fully-Eulerian, three-dimensional, phase-field model of thrombus that is calibrated with existing in vitro experimental data. This phase-field model considers spatial variations in permeability and material properties within a single unified mathematical framework derived from an energy perspective, thereby allowing us to study effects of thrombus microstructure and properties on its deformation and possible release of emboli under different hemodynamic conditions. Moreover, we combine this proposed thrombus model with a particle-based model which simulates the initiation of the thrombus. The volume fraction of a thrombus obtained from the particle simulation is mapped to an input variable in the proposed phase-field thrombus model. The present work is thus the first computational study to integrate the initiation of a thrombus through platelet aggregation with its subsequent viscoelastic responses to various shear flows. This framework can be informed by clinical data and potentially be used to predict the risk of diverse thromboembolic events under physiological and pathological conditions., Author summary Thromboembolism is associated with detachment of small thrombus pieces from the bulk in the blood vessel. These detached pieces, also known as emboli, travel through the blood flow and may block other vessels downstream, e.g., they may plug the deep veins of the leg, groin or arm, leading to venous thromboembolism (VTE). VTE is a significant cause of morbidity and mortality and it affects more than 900,000 people in the United States and result in approximately 100,000 deaths every year. Mechanical interaction between flowing blood and a thrombus is crucial in determining the deformation of the thrombus and the possibility of releasing emboli. In this study, we develop a phase-field model that is capable of describing the structural properties of a thrombus and its biomechanical properties under different blood flow conditions. Moreover, we combine this thrombus model with a particle-based model which simulates the initiation of the thrombus. This combined framework is the first computational study to simulate the development of a thrombus from platelet aggregation to its subsequent viscoelastic responses to various shear flows. Informed by clinical data, this framework can be used to predict the risk of diverse thromboembolic events under physiological and pathological conditions.

Published

2020

27. Dairy products viscosity estimated by laser speckle correlation

Author

Flemming Møller, Olga Sosnovtseva, and Dmitry D. Postnov

Subjects

0301 basic medicine, Light, Physiology, lcsh:Medicine, Physical Chemistry, Biochemistry, 01 natural sciences, Fats, Scattering, Viscosity, Materials Physics, Image Processing, Computer-Assisted, Medicine and Health Sciences, lcsh:Science, Multidisciplinary, Physics, Electromagnetic Radiation, Optical Imaging, Classical Mechanics, Lipids, Chemistry, Optical Equipment, Physical Sciences, Engineering and Technology, Rheology, Biological system, Research Article, Lightness, Computer and Information Sciences, Materials science, Materials Science, Equipment, Continuum Mechanics, Viscoelasticity, Degree (temperature), 010309 optics, 03 medical and health sciences, Speckle pattern, Consistency (statistics), 0103 physical sciences, Animals, Measurement Equipment, Lasers, Data Visualization, lcsh:R, Autocorrelation, Food Consumption, Light Scattering, Biology and Life Sciences, Color Codes, 030104 developmental biology, Chemical Properties, lcsh:Q, Dairy Products, Physiological Processes

Abstract

Dairy products exhibit several physical properties that are crucial to define whether we like the food or not: firmness, creaminess, thickness, or lightness. Viscosity changes the flow properties of food and influences the appearance and the consistency of a product; this control variable is important in most production stages-manufacture, processing, and storage. Viscosity of heterogeneous products at a given temperature depends on its composition and physical state of its substances. Although rheology provides a method to access the product viscosity, it lacks non-contact full-field monitoring. We apply a simple correlation analysis of laser speckle images to evaluate viscosity properties of dairy products. Our approach ensures robust measurements with high degree of detectability.

Published

2018

28. Transient viscous response of the human cornea probed with the Surface Force Apparatus

Author

Navinkumar J. Patil, Bruno Zappone, Marco Lombardo, and Giuseppe Lombardo

Subjects

Male, Compressive Strength, cornea tissue, lcsh:Medicine, 02 engineering and technology, Physical Chemistry, Biochemistry, Cornea, 0302 clinical medicine, Medicine and Health Sciences, Relaxation Time, Cross-Linking, lcsh:Science, Multidisciplinary, Viscosity, Corneal Diseases, Physics, Classical Mechanics, Surface forces apparatus, Middle Aged, Deformation, Tissue Donors, Biomechanical Phenomena, Chemistry, medicine.anatomical_structure, Physical Sciences, Female, Deformation (engineering), Anatomy, Research Article, SFA, Materials science, Ocular Anatomy, Corneal Stroma, 0206 medical engineering, Materials Science, Material Properties, Visco-elastic behaviour, Fluid Mechanics, Continuum Mechanics, Models, Biological, Viscoelasticity, Permeability, Stress (mechanics), 03 medical and health sciences, Imaging, Three-Dimensional, Ocular System, Elastic Modulus, medicine, Humans, Elastic modulus, Relaxation (Physics), Fluid Flow, Aged, Damage Mechanics, Chemical Bonding, lcsh:R, Biology and Life Sciences, Proteins, Fluid Dynamics, 020601 biomedical engineering, eye diseases, Interferometry, Permeability (electromagnetism), 030221 ophthalmology & optometry, Eyes, lcsh:Q, Stress, Mechanical, sense organs, Head, Collagens, Biomedical engineering

