Your search keyword '"Joris Sprakel"' showing total 141 results

1. Phytophthora zoospores display klinokinetic behaviour in response to a chemoattractant.

Author

Michiel Kasteel, Tharun P Rajamuthu, Joris Sprakel, Tijs Ketelaar, and Francine Govers

Subjects

Immunologic diseases. Allergy, RC581-607, Biology (General), QH301-705.5

Abstract

Microswimmers are single-celled bodies powered by flagella. Typical examples are zoospores, dispersal agents of oomycete plant pathogens that are used to track down hosts and infect. Being motile, zoospores presumably identify infection sites using chemical cues such as sugars, alcohols and amino acids. With high-speed cameras we traced swimming trajectories of Phytophthora zoospores over time and quantified key trajectory parameters to investigate chemotactic responses. Zoospores adapt their native run-and-tumble swimming patterns in response to the amino acid glutamic acid by increasing the rate at which they turn. Simulations predict that tuneable tumble frequencies are sufficient to explain zoospore aggregation, implying positive klinokinesis. Zoospores thus exploit a retention strategy to remain at the plant surface once arriving there. Interference of G-protein mediated signalling affects swimming behaviour. Zoospores of a Phytophthora infestans G⍺-deficient mutant show higher tumbling frequencies but still respond and adapt to glutamic acid, suggesting chemoreception to be intact.

Published

2024

2. Molecular sensors reveal the mechano-chemical response of Phytophthora infestans walls and membranes to mechanical and chemical stress

Author

Lucile Michels, Jochem Bronkhorst, Michiel Kasteel, Djanick de Jong, Bauke Albada, Tijs Ketelaar, Francine Govers, and Joris Sprakel

Subjects

Cell wall, Plasma membrane, Fluorescence Lifetime Imaging, Crop protection agents, Mechanobiology, Molecular mechanosensors, Cytology, QH573-671

Abstract

Phytophthora infestans, causal agent of late blight in potato and tomato, remains challenging to control. Unravelling its biomechanics of host invasion, and its response to mechanical and chemical stress, could provide new handles to combat this devastating pathogen. Here we introduce two fluorescent molecular sensors, CWP-BDP and NR12S, that reveal the micromechanical response of the cell wall-plasma membrane continuum in P. infestans during invasive growth and upon chemical treatment. When visualized by live-cell imaging, CWP-BDP reports changes in cell wall (CW) porosity while NR12S reports variations in chemical polarity and lipid order in the plasma membrane (PM). During invasive growth, mechanical interactions between the pathogen and a surface reveal clear and localized changes in the structure of the CW. Moreover, the molecular sensors can reveal the effect of chemical treatment to CW and/or PM, thereby revealing the site-of-action of crop protection agents. This mechano-chemical imaging strategy resolves, non-invasively and with high spatio-temporal resolution, how the CW-PM continuum adapts and responds to abiotic stress, and provides information on the dynamics and location of cellular stress responses for which, to date, no other methods are available.

Published

2022

3. Understanding and optimizing Evolon® CR for varnish removal from oil paintings

Author

Lambert Baij, Chun Liu, Jesse Buijs, Alba Alvarez Martin, Dorien Westert, Laura Raven, Norbert Geels, Petria Noble, Joris Sprakel, and Katrien Keune

Subjects

Oil paint cleaning, Evolon $$^\circledR$$ ® CR, Varnish removal, Portable laser speckle imaging, Fine Arts, Analytical chemistry, QD71-142

Abstract

Abstract Evolon $$^\circledR$$ ® CR is increasingly used in paintings conservation for varnish removal from oil paintings. Its key benefits over traditional cotton swabs are limiting solvent exposure and reducing mechanical action on the paint surface. However, this non-woven microfilament textile was not originally engineered for conservation use and little is known about its chemical stability towards organic solvents. Moreover, the physical processes of solvent loading and release by Evolon $$^\circledR$$ ® CR, as well as solvent retention inside paint after cleaning, have not been studied. These three topics were investigated using a multi-analytical approach, aiming for an improved understanding and optimized use of Evolon $$^\circledR$$ ® CR for varnish removal. Our results show that the tissue is generally chemically and physically stable to organic solvents when exposed on timescales that are typical in conservation practice. However, a pre-treatment step of Evolon $$^\circledR$$ ® CR is necessary to avoid the release of unwanted saturated fatty acids into the paint during varnish removal. We show that the primary mechanism of solvent uptake by the fibers is adsorption rather than absorption and that the dominant factor dictating the maximum solvent load is the volume of the voids between the fibers. Finally, solvent induced dynamics after application of solvent-loaded Evolon $$^\circledR$$ ® CR within the paint film was monitored using portable laser speckle imaging on model paints. A method to quantify solvent-retention in real-time was developed and revealed that the presence of varnish on paintings results in lower dynamics of solvents within the paint in comparison to unvarnished paint. Comparing various solvents, it was found that cleaning with acetone resulted in a roughly six-fold increase in dynamics compared to ethanol and isopropanol.

Published

2021

4. Morphing of liquid crystal surfaces by emergent collectivity

Author

Hanne M. van der Kooij, Slav A. Semerdzhiev, Jesse Buijs, Dirk J. Broer, Danqing Liu, and Joris Sprakel

Subjects

Science

Abstract

Liquid crystal networks can morph their shape in response to electrical stimulus. Here the authors provide a detailed description of their deformation mechanism and introduce a method to observe the dynamic surface of liquid crystal elastomers. This could help with the development of smart materials.

Published

2019

5. The Arabidopsis embryo as a quantifiable model for studying pattern formation

Author

Yosapol Harnvanichvech, Vera Gorelova, Joris Sprakel, and Dolf Weijers

Subjects

cell specification, computational cell biology, gene expression, plant embryogenesis, plant development, pattern formation, Plant culture, SB1-1110, Botany, QK1-989

Abstract

Phenotypic diversity of flowering plants stems from common basic features of the plant body pattern with well-defined body axes, organs and tissue organisation. Cell division and cell specification are the two processes that underlie the formation of a body pattern. As plant cells are encased into their cellulosic walls, directional cell division through precise positioning of division plane is crucial for shaping plant morphology. Since many plant cells are pluripotent, their fate establishment is influenced by their cellular environment through cell-to-cell signaling. Recent studies show that apart from biochemical regulation, these two processes are also influenced by cell and tissue morphology and operate under mechanical control. Finding a proper model system that allows dissecting the relationship between these aspects is the key to our understanding of pattern establishment. In this review, we present the Arabidopsis embryo as a simple, yet comprehensive model of pattern formation compatible with high-throughput quantitative assays.

Published

2021

6. Chemical Design Model for Emergent Synthetic Catch Bonds

Author

Martijn van Galen, Jasper van der Gucht, and Joris Sprakel

Subjects

catch bond, mechanochemistry, supramolecular chemistry, kinetic Monte Carlo (KMC), chemical kinetics, Physics, QC1-999

Abstract

All primary chemical bonds inherently weaken under increasing tension. Interestingly, nature is able to combine such bonds into protein complexes that accomplish the opposite behavior: they strengthen with increasing tensional force. These complexes known as catch bonds are increasingly considered a general feature in biological systems subjected to mechanical stress. Despite their prevalence in nature however, no truly synthetic realizations of catch bonds have been accomplished so far, as it is a profound challenge to synthetically mimic the allosteric mechanisms employed by protein catch bonds. In this work we propose a computational model that shows how a synthetic catch bond could be accomplished with the help of existing supramolecular motifs and mechanophores, each of which individually act as slip bonds. This model allows us to identify the limits of catch bonding in terms of a number of experimentally measurable parameters. This knowledge could be used to suggest potential molecular candidates, thereby providing a foothold in the ongoing pursuit to realize synthetic catch bonds.

