Your search keyword '"Marino Arroyo"' showing total 120 results

1. 3D Micropatterned Traction Force Microscopy: A Technique to Control 3D Cell Shape While Measuring Cell‐Substrate Force Transmission

Author

Laura M. Faure, Manuel Gómez‐González, Ona Baguer, Jordi Comelles, Elena Martínez, Marino Arroyo, Xavier Trepat, and Pere Roca‐Cusachs

Subjects

cell volumes, cytoskeleton, micro‐wells, traction forces, Science

Abstract

Abstract Cell shape and function are intimately linked, in a way that is mediated by the forces exerted between cells and their environment. The relationship between cell shape and forces has been extensively studied for cells seeded on flat 2D substrates, but not for cells in more physiological 3D settings. Here, a technique called 3D micropatterned traction force microscopy (3D‐µTFM) to confine cells in 3D wells of defined shape, while simultaneously measuring the forces transmitted between cells and their microenvironment is demonstrated. This technique is based on the 3D micropatterning of polyacrylamide wells and on the calculation of 3D traction force from their deformation. With 3D‐µTFM, it is shown that MCF10A breast epithelial cells exert defined, reproducible patterns of forces on their microenvironment, which can be both contractile and extensile. Cells switch from a global contractile to extensile behavior as their volume is reduced are further shown. The technique enables the quantitative study of cell mechanobiology with full access to 3D cellular forces while having accurate control over cell morphology and the mechanical conditions of the microenvironment.

Published

2024

2. Patterning and dynamics of membrane adhesion under hydraulic stress

Author

Céline Dinet, Alejandro Torres-Sánchez, Roberta Lanfranco, Lorenzo Di Michele, Marino Arroyo, and Margarita Staykova

Subjects

Science

Abstract

Abstract Hydraulic fracturing plays a major role in cavity formation during embryonic development, when pressurized fluid opens microlumens at cell-cell contacts, which evolve to form a single large lumen. However, the fundamental physical mechanisms behind these processes remain masked by the complexity and specificity of biological systems. Here, we show that adhered lipid vesicles subjected to osmotic stress form hydraulic microlumens similar to those in cells. Combining vesicle experiments with theoretical modelling and numerical simulations, we provide a physical framework for the hydraulic reconfiguration of cell-cell adhesions. We map the conditions for microlumen formation from a pristine adhesion, the emerging dynamical patterns and their subsequent maturation. We demonstrate control of the fracturing process depending on the applied pressure gradients and the type and density of membrane bonds. Our experiments further reveal an unexpected, passive transition of microlumens to closed buds that suggests a physical route to adhesion remodeling by endocytosis.

Published

2023

3. Mapping mechanical stress in curved epithelia of designed size and shape

Author

Ariadna Marín-Llauradó, Sohan Kale, Adam Ouzeri, Tom Golde, Raimon Sunyer, Alejandro Torres-Sánchez, Ernest Latorre, Manuel Gómez-González, Pere Roca-Cusachs, Marino Arroyo, and Xavier Trepat

Subjects

Science

Abstract

Abstract The function of organs such as lungs, kidneys and mammary glands relies on the three-dimensional geometry of their epithelium. To adopt shapes such as spheres, tubes and ellipsoids, epithelia generate mechanical stresses that are generally unknown. Here we engineer curved epithelial monolayers of controlled size and shape and map their state of stress. We design pressurized epithelia with circular, rectangular and ellipsoidal footprints. We develop a computational method, called curved monolayer stress microscopy, to map the stress tensor in these epithelia. This method establishes a correspondence between epithelial shape and mechanical stress without assumptions of material properties. In epithelia with spherical geometry we show that stress weakly increases with areal strain in a size-independent manner. In epithelia with rectangular and ellipsoidal cross-section we find pronounced stress anisotropies that impact cell alignment. Our approach enables a systematic study of how geometry and stress influence epithelial fate and function in three-dimensions.

Published

2023

4. A mechanosensing mechanism controls plasma membrane shape homeostasis at the nanoscale

Author

Xarxa Quiroga, Nikhil Walani, Andrea Disanza, Albert Chavero, Alexandra Mittens, Francesc Tebar, Xavier Trepat, Robert G Parton, María Isabel Geli, Giorgio Scita, Marino Arroyo, Anabel-Lise Le Roux, and Pere Roca-Cusachs

Subjects

mechanobiology, bar proteins, membrane biophysics, Medicine, Science, Biology (General), QH301-705.5

Abstract

As cells migrate and experience forces from their surroundings, they constantly undergo mechanical deformations which reshape their plasma membrane (PM). To maintain homeostasis, cells need to detect and restore such changes, not only in terms of overall PM area and tension as previously described, but also in terms of local, nanoscale topography. Here, we describe a novel phenomenon, by which cells sense and restore mechanically induced PM nanoscale deformations. We show that cell stretch and subsequent compression reshape the PM in a way that generates local membrane evaginations in the 100 nm scale. These evaginations are recognized by I-BAR proteins, which triggers a burst of actin polymerization mediated by Rac1 and Arp2/3. The actin polymerization burst subsequently re-flattens the evagination, completing the mechanochemical feedback loop. Our results demonstrate a new mechanosensing mechanism for PM shape homeostasis, with potential applicability in different physiological scenarios.

Published

2023

5. Dynamic mechanochemical feedback between curved membranes and BAR protein self-organization

Author

Anabel-Lise Le Roux, Caterina Tozzi, Nikhil Walani, Xarxa Quiroga, Dobryna Zalvidea, Xavier Trepat, Margarita Staykova, Marino Arroyo, and Pere Roca-Cusachs

Subjects

Science

Abstract

Amphiphysin BAR proteins reshape membranes, but the dynamics of the process remained unexplored. Here, the authors show through experiment and modelling that reshaping depends on the initial template shape, occurs even at low initial curvature, and involves the coexistence of isotropic and nematic states.

Published

2021

6. A physical mechanism of TANGO1-mediated bulky cargo export

Author

Ishier Raote, Morgan Chabanon, Nikhil Walani, Marino Arroyo, Maria F Garcia-Parajo, Vivek Malhotra, and Felix Campelo

Subjects

membrane tension, procollagen export, secretory pathway, membrane curvature, membrane dynamics, budding, Medicine, Science, Biology (General), QH301-705.5

Abstract

The endoplasmic reticulum (ER)-resident protein TANGO1 assembles into a ring around ER exit sites (ERES), and links procollagens in the ER lumen to COPII machinery, tethers, and ER-Golgi intermediate compartment (ERGIC) in the cytoplasm (Raote et al., 2018). Here, we present a theoretical approach to investigate the physical mechanisms of TANGO1 ring assembly and how COPII polymerization, membrane tension, and force facilitate the formation of a transport intermediate for procollagen export. Our results indicate that a TANGO1 ring, by acting as a linactant, stabilizes the open neck of a nascent COPII bud. Elongation of such a bud into a transport intermediate commensurate with bulky procollagens is then facilitated by two complementary mechanisms: (i) by relieving membrane tension, possibly by TANGO1-mediated fusion of retrograde ERGIC membranes and (ii) by force application. Altogether, our theoretical approach identifies key biophysical events in TANGO1-driven procollagen export.

Published

2020

7. Out-of-equilibrium mechanochemistry and self-organization of fluid membranes interacting with curved proteins

Author

Caterina Tozzi, Nikhil Walani, and Marino Arroyo

Subjects

lipid bilayers, membrane proteins, curvature sensing, curvature generation, Science, Physics, QC1-999

Abstract

The function of biological membranes is controlled by the interaction of the fluid lipid bilayer with various proteins, some of which induce or react to curvature. These proteins can preferentially bind or diffuse towards curved regions of the membrane, induce or stabilize membrane curvature and sequester membrane area into protein-rich curved domains. The resulting tight interplay between mechanics and chemistry is thought to control organelle morphogenesis and dynamics, including traffic, membrane mechanotransduction, or membrane area regulation and tension buffering. Despite all these processes are fundamentally dynamical, previous work has largely focused on equilibrium and a self-consistent theoretical treatment of the dynamics of curvature sensing and generation has been lacking. Here, we develop a general theoretical and computational framework based on a nonlinear Onsager’s formalism of irreversible thermodynamics for the dynamics of curved proteins and membranes. We develop variants of the model, one of which accounts for membrane curving by asymmetric crowding of bulky off-membrane protein domains. As illustrated by a selection of test cases, the resulting governing equations and numerical simulations provide a foundation to understand the dynamics of curvature sensing, curvature generation, and more generally membrane curvature mechano-chemistry.

Published

2019

8. Force transduction and lipid binding in MscL: a continuum-molecular approach.

Author

Juan M Vanegas and Marino Arroyo

Subjects

Medicine, Science

Abstract

The bacterial mechanosensitive channel MscL, a small protein mainly activated by membrane tension, is a central model system to study the transduction of mechanical stimuli into chemical signals. Mutagenic studies suggest that MscL gating strongly depends on both intra-protein and interfacial lipid-protein interactions. However, there is a gap between this detailed chemical information and current mechanical models of MscL gating. Here, we investigate the MscL bilayer-protein interface through molecular dynamics simulations, and take a combined continuum-molecular approach to connect chemistry and mechanics. We quantify the effect of membrane tension on the forces acting on the surface of the channel, and identify interactions that may be critical in the force transduction between the membrane and MscL. We find that the local stress distribution on the protein surface is largely asymmetric, particularly under tension, with the cytoplasmic side showing significantly larger and more localized forces, which pull the protein radially outward. The molecular interactions that mediate this behavior arise from hydrogen bonds between the electronegative oxygens in the lipid headgroup and a cluster of positively charged lysine residues on the amphipathic S1 domain and the C-terminal end of the second trans-membrane helix. We take advantage of this strong interaction (estimated to be 10-13 kT per lipid) to actuate the channel (by applying forces on protein-bound lipids) and explore its sensitivity to the pulling magnitude and direction. We conclude by highlighting the simple motif that confers MscL with strong anchoring to the bilayer, and its presence in various integral membrane proteins including the human mechanosensitive channel K2P1 and bovine rhodopsin.

Published

2014

9. Mechanics of tubular meshes made of helical fibers and application to modeling McKibben artificial muscles.

Author

Jacopo Quaglierini, Marino Arroyo, and Antonio DeSimone

Published

2023

10. Approximation of tensor fields on surfaces of arbitrary topology based on local Monge parametrizations.

Author

Alejandro Torres-Sánchez, Daniel Santos-Oliván, and Marino Arroyo

Published

2020

11. Binding of anisotropic curvature-inducing proteins onto membrane tubes

Author

Hiroshi Noguchi, Caterina Tozzi, and Marino Arroyo

Subjects

Quantitative Biology::Biomolecules, Membranes, Quantitative Biology::Molecular Networks, Cell Membrane, FOS: Physical sciences, General Chemistry, Condensed Matter - Soft Condensed Matter, Condensed Matter Physics, Quantitative Biology::Subcellular Processes, Biological Physics (physics.bio-ph), Soft Condensed Matter (cond-mat.soft), Anisotropy, Computer Simulation, Physics - Biological Physics, Protein Binding

Abstract

Bin/Amphiphysin/Rvs superfamily proteins and other curvature-inducing proteins have anisotropic shapes and anisotropically bend biomembrane. Here, we report how the anisotropic proteins bind the membrane tube and are orientationally ordered using mean-field theory including an orientation-dependent excluded volume. The proteins exhibit a second-order or first-order nematic transition with increasing protein density depending on the radius of the membrane tube. The tube curvatures for the maximum protein binding and orientational order are different and varied by the protein density and rigidity. As the external force along the tube axis increases, a first-order transition from a large tube radius with low protein density to a small radius with high density occurs once, and subsequently, the protein orientation tilts to the tube-axis direction. When an isotropic bending energy is used for the proteins with an elliptic shape, the force-dependence curves become symmetric and the first-order transition occurs twice. This theory quantitatively reproduces the results of meshless membrane simulation for short proteins, whereas deviations are seen for long proteins owing to the formation of protein clusters., 11 pages, 13 figures

Published

2022

12. Patterning of membrane adhesion under hydraulic stress

Author

Céline Dinet, Alejandro Torres-Sánchez, Marino Arroyo, and Margarita Staykova

Abstract

Hydraulic fracturing plays a major role in the formation of biological lumens during embryonic development, when the accumulation of pressurized fluid leads to the formation of microlumens that fracture cell-cell contacts and later evolve to form a single large lumen. However, the physical principles underpinning the formation of a pattern of microlumens from a pristine adhesion and their subsequent coarsening are poorly understood. Here, we use giant unilamellar vesicles adhered to a supported lipid bilayer and subjected to osmotic stress to generate and follow the dynamics of hydraulic fracturing akin to those in cells. Using this simplified system together with theoretical modelling and numerical simulations, we provide a mechanistic understanding of the nucleation of hydraulic cracks, their spatial patterns and their coarsening dynamics. Besides coarsening, we show that microlumens can irreversibly bud out of the membrane, reminiscent of endocytic vesicles in cell-cell adhesion. By establishing the physics of patterning and dynamics of hydraulic cracks, our work unveils the mechanical constraints for the biological regulation of hydraulically-driven adhesion remodeling.