Abstract

Knowledge of the biomechanical properties of the human cornea is crucial for understanding the development of corneal diseases and impact of surgical treatments (e.g., corneal laser surgery, corneal cross-linking). Using a Surface Force Apparatus we investigated the transient viscous response of the anterior cornea from donor human eyes compressed between macroscopic crossed cylinders. Corneal biomechanics was analyzed using linear viscoelastic theory and interpreted in the framework of a biphasic model of soft hydrated porous tissues, including a significant contribution from the pressurization and viscous flow of fluid within the corneal tissue. Time-resolved measurements of tissue deformation and careful determination of the relaxation time provided an elastic modulus in the range between 0.17 and 1.43 MPa, and fluid permeability of the order of 10(-13) m(4)/(N.s). The permeability decreased as the deformation was increased above a strain level of about 10%, indicating that the interstitial space between fibrils of the corneal stromal matrix was reduced under the effect of strong compression. This effect may play a major role in determining the observed rate-dependent non-linear stress-strain response of the anterior cornea, which underlies the shape and optical properties of the tissue.

Published

2018

29. Viscoelastic parameters as discriminators of breast masses: Initial human study results

Author

Adriana Gregory, Max Denis, Azra Alizad, Mostafa Fatemi, Mohammad Mehrmohammadi, Viksit Kumar, Mahdi Bayat, and Robert T. Fazzio

Subjects

Biopsy, Velocity, lcsh:Medicine, Physical Chemistry, 01 natural sciences, 030218 nuclear medicine & medical imaging, Breast Diseases, 0302 clinical medicine, Nuclear magnetic resonance, Materials Physics, Medicine and Health Sciences, Breast, lcsh:Science, 010301 acoustics, Ultrasonography, Physics, Multidisciplinary, medicine.diagnostic_test, Viscosity, Ultrasound, Classical Mechanics, Soft tissue, Middle Aged, Chemistry, Kelvin–Voigt material, Physical Sciences, Elasticity Imaging Techniques, Female, Elastography, Anatomy, Research Article, Soft Tissues, Materials Science, Material Properties, Surgical and Invasive Medical Procedures, Breast Neoplasms, Human study, Vibration, Viscoelasticity, Diagnosis, Differential, Motion, 03 medical and health sciences, 0103 physical sciences, medicine, Mechanical Properties, Humans, Elasticity (economics), business.industry, lcsh:R, Reproductive System, Biology and Life Sciences, Acoustics, Elasticity, Biological Tissue, Chemical Properties, lcsh:Q, business, Breast Tissue

Abstract

Shear wave elastography is emerging as a clinically valuable diagnostic tool to differentiate between benign and malignant breast masses. Elastography techniques assume that soft tissue can be modelled as a purely elastic medium. However, this assumption is often violated as soft tissue exhibits viscoelastic properties. In order to explore the role of viscoelastic parameters in suspicious breast masses, a study was conducted on a group of patients using shear wave dispersion ultrasound vibrometry in the frequency range of 50-400 Hz. A total of 43 female patients with suspicious breast masses were recruited before their scheduled biopsy. Of those, 15 patients did not meet the data selection criteria. Voigt model based shear elasticity showed a significantly (p = 7.88x10(-6)) higher median value for the 13 malignant masses (16.76±13.10 kPa) compared to 15 benign masses (1.40±1.12 kPa). Voigt model based shear viscosity was significantly different (p = 4.13x10(-5)) between malignant (8.22±3.36 Pa-s) and benign masses (2.83±1.47 Pa-s). Moreover, the estimated time constant from the Voigt model, which is dependent on both shear elasticity and viscosity, differed significantly (p = 6.13x10(-5)) between malignant (0.68±0.33 ms) and benign masses (3.05±1.95 ms). Results suggest that besides elasticity, viscosity based parameters like shear viscosity and time constant can also be used to differentiate between malignant and benign breast masses.

Published

2018

30. Filament turnover tunes both force generation and dissipation to control long-range flows in a model actomyosin cortex

Author

Margaret L. Gardel, Patrick M. McCall, William M. McFadden, and Edwin Munro

Subjects

0301 basic medicine, Actin Filaments, Physical Chemistry, Biochemistry, Protein filament, Viscosity, Contractile Proteins, Materials Physics, Morphogenesis, lcsh:QH301-705.5, Cytoskeleton, Ecology, Physics, Molecular Motor Proteins, Classical Mechanics, Actomyosin, Mechanics, Dissipation, Deformation, Drag, Biomechanical Phenomena, Chemistry, Cell Motility, Actin Cytoskeleton, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Mechanical Stress, Rheology, Network Analysis, Research Article, Computer and Information Sciences, Materials science, Materials Science, Motor Proteins, Flow (psychology), Actin Motors, Fluid Mechanics, macromolecular substances, Myosins, Continuum Mechanics, Models, Biological, Viscoelasticity, Stress (mechanics), 03 medical and health sciences, Cellular and Molecular Neuroscience, Molecular Motors, Stress, Physiological, Genetics, Animals, Computer Simulation, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Damage Mechanics, Steady state, Passive resistance, Biology and Life Sciences, Proteins, Computational Biology, Fluid Dynamics, Cell Biology, Cytoskeletal Proteins, 030104 developmental biology, Chemical Properties, lcsh:Biology (General)