Published

2020

7. An elastic proteinaceous envelope encapsulates the earlyArabidopsisembryo

Author

Yosapol Harnvanichvech, Cecilia Borassi, Diaa Eldin S. Daghma, Hanne M. van der Kooij, Joris Sprakel, and Dolf Weijers

Abstract

Plant external surfaces are often covered by barriers that control the exchange of molecules, protect from pathogens, and offer mechanical integrity. A key question is when and how such surface barriers are generated. Post-embryonic surfaces have well-studied barriers, including the cuticle, and late Arabidopsis embryo was shown to be protected by an endosperm-derived sheath deposited onto a primordial cuticle. Here we show that both cuticle and sheath are preceded by another structure during the earliest stages of embryogenesis. This structure, which we named the embryonic envelope, is tightly wrapped around the embryonic surface but can be physically detached by cell wall digestion. We show that this structure is composed primarily of Extensin and ArabinogalactanO-glycoproteins and lipids, which appear to form a dense and elastic crosslinked embryonic envelope. The envelope forms in cuticle-deficient mutants and in a mutant that lacks endosperm. This embryo-derived envelope is therefore distinct from previously described cuticle and sheath structures. We propose that it acts as an expandable diffusion barrier, as well as a means to mechanically confine the embryo to maintain its tensegrity during early embryogenesis.Summary statementThe early Arabidopsis embryo is surrounded by a proteinaceous envelope that is distinct from the cuticle or embryo sheath

Published

2023

8. DNA dynamics in complex coacervate droplets and micelles

Author

Inge Bos, Eline Brink, Lucile Michels, and Joris Sprakel

Subjects

Polymers, Cations, Fluorescence Resonance Energy Transfer, Life Science, DNA, General Chemistry, Condensed Matter Physics, Physical Chemistry and Soft Matter, Micelles, VLAG

Abstract

Single stranded DNA (ssDNA), or another polyanion, can be mixed with polycations to form liquid-like complex coacervates. When the polycations are replaced by cationic-neutral diblock copolymers, complex coacervate core micelles (C3Ms) can be formed instead. In both complex coacervates and C3Ms, dynamics plays an important role. Yet, to date, the effect of chain length on the dynamics effect is still not fully understood. The DNA complexes provide a versatile platform to further elucidate these chain length effects because the DNA is monodisperse and its length can be easily adapted. Therefore, we study in this paper the dynamics of fluorescently labelled ssDNA in both complex coacervate droplets and micelles. The DNA dynamics in the complex coacervate droplets is probed by fluorescence recovery after photobleaching (FRAP). We observe that the DNA diffusion coefficient depends more strongly on the DNA length than predicted by the sticky Rouse model and we show that this can be partly explained by changes in complex coacervate density, but that also other factors might play a role. We measure the molecular exchange of C3Ms by making use of Förster resonance energy transfer (FRET) and complement these measurements with Langevin dynamics simulations. We conclude that chain length polydispersity is the main cause of a broad distribution of exchange rates. We hypothesise that the different exchange rates that we observe for the monodisperse DNA are mainly caused by differences in dye interactions and show that the dye can indeed have a large effect on the C3M exchange. In addition, we show that a new description of the C3M molecular exchange is required that accounts among others for the effect of the length of the oppositely charged core species. Together our findings can help to better understand the dynamics in both specific DNA systems and in complex coacervate droplets and micelles in general.

Published

2022

9. Rapid Molecular Mechanotyping with Microfluidic Force Spectroscopy

Author

Martijn van Galen, Annemarie Bok, Taieesa Peshkovsky, Jasper van der Gucht, Bauke Albada, and Joris Sprakel

Abstract

Molecular mechanotyping, the quantification of changes in the stability of supramolecular interactions and chemical bonds under the action of mechanical forces, is an essential tool in the field of mechanochemistry. This is conventionally done in single-molecule force-spectroscopy (smFS) assays, for example with optical tweezers or Atomic Force Microscopy. While these techniques provide detailed mechanochemical insights, they are time-consuming, technically demanding and expensive; as a result, high-throughput screening of the mechanochemical properties of molecules of interest is challenging. To resolve this, we present a rapid, simple and low-cost mechanotyping assay: microfluidic force spectroscopy (µFFS), which probes force-dependent bond stability by measuring the detachment of microparticles, bound to microfluidic channels by the interaction of interest, under hydrodynamic forcing. As this allows the simultaneous observation of hundreds of microparticles, we obtain a quantitative mechanotype in a single measurement, using readily available equipment. We validate our method by studying the stability of DNA duplexes, previously characterized through smFS. We further show that we can quantitatively describe the experimental data with simulations, which allows us to link theµFFS data to single-bond mechanochemical properties. This opens the way to use (µFFS) as a rapid molecular mechanotyping tool.

Published

2023

10. Understanding and optimizing Evolon® CR for varnish removal from oil paintings

Author

Chun Liu, Katrien Keune, Jesse Buijs, Joris Sprakel, Dorien Westert, Laura Raven, Petria Noble, Alba Alvarez Martin, Lambert Baij, and Norbert J. Geels

Subjects

Archeology, Portable laser speckle imaging, Materials science, Evolon $$^\circledR$$ ® CR, Fine Arts, Varnish, Conservation, chemistry.chemical_compound, Adsorption, Oil paint cleaning, Varnish removal, Acetone, VLAG, QD71-142, Evolon CR, Dominant factor, Solvent, chemistry, Chemical engineering, visual_art, visual_art.visual_art_medium, Chemical stability, Absorption (chemistry), Solvent exposure, Physical Chemistry and Soft Matter, Analytical chemistry

Abstract

Evolon$$^\circledR$$ ® CR is increasingly used in paintings conservation for varnish removal from oil paintings. Its key benefits over traditional cotton swabs are limiting solvent exposure and reducing mechanical action on the paint surface. However, this non-woven microfilament textile was not originally engineered for conservation use and little is known about its chemical stability towards organic solvents. Moreover, the physical processes of solvent loading and release by Evolon$$^\circledR$$ ® CR, as well as solvent retention inside paint after cleaning, have not been studied. These three topics were investigated using a multi-analytical approach, aiming for an improved understanding and optimized use of Evolon$$^\circledR$$ ® CR for varnish removal. Our results show that the tissue is generally chemically and physically stable to organic solvents when exposed on timescales that are typical in conservation practice. However, a pre-treatment step of Evolon$$^\circledR$$ ® CR is necessary to avoid the release of unwanted saturated fatty acids into the paint during varnish removal. We show that the primary mechanism of solvent uptake by the fibers is adsorption rather than absorption and that the dominant factor dictating the maximum solvent load is the volume of the voids between the fibers. Finally, solvent induced dynamics after application of solvent-loaded Evolon$$^\circledR$$ ® CR within the paint film was monitored using portable laser speckle imaging on model paints. A method to quantify solvent-retention in real-time was developed and revealed that the presence of varnish on paintings results in lower dynamics of solvents within the paint in comparison to unvarnished paint. Comparing various solvents, it was found that cleaning with acetone resulted in a roughly six-fold increase in dynamics compared to ethanol and isopropanol.

Published

2021

11. A RAF-like kinase mediates a deeply conserved, ultra-rapid auxin response

Author

Andre Kuhn, Mark Roosjen, Sumanth Mutte, Shiv Mani Dubey, Polet Carrillo Carrasco, Aline Monzer, Takayuki Kohchi, Ryuichi Nishihama, Matyáš Fendrych, Jiří Friml, Joris Sprakel, and Dolf Weijers

Abstract

SUMMARYThe plant signaling molecule auxin triggers both fast and slow cellular responses across the plant kingdom, including both land plants and algae. A nuclear response pathway mediates auxin-dependent gene expression, and controls a range of growth and developmental processes in land plants. It is unknown what mechanisms underlie both the physiological responses occurring within seconds, and the responses in algae, that lack the nuclear auxin response pathway. We discovered an ultra-fast proteome-wide phosphorylation response to auxin across 5 land plant and algal species, converging on a core group of shared target proteins. We find conserved rapid physiological responses to auxin in the same species and identified a RAF-like protein kinase as a central mediator of auxin-triggered phosphorylation across species. Genetic analysis allowed to connect this kinase to both auxin-triggered protein phosphorylation and a rapid cellular response, thus identifying an ancient mechanism for fast auxin responses in the green lineage.