Published

2023

13. Caveolin-1 dolines form a distinct and rapid caveolae-independent mechanoadaptation system

Author

Fidel-Nicolás Lolo, Nikhil Walani, Eric Seemann, Dobryna Zalvidea, Dácil María Pavón, Gheorghe Cojoc, Moreno Zamai, Christine Viaris de Lesegno, Fernando Martínez de Benito, Miguel Sánchez-Álvarez, Juan José Uriarte, Asier Echarri, Daniel Jiménez-Carretero, Joan-Carles Escolano, Susana A. Sánchez, Valeria R. Caiolfa, Daniel Navajas, Xavier Trepat, Jochen Guck, Christophe Lamaze, Pere Roca-Cusachs, Michael M. Kessels, Britta Qualmann, Marino Arroyo, Miguel A. del Pozo, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria, Unión Europea. Comisión Europea. H2020, Marie Curie, Ministerio de Ciencia e Innovación (España), European Union Next Generation, Asociación Española Contra el Cáncer, Comunidad de Madrid (España), Fundación La Marató TV3, Fundación La Caixa, Ministerio de Ciencia e Innovación. Centro de Excelencia Severo Ochoa (España), and Fundación ProCNIC

Subjects

Biomathematics, Biologia, Biomatemàtica, 92 Biology and other natural sciences::92B Mathematical biology in general [Classificació AMS], Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Cell Biology, Biology, 92 Biology and other natural sciences::92C Physiological, cellular and medical topics [Classificació AMS]

Abstract

In response to different types and intensities of mechanical force, cells modulate their physical properties and adapt their plasma membrane (PM). Caveolae are PM nano-invaginations that contribute to mechanoadaptation, buffering tension changes. However, whether core caveolar proteins contribute to PM tension accommodation independently from the caveolar assembly is unknown. Here we provide experimental and computational evidence supporting that caveolin-1 confers deformability and mechanoprotection independently from caveolae, through modulation of PM curvature. Freeze-fracture electron microscopy reveals that caveolin-1 stabilizes non-caveolar invaginations-dolines-capable of responding to low-medium mechanical forces, impacting downstream mechanotransduction and conferring mechanoprotection to cells devoid of caveolae. Upon cavin-1/PTRF binding, doline size is restricted and membrane buffering is limited to relatively high forces, capable of flattening caveolae. Thus, caveolae and dolines constitute two distinct albeit complementary components of a buffering system that allows cells to adapt efficiently to a broad range of mechanical stimuli. We thank R. Parton (Institute for Molecular Biosciences, Queensland), P. Pilch (Boston University School of Medicine) and L. Liu (Boston University School of Medicine) for kindly providing PTRFKO cells and reagents, S. Casas Tintó for kindly providing SH-Sy5y cells, P. Bassereau (Curie Institute, Paris) for kindly providing OT setup, V. Labrador Cantarero from CNIC microscopy Unit for helping with ImageJ analysis, O. Otto and M. Herbig for providing help with RTDC experiments, S. Berr and K. Gluth for technical assistance in cell culture, F. Steiniger for support in electron tomography, and A. Norczyk Simón for providing pCMV-FLAG-PTRF construct. This project received funding from the European Union Horizon 2020 Research and Innovation Programme through Marie Sklodowska-Curie grant 641639; grants from the Spanish Ministry of Science and Innovation (MCIN/AEI/10.13039/501100011033): SAF2014-51876-R, SAF2017-83130-R co-funded by ‘ERDF A way of making Europe’, PID2020-118658RB-I00, PDC2021-121572-100 co-funded by ‘European Union NextGenerationEU/PRTR’, CSD2009- 0016 and BFU2016-81912-REDC; and the Asociación Española Contra el Cáncer foundation (PROYE20089DELP) all to M.A.d.P. M.A.d.P. is member of the Tec4Bio consortium (ref. S2018/NMT¬4443; Comunidad Autónoma de Madrid/FEDER, Spain), co-recipient with P.R.-C. of grants from Fundació La Marató de TV3 (674/C/2013 and 201936- 30-31), and coordinator of a Health Research consortium grant from Fundación Obra Social La Caixa (AtheroConvergence, HR20-00075). M.S.-A. is recipient of a Ramón y Cajal research contract from MCIN (RYC2020-029690-I). The CNIC Unit of Microscopy and Dynamic Imaging is supported by FEDER ‘Una manera de hacer Europa’ (ReDIB ICTS infrastructure TRIMA@CNIC, MCIN). We acknowledge the support from Deutsche Forschungsgemeinschaft through grants to M.M.K. (KE685/7-1) and B.Q. (QU116/6-2 and QU116/9-1). Work in D.N. laboratory was supported by grants from the European Union Horizon 2020 Research and Innovation Programme through Marie Sklodowska-Curie grant 812772 and MCIN (DPI2017-83721-P). Work in C.L. laboratory was supported by grants from Curie, INSERM, CNRS, Agence Nationale de la Recherche (ANR-17-CE13-0020-01) and Fondation ARC pour la Recherche (PGA1-RF20170205456). Work in P.R.-C. lab is funded by the MCIN (PID2019-110298GB-I00), the EC (H20 20-FETPROACT-01-2016-731957). Work in X.T. lab is funded by the MICIN (PID2021-128635NB-I00), ERC (Adv-883739) and La Caixa Foundation (LCF/PR/HR20/52400004; co-recipient with P.R.-C.). IBEC is recipient of a Severo Ochoa Award of Excellence from the MINECO. The funders had no role in study design, data collection and analysis, decision to publish or preparation of the manuscript. The CNIC is supported by the Instituto de Salud Carlos III (ISCIII), the MCIN and the Pro CNIC Foundation, and is a Severo Ochoa Center of Excellence (grant CEX2020-001041-S funded by MICIN/AEI/10.13039/501100011033). Sí

Published

2022

14. Mechanical compartmentalization of the intestinal organoid enables crypt folding and collective cell migration

Author

Gerardo Ceada, Marija Matejčić, Andrew G. Clark, Marino Arroyo, Anghara Menendez, Denis Krndija, Venkata Ram Gannavarapu, Pere Roca-Cusachs, Natalia Castro, Manuel Gomez-Gonzalez, Xavier Trepat, Adrián Álvarez-Varela, Francesco Greco, Carlos Pérez-González, Danijela Matic Vignjevic, Sohan Kale, Eduard Batlle, Universitat Politècnica de Catalunya. Centre Específic de Recerca de Mètodes Numèrics en Ciències Aplicades i Enginyeria, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Biomatemàtica, Crypt, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Numerical analysis--Simulation methods, Extracellular matrix, 03 medical and health sciences, 0302 clinical medicine, Organoid, Cell migration, 65 Numerical analysis::65C Probabilistic methods, simulation and stochastic differential equations [Classificació AMS], 030304 developmental biology, Biomathematics, Anàlisi numèrica, Intestins, 0303 health sciences, Migració cel·lular, Chemistry, Matemàtiques i estadística::Anàlisi numèrica::Mètodes numèrics [Àrees temàtiques de la UPC], 92 Biology and other natural sciences::92B Mathematical biology in general [Classificació AMS], Apical constriction, Cell Biology, Compartmentalization (psychology), Intestinal epithelium, Cell biology, Intestines, Folding (chemistry), 030220 oncology & carcinogenesis, Self-healing hydrogels

Abstract

Intestinal organoids capture essential features of the intestinal epithelium such as crypt folding, cellular compartmentalization and collective movements. Each of these processes and their coordination require patterned forces that are at present unknown. Here we map three-dimensional cellular forces in mouse intestinal organoids grown on soft hydrogels. We show that these organoids exhibit a non-monotonic stress distribution that defines mechanical and functional compartments. The stem cell compartment pushes the extracellular matrix and folds through apical constriction, whereas the transit amplifying zone pulls the extracellular matrix and elongates through basal constriction. The size of the stem cell compartment depends on the extracellular-matrix stiffness and endogenous cellular forces. Computational modelling reveals that crypt shape and force distribution rely on cell surface tensions following cortical actomyosin density. Finally, cells are pulled out of the crypt along a gradient of increasing tension. Our study unveils how patterned forces enable compartmentalization, folding and collective migration in the intestinal epithelium.

Published

2021

15. An adaptive meshfree method for phase-field models of biomembranes. Part I: Approximation with maximum-entropy basis functions.

Author

A. Rosolen, C. Peco, and Marino Arroyo

Published

2013

16. An adaptive meshfree method for phase-field models of biomembranes. Part II: A Lagrangian approach for membranes in viscous fluids.

Author

C. Peco, A. Rosolen, and Marino Arroyo

Published

2013

17. Mapping mechanical stress in curved epithelia of designed size and shape

Author

Ariadna Marín-Llauradó, Sohan Kale, Adam Ouzeri, Raimon Sunyer, Alejandro Torres-Sánchez, Ernest Latorre, Manuel Gómez-González, Pere Roca-Cusachs, Marino Arroyo, and Xavier Trepat

Abstract

The function of organs such as lungs, kidneys and mammary glands relies on the three-dimensional geometry of their epithelium. To adopt shapes such as spheres, tubes and ellipsoids, epithelia generate mechanical stresses that are generally unknown. Here we engineered curved epithelial monolayers of controlled size and shape and mapped their state of stress. We designed pressurized epithelia with circular, rectangular and ellipsoidal footprints. We developed a computational method to map the stress tensor in these epithelia. This method establishes a direct correspondence between epithelial shape and mechanical stress without assumptions of material properties. In epithelia with spherical geometry spanning more than one order of magnitude in radius, we show that stress weakly increases with areal strain in a size-independent manner. In epithelia with rectangular and ellipsoidal cross-section we found pronounced stress anisotropies consistent with the asymmetric distribution of tractions measured at the cell-substrate contact line. In these anisotropic profiles, cell shape tended to align with the direction of maximum principal stress but this alignment was non-universal and depended on epithelial geometry. Besides interrogating the fundamental mechanics of epithelia over a broad range of sizes and shapes, our approach will enable a systematic study of how geometry and stress influence epithelial fate and function in three-dimensions.