Abstract

Actomyosin-based cortical flow is a fundamental engine for cellular morphogenesis. Cortical flows are generated by cross-linked networks of actin filaments and myosin motors, in which active stress produced by motor activity is opposed by passive resistance to network deformation. Continuous flow requires local remodeling through crosslink unbinding and and/or filament disassembly. But how local remodeling tunes stress production and dissipation, and how this in turn shapes long range flow, remains poorly understood. Here, we study a computational model for a cross-linked network with active motors based on minimal requirements for production and dissipation of contractile stress: Asymmetric filament compliance, spatial heterogeneity of motor activity, reversible cross-links and filament turnover. We characterize how the production and dissipation of network stress depend, individually, on cross-link dynamics and filament turnover, and how these dependencies combine to determine overall rates of cortical flow. Our analysis predicts that filament turnover is required to maintain active stress against external resistance and steady state flow in response to external stress. Steady state stress increases with filament lifetime up to a characteristic time τm, then decreases with lifetime above τm. Effective viscosity increases with filament lifetime up to a characteristic time τc, and then becomes independent of filament lifetime and sharply dependent on crosslink dynamics. These individual dependencies of active stress and effective viscosity define multiple regimes of steady state flow. In particular our model predicts that when filament lifetimes are shorter than both τc and τm, the dependencies of effective viscosity and steady state stress on filament turnover cancel one another, such that flow speed is insensitive to filament turnover, and shows a simple dependence on motor activity and crosslink dynamics. These results provide a framework for understanding how animal cells tune cortical flow through local control of network remodeling., Author summary In this paper, we develop and analyze a minimal model for a 2D network of cross-linked actin filaments and myosin motors, representing the cortical cytoskeleton of eukaryotic cells. We implement coarse-grained representations of force production by myosin motors and stress dissipation through an effective cross-link friction and filament turnover. We use this model to characterize how the sustained production of active stress, and the steady dissipation of elastic stress, depend individually on motor activity, effective cross-link friction and filament turnover. Then we combine these results to gain insights into how microscopic network parameters control steady state flow produced by asymmetric distributions of motor activity. Our results provide a framework for understanding how local modulation of microscopic interactions within contractile networks control macroscopic quantities like active stress and effective viscosity to control cortical deformation and flow at cellular scales.

Published

2017

31. Probing eukaryotic cell mechanics via mesoscopic simulations

Author

Yasaman Nematbakhsh, Menglin Shang, Igor V. Pivkin, Chwee Teck Lim, and Kirill Lykov

Subjects

0301 basic medicine, Cell, Microfluidics, Cell Membranes, 02 engineering and technology, Physical Chemistry, Cell membrane, Micromanipulation, Materials Physics, Cell Mechanics, Biomechanics, Cytoskeleton, lcsh:QH301-705.5, Physics, Mesoscopic physics, Ecology, Viscosity, Simulation and Modeling, Dissipative particle dynamics, Biomechanical Phenomena, Chemistry, medicine.anatomical_structure, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Engineering and Technology, Fluidics, Cellular Structures and Organelles, Biological system, Research Article, 0206 medical engineering, Materials Science, Biophysics, Research and Analysis Methods, Models, Biological, Viscoelasticity, Cell Line, 03 medical and health sciences, Cellular and Molecular Neuroscience, Nuclear Membrane, Component (UML), Genetics, medicine, Humans, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Cell Nucleus, Cell Membrane, Computational Biology, Biology and Life Sciences, Epithelial Cells, Cell Biology, 020601 biomedical engineering, Elasticity, 030104 developmental biology, lcsh:Biology (General), Chemical Properties

Abstract

Cell mechanics has proven to be important in many biological processes. Although there is a number of experimental techniques which allow us to study mechanical properties of cell, there is still a lack of understanding of the role each sub-cellular component plays during cell deformations. We present a new mesoscopic particle-based eukaryotic cell model which explicitly describes cell membrane, nucleus and cytoskeleton. We employ Dissipative Particle Dynamics (DPD) method that provides us with the unified framework for modeling of a cell and its interactions in the flow. Data from micropipette aspiration experiments were used to define model parameters. The model was validated using data from microfluidic experiments. The validated model was then applied to study the impact of the sub-cellular components on the cell viscoelastic response in micropipette aspiration and microfluidic experiments., Author summary Predictive simulations of cell flow in microfluidic devices and capillary networks may help to quantify the impact of different cell components on its behavior. Cells have complex mechanical properties and can undergo significant deformations, requiring detailed models to give an insight into the cell rheology. We developed computational model for simulations of cells with nucleus and cytoskeleton in flows in complex domains such as capillary networks and microfluidic devices. We validated the model using experimental data and used it to quantify the effects of cell components on its behavior. We envision that the proposed model will allow to study in silico numerous problems related to the cell biomechanics in flows.