Published

2022

12. A slicing mechanism facilitates host entry by plant-pathogenic Phytophthora

Author

Michiel Kasteel, K. Kots, Jesse Buijs, Jasper van der Gucht, Tijs Ketelaar, JM Jessica Clough, Francine Govers, Stijn van der Veen, Joris Sprakel, and Jochem Bronkhorst

Subjects

Microbiology (medical), Phytophthora infestans, Phytophthora palmivora, Immunology, Applied Microbiology and Biotechnology, Microbiology, 03 medical and health sciences, Genetics, Life Science, VLAG, Plant Diseases, 030304 developmental biology, Oomycete, 0303 health sciences, Appressorium, biology, 030306 microbiology, Host (biology), fungi, food and beverages, Laboratorium voor Celbiologie, Cell Biology, Plants, biology.organism_classification, Entry into host, Laboratorium voor Phytopathologie, Cell biology, Laboratory of Cell Biology, Phytophthora capsici, Laboratory of Phytopathology, Host-Pathogen Interactions, Phytophthora, EPS, Physical Chemistry and Soft Matter

Abstract

Phytophthora species, classified as oomycetes, are among the most destructive plant pathogens worldwide and pose a substantial threat to food security. Plant pathogens have developed various methods to breach the cuticle and walls of plant cells. For example, plant-pathogenic fungi use a ‘brute-force’ approach by producing a specialized and fortified invasion organ to generate invasive pressures. Unlike in fungi, the biomechanics of host invasion in oomycetes remains poorly understood. Here, using a combination of surface-deformation imaging, molecular-fracture sensors and modelling, we find that Phytophthora infestans, Phytophthora palmivora and Phytophthora capsici slice through the plant surface to gain entry into host tissues. To distinguish this mode of entry from the brute-force approach of fungi that use appressoria, we name this oomycete entry without appressorium formation ‘naifu’ invasion. Naifu invasion relies on polarized, non-concentric, force generation onto the surface at an oblique angle, which concentrates stresses at the site of invasion to enable surface breaching. Measurements of surface deformations during invasion of artificial substrates reveal a polarized mechanical geometry that we describe using a mathematical model. We confirm that the same mode of entry is used on real hosts. Naifu invasion uses actin-mediated polarity, surface adherence and turgor generation to enable Phytophthora to invade hosts without requiring specialized organs or vast turgor generation.

Published

2021

13. Direct measurement of appressorium turgor using a molecular mechanosensor in the rice blast fungus Magnaporthe oryzae

Author

Lauren S. Ryder, Sergio G. Lopez, Lucile Michels, Alice B. Eseola, Joris Sprakel, Weibin Ma, and Nicholas J. Talbot

Abstract

Many plant pathogenic fungi forcibly enter their hosts to cause disease. The rice blast fungus Magnaporthe oryzae, for example, infects plants using a specialised infection cell called an appressorium, which generates enormous turgor to drive a rigid penetration peg through the rice leaf cuticle. While these vast internal pressures are a critical weapon in fungal host penetration, they have remained very challenging to probe directly during host invasion, leaving our understanding of these extreme cellular mechanics incomplete. Here, we combine Fluorescence Lifetime Imaging (FLIM) with a membrane-targeting molecular mechanoprobe to quantify changes in membrane tension as a direct proxy for appressorial turgor in M. oryzae. We report that mature melanin-pigmented M. oryzae appressoria display a heterogeneous low fluorescence lifetime and high membrane tension, consistent with enormous turgor. These extreme pressures lead to large-scale spatial heterogeneities in membrane mechanics, much greater than observed in any other cell type previously, highlighting the extreme mechanics of turgor-driven appressorium-mediated plant infection. By contrast, appressoria of non-pathogenic melanin-deficient mutants, alb1 and buf1, or immature non-melanised appressoria, exhibit high fluorescence lifetime, consistent with low membrane tension and turgor, that remain spatially homogeneous. To evaluate the method, we investigated turgor dynamics in a range of mutants impaired in appressorium function. We show that the turgor sensor kinase mutant Δsln1, recently proposed to generate excess appressorium turgor, displayed a significantly higher membrane tension compared to an isogenic wild type M. oryzae strain. This non-invasive, live cell imaging technique allows direct quantification and visualization of the enormous turgor pressures deployed during pathogen infection.

Published

2022

14. An actin mechanostat ensures hyphal tip sharpness in

Author

Jochem, Bronkhorst, Kiki, Kots, Djanick, de Jong, Michiel, Kasteel, Thomas, van Boxmeer, Tanweer, Joemmanbaks, Francine, Govers, Jasper, van der Gucht, Tijs, Ketelaar, and Joris, Sprakel

Abstract

Filamentous plant pathogens apply mechanical forces to pierce their hosts surface and penetrate its tissues. Devastating

Published

2022

15. Stochastic buckling of self-assembled colloidal structures

Author

Simon Stuij, Jan Maarten van Doorn, Thomas Kodger, Joris Sprakel, Corentin Coulais, and Peter Schall

Subjects

Physics, QC1-999

Abstract

The vast majority of soft and biological materials, gels, and tissues are made from micrometer-size slender structures such as biofilaments and colloidal and molecular chains, which are believed to crucially control their mechanics. These constituents show intriguing extreme mechanics, mechanical instabilities, and plasticity, which, besides attracting significant theoretical attention, have not been studied experimentally and as such remain poorly understood. Here we investigate, by experiments, simulations, and theory, the mechanical instabilities of a slender self-assembled colloidal structure, observing a form of stochastic buckling where thermal fluctuations and associated entropic force effects are amplified in the vicinity of a buckling instability. We fully characterize how the persistence length and plasticity control the stochastic buckling transition, leading to intriguing higher-order buckling modes. These results elucidate the interplay of geometrical, thermal, and plastic interactions in the nonlinear mechanics of thermal self-assembled structures, crucial to the mechanical response and function of fiber-based soft and biological materials, as well as the rational design of micro- and nanoscale architectures.

Published

2019

16. Complex coacervation and metal–ligand bonding as synergistic design elements for aqueous viscoelastic materials

Author

Alexei D. Filippov, Joris Sprakel, Marleen Kamperman, and Polymer Science

Subjects

Materials science, Coacervate, Ligand, Relaxation (NMR), 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Dissociation (chemistry), Polyelectrolyte, Viscoelasticity, 0104 chemical sciences, Rheology, Chemical physics, Dissipative system, Life Science, 0210 nano-technology, Physical Chemistry and Soft Matter, VLAG

Abstract

The application of complex coacervates in promising areas such as coatings and surgical glues requires a tight control of their viscous and elastic behaviour, and a keen understanding of the corresponding microscopic mechanisms. While the viscous, or dissipative, aspect is crucial at pre-setting times and in preventing detachment, elasticity at long waiting times and low strain rates is crucial to sustain a load-bearing joints. The independent tailoring of dissipative and elastic properties proves to be a major challenge that can not be addressed adequately by the complex coacervate motif by itself. We propose a versatile model of complex coacervates with customizable rheological fates by functionalization of polyelectrolytes with terpyridines, which provide transient crosslinks through complexation with metals. We show that the rheology of the hybrid complexes shows distinct footprints of both metal-ligand and coacervate dynamics, the former as a contribution very close to pure Maxwell viscoelasticity, the latter approaching a sticky Rouse fluid. Strikingly, when the contribution of metal-ligand bonds is dominant at long times, the relaxation of the overall complex is much slower than either the "native"coacervate relaxation time or the dissociation time of a comparable non-coacervate polyelectrolyte-metal-ligand complex. We recognize this slowing-down of transient bonds as a synergistic effect that has important implications for the use of complementary transient bonding in coacervate complexes.

Published

2021

17. Direct Observation of Entropic Stabilization of bcc Crystals Near Melting

Author

Joris Sprakel, Alessio Zaccone, Frans Spaepen, Peter Schall, and David A. Weitz

Published

2017

18. Chemical Feedback in Templated Reaction-Assembly Networks

Author

Inge Bos, Camilla Terenzi, and Joris Sprakel

Subjects

Polymers and Plastics, Chemistry, Organic Chemistry, Biophysics, Supramolecular chemistry, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Article, 0104 chemical sciences, Inorganic Chemistry, Biofysica, Polymerization, Reaction model, Materials Chemistry, Life Science, Protein folding, 0210 nano-technology, Physical Chemistry and Soft Matter, VLAG, Macromolecule

Abstract

Chemical feedback between building block synthesis and their subsequent supramolecular self-assembly into nanostructures has profound effects on assembly pathways. Nature harnesses feedback in reaction-assembly networks in a variety of scenarios including virion formation and protein folding. Also in nanomaterial synthesis, reaction-assembly networks have emerged as a promising control strategy to regulate assembly processes. Yet, how chemical feedback affects the fundamental pathways of structure formation remains unclear. Here, we unravel the pathways of a templated reaction-assembly network that couples a covalent polymerization to an electrostatic coassembly process. We show how the supramolecular staging of building blocks at a macromolecular template can accelerate the polymerization reaction and prevent the formation of kinetically trapped structures inherent to the process in the absence of feedback. Finally, we establish a predictive kinetic reaction model that quantitatively describes the pathways underlying these reaction-assembly networks. Our results shed light on the fundamental mechanisms by which chemical feedback can steer self-assembly reactions and can be used to rationally design new nanostructures.