Published

2022

18. Peeling dynamics of fluid membranes bridged by molecular bonds: moving or breaking

Author

Dimitri Kaurin, Pradeep K. Bal, Marino Arroyo, Universitat Politècnica de Catalunya. Doctorat en Enginyeria Civil, and Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental

Subjects

Biomathematics, Focal Adhesions, Biomatemàtica, Biomedical Engineering, Biophysics, 92 Biology and other natural sciences::92B Mathematical biology in general [Classificació AMS], Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], FOS: Physical sciences, Bioengineering, Condensed Matter - Soft Condensed Matter, Biochemistry, Biomaterials, Diffusion, Fractures, Bone, Motion, Biological Physics (physics.bio-ph), Biomimetics, Cell-cell adhesion, Soft Condensed Matter (cond-mat.soft), Humans, Physics - Biological Physics, Vesicle adhesion, Peeling, Biotechnology

Abstract

Biological adhesion is a critical mechanical function of complex organisms operating at multiple scales. At the cellular scale, cell-cell adhesion is remarkably tunable to enable both cohesion and malleability during development, homeostasis and disease. Such adaptable adhesion is physically supported by transient bonds between laterally mobile molecules embedded in fluid membranes. Thus, unlike specific adhesion at solid-solid or solid-fluid interfaces, peeling at fluid-fluid interfaces can proceed by breaking bonds, by moving bonds, or by a combination of both. How the additional degree of freedom provided by bond mobility changes the mechanics of peeling is not understood. To address this, we develop a theoretical model coupling self-consistently diffusion, reactions and mechanics. Lateral mobility and reaction rates determine distinct peeling regimes. In a diffusion-dominated Stefan-like regime, bond motion establishes self-stabilizing dynamics that increase the effective adhesion fracture energy. A reaction-dominated regime exhibits traveling peeling solutions where small-scale diffusion and marginal unbinding control peeling speed. In a mixed reaction-diffusion regime, strengthening by bond motion competes with weakening by bond breaking in a force-dependent manner, defining the strength of the adhesion patch. In turn, patch strength depends on molecular properties such as bond stiffness, force sensitivity, or crowding. We thus establish the physical rules enabling tunable cohesion in cellular tissues and in engineered biomimetic systems., 14 pages

Published

2022

19. The laminin-keratin link shields the nucleus from mechanical deformation and signalling

Author

Zanetta Kechagia, Pablo Sáez, Manuel Gómez-González, Martín Zamarbide, Ion Andreu, Thijs Koorman, Amy E.M. Beedle, Patrick W.B. Derksen, Xavier Trepat, Marino Arroyo, and Pere Roca-Cusachs

Abstract

The mechanical properties of the extracellular matrix (ECM) dictate tissue behaviour. In epithelial tissues, laminin is both a very abundant ECM component, and a key supporting element. Here we show that laminin hinders the mechanoresponses of breast epithelial cells by shielding the nucleus from mechanical deformation. Coating substrates with laminin-111, unlike fibronectin or collagen I, impairs cell response to substrate rigidity, and YAP nuclear localization. Blocking the laminin-specific integrin β4 increases nuclear YAP ratios in a rigidity dependent manner, without affecting cell forces or focal adhesions. By combining mechanical perturbations and mathematical modelling, we show that β4 integrins establish a mechanical linkage between the substrate and the keratin cytoskeleton, which stiffens the network and shields the nucleus from actomyosin-mediated mechanical deformation. In turn, this affects nuclear YAP mechanoresponses and chromatin methylation. Our results demonstrate a mechanism by which tissues can regulate their sensitivity to mechanical signals.

Published

2022

20. A theory for the flow of chemically-responsive polymer solutions: equilibrium and shear-induced phase separation

Author

Marco De Corato and Marino Arroyo

Subjects

Condensed Matter::Soft Condensed Matter, Quantitative Biology::Biomolecules, Mechanics of Materials, Mechanical Engineering, Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, General Materials Science, Condensed Matter - Soft Condensed Matter, Condensed Matter Physics

Abstract

Chemically responsive polymers are macromolecules that respond to local variations of the chemical composition of the solution by changing their conformation, with notable examples including polyelectrolytes, proteins, and DNA. The polymer conformation changes can occur in response to changes in the pH, the ionic strength, or the concentration of a generic solute that interacts with the polymer. These chemical stimuli can lead to drastic variations of the polymer flexibility and even trigger a transition from a coil to a globule polymer conformation. In many situations, the spatial distribution of the chemical stimuli can be highly inhomogeneous, which can lead to large spatial variations of polymer conformation and of the rheological properties of the mixture. In this paper, we develop a theory for the flow of a mixture of solute and chemically responsive polymers. The approach is valid for generic flows and inhomogeneous distributions of polymers and solutes. To model the polymer conformation changes introduced by the interactions with the solute, we consider the polymers as linear elastic dumbbells whose spring stiffness depends on the solute concentration. We use Onsager’s variational formalism to derive the equations governing the evolution of the variables, which unveils novel couplings between the distribution of dumbbells and that of the solute. Finally, we use a linear stability analysis to show that the governing equations predict an equilibrium phase separation and a distinct shear-induced phase separation whereby a homogeneous distribution of solute and dumbbells spontaneously demix. Similar phase transitions have been observed in previous experiments using stimuli-responsive polymers and may play an important role in living systems.

Published

2022

21. Cargo control of bulky carrier formation during collagen export

Author

Morgan Chabanon, Nikhil Walani, Marino Arroyo, and Felix Campelo

Subjects

Biophysics

Published

2023

22. Computational vertex models for intestinal organoid mechanics simulation

Author

Marino Arroyo and Francesco Greco

Published

2021

23. A mechanosensing mechanism mediated by IRSp53 controls plasma membrane shape homeostasis at the nanoscale

Author

Andrea Disanza, Francesc Tebar, Giorgio Scita, Marino Arroyo, Alexandra Mittens, Xavier Trepat, Nikhil Walani, Anabel-Lise Le Roux, Xarxa Quiroga, Robert G. Parton, Pere Roca-Cusachs, Albert Chavero, and María Isabel Geli

Subjects

Membrane, Evagination, Polymerization, Chemistry, Biophysics, RAC1, Plasma, Nanoscopic scale, Actin, Homeostasis

Abstract

As cells migrate and experience forces from their surroundings, they constantly undergo mechanical deformations which reshape their plasma membrane (PM). To maintain homeostasis, cells need to detect and restore such changes, not only in terms of overall PM area and tension as previously described, but also in terms of local, nano-scale topography. Here we describe a novel phenomenon, by which cells sense and restore mechanically induced PM nano-scale deformations. We show that cell stretch and subsequent compression reshape the PM in a way that generates local membrane evaginations in the 100 nm scale. These evaginations are recognized by the I-BAR protein IRSp53, which triggers a burst of actin polymerization mediated by Rac1 and Arp2/3. The actin polymerization burst subsequently re-flattens the evagination, completing the mechanochemical feedback loop. Our results demonstrate a new mechanosensing mechanism for PM shape homeostasis, with potential applicability in different physiological scenarios.TeaserCell stretch cycles generate PM evaginations of ≈100 nm which are sensed by IRSp53, triggering a local event of actin polymerization that flattens and recovers PM shape.

Published

2021

24. A theory of ordering of elongated and curved proteins on membranes driven by density and curvature

Author

Caterina Tozzi, Marino Arroyo, Pere Roca-Cusachs, Nikhil Walani, Anabel-Lise Le Roux, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, Universitat Politècnica de Catalunya. Centre Específic de Recerca de Mètodes Numèrics en Ciències Aplicades i Enginyeria, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Morphology, Biomatemàtica, FOS: Physical sciences, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Condensed Matter - Soft Condensed Matter, Numerical analysis--Simulation methods, Curvature, Mechanotransduction, Cellular, Morfologia (Biologia), Quantitative Biology::Subcellular Processes, 03 medical and health sciences, Entropy (classical thermodynamics), 0302 clinical medicine, Liquid crystal, Membrane proteins, Physics - Biological Physics, 65 Numerical analysis::65C Probabilistic methods, simulation and stochastic differential equations [Classificació AMS], Anisotropy, 030304 developmental biology, Physics, Particle system, Biomathematics, Anàlisi numèrica, 0303 health sciences, Membranes, Matemàtiques i estadística::Anàlisi numèrica::Modelització matemàtica [Àrees temàtiques de la UPC], Cell Membrane, Isotropy, Proteïnes de membrana, 92 Biology and other natural sciences::92B Mathematical biology in general [Classificació AMS], General Chemistry, Condensed Matter Physics, Membrane, Classical mechanics, Biological Physics (physics.bio-ph), Soft Condensed Matter (cond-mat.soft), Density functional theory, 030217 neurology & neurosurgery

Abstract

Cell membranes interact with a myriad of curvature-active proteins that control membrane morphology and are responsible for mechanosensation and mechanotransduction. Some of these proteins, such as those containing BAR domains, are curved and elongated, and hence may adopt different states of orientational order, from isotropic to maximize entropy to nematic as a result of crowding or to adapt to the curvature of the underlying membrane. Here, extending the work of [Nascimento et. al, Phys. Rev. E, 2017, 96, 022704], we develop a mean-field density functional theory to predict the orientational order and evaluate the free-energy of ensembles of elongated and curved objects on curved membranes. This theory depends on the microscopic properties of the particles and explains how a density-dependent isotropic-to-nematic transition is modified by anisotropic curvature. We also examine the coexistence of isotropic and nematic phases. This theory lays the ground to understand the interplay between membrane reshaping by BAR proteins and molecular order, examined in [Le Roux et. al, Submitted, 2020]., 12 pages, 8 figures

Published

2021

25. Author response: A physical mechanism of TANGO1-mediated bulky cargo export

Author

Vivek Malhotra, Ishier Raote, Maria F. Garcia-Parajo, Felix Campelo, Marino Arroyo, Morgan Chabanon, and Nikhil Walani

Subjects

Chemistry, Biophysics, Mechanism (sociology)

Published

2020

26. Mechanical compartmentalization of the intestinal organoid enables crypt folding and collective cell migration

Author

Adrián Álvarez-Varela, Sohan Kale, Marija Matejčić, Xavier Trepat, Manuel Gomez-Gonzalez, Pere Roca-Cusachs, Eduard Batlle, Natalia Castro, Carlos Pérez-González, Marino Arroyo, Gerardo Ceada, Francesco Greco, and Danijela Matic Vignjevic

Subjects

0303 health sciences, Cell type, Chemistry, digestive, oral, and skin physiology, Crypt, Apical constriction, Compartmentalization (psychology), Intestinal epithelium, Folding (chemistry), 03 medical and health sciences, 0302 clinical medicine, Organoid, Biophysics, Mitosis, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Intestinal organoids capture essential features of the intestinal epithelium such as folding of the crypt, spatial compartmentalization of different cell types, and cellular movements from crypt to villus-like domains. Each of these processes and their coordination in time and space requires patterned physical forces that are currently unknown. Here we map the three-dimensional cell-ECM and cell-cell forces in mouse intestinal organoids grown on soft hydrogels. We show that these organoids exhibit a non-monotonic stress distribution that defines mechanical and functional compartments. The stem cell compartment pushes the ECM and folds through apical constriction, whereas the transit amplifying zone pulls the ECM and elongates through basal constriction. Tension measurements establish that the transit amplifying zone isolates mechanically the stem cell compartment and the villus-like domain. A 3D vertex model shows that the shape and force distribution of the crypt can be largely explained by cell surface tensions following the measured apical and basal actomyosin density. Finally, we show that cells are pulled out of the crypt along a gradient of increasing tension, rather than pushed by a compressive stress downstream of mitotic pressure as previously assumed. Our study unveils how patterned forces enable folding and collective migration in the intestinal crypt.