Published

2017

32. Mechanical Stress Induces Remodeling of Vascular Networks in Growing Leaves

Author

Yohai Bar-Sinai, Shahaf Armon, Eran Sharon, Arezki Boudaoud, Jean-Daniel Julien, Mokhtar Adda-Bedia, Naomi Nakayama, Weizmann Institute of Science, Racah Institute of Physics (Racah Institute of Physics), The Hebrew University of Jerusalem (HUJ)-Racah Institute of Physics, Laboratoire de Physique Statistique de l'ENS (LPS), Fédération de recherche du Département de physique de l'Ecole Normale Supérieure - ENS Paris (FRDPENS), Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Physique de l'ENS Lyon (Phys-ENS), École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), Reproduction et développement des plantes (RDP), École normale supérieure - Lyon (ENS Lyon)-Institut National de la Recherche Agronomique (INRA)-Université Claude Bernard Lyon 1 (UCBL), Laboratoire Joliot Curie, École normale supérieure - Lyon (ENS Lyon)-Centre National de la Recherche Scientifique (CNRS), University of Edinburgh, Institut Universitaire de France (IUF), Ministère de l'Education nationale, de l’Enseignement supérieur et de la Recherche (M.E.N.E.S.R.), Weizmann Institute of Science [Rehovot, Israël], Université Paris Diderot - Paris 7 (UPD7)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS)-Fédération de recherche du Département de physique de l'Ecole Normale Supérieure - ENS Paris (FRDPENS), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS), École normale supérieure - Lyon (ENS Lyon)-Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon, European Union New and Emerging Science and Technology grant MechPlant, fondation Pierre-Gilles de Gennes, Eshkol Scholarship - Israeli Ministry of Science, École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), École normale supérieure de Lyon (ENS de Lyon)-Institut National de la Recherche Agronomique (INRA)-Université Claude Bernard Lyon 1 (UCBL), École normale supérieure de Lyon (ENS de Lyon)-Centre National de la Recherche Scientifique (CNRS), and Boudaoud, Arezki

Subjects

0301 basic medicine, Work (thermodynamics), Leaves, leaf venation patterns, quantitative-analysis, growth, arabidopsis, morphogenesis, dynamics, polarity, tissues, forces, model, Body Patterning, Plant Science, Infographics, lcsh:QH301-705.5, Ecology, Deformation (mechanics), Plant Anatomy, Physics, Simulation and Modeling, Stiffness, Classical Mechanics, [SDV.BV.BOT]Life Sciences [q-bio]/Vegetal Biology/Botanics, Condensed Matter Physics, Deformation, Biomechanical Phenomena, Computational Theory and Mathematics, Ellipses, Modeling and Simulation, Physical Sciences, Mechanical Stress, medicine.symptom, Leaf Veins, Graphs, Research Article, Computer and Information Sciences, Materials science, Materials Science, Material Properties, Geometry, Research and Analysis Methods, Models, Biological, Viscoelasticity, Stress (mechanics), 03 medical and health sciences, Cellular and Molecular Neuroscience, Genetics, medicine, Computer Simulation, Molecular Biology, Process (anatomy), Ecology, Evolution, Behavior and Systematics, Damage Mechanics, Data Visualization, Computational Biology, Biology and Life Sciences, Plant Leaves, 030104 developmental biology, lcsh:Biology (General), Biophysics, Anisotropy, Stress, Mechanical, Plant Vascular Bundle, [INFO.INFO-BI]Computer Science [cs]/Bioinformatics [q-bio.QM], Mathematics

Abstract

Differentiation into well-defined patterns and tissue growth are recognized as key processes in organismal development. However, it is unclear whether patterns are passively, homogeneously dilated by growth or whether they remodel during tissue expansion. Leaf vascular networks are well-fitted to investigate this issue, since leaves are approximately two-dimensional and grow manyfold in size. Here we study experimentally and computationally how vein patterns affect growth. We first model the growing vasculature as a network of viscoelastic rods and consider its response to external mechanical stress. We use the so-called texture tensor to quantify the local network geometry and reveal that growth is heterogeneous, resembling non-affine deformations in composite materials. We then apply mechanical forces to growing leaves after veins have differentiated, which respond by anisotropic growth and reorientation of the network in the direction of external stress. External mechanical stress appears to make growth more homogeneous, in contrast with the model with viscoelastic rods. However, we reconcile the model with experimental data by incorporating randomness in rod thickness and a threshold in the rod growth law, making the rods viscoelastoplastic. Altogether, we show that the higher stiffness of veins leads to their reorientation along external forces, along with a reduction in growth heterogeneity. This process may lead to the reinforcement of leaves against mechanical stress. More generally, our work contributes to a framework whereby growth and patterns are coordinated through the differences in mechanical properties between cell types., Author Summary The development of an organism involves a coordination between the differentiation of cells in well-defined spatial patterns and the growth of tissues towards their target shapes. While extensive research has addressed each of these key processes, their coordination has received less attention. In particular, when a pattern has formed and the tissue continues growing, is the pattern passively dilated like a drawing on an inflated balloon, or does the pattern remodel during tissue expansion? We address this question in the context of leaf vasculature and examine the role of mechanics in leaf growth. We model the growing vascular network and identify quantities that compare network growth to background tissue growth. We apply this quantification to mature leaves that are stretched mechanically; we find that vasculature does not dilate passively and that veins reorient in the direction of external forces. This is reminiscent of the reinforcement of bones or of the cytoskeleton so as to resist to mechanical stress. In a developmental context, this might be an essential process to match patterns and growth.