Published

2020

19. Electroplasticization of Liquid Crystal Polymer Networks

Author

Dirk J. Broer, Joris Sprakel, Danqing Liu, Hanne M. van der Kooij, Stimuli-responsive Funct. Materials & Dev., and ICMS Core

Subjects

Materials science, Soft robotics, Nanotechnology, 02 engineering and technology, surface morphing, 010402 general chemistry, 01 natural sciences, active materials, Viscoelasticity, Liquid crystal, Electric field, General Materials Science, glass transition, nanoscale dynamics, VLAG, chemistry.chemical_classification, laser speckle imaging, Electric potential energy, Polymer, electrical actuation, liquid crystal polymer networks, 021001 nanoscience & nanotechnology, nonlinear mechanics, 0104 chemical sciences, Devitrification, chemistry, 0210 nano-technology, Glass transition, Physical Chemistry and Soft Matter, Research Article

Abstract

Shape-shifting liquid crystal networks (LCNs) can transform their morphology and properties in response to external stimuli. These active and adaptive polymer materials can have impact in a diversity of fields, including haptic displays, energy harvesting, biomedicine, and soft robotics. Electrically driven transformations in LCN coatings are particularly promising for application in electronic devices, in which electrodes are easily integrated and allow for patterning of the functional response. The morphing of these coatings, which are glassy in the absence of an electric field, relies on a complex interplay between polymer viscoelasticity, liquid crystal order, and electric field properties. Morphological transformations require the material to undergo a glass transition that plasticizes the polymer sufficiently to enable volumetric and shape changes. Understanding how an alternating current can plasticize very stiff, densely cross-linked networks remains an unresolved challenge. Here, we use a nanoscale strain detection method to elucidate this electric-field-induced devitrification of LCNs. We find how a high-frequency alternating field gives rise to pronounced nanomechanical changes at a critical frequency, which signals the electrical glass transition. Across this transition, collective motion of the liquid crystal molecules causes the network to yield from within, leading to network weakening and subsequent nonlinear expansion. These results unambiguously prove the existence of electroplasticization. Fine-tuning the induced emergence of plasticity will not only enhance the surface functionality but also enable more efficient conversion of electrical energy into mechanical work.

Published

2020

20. The contribution of colloidal aggregates to the clogging dynamics at the pore scale

Author

Nolwenn Delouche, Joris Sprakel, Thomas E. Kodger, Andrew B. Schofield, J. van Doorn, Hervé Tabuteau, Institut de Physique de Rennes (IPR), Université de Rennes (UR)-Centre National de la Recherche Scientifique (CNRS), Wageningen University and Research [Wageningen] (WUR), University of Edinburgh, Agence Nationale de la Recherche, ANR (ANR-12-JS09-0003), Centre National d’Etudes Spatiales, CNES (Collmat)., ANR-12-JS09-0003,COLLMAT,Colmatage des milieux poreux : de la particule colloïdale au bouchon(2012), Université de Rennes 1 (UR1), and Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Aggregates, Materials science, Microfluidics, Filtration and Separation, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biochemistry, law.invention, Clogging, Pore clogging, Colloidal particles, law, General Materials Science, Physical and Theoretical Chemistry, Filtration, VLAG, [PHYS]Physics [physics], Fouling, 021001 nanoscience & nanotechnology, Particle size and type distributions, 0104 chemical sciences, Chemical engineering, DLVO theory, Particle, Particle size, 0210 nano-technology, Dispersion (chemistry), Physical Chemistry and Soft Matter, Particle deposition

Abstract

International audience; During the filtration of colloidal dispersions by a membrane, pores often get clogged by the suspended particles. Knowing the shape and size of the particles that cause this clog would be a great help to membrane users since they could then choose the ideal filtering device. Microfluidic technology enables the fabrication of model membranes or filters that are transparent, which allows for measuring the particle geometrical features that deposit either at the surface of the pores or on top of the fouling layer that has already formed. However, the use of microfluidic filters have been confined to the study of clog formation at the pore scale, overlooking the influence of the dynamics of the particle deposition on the clogging process. We have recently shown that looking precisely at what is deposited and how this is captured inside the pore provides new insight into the clogging process. In particular, we have found that a minute concentration of aggregates in a supposedly monodisperse dispersions are mainly responsible for pore fouling. In this paper, we use the same imaging technique to determine the entire clogging process for different types of monodisperses dispersions under various flow conditions, DLVO interactions with the pore walls, and confinements. We show that the way clogs form is appear complex but is also quite systematic in the fact that aggregates are the building blocks of the clog. Pores are clogged by progressive accumulation of aggregates with the average size of the aggregate required to cause the blockage increasing with increasing flow velocity. This work demonstrates that particle size and shape distributions of the feeding dispersion must be determined to understand which physical mechanisms are at play during the clogging process.

Published

2021

21. Diffusion Decoupling in Binary Colloidal Systems Observed with Contrast Variation Multispeckle Diffusing Wave Spectroscopy

Author

Ruben Higler, Joris Sprakel, and Raoul A. M. Frijns

Subjects

Diffusing-wave spectroscopy, Materials science, Dispersity, Population, Binary number, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, law.invention, Colloid, law, Electrochemistry, Life Science, General Materials Science, Crystallization, education, Spectroscopy, VLAG, education.field_of_study, Surfaces and Interfaces, Decoupling (cosmology), 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Condensed Matter::Soft Condensed Matter, Chemical physics, 0210 nano-technology, Glass transition, Physical Chemistry and Soft Matter

Abstract

[Image: see text] In the study of colloidal glasses, crystallization is often suppressed by leveraging size polydispersity, ranging from systems where particle sizes exhibit a continuous distribution to systems composed of particles of two or more distinct sizes. The effects of the disparities in size of the particles on the colloidal glass transition are not yet completely understood. Especially, the question of the existence of a decoupled glass transition between the large and small population remains. In order to measure colloidal dynamics on very long time scales and to disentangle the dynamics of the two populations, we employ contrast variation multispeckle diffusing wave spectroscopy. With this method, we aim to analyze the effect of size ratio, a = r(PS)/r(pNIPAM), on particle dynamics near the glass transition of a binary colloidal system. We find that both for long-time (α−) and short-time (β−) relaxation, the dynamics of the small particles either completely decouple from the large ones (a = 0.2), moving freely through a glassy matrix, or are identical to the dynamics of the larger-sized population (a = 0.37 and 1.44). For a size ratio of 0.37, we find a single-glass transition for both particle populations. The postulated double-glass transition in simulations and theory is not observed.

Published

2019

22. Langevin Dynamics Simulations of the Exchange of Complex Coacervate Core Micelles: The Role of Nonelectrostatic Attraction and Polyelectrolyte Length

Author

Inge Bos and Joris Sprakel

Subjects

Coacervate, Polymers and Plastics, Chemistry, Organic Chemistry, Rational design, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Micelle, Attraction, Article, Polyelectrolyte, 0104 chemical sciences, Inorganic Chemistry, Chemical physics, Materials Chemistry, Molecule, Life Science, 0210 nano-technology, Langevin dynamics, Physical Chemistry and Soft Matter, Dynamic equilibrium, VLAG

Abstract

Complex coacervate core micelles (C3Ms) are promising encapsulators for a wide variety of (bio)molecules. To protect and stabilize their cargo, it is essential to control their exchange dynamics. Yet, to date, little is known about the kinetic stability of C3Ms and the dynamic equilibrium of molecular building blocks with micellar species. Here we study the C3M exchange during the initial micellization by using Langevin dynamics simulations. In this way, we show that charge neutral heterocomplexes consisting of multiple building blocks are the primary mediator for exchange. In addition, we show that the kinetic stability of the C3Ms can be tuned not only by the electrostatic interaction but also by the nonelectrostatic attraction between the polyelectrolytes, the polyelectrolyte length ratio, and the overall polyelectrolyte length. These insights offer new rational design guides to aid the development of new C3M encapsulation strategies.

Published

2019

23. Rigidochromic conjugated polymers carrying main-chain molecular rotors

Author

Joris Sprakel, Pieter van der Scheer, and Quintin van Zuijlen

Subjects

chemistry.chemical_classification, Materials science, Polymer science, 010405 organic chemistry, Metals and Alloys, Micromechanics, General Chemistry, Polymer, Molecular rotors, Conjugated system, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Chain (algebraic topology), chemistry, Materials Chemistry, Ceramics and Composites, Life Science, Polymer blend, Physical Chemistry and Soft Matter

Abstract

We design and prepare rigidochromic conjugated polymers that carry molecular rotors in the main chain. We show how a suitable design maintains the mechanosensitivity of the rotors upon incorporation into an extended π-conjugated system. Construction of donor-acceptor polymers enables their use as ratiometric probes for polymer micromechanics, which we evidence through micromechanical imaging of a phase-separated polymer blend.