Published

2020

27. Examining the mechanical equilibrium of microscopic stresses in molecular simulations

Author

Alejandro Torres-Sánchez, Marino Arroyo, Juan M. Vanegas, Universitat Politècnica de Catalunya. Departament de Matemàtica Aplicada III, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

GRAPHENE, DECOMPOSITION, BILAYERS, Engineering, Civil, Mechanical equilibrium, EFFICIENT, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], General Physics and Astronomy, Engineering, Multidisciplinary, PRESSURE, law.invention, Molecular dynamics, FLUIDS, law, STRENGTH, Statistical physics, Engineering, Ocean, Defective graphene, Engineering, Aerospace, Engineering, Biomedical, 92 Biology and other natural sciences::92C Physiological, cellular and medical topics [Classificació AMS], Biomathematics, Physics, Continuum (measurement), DYNAMICS SIMULATIONS, Statistical mechanics, Computer Science, Software Engineering, Biologia -- Models matemàtics, Engineering, Marine, Stress field, Engineering, Manufacturing, Engineering, Mechanical, STATISTICAL-MECHANICS, Engineering, Industrial, TENSOR

Abstract

The microscopic stress field provides a unique connection between atomistic simulations and mechanics at the nanoscale. However, its definition remains ambiguous. Rather than a mere theoretical preoccupation, we show that this fact acutely manifests itself in local stress calculations of defective graphene, lipid bilayers, and fibrous proteins. We find that popular definitions of the microscopic stress violate the continuum statements of mechanical equilibrium, and we propose an unambiguous and physically sound definition. Award-winning

Published

2020

28. Phase field modeling of brittle fracture in an Euler–Bernoulli beam accounting for transverse part-through cracks

Author

Marino Arroyo, Yihuan Li, Jian Gao, Yongxing Shen, Wenyu Lai, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Engineering, Civil, Field (physics), Computational Mechanics, Phase (waves), General Physics and Astronomy, Engineering, Multidisciplinary, 010103 numerical & computational mathematics, Bending, Rotation, 01 natural sciences, Matemàtiques i estadística::Anàlisi numèrica [Àrees temàtiques de la UPC], Cross section (physics), Phase field, Engineering, Ocean, 0101 mathematics, Strength of materials, Resistència de materials, 65 Numerical analysis::65K Mathematical programming, optimization and variational techniques [Classificació AMS], Engineering, Aerospace, Engineering, Biomedical, Physics, Anàlisi numèrica, Mechanical Engineering, Matemàtiques i estadística::Anàlisi numèrica::Mètodes numèrics [Àrees temàtiques de la UPC], Mechanics, Computer Science, Software Engineering, Potential energy, Engineering, Marine, Computer Science Applications, 010101 applied mathematics, Engineering, Manufacturing, Engineering, Mechanical, Mechanics of Materials, Brittle fracture, Euler–Bernoulli beam, Displacement field, Engineering, Industrial, Dimension reduction, 74 Mechanics of deformable solids::74S Numerical methods [Classificació AMS], Beam (structure), Numerical analysis

Abstract

© 2020 Elsevier. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/ We present a phase field model to simulate brittle fracture in an initially straight Euler–Bernoulli beam, with generalization to curved beams. We start from formulating the problem with the principle of minimum potential energy in a 3D solid, with the displacement field and the phase field as primary arguments. We then select, for each cross section, representative fields that characterize the said cross section, including the beam deflection and rotation, and two independent ansatz variables within the cross section to represent the phase field. The problem then reduces to a minimization with only one-dimensional field variables. A feature of the proposed method is, without discretizing the phase field within the cross section, it can represent its variation within the cross section, allowing to simulate cracks partially going through the thickness due to bending as well as axial loads.

Published

2020

29. An adaptive meshfree method for phase-field models of biomembranes. Part I: Approximation with maximum-entropy basis functions

Author

Adrian Rosolen, Marino Arroyo, Christian Peco, Universitat Politècnica de Catalunya. Departament de Matemàtica Aplicada III, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Meshfree methods, Engineering, Civil, Physics and Astronomy (miscellaneous), Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Engineering, Multidisciplinary, 010103 numerical & computational mathematics, 01 natural sciences, Maximum-entropy approximants, Membranes (Biology) -- Mathematical models, Membranes (Biologia), Biomembranes, Smoothed finite element method, Vesicles, Engineering, Ocean, 0101 mathematics, Engineering, Aerospace, Engineering, Biomedical, Weakened weak form, Mathematics, Numerical Analysis, Diffuse element method, Partial differential equation, Applied Mathematics, Matemàtiques i estadística::Anàlisi numèrica::Mètodes numèrics [Àrees temàtiques de la UPC], Mathematical analysis, Finite difference, Computer Science, Software Engineering, Finite element method, Engineering, Marine, Computer Science Applications, 010101 applied mathematics, Engineering, Manufacturing, Engineering, Mechanical, Computational Mathematics, Adaptivity, Modeling and Simulation, Engineering, Industrial, Spectral method, Phase field models

Abstract

We present an adaptive meshfree method to approximate phase-field models of biomembranes. In such models, the Helfrich curvature elastic energy, the surface area, and the enclosed volume of a vesicle are written as functionals of a continuous phase-field, which describes the interface in a smeared manner. Such functionals involve up to second-order spatial derivatives of the phase-field, leading to fourth-order Euler–Lagrange partial differential equations (PDE). The solutions develop sharp internal layers in the vicinity of the putative interface, and are nearly constant elsewhere. Thanks to the smoothness of the local maximum-entropy (max-ent) meshfree basis functions, we approximate numerically this high-order phase-field model with a direct Ritz–Galerkin method. The flexibility of the meshfree method allows us to easily adapt the grid to resolve the sharp features of the solutions. Thus, the proposed approach is more efficient than common tensor product methods (e.g. finite differences or spectral methods), and simpler than unstructured Cº finite element methods, applicable by reformulating the model as a system of second-order PDE. The proposed method, implemented here under the assumption of axisymmetry, allows us to show numerical evidence of convergence of the phase-field solutions to the sharp interface limit as the regularization parameter approaches zero. In a companion paper, we present a Lagrangian method based on the approximants analyzed here to study the dynamics of vesicles embedded in a viscous fluid. We present an adaptive meshfree method to approximate phase-field models of biomembranes. In such models, the Helfrich curvature elastic energy, the surface area, and the enclosed volume of a vesicle are written as functionals of a continuous phase-field, which describes the interface in a smeared manner. Such functionals involve up to second-order spatial derivatives of the phase-field, leading to fourth-order Euler–Lagrange partial differential equations (PDE). The solutions develop sharp internal layers in the vicinity of the putative interface, and are nearly constant elsewhere. Thanks to the smoothness of the local maximum-entropy (max-ent) meshfree basis functions, we approximate numerically this high-order phase-field model with a direct Ritz–Galerkin method. The flexibility of the meshfree method allows us to easily adapt the grid to resolve the sharp features of the solutions. Thus, the proposed approach is more efficient than common tensor product methods (e.g. finite differences or spectral methods), and simpler than unstructured C0C0 finite element methods, applicable by reformulating the model as a system of second-order PDE. The proposed method, implemented here under the assumption of axisymmetry, allows us to show numerical evidence of convergence of the phase-field solutions to the sharp interface limit as the regularization parameter approaches zero. In a companion paper, we present a Lagrangian method based on the approximants analyzed here to study the dynamics of vesicles embedded in a viscous fluid.

Published

2020

30. Understanding and strain-engineering wrinkle networks in supported graphene through simulations

Author

Marino Arroyo, Kuan Zhang, Universitat Politècnica de Catalunya. Departament de Matemàtica Aplicada III, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Engineering, Civil, Materials science, STRESS, Enginyeria de la telecomunicació::Telemàtica i xarxes d'ordinadors [Àrees temàtiques de la UPC], Semiconductor industrial equipment industry, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Engineering, Multidisciplinary, Carbon nanotube, ADHESION, FILMS, CARBON NANOTUBES, law.invention, Stress (mechanics), Planar, Strain engineering, SUBSTRATE, Wrinkles, Semiconductors -- Mètodes de simulació, law, medicine, ELASTIC MEMBRANES, Blisters, SCATTERING, Engineering, Ocean, Composite material, Wrinkle, Engineering, Aerospace, Engineering, Biomedical, Coupling, Graphene, Buckling, Mechanical Engineering, Mechanics, DEFECTS, Condensed Matter Physics, Computer Science, Software Engineering, SHEETS, TRANSPORT, Engineering, Marine, Engineering, Manufacturing, Engineering, Mechanical, Mechanics of Materials, Engineering, Industrial, medicine.symptom

Abstract

Wrinkle networks are ubiquitous buckle-induced delaminations in supported graphene, which locally modify the electronic structure and degrade device performance. Although the strong property-deformation coupling of graphene can be potentially harnessed by strain engineering, it has not been possible to precisely control the geometry of wrinkle networks. Through numerical simulations based on an atomistically informed continuum theory, we understand how strain anisotropy, adhesion and friction govern spontaneous wrinkling. We then propose a strategy to control the location of wrinkles through patterns of weaker adhesion. This strategy is deceptively simple, and can in fact fail in several ways, particularly under biaxial compression. However, within bounds set by the physics of wrinkling, it is possible to robustly create by strain a variety of wrinkle network geometries and junction configurations. Graphene is nearly unstrained in the planar regions bounded by wrinkles, highly curved along wrinkles, and highly stretched and curved at junctions, which can either locally attenuate or amplify the applied strain depending on their configuration. These mechanically self-assembled networks are stable under the pressure produced by an enclosed fluid and form continuous channels, opening the door to nano-fluidic applications.

Published

2020

31. Reverse engineering the euglenoid movement

Author

Antonio DeSimone, Luca Heltai, Marino Arroyo, Daniel Millán, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria, Arroyo, M., Heltai, L., Milan, D., and Desimone, A.

Subjects

Kinematics, Body volume, computer.software_genre, 01 natural sciences, Shape control, 0302 clinical medicine, Flagellar motility, Self-propulsion, Euglenida, 0303 health sciences, Active soft matter, Multidisciplinary, Movement (music), food and beverages, microswimmer, Biomechanical Phenomena, Engineering, Mechanical, Classical mechanics, Euglenoids, Physical Sciences, Biological system, Microswimmers, microswimmers, Reverse engineering, Engineering, Civil, active soft matter, Microfluidics, Biophysics, Engineering, Multidisciplinary, Cinemàtica, Biology, 03 medical and health sciences, Optics, 0103 physical sciences, Molecular motor, Engineering, Ocean, 010306 general physics, Engineering, Aerospace, Engineering, Biomedical, 030304 developmental biology, business.industry, Statistical learning, fungi, self-propulsion, Enginyeria mecànica::Mecànica::Cinemàtica [Àrees temàtiques de la UPC], Computer Science, Software Engineering, Engineering, Marine, Engineering, Manufacturing, Engineering, Industrial, business, computer, 030217 neurology & neurosurgery, Stroke kinematics

Abstract

Euglenids exhibit an unconventional motility strategy amongst unicellular eukaryotes, consisting of large-amplitude highly concerted deformations of the entire body (euglenoid movement or metaboly). A plastic cell envelope called pellicle mediates these deformations. Unlike ciliary or flagellar motility, the biophysics of this mode is not well understood, including its efficiency and molecular machinery. We quantitatively examine video recordings of four euglenids executing such motions with statistical learning methods. This analysis reveals strokes of high uniformity in shape and pace. We then interpret the observations in the light of a theory for the pellicle kinematics, providing a precise understanding of the link between local actuation by pellicle shear and shape control. We systematically understand common observations, such as the helical conformations of the pellicle, and identify previously unnoticed features of metaboly. While two of our euglenids execute their stroke at constant body volume, the other two exhibit deviations of about 20% from their average volume, challenging current models of low Reynolds number locomotion. We find that the active pellicle shear deformations causing shape changes can reach 340%, and estimate the velocity of the molecular motors. Moreover, we find that metaboly accomplishes locomotion at hydrodynamic efficiencies comparable to those of ciliates and flagellates. Our results suggest new quantitative experiments, provide insight into the evolutionary history of euglenids, and suggest that the pellicle may serve as a model for engineered active surfaces with applications in microfluidics.