Published

2016

33. Modeling and Simulation of Mucus Flow in Human Bronchial Epithelial Cell Cultures – Part I: Idealized Axisymmetric Swirling Flow

Author

Paula A. Vasquez, Erik Palmer, David Hill, Yuan Jin, and M. Gregory Forest

Subjects

0301 basic medicine, Physiology, Constitutive equation, Physics::Fluid Dynamics, 0302 clinical medicine, Medicine and Health Sciences, Fluid dynamics, lcsh:QH301-705.5, Cells, Cultured, Flow Rate, Fluids, Physics::Biological Physics, Ecology, Viscosity, Physics, Classical Mechanics, Mechanics, respiratory system, Deformation, Body Fluids, Shear (sheet metal), Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, symbols, Biological Cultures, Anatomy, Cellular Structures and Organelles, Algorithms, Research Article, States of Matter, Materials science, Flow (psychology), Bronchi, Fluid Mechanics, Péclet number, Research and Analysis Methods, Drug Absorption, Continuum Mechanics, Models, Biological, Quantitative Biology::Other, Viscoelasticity, 03 medical and health sciences, Cellular and Molecular Neuroscience, symbols.namesake, Rheology, Genetics, Humans, Pharmacokinetics, Computer Simulation, Cilia, Fluid Flow, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Simulation, Pharmacology, Damage Mechanics, Biology and Life Sciences, Computational Biology, Fluid Dynamics, Epithelial Cells, Cell Biology, Cell Cultures, Mucus, Elasticity, 030104 developmental biology, lcsh:Biology (General), Nonlinear Dynamics, 030228 respiratory system

Abstract

A multi-mode nonlinear constitutive model for mucus is constructed directly from micro- and macro-rheology experimental data on cell culture mucus, and a numerical algorithm is developed for the culture geometry and idealized cilia driving conditions. This study investigates the roles that mucus rheology, wall effects, and HBE culture geometry play in the development of flow profiles and the shape of the air-mucus interface. Simulations show that viscoelasticity captures normal stress generation in shear leading to a peak in the air-mucus interface at the middle of the culture and a depression at the walls. Linear and nonlinear viscoelastic regimes can be observed in cultures by varying the hurricane radius and mean rotational velocity. The advection-diffusion of a drug concentration dropped at the surface of the mucus flow is simulated as a function of Peclet number., Author Summary In the lungs, the airway surface liquid protects the airway epithelium from inhaled pathogens and particulates. It is well known that failure to properly clear mucus from the airways leads to chronic, even fatal, lung infections. To date, there is no validated constitutive model capable of recapitulating mucus rheology under diverse, physiological stress and deformation conditions. This gap has hindered studies into the causal relationship between mucus rheology and mucociliary clearance. Our modeling-experimental approach fulfills several purposes: to implement linear and nonlinear constitutive modeling of mucus from micro- and macro-rheology, to test constitutive modeling in an independent experimental system, to build a coarse-grained model of the PCL-mucus boundary condition, to measure and understand modifications in mucociliary transport during and after deposition of a controlled drug concentration, to measure and simulate both the flow and stress fields throughout the mucus layer, and to measure and simulate how the advection profiles in the culture couple with diffusion of particulates landing on the air-mucus interface. These results lay the groundwork for extension of the code to three dimensions and more realistic metachronal wave boundary conditions, both in cell cultures and in airways.

Published

2016

34. Elastic modulus and toughness of orb spider glycoprotein glue

Author

Sheree F. Andrews, Mary E. Clouse, Brent D. Opell, and Biological Sciences

Subjects

030110 physiology, 0301 basic medicine, Atmospheric Science, Glycobiology, lcsh:Medicine, Predation, Modulus, Biochemistry, Physical Chemistry, Materials Physics, Composite material, lcsh:Science, Spider Webs, Multidisciplinary, Aqueous solution, Ecology, biology, Viscosity, Physics, Eukaryota, Spiders, Biomechanical Phenomena, Trophic Interactions, Insects, Fibers, Chemistry, Community Ecology, Physical Sciences, Insect Proteins, Female, Research Article, Toughness, Materials science, Arthropoda, Materials by Structure, Materials Science, Thread (computing), Viscoelasticity, 03 medical and health sciences, Meteorology, Species Specificity, Adhesives, Elastic Modulus, Arachnida, Animals, Elastic modulus, Materials by Attribute, Glycoproteins, lcsh:R, Ecology and Environmental Sciences, Organisms, technology, industry, and agriculture, Biology and Life Sciences, Humidity, Invertebrates, Fibronectins, Chemical Properties, Earth Sciences, biology.protein, lcsh:Q, Adhesive, Resilin

Abstract

An orb web's prey capture thread features tiny glue droplets, each formed of an adhesive glycoprotein core surrounded by an aqueous layer. Small molecules in the aqueous layer confer droplet hygroscopicity and maintain glycoprotein viscoelasticity, causing droplet volume and glycoprotein performance to track changes in environmental humidity. Droplet extension combines with that of a thread's supporting flagelliform fibers to sum the adhesive forces of multiple droplets, creating an effective adhesive system. We combined measurements of the force on an extending droplet, as gauged by the deflection of its support line, with measurements of glycoprotein volume and droplet extension to determine the Young's modulus (E) and toughness of three species' glycoproteins. We did this at five relative humidities between 20 - 90% to assess the effect of humidity on these properties. When droplets of a thread span extend, their extensions are constrained and their glycoprotein filaments remain covered by aqueous material. This was also the case during the first extension phase of the individual droplets that we examined. However, as extension progressed, the aqueous layer was progresses disrupted, exposing the glycoprotein. During the first extension phase E ranged from 0.00003 GPa, a value similar to that of fibronectin, a glycoprotein that anchors cells in the extracellular matrix, to 0.00292 GPa, a value similar to that of resilin in insect ligaments. Second phase E increased 4.7 - 19.4-fold. When compared at the same humidity the E of each species' glycoprotein was less than 5% of the value reported for its flagelliform fibers. This difference may facilitate the coordinated extension of these two capture thread components that is responsible for summing the thread's adhesive forces. National Science Foundation grant [IOS-1257719] National Science Foundation grant IOS-1257719 (BO) supported this study. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Published