Published

2019

24. Temperature-Triggered Colloidal Gelation through Well-Defined Grafted Polymeric Surfaces

Author

Jan Maarten van Doorn, Joris Sprakel, and Thomas E. Kodger

Subjects

colloid gel, grafting density, temperature-triggered gelation, surface initiated atom transfer radical polymerization, Science, Chemistry, QD1-999, Inorganic chemistry, QD146-197, General. Including alchemy, QD1-65

Abstract

Sufficiently strong interparticle attractions can lead to aggregation of a colloidal suspension and, at high enough volume fractions, form a mechanically rigid percolating network known as a colloidal gel. We synthesize a model thermo-responsive colloidal system for systematically studying the effect of surface properties, grafting density and chain length, on the particle dynamics within colloidal gels. After inducing an attraction between particles by heating, aggregates undergo thermal fluctuation which we observe and analyze microscopically; the magnitude of the variance in bond angle is larger for lower grafting densities. Macroscopically, a clear increase of the linear mechanical behavior of the gels on both the grafting density and chain length arises, as measured by rheology, which is inversely proportional to the magnitude of local bond angle fluctuations. This colloidal system will allow for further elucidation of the microscopic origins to the complex macroscopic mechanical behavior of colloidal gels including bending modes within the network.

Published

2017

25. Plant cell polarity as the nexus of tissue mechanics and morphogenesis

Author

Vera Gorelova, Joris Sprakel, and Dolf Weijers

Subjects

0106 biological sciences, 0303 health sciences, Biochemie, Cell Polarity, Plant Science, 01 natural sciences, Biochemistry, 03 medical and health sciences, Plant Cells, Morphogenesis, Life Science, EPS, Physical Chemistry and Soft Matter, 030304 developmental biology, 010606 plant biology & botany

Abstract

How reproducible body patterns emerge from the collective activity of individual cells is a key question in developmental biology. Plant cells are encaged in their walls and unable to migrate. Morphogenesis thus relies on directional cell division, by precise positioning of division planes, and anisotropic cellular growth, mediated by regulated mechanical inhomogeneity of the walls. Both processes require the prior establishment of cell polarity, marked by the formation of polar domains at the plasma membrane, in a number of developmental contexts. The establishment of cell polarity involves biochemical cues, but increasing evidence suggests that mechanical forces also play a prominent instructive role. While evidence for mutual regulation between cell polarity and tissue mechanics is emerging, the nature of this bidirectional feedback remains unclear. Here we review the role of cell polarity at the interface of tissue mechanics and morphogenesis. We also aim to integrate biochemistry-centred insights with concepts derived from physics and physical chemistry. Lastly, we propose a set of questions that will help address the fundamental nature of cell polarization and its mechanistic basis.

Published

2021

26. High-speed laser speckle imaging to unravel picoliter drop-on-demand to substrate interaction

Author

Remco Fokkink, Joris Sprakel, N. Tomozeiu, R. Antonelli, and Thomas E. Kodger

Subjects

Materials science, Opacity, Inkwell, business.industry, Drop (liquid), Evaporation, Laser Speckle Imaging, Substrate (printing), Optoelectronics, Life Science, Imbibition, Wetting, business, Instrumentation, Physical Chemistry and Soft Matter, VLAG

Abstract

Understanding phenomena such as evaporation and imbibition of picoliter droplets into porous substrates is crucial in printing industry to achieve a higher printing quality and print speed. After printing, the residual pigment must remain fixed at the desired location on a substrate and be of a desired volume to yield a high resolution and vibrantly printed page that has become the expectation of modern printing technology. Current research entails not only chemical composition of the ink but also how this links to the dynamics and interactions that occur between the ink and the substrate at every stage of the printed spot formation, including evaporation, wetting, and imbibition. In this paper, we present an instrument that can print on-demand picoliter volume droplets of ink onto substrates and then immediately record on evolution of the resulting dynamics when these two materials interact. This high-speed laser speckle imaging (HS-LSI) technique has been developed to monitor nanometer displacement of the drying and imbibing ink droplet at a high frame rate, up to 20000 Hz, given the short timescales of these interactions. We present the design of the instrument, discuss the related challenges and the theory underlying the LSI technique, specifically how photons non-evasively probe opaque objects in a multiple scattering regime, and show how this technique can unravel the dynamics of drying and imbibition. We will finish giving a validation on the instrument and an example of its usage.

Published

2021

27. TheArabidopsisembryo as a quantifiable model for studying pattern formation

Author

Yosapol Harnvanichvech, Vera Gorelova, Dolf Weijers, and Joris Sprakel

Subjects

Cell division, Plant embryogenesis, Biochemie, Pattern formation, Physical Therapy, Sports Therapy and Rehabilitation, Biology, Biochemistry, 03 medical and health sciences, 0302 clinical medicine, pattern formation, plant embryogenesis, Arabidopsis, 030304 developmental biology, 0303 health sciences, Rehabilitation, food and beverages, cell specification, Embryo, computational cell biology, General Medicine, Plant cell, biology.organism_classification, Phenotype, Cell biology, Plant morphology, gene expression, plant development, EPS, Physical Chemistry and Soft Matter, 030217 neurology & neurosurgery

Abstract

Phenotypic diversity of flowering plants stems from common basic features of the plant body pattern with well-defined body axes, organs and tissue organisation. Cell division and cell specification are the two processes that underlie the formation of a body pattern. As plant cells are encased into their cellulosic walls, directional cell division through precise positioning of division plane is crucial for shaping plant morphology. Since many plant cells are pluripotent, their fate establishment is influenced by their cellular environment through cell-to-cell signaling. Recent studies show that apart from biochemical regulation, these two processes are also influenced by cell and tissue morphology and operate under mechanical control. Finding a proper model system that allows dissecting the relationship between these aspects is the key to our understanding of pattern establishment. In this review, we present theArabidopsisembryo as a simple, yet comprehensive model of pattern formation compatible with high-throughput quantitative assays.

Published

2021

28. FRET-based determination of the exchange dynamics of complex coacervate core micelles

Author

Inge Bos, Marga Timmerman, and Joris Sprakel

Subjects

Coacervate, Polymers and Plastics, Chemistry, Organic Chemistry, Ionic bonding, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Micelle, Article, 0104 chemical sciences, Inorganic Chemistry, Förster resonance energy transfer, Chemical physics, Materials Chemistry, Life Science, Molecule, 0210 nano-technology, Nanoscopic scale, Physical Chemistry and Soft Matter, Dynamic equilibrium, Macromolecule, VLAG

Abstract

Complex coacervate core micelles (C3Ms) are nanoscopic structures formed by charge interactions between oppositely charged macroions and used to encapsulate a wide variety of charged (bio)molecules. In most cases, C3Ms are in a dynamic equilibrium with their surroundings. Understanding the dynamics of molecular exchange reactions is essential as this determines the rate at which their cargo is exposed to the environment. Here, we study the molecular exchange in C3Ms by making use of Förster resonance energy transfer (FRET) and derive an analytical model to relate the experimentally observed increase in FRET efficiency to the underlying macromolecular exchange rates. We show that equilibrated C3Ms have a broad distribution of exchange rates. The overall exchange rate can be strongly increased by increasing the salt concentration. In contrast, changing the unlabeled homopolymer length does not affect the exchange of the labeled homopolymers and an increase in the micelle concentration only affects the FRET increase rate at low micelle concentrations. Together, these results suggest that the exchange of these equilibrated C3Ms occurs mainly by expulsion and insertion, where the rate-limiting step is the breaking of ionic bonds to expel the chains from the core. These are important insights to further improve the encapsulation efficiency of C3Ms.