Published

2020

32. Relaxation dynamics of fluid membranes

Author

Antonio DeSimone, Marino Arroyo, Universitat Politècnica de Catalunya. Departament de Matemàtica Aplicada III, Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria, Arroyo, M, and Desimone, A

Subjects

Models, Molecular, Osmosis, Time Factors, Física::Física de fluids [Àrees temàtiques de la UPC], friction, biological fluid dynamics, Quantitative Biology::Cell Behavior, Cell membrane, Physics::Fluid Dynamics, biomembranes, cellular biophysics, elasticity, molecular biophysics, viscosity, Membrane fluidity, Viscosity, Temperature, Mechanics, Dissipation, biomembrane, Membranes líquides, Biomechanical Phenomena, Engineering, Mechanical, medicine.anatomical_structure, Classical mechanics, Membrane, Engineering, Civil, Materials science, Membrane Fluidity, Surface Properties, Engineering, Multidisciplinary, biological fluid dynamic, Viscous liquid, Curvature, Quantitative Biology::Subcellular Processes, Fluid dynamics, medicine, Engineering, Ocean, Engineering, Aerospace, Engineering, Biomedical, Cell Membrane, Proteins, Lipid Metabolism, Computer Science, Software Engineering, Elasticity, Engineering, Marine, Engineering, Manufacturing, molecular biophysic, Dinàmica de fluids, Engineering, Industrial, cellular biophysic, Conservative force, Liquid membranes

Abstract

We study the effect of membrane viscosity in the dynamics of liquid membranes{possibly with free or internal boundaries{ driven by conservative forces (curvature elasticity and line tension) and dragged by the bulk dissipation of the ambient fluid and the friction occurring when the amphiphilic molecules move relative to each other. To this end, we formulate a continuum model which includes a new form of the governing equations for a two-dimensional viscous fluid moving on a curved, time-evolving surface. The effect of membrane viscosity has received very limited attention in previous continuum studies of the dynamics of fluid membranes, although recent coarse-grained discrete simulations suggest its importance. By applying our model to the study of vesiculation and membrane fusion in a simpli ed geometry, we conclude that membrane viscosity plays a dominant role in the relaxation dynamics of fluid membranes of sizes comparable to those found in eukaryotic cells, and is not negligible in many large synthetic systems of current interest.

Published

2020

33. Mechanics of axisymmetric sheets of interlocking and slidable rods

Author

Antonio DeSimone, Marino Arroyo, Giovanni Noselli, Davide Riccobelli, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria, Riccobelli, D., Noselli, G., Arroyo, M., and Desimone, A.

Subjects

Rotational symmetry, FOS: Physical sciences, Biomimetic structures, Elastic structures, Helical rods, Mechanical instabilities, Metamaterials, Post-buckling analysis, Physics - Classical Physics, 02 engineering and technology, Kinematics, Biomimetic structure, Condensed Matter - Soft Condensed Matter, 01 natural sciences, Rod, 010305 fluids & plasmas, Metamaterial, 0103 physical sciences, Settore ICAR/08 - Scienza delle Costruzioni, Strength of materials, Resistència de materials, Settore MAT/07 - Fisica Matematica, Mechanical instabilitie, Bifurcation, Interlocking, Physics, Elastic structure, Matemàtiques i estadística::Anàlisi numèrica::Mètodes numèrics [Àrees temàtiques de la UPC], Mechanical Engineering, Classical Physics (physics.class-ph), Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Finite element method, Post-buckling analysi, Buckling, Mechanics of Materials, Soft Condensed Matter (cond-mat.soft), 74 Mechanics of deformable solids::74S Numerical methods [Classificació AMS], 0210 nano-technology, Asymptotic expansion, Helical rod

Abstract

© 2020 Elsevier. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/ In this work, we study the mechanics of metamaterial sheets inspired by the pellicle of Euglenids. They are composed of interlocking elastic rods which can freely slide along their edges. We characterize the kinematics and the mechanics of these structures using the special Cosserat theory of rods and by assuming axisymmetric deformations of the tubular assembly. Through an asymptotic expansion, we investigate both structures that comprise a discrete number of rods and the limit case of a sheet composed by infinitely many rods. We apply our theoretical framework to investigate the stability of these structures in the presence of an axial load. Through a linear analysis, we compute the critical buckling force for both the discrete and the continuous case. For the latter, we also perform a numerical post-buckling analysis, studying the non-linear evolution of the bifurcation through finite elements simulations.

Published

2020

34. Hydraulic fracture during epithelial stretching

Author

Romaric Vincent, Dobryna Zalvidea, Marino Arroyo, Noelia Campillo, Xavier Trepat, Laura Casares, Daniel Navajas, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

PHYSICAL FORCES, Hydrostatic pressure, 02 engineering and technology, CELL-MIGRATION, ADHESION, Matrix (biology), Mechanotransduction, Cellular, DISEASE, Madin Darby Canine Kidney Cells, Micromanipulation, General Materials Science, Mechanotransduction, 0303 health sciences, Tension (physics), Adhesion, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Compression (physics), 74 Mechanics of deformable solids::74M Special kinds of problems [Classificació AMS], Engineering, Mechanical, HYDROSTATIC-PRESSURE, Mechanics of Materials, 0210 nano-technology, Engineering, Civil, Materials science, Surface Properties, Engineering, Multidisciplinary, Nanotechnology, Lung injury, Models, Biological, Article, 03 medical and health sciences, Dogs, Tensile Strength, Pressure, Animals, Engineering, Ocean, Strength of materials, GELS, Resistència de materials, Engineering, Aerospace, Engineering, Biomedical, 030304 developmental biology, Matemàtiques i estadística::Anàlisi numèrica::Mètodes numèrics [Àrees temàtiques de la UPC], Mechanical Engineering, Epithelial Cells, General Chemistry, Computer Science, Software Engineering, Engineering, Marine, VENTILATION, Engineering, Manufacturing, MECHANICS, MORPHOGENESIS, Engineering, Industrial, Hydrodynamics, Fracture (geology), Biophysics, Stress, Mechanical, LUNG INJURY

Abstract

The origin of fracture in epithelial cell sheets subject to stretch is commonly attributed to excess tension in the cells' cytoskeleton, in the plasma membrane, or in cell-cell contacts. Here, we demonstrate that for a variety of synthetic and physiological hydrogel substrates the formation of epithelial cracks is caused by tissue stretching independently of epithelial tension. We show that the origin of the cracks is hydraulic; they result from a transient pressure build-up in the substrate during stretch and compression manoeuvres. After pressure equilibration, cracks heal readily through actomyosin-dependent mechanisms. The observed phenomenology is captured by the theory of poroelasticity, which predicts the size and healing dynamics of epithelial cracks as a function of the stiffness, geometry and composition of the hydrogel substrate. Our findings demonstrate that epithelial integrity is determined in a tension-independent manner by the coupling between tissue stretching and matrix hydraulics.

Published

2020

35. Physical principles of membrane remodelling during cell mechanoadaptation

Author

Satyajit Mayor, Nils C. Gauthier, Miguel A. del Pozo, Xavier Trepat, Anita Joanna Kosmalska, Alberto Elosegui-Artola, Daniel Navajas, Marino Arroyo, Roberto Moreno-Vicente, Joseph Jose Thottacherry, Víctor González-Tarragó, Pere Roca-Cusachs, Laura Casares, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria, Ministerio de Economía y Competitividad (España), Unión Europea. Comisión Europea, European Research Council, Government of Catalonia (España), Fundación La Caixa, Fundación La Marató TV3, Institució Catalana de Recerca i Estudis Avançats, National Research Foundation (Singapur), Universitat de Barcelona, Arroyo, Marino [0000-0003-1647-940X], and Apollo - University of Cambridge Repository

Subjects

DYNAMICS, Osmosis, STRESS, TENSION, Physiology, Cell, General Physics and Astronomy, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], 02 engineering and technology, Cell size, Cell membrane, Mice, EXOCYTOSIS, LIVING CELLS, NEURONS, 0303 health sciences, Multidisciplinary, Bilayer, 92 Biology and other natural sciences::92B Mathematical biology in general [Classificació AMS], Models biològics, 021001 nanoscience & nanotechnology, Adaptation, Physiological, Biologia -- Models matemàtics, Cell biology, Engineering, Mechanical, Membrane, Order (biology), medicine.anatomical_structure, SHAPE, ALVEOLAR EPITHELIAL-CELLS, 0210 nano-technology, Engineering, Civil, MIGRATION, Biophysics, Fisiologia, Engineering, Multidisciplinary, Biology, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Exocytosis, Article, 03 medical and health sciences, medicine, Animals, Engineering, Ocean, Process (anatomy), Cell Shape, Engineering, Aerospace, Engineering, Biomedical, 030304 developmental biology, Cell Size, Biological models, Biomathematics, Cell Membrane, Osmolar Concentration, Osmosi, General Chemistry, Fibroblasts, Models, Theoretical, Computer Science, Software Engineering, Biofísica, Elasticity, Engineering, Marine, Cell membranes, Engineering, Manufacturing, Engineering, Industrial, Stress, Mechanical, SURFACE-AREA REGULATION, Membranes cel·lulars

Abstract

Biological processes in any physiological environment involve changes in cell shape, which must be accommodated by their physical envelope—the bilayer membrane. However, the fundamental biophysical principles by which the cell membrane allows for and responds to shape changes remain unclear. Here we show that the 3D remodelling of the membrane in response to a broad diversity of physiological perturbations can be explained by a purely mechanical process. This process is passive, local, almost instantaneous, before any active remodelling and generates different types of membrane invaginations that can repeatedly store and release large fractions of the cell membrane. We further demonstrate that the shape of those invaginations is determined by the minimum elastic and adhesive energy required to store both membrane area and liquid volume at the cell–substrate interface. Once formed, cells reabsorb the invaginations through an active process with duration of the order of minutes., Variations in cell shape must be accommodated by the cell membrane, but how the membrane adjusts to changes in area and volume is not known. Here the authors show that the membrane responds in a nearly instantaneous, purely physical manner involving the flattening or generation of membrane invaginations.

Published

2020

36. A finite deformation membrane based on inter-atomic potentials for the transverse mechanics of nanotubes

Author

Marino Arroyo, Ted Belytschko, Universitat Politècnica de Catalunya. Departament de Matemàtica Aplicada III, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Engineering, Civil, Materials science, Born rule, Carbon nanotubes, Engineering, Multidisciplinary, Interatomic potential, Física::Física de l'estat sòlid [Àrees temàtiques de la UPC], Carbon nanotube, Deformation (meteorology), Curvature, Quasicontinuum, law.invention, law, General Materials Science, Engineering, Ocean, Exponential map (Riemannian geometry), Instrumentation, Engineering, Aerospace, Engineering, Biomedical, Continuum mechanics, Nanotubes, Carbon, Membrane, Mechanics, Elasticity (physics), Computer Science, Software Engineering, Engineering, Marine, Crystal elasticity, Exponential map, Engineering, Manufacturing, Engineering, Mechanical, Classical mechanics, Mechanics of Materials, Finite strain theory, Nanotubs de carboni, Engineering, Industrial

Abstract

A finite deformation hyper-elastic membrane theory based on inter-atomic potentials for crystalline films composed of a single atomic layer is developed. For this purpose, an extension of the standard Born rule that exploits the differential geometry concept of the exponential map is proposed to deal with the curvature of surfaces. The exponential map is approximated locally and strain measures based on the stretch and the curvature of the membrane arise. The methodology is first particularized to atomic chains in two dimensions, and then to graphene sheets. A reduced model for the transverse mechanics of carbon nanotubes is developed in detail. This model is a hyper-elastic constrained membrane which fully exploits the symmetry of the transverse deformation. Additionally, a continuum version of the non-bonded interactions is provided. The continuum model is discretized using finite elements and very good agreement with molecular mechanics simulations is obtained. Finally, several simulations illustrate the strong effect of the van der Waals interactions in the transverse deformation of carbon nanotubes.