2018

35. Quantitative characterization of viscoelastic behavior in tissue-mimicking phantoms and ex vivo animal tissues

Author

George N. Saddik, Warren S. Grundfest, Nikan K. Namiri, Neha Bajwa, Maie A. St. John, Andrew Shin, Ashkan Maccabi, Zachary Taylor, and Dague, Etienne

Subjects

Male, Swine, 02 engineering and technology, Palpation, Phantoms, Imaging, 030218 nuclear medicine & medical imaging, Rats, Sprague-Dawley, 0302 clinical medicine, Models, Animal Products, Medicine and Health Sciences, Relaxation Time, Biomechanics, screening and diagnosis, Multidisciplinary, medicine.diagnostic_test, Phantoms, Imaging, Viscosity, Liver Disease, Physics, Gallbladder, Classical Mechanics, Soft tissue, Agriculture, Deformation, Detection, Liver, Homogeneous, Physical Sciences, Models, Animal, Medicine, Anatomy, Research Article, Tissue Mechanics, Materials science, General Science & Technology, Tissue mimicking phantom, Science, Materials Science, Material Properties, 0206 medical engineering, Biophysics, Bioengineering, Viscoelasticity, 03 medical and health sciences, medicine, Mechanical Properties, Animals, Relaxation (Physics), Damage Mechanics, Animal, Biology and Life Sciences, Acoustics, 020601 biomedical engineering, Elasticity, Rats, 4.1 Discovery and preclinical testing of markers and technologies, Tumor detection, Biliary System, Rat liver, Gelatin, Sprague-Dawley, Digestive Diseases, Ex vivo, Biomedical engineering

Abstract

Viscoelasticity of soft tissue is often related to pathology, and therefore, has become an important diagnostic indicator in the clinical assessment of suspect tissue. Surgeons, particularly within head and neck subsites, typically use palpation techniques for intra-operative tumor detection. This detection method, however, is highly subjective and often fails to detect small or deep abnormalities. Vibroacoustography (VA) and similar methods have previously been used to distinguish tissue with high-contrast, but a firm understanding of the main contrast mechanism has yet to be verified. The contributions of tissue mechanical properties in VA images have been difficult to verify given the limited literature on viscoelastic properties of various normal and diseased tissue. This paper aims to investigate viscoelasticity theory and present a detailed description of viscoelastic experimental results obtained in tissue-mimicking phantoms (TMPs) and ex vivo tissues to verify the main contrast mechanism in VA and similar imaging modalities. A spherical-tip micro-indentation technique was employed with the Hertzian model to acquire absolute, quantitative, point measurements of the elastic modulus (E), long term shear modulus (η), and time constant (τ) in homogeneous TMPs and ex vivo tissue in rat liver and porcine liver and gallbladder. Viscoelastic differences observed between porcine liver and gallbladder tissue suggest that imaging modalities which utilize the mechanical properties of tissue as a primary contrast mechanism can potentially be used to quantitatively differentiate between proximate organs in a clinical setting. These results may facilitate more accurate tissue modeling and add information not currently available to the field of systems characterization and biomedical research.

Published

2018

36. In Vivo Dynamic Deformation of Articular Cartilage in Intact Joints Loaded by Controlled Muscular Contractions

Author

Ziad Abusara, Markus Von Kossel, and Walter Herzog

Subjects

0301 basic medicine, Cartilage, Articular, Muscle Physiology, Knee Joint, Physiology, Knees, lcsh:Medicine, 02 engineering and technology, Isometric exercise, Statics, medicine.disease_cause, Weight-bearing, Weight-Bearing, Mice, Animal Cells, Medicine and Health Sciences, Biomechanics, lcsh:Science, Musculoskeletal System, Connective Tissue Cells, Multidisciplinary, Physics, Classical Mechanics, Anatomy, Deformation, medicine.anatomical_structure, Connective Tissue, Physical Sciences, Legs, medicine.symptom, Cellular Types, Muscle contraction, Muscle Contraction, Research Article, musculoskeletal diseases, Materials science, 0206 medical engineering, Deformation (meteorology), Viscoelasticity, 03 medical and health sciences, Chondrocytes, medicine, Animals, Damage Mechanics, Cartilage, lcsh:R, Limbs (Anatomy), Biology and Life Sciences, Cell Biology, 020601 biomedical engineering, 030104 developmental biology, Contact mechanics, Biological Tissue, lcsh:Q, Stress, Mechanical, Musculoskeletal Mechanics, Articular Cartilage

Abstract

When synovial joints are loaded, the articular cartilage and the cells residing in it deform. Cartilage deformation has been related to structural tissue damage, and cell deformation has been associated with cell signalling and corresponding anabolic and catabolic responses. Despite the acknowledged importance of cartilage and cell deformation, there are no dynamic data on these measures from joints of live animals using muscular load application. Research in this area has typically been done using confined and unconfined loading configurations and indentation testing. These loading conditions can be well controlled and allow for accurate measurements of cartilage and cell deformations, but they have little to do with the contact mechanics occurring in a joint where non-congruent cartilage surfaces with different material and functional properties are pressed against each other by muscular forces. The aim of this study was to measure in vivo, real time articular cartilage deformations for precisely controlled static and dynamic muscular loading conditions in the knees of mice. Fifty and 80% of the maximal knee extensor muscular force (equivalent to approximately 0.4N and 0.6N) produced average peak articular cartilage strains of 10.5±1.0% and 18.3±1.3% (Mean ± SD), respectively, during 8s contractions. A sequence of 15 repeat, isometric muscular contractions (0.5s on, 3.5s off) of 50% and 80% of maximal muscular force produced cartilage strains of 3.0±1.1% and 9.6±1.5% (Mean ± SD) on the femoral condyles of the mouse knee. Cartilage thickness recovery following mechanical compression was highly viscoelastic and took almost 50s following force removal in the static tests.