Published

2020

29. Quantifying solvent action in oil paint using portable laser speckle imaging

Author

Joen J. Hermans, Lambert Baij, Joris Sprakel, Piet D. Iedema, Katrien Keune, Laura Raven, Jesse Buijs, and CC overig (HIMS, FNWI)

Subjects

Materials science, Varnish, lcsh:Medicine, Mechanical properties, 02 engineering and technology, Imaging techniques, 01 natural sciences, Article, Imaging studies, chemistry.chemical_compound, Thermal, Life Science, lcsh:Science, VLAG, Multidisciplinary, 010405 organic chemistry, lcsh:R, Laser Speckle Imaging, Motion detection, Penetration (firestop), 021001 nanoscience & nanotechnology, 0104 chemical sciences, Solvent, Oil paint, Chemical engineering, chemistry, visual_art, visual_art.visual_art_medium, lcsh:Q, Solvent exposure, 0210 nano-technology, Physical Chemistry and Soft Matter

Abstract

The exposure of oil paintings to organic solvents for varnish removal or to water for the removal of surface dirt can affect the chemical and physical properties of oil paint in an undesired way. Solvents can temporarily plasticise and swell the polymerised oil paint binding medium, enhancing both the thermal mobility and mechanical displacement of pigments embedded in this film. The enhancement of these microscopic motions can affect both the chemical and physical stability of the object as a whole. In order to minimise solvent exposure during cleaning, an analytical method that can quantitatively measure the microscopic motions induced by solvent uptake, is required first. In this study, we use Fourier Transform Laser Speckle Imaging (FT-LSI) and a newly developed portable FT-LSI setup as highly resolved motion detection instruments. We employ FT-LSI to probe pigment motion, with high spatiotemporal resolution, as a proxy for the destabilising effects of cleaning solvents. In this way, we can study solvent diffusion and evaporation rates and the total solvent retention time. In addition, qualitative spatial information on the spreading and homogeneity of the applied solvent is obtained. We study mobility in paint films caused by air humidity, spreading of solvents as a result of several cleaning methods and the protective capabilities of varnish. Our results show that FT-LSI is a powerful technique for the study of solvent penetration during oil paint cleaning and has a high potential for future use in the conservation studio.

Published

2020

30. Cephalopod-Inspired High Dynamic Range Mechano-Imaging in Polymeric Materials

Author

Joris Sprakel, Jasper van der Gucht, JM Jessica Clough, and Thomas E. Kodger

Subjects

Materials science, photonics, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biomaterials, Responsivity, colloids, biology.animal, Electrochemistry, Nanoscopic scale, High dynamic range, polymers, VLAG, chemistry.chemical_classification, Squid, biology, business.industry, Dynamic range, Polymer, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, chemistry, Photonics, Deformation (engineering), mechanochemistry, 0210 nano-technology, business, Physical Chemistry and Soft Matter, mechanochromism

Abstract

Cephalopods, such as squid, cuttlefish, and octopuses, use an array of responsive absorptive and photonic dermal structures to achieve rapid and reversible color changes for spectacular camouflage and signaling displays. Challenges remain in designing synthetic soft materials with similar multiple and dynamic responsivity for the development of optical sensors for the sensitive detection of mechanical stresses and strains. Here, a high dynamic range mechano-imaging (HDR-MI) polymeric material integrating physical and chemical mechanochromism is designed providing a continuous optical read-out of strain upon mechanical deformation. By combining a colloidal photonic array with a mechanically responsive dye, the material architecture significantly improves the mechanochromic sensitivity, which is moreover readily tuned, and expands the range of detectable strains and stresses at both microscopic and nanoscopic length scales. This multi-functional material is highlighted by creating detailed HDR mechanographs of membrane deformation and around defects using a low-cost hyperspectral camera, which is found to be in excellent agreement with the results of finite element simulations. This multi-scale approach to mechano-sensing and -imaging provides a platform to develop mechanochromic composites with high sensitivity and high dynamic mechanical range.

Published

2020

31. Pickering particles as interfacial reservoirs of antioxidants

Author

Karin Schroën, Joris Sprakel, Mickaël Laguerre, Claire C. Berton-Carabin, and Anja Schröder

Subjects

Antioxidant, medicine.medical_treatment, Bioactive molecules, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Fat crystal, Biomaterials, Colloid, Colloid and Surface Chemistry, Lipophilic antioxidant, Functional importance, Lipid oxidation, medicine, Food Process Engineering, VLAG, α-tocopherol, Chemistry, Interface, 021001 nanoscience & nanotechnology, Natural bioactive, Pickering emulsion, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Biobased particle, Chemical engineering, Oil droplet, Emulsion, Encapsulation, 0210 nano-technology, Physical Chemistry and Soft Matter

Abstract

Hypothesis Emulsions are common structures encapsulating lipophilic bioactive molecules, both in biological systems and in manufactured products. Protecting these functional molecules from oxidation is essential; Nature excels at doing so by placing antioxidants at the oil-water interface, where oxidative reactions primarily occur. We imagined a novel approach to boost the activity of antioxidants in designer emulsions by employing Pickering particles that act both as physical emulsion stabilizers and as interfacial reservoirs of antioxidants. Experiments α-Tocopherol or carnosic acid, two model lipophilic antioxidants, were entrapped in colloidal lipid particles (CLPs) that were next used to physically stabilize sunflower oil-in-water emulsions (“concept” Pickering emulsions). We first assessed the physical properties and stability of the CLPs and of the Pickering emulsions. We then monitored the oxidative stability of the concept emulsions upon incubation, and compared it to that of control emulsions of similar structure, yet with the antioxidant present in the oil droplet interior. Findings Both tested antioxidants are largely more effective when loaded within Pickering particles than when solubilized in the oil droplet interior, thus confirming the importance of the interfacial localization of antioxidants. This approach revisits the paradigm for lipid oxidation prevention in emulsions and offers potential for many applications.

Published

2020

32. Complete microviscosity maps of living plant cells and tissues with a toolbox of targeting mechanoprobes

Author

Vera Gorelova, Lucile Michels, Dolf Weijers, Yosapol Harnvanichvech, Joris Sprakel, Bauke Albada, and Jan Willem Borst

Subjects

0106 biological sciences, FLIM, Plant Biology, Biochemie, Vacuole, Models, Biological, Biochemistry, 01 natural sciences, Microviscosity, Cell wall, molecular rotors, 03 medical and health sciences, Mechanobiology, Plant Cells, Organelle, microviscosity, Plant Physiological Phenomena, Cellular compartment, Fluorescent Dyes, VLAG, 030304 developmental biology, Organelles, 0303 health sciences, Multidisciplinary, Viscosity, Chemistry, Molecular Motor Proteins, Organic Chemistry, Biological Sciences, Plant cell, Organische Chemie, Cytosol, Organ Specificity, Molecular Probes, Biophysics, EPS, plant mechanobiology, Physical Chemistry and Soft Matter, 010606 plant biology & botany

Abstract

Significance Spatial variations in microviscosity are triggered throughout plant cells, and these provide insight into local mechanobiological processes. However, it has so far been challenging to visualize such variations in living plant cells. Here we report an imaging microviscosity toolbox of chemically modified molecular rotors that yield complete microviscosity maps of several key plant cell structures. This toolbox opens up new ways to understand the role of mechanical stress in the regulation of biological processes., Mechanical patterns control a variety of biological processes in plants. The microviscosity of cellular structures effects the diffusion rate of molecules and organelles, thereby affecting processes such as metabolism and signaling. Spatial variations in local viscosity are also generated during fundamental events in the cell life cycle. While crucial to a complete understanding of plant mechanobiology, resolving subcellular microviscosity patterns in plants has remained an unsolved challenge. We present an imaging microviscosimetry toolbox of molecular rotors that yield complete microviscosity maps of cells and tissues, specifically targeting the cytosol, vacuole, plasma membrane, and wall of plant cells. These boron-dipyrromethene (BODIPY)-based molecular rotors are rigidochromic by means of coupling the rate of an intramolecular rotation, which depends on the mechanics of their direct surroundings, with their fluorescence lifetime. This enables the optical mapping of fluidity and porosity patterns in targeted cellular compartments. We show how apparent viscosity relates to cell function in the root, how the growth of cellular protrusions induces local tension, and how the cell wall is adapted to perform actuation surrounding leaf pores. These results pave the way to the noninvasive micromechanical mapping of complex tissues.

Published

2020

33. Recombinant Protein Polymers for Colloidal Stabilization and Improvement of Cellular Uptake of Diamond Nanosensors

Author

Wolf H. Rombouts, Romana Schirhagl, Renko de Vries, Joris Sprakel, Ingeborg M. Storm, Tingting Zheng, Felipe Perona Martinez, Nanotechnology and Biophysics in Medicine (NANOBIOMED), and ​Basic and Translational Research and Imaging Methodology Development in Groningen (BRIDGE)

Subjects

Light, Biocompatibility, Nanotechnology, 02 engineering and technology, engineering.material, 010402 general chemistry, 01 natural sciences, Fluorescence, Nanodiamonds, Analytical Chemistry, law.invention, Colloid, Adsorption, law, Nanosensor, Cell Line, Tumor, MAGNETIC-RESONANCE, Humans, Life Science, Colloids, OPTICAL MICROSCOPY, DRUG, VLAG, chemistry.chemical_classification, Chemistry, FLUORESCENT NANODIAMONDS, Diamond, Biological Transport, Polymer, 021001 nanoscience & nanotechnology, Recombinant Proteins, NITROGEN-VACANCY CENTERS, 0104 chemical sciences, POLYGLYCEROL, SPIN, CELLS, engineering, Recombinant DNA, INTERNALIZATION, 0210 nano-technology, Physical Chemistry and Soft Matter

Abstract

Fluorescent nanodiamonds are gaining increasing attention as fluorescent labels in biology in view of the fact that they are essentially nontoxic, do not bleach, and can be used as nanoscale sensors for various physical and chemical properties. To fully realize the nanosensing potential of nanodiamonds in biological applications, two problems need to be addressed: their limited colloidal stability, especially in the presence of salts, and their limited ability to be taken up by cells. We show that the physical adsorption of a suitably designed recombinant polypeptide can address both the colloidal stability problem and the problem of the limited uptake of nanodiamonds by cells in a very straightforward way, while preserving both their spectroscopic properties and their excellent bio compatibility.