Published

2020

37. Blending isogeometric analysis and local maximum entropy meshfree approximants

Author

Marino Arroyo, Adrian Rosolen, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Mathematical optimization, Engineering, Civil, Local refinement, Discretization, Computational Mechanics, General Physics and Astronomy, Geometry, Engineering, Multidisciplinary, Basis function, Matemàtiques i estadística::Geometria::Geometria algebraica [Àrees temàtiques de la UPC], 02 engineering and technology, Isogeometric analysis, 01 natural sciences, Complex geometry, 0203 mechanical engineering, Meshfree methods, Applied mathematics, Boundary value problem, Matemàtiques i estadística::Geometria::Geometria computacional [Àrees temàtiques de la UPC], Engineering, Ocean, 0101 mathematics, Max-ent approximants, Engineering, Aerospace, Engineering, Biomedical, Mathematics, Volume discretization, Mechanical Engineering, Principle of maximum entropy, Geometria, Computer Science, Software Engineering, Engineering, Marine, Computer Science Applications, 010101 applied mathematics, Geometry, Algebraic, Engineering, Manufacturing, Engineering, Mechanical, Boundary representation, 020303 mechanical engineering & transports, Geometria algebraica, 51 Geometry::51P05 Geometry and physics [Classificació AMS], Mechanics of Materials, Engineering, Industrial, High-fidelity geometry, 51 Geometry::51K Distance geometry [Classificació AMS]

Abstract

We present a method to blend local maximum entropy (LME) meshfree approximants and isogeometric analysis. The coupling strategy exploits the optimization program behind LME approximation, treats isogeometric and LME basis functions on an equal footing in the reproducibility constraints, but views the former as data in the constrained minimization. The resulting scheme exploits the best features and overcomes the main drawbacks of each of these approximants. Indeed, it preserves the high fidelity boundary representation (exact CAD geometry) of isogeometric analysis, out of reach for bare meshfree methods, and easily handles volume discretization and unstructured grids with possibly local refinement, while maintaining the smoothness and non-negativity of the basis functions. We implement the method with B-Splines in two dimensions, but the procedure carries over to higher spatial dimensions or to other non-negative approximants such as NURBS or subdivision schemes. The performance of the method is illustrated with the heat equation, and linear and nonlinear elasticity. The ability of the proposed method to impose directly essential boundary conditions in non-convex domains, and to deal with unstructured grids and local refinement in domains of complex geometry and topology is highlighted by the numerical examples.

Published

2020

38. An adaptive meshfree method for phase-field models of biomembranes. Part II: A Lagrangian approach for membranes in viscous fluids

Author

Adrian Rosolen, Christian Peco, Marino Arroyo, Universitat Politècnica de Catalunya. Departament de Matemàtica Aplicada III, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Meshfree methods, Engineering, Civil, Physics and Astronomy (miscellaneous), Discretization, Phase field models, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Engineering, Multidisciplinary, Viscous liquid, 01 natural sciences, 010305 fluids & plasmas, symbols.namesake, Membranes (Biology) -- Mathematical models, Variational methods, Membranes (Biologia), Biomembranes, 0103 physical sciences, Smoothed finite element method, Vesicles, Engineering, Ocean, 0101 mathematics, Engineering, Aerospace, Engineering, Biomedical, Weakened weak form, Mathematics, Numerical Analysis, Diffuse element method, Applied Mathematics, Matemàtiques i estadística::Anàlisi numèrica::Mètodes numèrics [Àrees temàtiques de la UPC], Mathematical analysis, Reynolds number, Computer Science, Software Engineering, Engineering, Marine, Computer Science Applications, 010101 applied mathematics, Engineering, Manufacturing, Engineering, Mechanical, Computational Mathematics, Adaptivity, Modeling and Simulation, Engineering, Industrial, symbols

Abstract

We present a Lagrangian phase-field method to study the low Reynolds number dynamics of vesicles embedded in a viscous fluid. In contrast to previous approaches, where the field variables are the phase-field and the fluid velocity, here we exploit the fact that the phasefield tracks a material interface to reformulate the problem in terms of the Lagrangian motion of a background medium, containing both the biomembrane and the fluid. We discretize the equations in space with maximum-entropy approximants, carefully shown to perform well in phase-field models of biomembranes in a companion paper. The proposed formulation is variational, lending itself to implicit time-stepping algorithms based on minimization of a time-incremental energy, which are automatically nonlinearly stable. The proposed method deals with two of the major challenges in the numerical treatment of coupled fluid/phase-field models of biomembranes, namely the adaptivity of the grid to resolve the sharp features of the phase-field, and the stiffness of the equations, leading to very small time-steps. In our method, local refinement follows the features of the phasefield as both are advected by the Lagrangian motion, and large time-steps can be robustly chosen in the variational time-stepping algorithm, which also lends itself to time adaptivity. The method is presented in the axisymmetric setting, but it can be directly extended to 3D. We present a Lagrangian phase-field method to study the low Reynolds number dynamics of vesicles embedded in a viscous fluid. In contrast to previous approaches, where the field variables are the phase-field and the fluid velocity, here we exploit the fact that the phase-field tracks a material interface to reformulate the problem in terms of the Lagrangian motion of a background medium, containing both the biomembrane and the fluid. We discretize the equations in space with maximum-entropy approximants, carefully shown to perform well in phase-field models of biomembranes in a companion paper. The proposed formulation is variational, lending itself to implicit time-stepping algorithms based on minimization of a time-incremental energy, which are automatically nonlinearly stable. The proposed method deals with two of the major challenges in the numerical treatment of coupled fluid/phase-field models of biomembranes, namely the adaptivity of the grid to resolve the sharp features of the phase-field, and the stiffness of the equations, leading to very small time-steps. In our method, local refinement follows the features of the phase-field as both are advected by the Lagrangian motion, and large time-steps can be robustly chosen in the variational time-stepping algorithm, which also lends itself to time adaptivity. The method is presented in the axisymmetric setting, but it can be directly extended to 3D.

Published

2020

39. Spontaneous polarization and locomotion of an active particle with surface-mobile enzymes

Author

Marco De Corato, Loai K. E. A. Abdelmohsen, Ignacio Pagonabarraga, Marino Arroyo, Samuel Sanchez, Bio-Organic Chemistry, ICMS Core, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Surface (mathematics), Computational Mechanics, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], FOS: Physical sciences, 02 engineering and technology, Péclet number, 76 Fluid mechanics::76Z Biological fluid mechanics [Classificació AMS], Condensed Matter - Soft Condensed Matter, 01 natural sciences, Instability, Homogeneous distribution, Quantitative Biology::Cell Behavior, Physics::Fluid Dynamics, Quantitative Biology::Subcellular Processes, symbols.namesake, Eukaryotic cells, 0103 physical sciences, Mecànica de fluids, Fluid mechanics, 010306 general physics, Locomoció, Fluid Flow and Transfer Processes, Physics, Quantitative Biology::Biomolecules, Cèl·lules eucariotes, Quantitative Biology::Molecular Networks, 021001 nanoscience & nanotechnology, Symmetry (physics), Supercritical fluid, Enzymes, Hysteresis, Chemical physics, Modeling and Simulation, symbols, Particle, Soft Condensed Matter (cond-mat.soft), Enzims, 0210 nano-technology, Locomotion

Abstract

We examine a mechanism of locomotion of active particles whose surface is uniformly coated with mobile enzymes. The enzymes catalyze a reaction that drives phoretic flows but their homogeneous distribution forbids locomotion by symmetry. We find that the ability of the enzymes to migrate over the surface combined with self-phoresis can lead to a spontaneous symmetry-breaking instability whereby the homogeneous distribution of enzymes polarizes and the particle propels. The instability is driven by the advection of enzymes by the phoretic flows and occurs above a critical Péclet number. The transition to polarized motile states occurs via a supercritical or subcritical pitchfork bifurcations, the latter of which enables hysteresis and coexistence of uniform and polarized states.

Published

2020

40. Morphable structures from unicellular organisms with active, shape-shifting envelopes: variations on a theme by Gauss

Author

Giancarlo Cicconofri, Antonio DeSimone, Marino Arroyo, Giovanni Noselli, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Deployable structures, Biomatemàtica, Computer science, 74 Mechanics of deformable solids::74B Elastic materials [Classificació AMS], Gaussian, Soft robotics, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Cell motility, 01 natural sciences, GeneralLiterature_MISCELLANEOUS, 010305 fluids & plasmas, Micro-swimmers, Matemàtiques i estadística::Anàlisi numèrica [Àrees temàtiques de la UPC], symbols.namesake, Active shells, 0103 physical sciences, Gaussian morphing, 010306 general physics, Unicellular swimmers, ComputingMethodologies_COMPUTERGRAPHICS, Biomathematics, Applied Mathematics, Mechanical Engineering, Elasticitat, Gauss, 92 Biology and other natural sciences::92B Mathematical biology in general [Classificació AMS], Elasticity, Morphing, Mechanics of Materials, Fluid–structure interaction, symbols, Biological cell, Theorema Egregium, Biological system

Abstract

© 2020. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/ We discuss some recent results on biological and bio-inspired morphing, and use them to identify promising research directions for the future. In particular, we consider issues related to morphing at microscopic scales inspired by unicellular organisms. We focus on broad conceptual principles and, in particular, on morphing approaches based on the use of Gauss’ theorema egregium (Gaussian morphing). We highlight some connections with biological cell envelopes containing filaments and motors, and discuss ideas for the implementation of Gaussian morphing in surfaces actuated by active shearing or stretching.

Published

2020

41. Nonsingular isogeometric boundary element method for stokes flows in 3D

Author

Luca Heltai, Antonio DeSimone, Marino Arroyo, Universitat Politècnica de Catalunya. Departament de Matemàtica Aplicada III, Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria, Heltai, Luca, Arroyo, M., and De Simone, Antonio

Subjects

Engineering, Civil, Open problem, 65D Aproximació numèrica i geometria computacional, Computational Mechanics, General Physics and Astronomy, Engineering, Multidisciplinary, Basis function, Isogeometric analysis, Matemàtiques i estadística::Anàlisi numèrica::Mètodes en elements finits [Àrees temàtiques de la UPC], Domain (mathematical analysis), Settore MAT/08 - Analisi Numerica, symbols.namesake, Boundary element method, NURBS, Stokes flows, Settore ICAR/08 - Scienza delle Costruzioni, Engineering, Ocean, Engineering, Aerospace, Engineering, Biomedical, Isogeometric analysi, Mathematics, Anàlisi numèrica, Partial differential equation, Mechanical Engineering, Mathematical analysis, Computer Science, Software Engineering, Computer Science::Numerical Analysis, Finite element method, Engineering, Marine, Computer Science Applications, Engineering, Manufacturing, Engineering, Mechanical, Mechanics of Materials, Engineering, Industrial, symbols, Gaussian quadrature, Numerical analysis

Abstract

Isogeometric analysis (IGA) is emerging as a technology bridging computer aided geometric design (CAGD), most commonly based on Non-Uniform Rational B-Splines (NURBS) surfaces, and engineering analysis. In finite element and boundary element isogeometric methods (FE-IGA and IGA-BEM), the NURBS basis functions that describe the geometry define also the approximation spaces. In the FE-IGA approach, the surfaces generated by the CAGD tools need to be extended to volumetric descriptions, a major open problem in 3D. This additional passage can be avoided in principle when the partial differential equations to be solved admit a formulation in terms of boundary integral equations, leading to boundary element isogeometric analysis (IGA-BEM). The main advantages of such an approach are given by the dimensionality reduction of the problem (from volumetric-based to surface-based), by the fact that the interface with CAGD tools is direct, and by the possibility to treat exterior problems, where the computational domain is infinite. By contrast, these methods produce system matrices which are full, and require the integration of singular kernels. In this paper we address the second point and propose a nonsingular formulation of IGA-BEM for 3D Stokes flows, whose convergence is carefully tested numerically. Standard Gaussian quadrature rules suffice to integrate the boundary integral equations, and carefully chosen known exact solutions of the interior Stokes problem are used to correct the resulting matrices, extending the work by Klaseboer et al. (2012) [27] to IGA-BEM.