Published

2015

37. Corneal viscoelastic properties from finite-element analysis of in vivo air-puff deformation

Author

Sabine Kling, Susana Marcos, Nandor Bekesi, Daniel Pascual, and Carlos Dorronsoro

Subjects

Computer and Information Sciences, Tissue Mechanics, genetic structures, Science, Dynamic imaging, Finite Element Analysis, Materials Science, Material Properties, Deformation (meteorology), Bioinformatics, Viscoelasticity, Biomechanical Phenomena, Cornea, Biological Fluid Mechanics, medicine, Medicine and Health Sciences, Humans, Mechanical Properties, Biomechanics, Physics, Multidisciplinary, Viscosity, Air, Stiffness, Biology and Life Sciences, Elasticity (physics), Models, Theoretical, Finite element method, eye diseases, Elasticity, Ophthalmology, medicine.anatomical_structure, Physical Sciences, Corneal Disorders, Medicine, Materials Characterization, sense organs, medicine.symptom, Biomedical engineering, Research Article, Computer Modeling

Abstract

Biomechanical properties are an excellent health marker of biological tissues, however they are challenging to be measured in-vivo. Non-invasive approaches to assess tissue biomechanics have been suggested, but there is a clear need for more accurate techniques for diagnosis, surgical guidance and treatment evaluation. Recently air-puff systems have been developed to study the dynamic tissue response, nevertheless the experimental geometrical observations lack from an analysis that addresses specifically the inherent dynamic properties. In this study a viscoelastic finite element model was built that predicts the experimental corneal deformation response to an air-puff for different conditions. A sensitivity analysis reveals significant contributions to corneal deformation of intraocular pressure and corneal thickness, besides corneal biomechanical properties. The results show the capability of dynamic imaging to reveal inherent biomechanical properties in vivo. Estimates of corneal biomechanical parameters will contribute to the basic understanding of corneal structure, shape and integrity and increase the predictability of corneal surgery. © 2014 Kling et al., Spanish Government FIS2011-25637, European Research Council ERC-2011 AdG-294099 to SM. FPI-BES-2009-024560 Pre-doctoral Fellowship to SK.

Published

2014

38. High-Resolution Mechanical Imaging of Glioblastoma by Multifrequency Magnetic Resonance Elastography

Author

Jens Wuerfel, Karl-Titus Hoffmann, Jürgen Braun, Martin Reiss-Zimmermann, Kaspar-Josche Streitberger, Jing Guo, Florian Baptist Freimann, Felix Arlt, Ingolf Sack, and Simon Bayerl

Subjects

Male, Pathology, Cancer detection and diagnosis, Edema, Hemorrhage, Magnetic resonance imaging, Necrosis, Tissue repair, Tumor physiology, Vibration, lcsh:Medicine, 600 Technik, Medizin, angewandte Wissenschaften::610 Medizin und Gesundheit, Brain mapping, 030218 nuclear medicine & medical imaging, Elasticity Imaging Techniques, 0302 clinical medicine, Nuclear magnetic resonance, Medicine and Health Sciences, Biomechanics, lcsh:Science, Physics, Brain Mapping, Multidisciplinary, medicine.diagnostic_test, Brain Neoplasms, Radiology and Imaging, Brain, Middle Aged, Magnetic Resonance Imaging, Neurology, Preoperative Period, Female, Elastography, Research Article, Adult, medicine.medical_specialty, Adolescent, Biophysics, Viscoelasticity, Shear modulus, 03 medical and health sciences, Imaging, Three-Dimensional, Image Interpretation, Computer-Assisted, medicine, Humans, Aged, lcsh:R, Biology and Life Sciences, Magnetoencephalography, Elasticity, Magnetic resonance elastography, lcsh:Q, Glioblastoma, 030217 neurology & neurosurgery

Abstract

Objective To generate high-resolution maps of the viscoelastic properties of human brain parenchyma for presurgical quantitative assessment in glioblastoma (GB). Methods Twenty-two GB patients underwent routine presurgical work-up supplemented by additional multifrequency magnetic resonance elastography. Two three-dimensional viscoelastic parameter maps, magnitude |G*|, and phase angle φ of the complex shear modulus were reconstructed by inversion of full wave field data in 2-mm isotropic resolution at seven harmonic drive frequencies ranging from 30 to 60 Hz. Results Mechanical brain maps confirmed that GB are composed of stiff and soft compartments, resulting in high intratumor heterogeneity. GB could be easily differentiated from healthy reference tissue by their reduced viscous behavior quantified by φ (0.37±0.08 vs. 0.58±0.07). |G*|, which in solids more relates to the material's stiffness, was significantly reduced in GB with a mean value of 1.32±0.26 kPa compared to 1.54±0.27 kPa in healthy tissue (P = 0.001). However, some GB (5 of 22) showed increased stiffness. Conclusion GB are generally less viscous and softer than healthy brain parenchyma. Unrelated to the morphology-based contrast of standard magnetic resonance imaging, elastography provides an entirely new neuroradiological marker and contrast related to the biomechanical properties of tumors.