Published

2017

34. Fourier transforms for fast and quantitative Laser Speckle Imaging

Author

Joris Sprakel, Jesse Buijs, and J. van der Gucht

Subjects

Diffusion (acoustics), Computer science, Fast Fourier transform, Measure (physics), ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, lcsh:Medicine, 02 engineering and technology, Imaging techniques, 01 natural sciences, Law Group, Article, 010309 optics, Speckle pattern, symbols.namesake, Fluid dynamics, 0103 physical sciences, Life Science, Computer vision, Optical techniques, lcsh:Science, VLAG, Multidisciplinary, business.industry, Soft materials, lcsh:R, Laser Speckle Imaging, 021001 nanoscience & nanotechnology, Fourier transform, Recht, Orders of magnitude (time), symbols, lcsh:Q, Artificial intelligence, 0210 nano-technology, business, Physical Chemistry and Soft Matter

Abstract

Laser speckle imaging is a powerful imaging technique that visualizes microscopic motion within turbid materials. At current two methods are widely used to analyze speckle data: one is fast but qualitative, the other quantitative but computationally expensive. We have developed a new processing algorithm based on the fast Fourier transform, which converts raw speckle patterns into maps of microscopic motion and is both fast and quantitative, providing a dynamnic spectrum of the material over a frequency range spanning several decades. In this article we show how to apply this algorithm and how to measure a diffusion coefficient with it. We show that this method is quantitative and several orders of magnitude faster than the existing quantitative method. Finally we harness the potential of this new approach by constructing a portable laser speckle imaging setup that performs quantitative data processing in real-time on a tablet.

Published

2019

35. Morphing of liquid crystal surfaces by emergent collectivity

Author

Jesse Buijs, Dirk J. Broer, Slav A. Semerdzhiev, Hanne M. van der Kooij, Danqing Liu, Joris Sprakel, Institute for Complex Molecular Systems, Stimuli-responsive Funct. Materials & Dev., and Nanobiophysics

Subjects

0301 basic medicine, Materials science, Science, Soft robotics, General Physics and Astronomy, 02 engineering and technology, Smart material, General Biochemistry, Genetics and Molecular Biology, Viscoelasticity, Article, 03 medical and health sciences, Liquid crystal, Life Science, lcsh:Science, Nanoscopic scale, Multidisciplinary, Liquid crystals, Imaging and sensing, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter::Soft Condensed Matter, Morphing, 030104 developmental biology, Deformation mechanism, Chemical physics, lcsh:Q, Deformation (engineering), 0210 nano-technology, Physical Chemistry and Soft Matter, Actuators

Abstract

Liquid crystal surfaces can undergo topographical morphing in response to external cues. These shape-shifting coatings promise a revolution in various applications, from haptic feedback in soft robotics or displays to self-cleaning solar panels. The changes in surface topography can be controlled by tailoring the molecular architecture and mechanics of the liquid crystal network. However, the nanoscopic mechanisms that drive morphological transitions remain unclear. Here, we introduce a frequency-resolved nanostrain imaging method to elucidate the emergent dynamics underlying field-induced shape-shifting. We show how surface morphing occurs in three distinct stages: (i) the molecular dipoles oscillate with the alternating field (10–100 ms), (ii) this leads to collective plasticization of the glassy network (~1 s), (iii) culminating in actuation of the topography (10–100 s). The first stage appears universal and governed by dielectric coupling. By contrast, yielding and deformation rely on a delicate balance between liquid crystal order, field properties and network viscoelasticity., Liquid crystal networks can morph their shape in response to electrical stimulus. Here the authors provide a detailed description of their deformation mechanism and introduce a method to observe the dynamic surface of liquid crystal elastomers. This could help with the development of smart materials.

Published

2019

36. Two-dimensional crystals of star polymers: a tale of tails

Author

Wouter G. Ellenbroek, Inge Bos, Joris Sprakel, Pieter van der Scheer, Soft Matter and Biological Physics, Institute for Complex Molecular Systems, and Responsive Soft Matter

Subjects

Physics, Isotropy, Oblique case, Near and far field, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Exponential function, Chemical physics, Lattice (order), Homogeneous space, Life Science, 0210 nano-technology, Anisotropy, Pair potential, Physical Chemistry and Soft Matter

Abstract

The formation of non-hexagonal crystalline structures by the organisation of colloidal nanoparticles often involves the use of complex particles with anisotropic shape or interactions or the imposition of non-uniform external fields. Here we explore how unusual symmetries can be created using experimentally realistic particles that interact through isotropic and purely repulsive potentials. In particular, we use simulations to explore the phase behavior of two-dimensional systems of star polymers. We uncover how the tail of the pair potential has a large role in dictating the phase behavior. Star polymers interacting in the far field with a Gaussian potential only form hexagonal phases, while an exponential tail gives rise to stable primitive oblique and honeycomb lattices. We identify the ratio in strength between long and short range interactions and the nature of the transition between these regimes as crucial parameters to predict when non-hexagonal crystals of star polymers can be stable. This leads to experimental design rules for creating star polymers which should exhibit unusual lattice formation.

Published

2019

37. Photonic Paints: Structural Pigments Combined with Water-Based Polymeric Film-Formers for Structurally Colored Coatings

Author

Joris Sprakel, Elise Guimard, Thomas E. Kodger, Cindy Rivet, and JM Jessica Clough

Subjects

Fabrication, Materials science, colloidal assembly, 02 engineering and technology, Substrate (printing), engineering.material, 010402 general chemistry, 01 natural sciences, Coating, photonic pigments, paints, Polymer science, business.industry, structural colors, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Iridescence, Colored, Emulsion, engineering, Photonics, 0210 nano-technology, business, Physical Chemistry and Soft Matter, Structural coloration

Abstract

Paints contain at least two components: a colorant and a polymeric binder, dispersed in a fluid medium. The first imparts color to the paint coating, while the second encapsulates the colorant upon drying in a robust polymeric film adherent to the surface substrate. Photonic pigments, inspired by nature's coloration strategy, hold promise as a replacement for toxic and fade-prone absorptive colorants, most prominently in the fabrication of stable and sustainable water-based paints. Crucially however, the step to combine photonic pigments with polymeric binders has not yet been taken. Here, a water-based paint is designed and realized containing both photonic pigments synthesized by a scalable emulsion process and commercial polymeric binders in an aqueous dispersion. The photonic pigments are silica spheres containing a close-packed array of air pores, of which both the periodicity and degree of long-range ordering can be controlled to produce pigments of varying colors and degrees of iridescence. The readiness of the photonic paints for application is demonstrated by applying them like traditional paints in homages of famous artistic paintings. These findings should stimulate widespread application of structural pigments as colorants in not only paints but also a variety of industrially important materials, such as plastics, inks, or cosmetics.