Published

2020

42. Dynamic Mechanochemical feedback between curved membranes and BAR protein self-organization

Author

Nikhil Walani, Anabel-Lise Le Roux, Marino Arroyo, Xarxa Quiroga, Caterina Tozzi, Dobryna Zalvidea, Margarita Staykova, Pere Roca-Cusachs, Xavier Trepat, Universitat Politècnica de Catalunya. Centre Específic de Recerca de Mètodes Numèrics en Ciències Aplicades i Enginyeria, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Phase transition, Materials science, Mechanotransduction, Bar (music), Science, Lipid Bilayers, Chemistry, Organic, General Physics and Astronomy, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], 02 engineering and technology, Plasma protein binding, Curvature, Mechanotransduction, Cellular, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Quantitative Biology::Subcellular Processes, Membrane biophysics, Computational biophysics, 03 medical and health sciences, Liquid crystal, 0103 physical sciences, Humans, 010306 general physics, Cells, Cultured, 030304 developmental biology, Self-organization, 0303 health sciences, Quantitative Biology::Biomolecules, Multidisciplinary, Cell Membrane, Computational Biology, Membrane Proteins, Proteins, General Chemistry, 021001 nanoscience & nanotechnology, Template, Membrane, Membrane protein, Microscopy, Fluorescence, Biophysics, 0210 nano-technology, Química orgànica, Proteïnes

Abstract

Reproducció del document publicat a: https://doi.org/10.1038/s41467-021-26591-3, In many physiological situations, BAR proteins reshape membranes with pre-existing curvature (templates), contributing to essential cellular processes. However, the mechanism and the biological implications of this reshaping process remain unclear. Here we show, both experimentally and through modelling, that BAR proteins reshape low curvature membrane templates through a mechanochemical phase transition. This phenomenon depends on initial template shape and involves the co-existence and progressive transition between distinct local states in terms of molecular organization (protein arrangement and density) and membrane shape (template size and spherical versus cylindrical curvature). Further, we demonstrate in cells that this phenomenon enables a mechanotransduction mode, in which cellular stretch leads to the mechanical formation of membrane templates, which are then reshaped into tubules by BAR proteins. Our results demonstrate the interplay between membrane mechanics and BAR protein molecular organization, integrating curvature sensing and generation in a comprehensive framework with implications for cell mechanical responses., This work was supported by the Spanish Ministry of Science and Innovation (PGC2018-099645-B-I00 to X.T., PID2019-110949GB-I00 to M.A., BFU2016-79916-P and PID2019-110298GB-I00 to P.R.-C.), the Spanish Ministry of Economy and Competitiveness/FEDER (BES-2016-078220 to C.T., the European Commission (H2020-FETPROACT-01-2016-731957), the European Research Council (Adv-883739 to X.T., CoG-681434 to M.A.), the Generalitat de Catalunya (2017-SGR-1602 to X.T. and P.R.-C., 2017-SGR-1278 to M.A.), the prize “ICREA Academia” for excellence in research to P.R.-C. and to M.A., Fundació la Marató de TV3 (201936-30-31 and 201903-30-31-32), and “la Caixa” Foundation (Agreement LCF/PR/HR20/52400004). IBEC and CIMNE are recipients of a Severo Ochoa Award of Excellence from the MINECO. We would like to thank all the members of P. Roca-Cusachs, X. Trepat, and M. Arroyo laboratories for technical assistance and discussions. We thank M. Pons, X. Menino, M.G. Parajo, M.-A. Rodriguez, N. Castro, R. Sunyer, I. Granero, V. González, the Unitat de Criomicroscòpia Electrònica (Centres Científics i Tecnològics de la Universitat de Barcelona, CCiTUB), and the MicroFabSpace and Microscopy Characterization Facility, Unit 7 of ICTS “NANBIOSIS” from CIBER-BBN at IBEC, for their excellent technical assistance.

Published

2020

43. Measuring mechanical stress in living tissues

Author

Manuel Gomez-Gonzalez, Xavier Trepat, Ernest Latorre, and Marino Arroyo

Subjects

Ciències de la salut, 0303 health sciences, Materials science, Continuum mechanics, Regeneration (biology), Mecànica dels medis continus, General Physics and Astronomy, 02 engineering and technology, 021001 nanoscience & nanotechnology, Medical sciences, Traction force microscopy, Stress (mechanics), 03 medical and health sciences, Tissues, In vivo, Microscopy, Cultured cell, 0210 nano-technology, 030304 developmental biology, Biomedical engineering, Teixits (Histologia)

Abstract

Living tissues are active, multifunctional materials capable of generating, sensing, withstanding and responding to mechanical stress. These capabilities enable tissues to adopt complex shapes during development, to sustain those shapes during homeostasis and to restore them during healing and regeneration. Abnormal stress is associated with a broad range of pathological conditions, including developmental defects, inflammatory diseases, tumour growth and metastasis. A number of techniques are available to measure mechanical stress in living tissues at cellular and subcellular resolution. 2D techniques that map stress in cultured cell monolayers provide the highest resolution and accessibility, and include 2D traction force microscopy, micropillar arrays, monolayer stress microscopy and monolayer stretching between flexible cantilevers. Mapping stresses in tissues cultured in 3D can be achieved using 3D traction force microscopy and the microbulge test. Techniques for measuring stress in vivo include servo-null methods for measuring luminal pressure, deformable inclusions, Forster resonance energy transfer tension sensors, laser ablation and computational methods for force inference. Although these techniques are far from becoming everyday tools in biomedical laboratories, their rapid development is fostering key advances in our understanding of the role of mechanics in morphogenesis, homeostasis and disease. Methods for measuring stress in living cells, tissues and organs are advancing steadily and are increasingly being used for biomedical applications. In this Review, we discuss the concept of tissue stress and the techniques available to measure it in 2D and 3D cell and tissue cultures and in vivo.

Published

2020

44. A physical mechanism of TANGO1-mediated bulky cargo export

Author

Marino Arroyo, Ishier Raote, Maria F. Garcia-Parajo, Felix Campelo, Nikhil Walani, Morgan Chabanon, Vivek Malhotra, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Protein Conformation, Regulator, Vesicular Transport Proteins, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Golgi Apparatus, 76 Fluid mechanics::76Z Biological fluid mechanics [Classificació AMS], budding, Endoplasmic Reticulum, Physics of Living Systems, Membrane tension, membrane tension, 0302 clinical medicine, Mecànica de fluids, Membrane dynamics, Biology (General), COPII, procollagen export, 0303 health sciences, Chemistry, General Neuroscience, European research, General Medicine, Transmembrane protein, Membrane, Medicine, Christian ministry, hormones, hormone substitutes, and hormone antagonists, QH301-705.5, Science, membrane dynamics, Citologia, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Protein Domains, Political science, None, Fluid mechanics, 030304 developmental biology, General Immunology and Microbiology, Endoplasmic reticulum, Aryl Hydrocarbon Receptor Nuclear Translocator, Cell Biology, secretory pathway, Procollagen peptidase, Cytosol, Models, Chemical, Cytoplasm, membrane curvature, Biophysics, Research Advance, Proteïnes, Humanities, 030217 neurology & neurosurgery

Abstract

The endoplasmic reticulum (ER)-resident protein TANGO1 assembles into a ring around ER exit sites (ERES), and links procollagens in the ER lumen to COPII machinery, tethers, and ER-Golgi intermediate compartment (ERGIC) in the cytoplasm (Raote et al., 2018). Here, we present a theoretical approach to investigate the physical mechanisms of TANGO1 ring assembly and how COPII polymerization, membrane tension, and force facilitate the formation of a transport intermediate for procollagen export. Our results indicate that a TANGO1 ring, by acting as a linactant, stabilizes the open neck of a nascent COPII bud. Elongation of such a bud into a transport intermediate commensurate with bulky procollagens is then facilitated by two complementary mechanisms: (i) by relieving membrane tension, possibly by TANGO1-mediated fusion of retrograde ERGIC membranes and (ii) by force application. Altogether, our theoretical approach identifies key biophysical events in TANGO1-driven procollagen export. M Chabanon, MF Garcia-Parajo and F Campelo acknowledge support from the Government of Spain (FIS2015-63550-R, FIS2017-89560-R, BFU2015-73288-JIN, RYC-2017–22227, and PID2019-106232RB-I00/10.13039/501100011033; Severo Ochoa CEX2019-000910-S), Fundació Cellex, Fundació Mir-Puig, and Generalitat de Catalunya (CERCA, AGAUR), ERC Advanced Grant NANO-MEMEC (GA 788546) and LaserLab 4 Europe (GA 654148). I Raote and V Malhotra acknowledge funding by grants from the Ministerio de Economía, Industria y Competitividad Plan Nacional (BFU2013-44188-P) and Consolider (CSD2009-00016); support of the Spanish Ministry of Economy and Competitiveness, through the Programmes ‘Centro de Excelencia Severo Ochoa 2013–2017’ (SEV-2012–0208) and Maria de Maeztu Units of Excellence in R and D (MDM-2015–0502); and support of the CERCA Programme/Generalitat de Catalunya. I Raote, MF Garcia-Parajo, V Malhotra., and F Campelo acknowledge initial support by a BIST Ignite Grant (eTANGO). I Raote acknowledges support from the Spanish Ministry of Science, Innovation and Universities (IJCI-2017–34751). M Arroyo and N Walani acknowledge the support of the European Research Council (CoG-681434), and M Arroyo that of the Generalitat de Catalunya (2017-SGR-1278 and ICREA Academia prize for excellence in research) and of the Spanish Ministry of Economy and Competitiveness, through the Severo Ochoa Programme (CEX2018-000797- S)

Published

2020

45. Adhesion and friction control localized folding in supported graphene

Author

Kuan Zhang, Marino Arroyo, Universitat Politècnica de Catalunya. Departament de Matemàtica Aplicada III, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Engineering, Civil, Materials science, Grafè, friction, General Physics and Astronomy, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Engineering, Multidisciplinary, Nanotechnology, Física::Física de l'estat sòlid [Àrees temàtiques de la UPC], 02 engineering and technology, Substrate (electronics), 01 natural sciences, Instability, law.invention, symbols.namesake, Strain engineering, law, 0103 physical sciences, buckling, Engineering, Ocean, 010306 general physics, Engineering, Aerospace, Engineering, Biomedical, Graphene, graphene, Adhesion, 021001 nanoscience & nanotechnology, compressive strength, Computer Science, Software Engineering, Engineering, Marine, Folding (chemistry), Engineering, Manufacturing, Engineering, Mechanical, adhesion, Buckling, thin films, Chemical physics, chemical vapour deposition, Engineering, Industrial, symbols, compressibility, elasticity, van der Waals force, 0210 nano-technology

Abstract

Graphene deposited on planar surfaces often exhibits sharp and localized folds delimiting seemingly planar regions, as a result of compressive stresses transmitted by the substrate. Such folds alter the electronic and chemical properties of graphene, and therefore, it is important to understand their emergence, to either suppress them or control their morphology. Here, we study the emergence of out-of-plane deformations in supported and laterally strained graphene with high-fidelity simulations and a simpler theoretical model. We characterize the onset of buckling and the nonlinear behavior after the instability in terms of the adhesion and frictional material parameters of the graphene-substrate interface. We find that localized folds evolve from a distributed wrinkling linear instability due to the nonlinearity in the van der Waals graphene-substrate interactions. We identify friction as a selection mechanism for the separation between folds, as the formation of far apart folds is penalized by the work of friction. Our systematic analysis is a first step towards strain engineering of supported graphene, and is applicable to other compressed thin elastic films weakly coupled to a substrate.