Published

2014

39. Modeling of Mesoscale Variability in Biofilm Shear Behavior

Author

Partha P. Mukherjee, Aloke Kumar, and Pallab Barai

Subjects

Exopolysaccharides, Glycobiology, lcsh:Medicine, 02 engineering and technology, Biochemistry, 01 natural sciences, Bacterial Adhesion, Stiffness, Diagnostic Radiology, Materials Physics, Medicine and Health Sciences, Composite material, lcsh:Science, Microstructure, chemistry.chemical_classification, Brain Mapping, Multidisciplinary, Physics, Radiology and Imaging, Classical Mechanics, Polymer, 021001 nanoscience & nanotechnology, Magnetic Resonance Imaging, Deformation, Biomechanical Phenomena, Extracellular Matrix, Shear (geology), Physical Sciences, Cellular Structures and Organelles, medicine.symptom, Shear Strength, 0210 nano-technology, Research Article, Materials science, Imaging Techniques, Brain Morphometry, Materials Science, Material Properties, Mesoscale meteorology, Neuroimaging, Bacterial Physiological Phenomena, Research and Analysis Methods, 010402 general chemistry, Models, Biological, Microbiology, Viscoelasticity, Polysaccharides, Diagnostic Medicine, medicine, Humans, Mechanical Properties, Deformation-Based Morphometry, Damage Mechanics, Morphometry, lcsh:R, Biofilm, Biology and Life Sciences, Bacteriology, Cell Biology, 0104 chemical sciences, chemistry, Biofilms, lcsh:Q, Bacterial Biofilms, Neuroscience

Abstract

Formation of bacterial colonies as biofilm on the surface/interface of various objects has the potential to impact not only human health and disease but also energy and environmental considerations. Biofilms can be regarded as soft materials, and comprehension of their shear response to external forces is a key element to the fundamental understanding. A mesoscale model has been presented in this article based on digitization of a biofilm microstructure. Its response under externally applied shear load is analyzed. Strain stiffening type behavior is readily observed under high strain loads due to the unfolding of chains within soft polymeric substrate. Sustained shear loading of the biofilm network results in strain localization along the diagonal direction. Rupture of the soft polymeric matrix can potentially reduce the intercellular interaction between the bacterial cells. Evolution of stiffness within the biofilm network under shear reveals two regimes: a) initial increase in stiffness due to strain stiffening of polymer matrix, and b) eventual reduction in stiffness because of tear in polymeric substrate.

Published

2016

40. An active poroelastic model for mechanochemical patterns in protoplasmic droplets of Physarum polycephalum

Author

Markus Radszuweit, Markus Bär, and Harald Engel

Subjects

Cytoplasm, lcsh:Medicine, Pattern Formation and Solitons (nlin.PS), Quantitative Biology::Cell Behavior, Biophysics Theory, Physics::Fluid Dynamics, pattern formation, Materials Physics, Physarum polycephalum, Cell Behavior (q-bio.CB), active gels, Cell Mechanics, Biomechanics, lcsh:Science, Cytoskeleton, Physics, Multidisciplinary, Physarum, biology, amoeboid movement, Turbulence, Classical Mechanics, 92C15, Biomechanical Phenomena, 89.75.Kd, Cell Motility, Classical mechanics, Drag, Physical Sciences, Research Article, Biotechnology, Biophysical Simulations, Materials Science, Poromechanics, Biophysics, FOS: Physical sciences, Viscous liquid, Continuum Mechanics, Models, Biological, Viscoelasticity, poroelasticity, Biomaterials, Standing wave, Quantitative Biology::Subcellular Processes, two-phase models, lcsh:R, Biology and Life Sciences, Cell Biology, biology.organism_classification, Nonlinear Sciences - Pattern Formation and Solitons, Elasticity, FOS: Biological sciences, Quantitative Biology - Cell Behavior, lcsh:Q, Calcium, Stress, Mechanical

Abstract

Motivated by recent experimental studies, we derive and analyze a twodimensional model for the contraction patterns observed in protoplasmic droplets of Physarum polycephalum. The model couples a model of an active poroelastic two-phase medium with equations describing the spatiotemporal dynamics of the intracellular free calcium concentration. The poroelastic medium is assumed to consist of an active viscoelastic solid representing the cytoskeleton and a viscous fluid describing the cytosol. The model equations for the poroelastic medium are obtained from continuum force-balance equations that include the relevant mechanical fields and an incompressibility relation for the two-phase medium. The reaction-diffusion equations for the calcium dynamics in the protoplasm of Physarum are extended by advective transport due to the flow of the cytosol generated by mechanical stresses. Moreover, we assume that the active tension in the solid cytoskeleton is regulated by the calcium concentration in the fluid phase at the same location, which introduces a chemomechanical feedback. A linear stability analysis of the homogeneous state without deformation and cytosolic flows exhibits an oscillatory Turing instability for a large enough mechanochemical coupling strength. Numerical simulations of the model equations reproduce a large variety of wave patterns, including traveling and standing waves, turbulent patterns, rotating spirals and antiphase oscillations in line with experimental observations of contraction patterns in the protoplasmic droplets., Comment: Additional supplemental material is supplied

Published

2013