Published

2020

46. Self-Propulsion of Active Colloids via Ion Release: Theory and Experiments

Author

Samuel Sanchez, Xavier Arqué, Ignacio Pagonabarraga, Marino Arroyo, Marco De Corato, Tania Patiño, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

gradients, Materials science, particle, General Physics and Astronomy, Non-equilibrium thermodynamics, Ionic bonding, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Electrolyte, 01 natural sciences, symbols.namesake, Colloid, 0103 physical sciences, Surface charge, Colloids, 010306 general physics, Debye length, Ion release, micromotors, urease, Col·loides, Particle physics, Geofísica, Condensed Matter::Soft Condensed Matter, Geophysics, Chemical physics, symbols, Particle, 86 Geophysics [Classificació AMS], Física de partícules, Experiments

Abstract

We study the self-propulsion of a charged colloidal particle that releases ionic species using theory and experiments. We relax the assumptions of thin Debye length and weak nonequilibrium effects assumed in classical phoretic models. This leads to a number of unexpected features that cannot be rationalized considering the classic phoretic framework: an active particle can reverse the direction of motion by increasing the rate of ion release and can propel even with zero surface charge. Our theory predicts that there are optimal conditions for self-propulsion and a novel regime in which the velocity is insensitive to the background electrolyte concentration. The theoretical results quantitatively capture the salt-dependent velocity measured in our experiments using active colloids that propel by decomposing urea via a surface enzymatic reaction.

Published

2019

47. Modelling fluid deformable surfaces with an emphasis on biological interfaces

Author

Alejandro Torres-Sánchez, Daniel Millán, Marino Arroyo, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], 01 natural sciences, Fluid interfaces, 65 Numerical analysis::65D Numerical approximation and computational geometry [Classificació AMS], Subdivision surface, Strain energy release rate, 0303 health sciences, Partial differential equation, 92 Biology and other natural sciences::92B Mathematical biology in general [Classificació AMS], Reynolds number, Physics - Fluid Dynamics, Computational Physics (physics.comp-ph), Dissipation, Condensed Matter Physics, Engineering, Mechanical, Classical mechanics, Biological Physics (physics.bio-ph), Mechanics of Materials, symbols, Physics - Computational Physics, Numerical analysis, Engineering, Civil, Biomatemàtica, FOS: Physical sciences, Engineering, Multidisciplinary, Condensed Matter - Soft Condensed Matter, Matemàtiques i estadística::Anàlisi numèrica [Àrees temàtiques de la UPC], 03 medical and health sciences, symbols.namesake, Actin cortex, 0103 physical sciences, Arbitrarily Lagrangian-Eulerian, Physics - Biological Physics, Engineering, Ocean, 010306 general physics, Engineering, Aerospace, Engineering, Biomedical, 030304 developmental biology, Biomathematics, Anàlisi numèrica, Continuum mechanics, Mechanical Engineering, Subdivision surfaces, Fluid Dynamics (physics.flu-dyn), Eulerian path, Lipid membranes, Computer Science, Software Engineering, Engineering, Marine, Engineering, Manufacturing, Nonlinear system, Engineering, Industrial, Soft Condensed Matter (cond-mat.soft)

Abstract

Fluid deformable surfaces are ubiquitous in cell and tissue biology, including lipid bilayers, the actomyosin cortex, or epithelial cell sheets. These interfaces exhibit a complex interplay between elasticity, low Reynolds number interfacial hydrodynamics, chemistry, and geometry, and govern important biological processes such as cellular traffic, division, migration, or tissue morphogenesis. To address the modelling challenges posed by this class of problems, in which interfacial phenomena tightly interact with the shape and dynamics of the surface, we develop a general continuum mechanics and computational framework for fluid deformable surfaces. The dual solid-fluid nature of fluid deformable surfaces challenges classical Lagrangian or Eulerian descriptions of deforming bodies. Here, we extend the notion of Arbitrarily Lagrangian-Eulerian (ALE) formulations, well-established for bulk media, to deforming surfaces. To systematically develop models for fluid deformable surfaces, which consistently treat all couplings between fields and geometry, we follow a nonlinear Onsager formalism according to which the dynamics minimize a Rayleighian functional where dissipation, power input and energy release rate compete. Finally, we propose new computational methods, which build on Onsager's formalism and our ALE formulation, to deal with the resulting stiff system of higher-order of partial differential equations. We apply our theoretical and computational methodology to classical models for lipid bilayers and the cell cortex. The methods developed here allow us to formulate/simulate these models for the first time in their full three-dimensional generality, accounting for finite curvatures and finite shape changes., Comment: 58 pages, 21 figures, submitted for publication to the Journal of Fluid Mechanics

Published

2019

48. Combined molecular/continuum modeling reveals the role of friction during fast unfolding of coiled-coil proteins

Author

Alejandro Torres-Sánchez, Prashant K. Purohit, Marino Arroyo, Juan M. Vanegas, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Models, Molecular, Engineering, Civil, Materials science, Biomatemàtica, Globular protein, Protein Conformation, Engineering, Multidisciplinary, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], 02 engineering and technology, Molecular Dynamics Simulation, 010402 general chemistry, 01 natural sciences, Molecular dynamics, Protein structure, Cytosol, Engineering, Ocean, Cytoskeleton, Continuum Modeling, Engineering, Aerospace, Engineering, Biomedical, Protein Unfolding, chemistry.chemical_classification, Coiled coil, Biomathematics, Quantitative Biology::Biomolecules, Continuum (measurement), Matemàtiques i estadística::Anàlisi numèrica::Modelització matemàtica [Àrees temàtiques de la UPC], Hidrodinàmica, 92 Biology and other natural sciences::92B Mathematical biology in general [Classificació AMS], Proteins, 76 Fluid mechanics::76E Hydrodynamic stability [Classificació AMS], General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Computer Science, Software Engineering, Engineering, Marine, 0104 chemical sciences, Engineering, Manufacturing, Engineering, Mechanical, chemistry, Electromagnetic coil, Chemical physics, Engineering, Industrial, Hydrodynamics, 0210 nano-technology

Abstract

Coiled-coils are filamentous proteins that form the basic building block of important force-bearing cellular elements, such as intermediate filaments and myosin motors. In addition to their biological importance, coiled-coil proteins are increasingly used in new biomaterials including fibers, nanotubes, or hydrogels. Coiled-coils undergo a structural transition from an a-helical coil to an unfolded state upon extension, which allows them to sustain large strains and is critical for their biological function. By performing equilibrium and out-of-equilibrium all-atom molecular dynamics (MD) simulations of coiledcoils in explicit solvent, we show that two-state models based on Kramers’ or Bell’s theories fail to predict the rate of unfolding at high pulling rates. We further show that an atomistically informed continuum rod model accounting for phase transformations and for the hydrodynamic interactions with the solvent can reconcile two-state models with our MD results. Our results show that frictional forces, usually neglected in theories of fibrous protein unfolding, reduce the thermodynamic force acting on the interface, and thus control the dynamics of unfolding at different pulling rates. Our results may help interpret MD simulations at high pulling rates, and could be pertinent to cytoskeletal networks or protein-based artificial materials subjected to shocks or blasts.

Published

2019

49. Swimming Euglena respond to confinement with a behavioural change enabling effective crawling

Author

Alfred Beran, Antonio DeSimone, Marino Arroyo, Giovanni Noselli, Noselli, Giovanni, Beran, Alfred, Arroyo, Marino, De Simone, Antonio, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Biologia, Engineering, Civil, General Physics and Astronomy, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], FOS: Physical sciences, Engineering, Multidisciplinary, Condensed Matter - Soft Condensed Matter, Crawling, Hydraulic resistance, 01 natural sciences, Euglena, Article, 010305 fluids & plasmas, Physics and Astronomy (all), Gait (human), 0103 physical sciences, Motor system, Settore ICAR/08 - Scienza delle Costruzioni, Physics - Biological Physics, 14. Life underwater, Engineering, Ocean, 010306 general physics, Biology, Engineering, Aerospace, Engineering, Biomedical, 92 Biology and other natural sciences::92C Physiological, cellular and medical topics [Classificació AMS], Physics, biology, biology.organism_classification, Computer Science, Software Engineering, Engineering, Marine, 3. Good health, Engineering, Manufacturing, Engineering, Mechanical, Biological Physics (physics.bio-ph), Engineering, Industrial, Soft Condensed Matter (cond-mat.soft), Biological system

Abstract

Some euglenids, a family of aquatic unicellular organisms, can develop highly concerted, large-amplitude peristaltic body deformations. This remarkable behaviour has been known for centuries. Yet, its function remains controversial, and is even viewed as a functionless ancestral vestige. Here, by examining swimming Euglena gracilis in environments of controlled crowding and geometry, we show that this behaviour is triggered by confinement. Under these conditions, it allows cells to switch from unviable flagellar swimming to a new and highly robust mode of fast crawling, which can deal with extreme geometric confinement and turn both frictional and hydraulic resistance into propulsive forces. To understand how a single cell can control such an adaptable and robust mode of locomotion, we developed a computational model of the motile apparatus of Euglena cells consisting of an active striated cell envelope. Our modelling shows that gait adaptability does not require specific mechanosensitive feedback but instead can be explained by the mechanical self-regulation of an elastic and extended motor system. Our study thus identifies a locomotory function and the operating principles of the adaptable peristaltic body deformation of Euglena cells., Comment: 8 pages, 4 figures

Published

2019

50. Embryonic self-fracking

Author

Marino Arroyo, Xavier Trepat, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Embryology, Biomatemàtica, animal structures, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], Natural Gas, 01 natural sciences, Mice, 03 medical and health sciences, 0103 physical sciences, Animals, Hydraulic Fracking, 010306 general physics, Environmental planning, 030304 developmental biology, Biomathematics, 0303 health sciences, Multidisciplinary, Laboratory animals, Embriologia, Chemistry, 92 Biology and other natural sciences::92B Mathematical biology in general [Classificació AMS], Animals de laboratori, Embryonic stem cell, Blastocyst, embryonic structures, Environmental Monitoring

Abstract

© 2019. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/ From a broken bone to a major earthquake, the fracture of a material usually means trouble. However, in some practical applications engineers have learned how to harness the mechanisms of fracture. This is illustrated by the well-known process of hydraulic fracturing, or “fracking,” in which injection of pressurized fluid in shale rocks opens cracks to extract oil or gas (1). On page 465 of this issue, Dumortier et al. (2) show that the developing mouse embryo uses this same principle to transiently disrupt its shape and sculpt a more complex one. Fracking is the key mechanism that enables the early embryo to develop its first symmetry axis, a key stage in fetal morphogenesis. The authors are supported by the European Research Council (CoG-616480 to XT, CoG-681434 to MA), European Union (H2020-FETPROACT-01-2016-731957), Generalitat de Catalunya and CERCA program, “ICREA Academia” award (MA), the Spanish Ministry for Science and Innovation/FEDER, Obra Social “La Caixa (XT)”, and Severo Ochoa Award (XT).

Published

2019