Published

2019

38. Can we prevent lipid oxidation in emulsions by using fat-based Pickering particles?

Author

Wieke Boerkamp, Joris Sprakel, Anja Schröder, Karin Schroën, and Claire C. Berton-Carabin

Subjects

030309 nutrition & dietetics, 03 medical and health sciences, Colloid, chemistry.chemical_compound, 0404 agricultural biotechnology, Adsorption, Lipid oxidation, Food-grade emulsions, Particle Size, Physical structure, Food Process Engineering, Triglycerides, Colloidal lipid particles, VLAG, 0303 health sciences, 04 agricultural and veterinary sciences, Lipid Droplets, Interface, Lipid Metabolism, 040401 food science, Lipids, Pickering emulsion, Palm stearin, Chemical engineering, chemistry, Food, Oil droplet, Tripalmitin, Melting point, Emulsions, Crystallization, Oxidation-Reduction, Physical Chemistry and Soft Matter, Food Science, Pickering particles

Abstract

Interest has recently been rising in the development of food-compatible Pickering emulsions, i.e., particle-stabilized emulsions, and various biobased particles have been demonstrated as useful for such a purpose. Most of the related work has focused on the physical stability of the emulsions, but whether such particles can be advantageous in terms of chemical stability, and in particular, with regard to lipid oxidation, is largely unexplored. Recently, we found that colloidal lipid particles (CLPs) are efficient Pickering stabilizers, and the objective of the present study was to investigate the oxidative stability of emulsions stabilized with those particles. Three types of sunflower oil-in-water (O/W) emulsions were considered: Pickering emulsions stabilized with colloidal lipid particles (CLPs) made of high melting point (HMP) fat (tripalmitin or palm stearin), adsorbed onto the liquid oil droplets; and, as references, two conventional sodium caseinate-stabilized emulsions, of which one contained only liquid oil, and the other liquid oil mixed with HMP fat as the core of the emulsion droplets. In the presence of iron, the latter oxidized faster than conventional liquid oil and Pickering emulsions, resulting in 2- to 3-fold higher amounts of primary and secondary lipid oxidation products. This may be due to intra-droplet HMP fat pushing oxidizable lipids towards the oil-water interface, which would promote lipid oxidation. This shows that the localization of solid fat in O/W emulsions affects lipid oxidation. We also found that CLP-stabilized Pickering emulsions had similar oxidation rates as conventional sodium caseinate-stabilized emulsions containing only liquid oil. This suggests that the potential of such Pickering particles to prevent lipid oxidation is limited. This could be because diffusion of small pro-oxidant molecules is not hindered by Pickering particles, as they cannot form an interfacial barrier that is structurally homogeneous at such a small scale.

Published

2019

39. Gel Trapping Enables Optical Spectroscopy of Single Solvated Conjugated Polymers in Equilibrium

Author

Ellard Hooiveld, Ruben Higler, Joris Sprakel, Pieter van der Scheer, and Ties van de Laar

Subjects

chemistry.chemical_classification, Materials science, single-molecule spectroscopy, Thermodynamic state, Intermolecular force, General Engineering, General Physics and Astronomy, Polymer, Conjugated system, Fluorescence, single-molecule fluorescent lifetime imaging, Article, chemistry, Chemical physics, gel entrapment, conjugated polymers, General Materials Science, Luminescence, Spectroscopy, Physical Chemistry and Soft Matter, photodynamics, Macromolecule

Abstract

Single-molecule studies have provided a wealth of insight into the photophysics of conjugated polymers in the solid and desolvated state. Desolvating conjugated chains, e.g., by their embedding in inert solid matrices, invariably leads to chain collapse and the formation of intermolecular aggregates, which have a pronounced effect on their properties. By contrast, the luminescent properties of individual semiconducting polymers in their solvated and thermodynamic state remain largely unexplored. In this paper, we demonstrate a versatile gel trapping technique that enables the chemistry-free immobilization and interrogation of individual conjugated macromolecules, which retain a fully equilibrated conformation by contrast to conventional solid-state immobilization methods. We show how the technique can be used to record full luminescence spectra of single chains, to evaluate their time-resolved fluorescence, and to probe their photodynamics. Finally, we explore how the photophysics of different conjugated polymers is strongly affected by desolvation and chain collapse.

Published

2019

40. Plasticity in colloidal gel strands

Author

Joris Sprakel, Frans A. M. Leermakers, Jasper van der Gucht, and Joanne E. Verweij

Subjects

Materials science, Failure mechanism, 02 engineering and technology, General Chemistry, Plasticity, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Colloid, Brittleness, Colloidal particle, Brownian dynamics, Life Science, Composite material, 0210 nano-technology, Softening, Physical Chemistry and Soft Matter, Necking, VLAG

Abstract

Colloidal gels are space-spanning networks of aggregated particles. The mechanical response of colloidal gels is governed, to a large extent, by the properties of the individual gel strands. To study how colloidal gels respond to repeated deformations, we perform Brownian dynamics simulations on single strands of aggregated colloidal particles. While current models assume that gel failure is due to the brittle rupture of gel strands, our simulations show that gel strands undergo large plastic deformations prior to breaking. Rearrangement of particles within the strands leads to plastic lengthening and softening of the strands, which may ultimately lead to strand necking and ductile failure. This failure mechanism occurs irrespective of the thickness and length of the strands and the range and strength of the interaction potential. Rupture of gel strands is more likely for long and thin strands and for a long-ranged interaction potential.

Published

2019

41. Probing Nanoscale Coassembly with Dual Mechanochromic Sensors

Author

Joris Sprakel, Emre B. Boz, Junyou Wang, Martien A. Cohen Stuart, and Hande E. Cingil

Subjects

Nanostructure, Materials science, Structure formation, micelles, Supramolecular chemistry, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Micelle, Biomaterials, complex coacervation, conjugated polymers, Electrochemistry, Nanoscopic scale, VLAG, chemistry.chemical_classification, self-assembly, Polymer, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, chemistry, Self-assembly, 0210 nano-technology, Physical Chemistry and Soft Matter, Macromolecule

Abstract

Attractive electrostatic forces between polymers can be exploited to create well-defined and responsive nanoscale structures. In the process of charge-driven coassembly, the polymers involved undergo subtle conformational changes. However, ascertaining these conformational transitions, and relating this to the nanostructures that are formed, has remained elusive to date. Here it is shown how the force-optical response of tailored mechanochromic polymers can be used to detect structural transitions that occur at the nanoscale during assembly. It is shown that at low-charge stoichiometry, electrostatic binding causes individual macromolecules to stretch and stiffen. Remarkably, at stoichiometries close to full charge compensation a gradual transition from single molecular complexes to multimolecular micelles is observed. Moreover, the same macromolecular sensors reveal how the assembly pathways are fully reversible as the binding strength is weakened. These results highlight how mechanochromic polymer sensors can be used to detect the molecular transitions occur during supramolecular structure formation with high precision.

Published

2016

42. Mechanics at the glass-to-gel transition of thermoresponsive microgel suspensions

Author

Joris Sprakel, Bart Fölker, and Jeroen Appel

Subjects

Bond strength, Chemistry, Linear elasticity, Nanotechnology, 02 engineering and technology, General Chemistry, Dissipation, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Condensed Matter::Soft Condensed Matter, Colloid, Rigidity (electromagnetism), Rheology, Chemical physics, Volume fraction, Life Science, Adhesive, 0210 nano-technology, Physical Chemistry and Soft Matter, VLAG

Abstract

We study the rheology of systems of thermoresponsive microgels which can transition between a repulsive glass and an attractive gel state. We find marked differences between these two colloidal solids, within the same experimental system, due to the different origins for their dynamic arrest. While the rigidity of the repulsive systems depends solely on particle volume fraction, we find that the change in linear elasticity upon introducing attractive bonds in the system scales linearly with the adhesive bond strength which can be tuned with the temperature in our experiments. And while the glasses yield reversibly and with a rate-dependent energy dissipation, bond-reorganisation in the gels is suppressed so that their rupture is irreversible and accompanied by a high, but rate-independent, dissipation. These results highlight how colloids with responsive interactions can be employed to shed new light onto solid-solid transitions.

Published

2016

43. Anomalous dynamics of interstitial dopants in soft crystals

Author

Joris Sprakel, Justin Tauber, and Ruben Higler

Subjects

Materials science, Crystalline materials, Thermal fluctuations, FOS: Physical sciences, 02 engineering and technology, Condensed Matter - Soft Condensed Matter, 01 natural sciences, Crystals, Condensed Matter::Materials Science, Impurity, Lattice (order), Condensed Matter::Superconductivity, 0103 physical sciences, Thermal, Physics::Atomic and Molecular Clusters, Doping, 010306 general physics, VLAG, Multidisciplinary, Dopant, Condensed matter physics, 021001 nanoscience & nanotechnology, Excited state, Physical Sciences, Soft Condensed Matter (cond-mat.soft), Anomalous dynamics, 0210 nano-technology, Physical Chemistry and Soft Matter

Abstract

The dynamics of interstitial dopants governs the properties of a wide variety of doped crystalline materials. To describe the hopping dynamics of such interstitial impurities, classical approaches often assume that dopant particles do not interact and travel through a static potential energy landscape. Here we show, using computer simulations, how these assumptions and the resulting predictions from classical Eyring-type theories break down in entropically-stabilised BCC crystals due to the thermal excitations of the crystalline matrix. Deviations are particularly severe close to melting where the lattice becomes weak and dopant dynamics exhibit strongly localised and heterogeneous dynamics. We attribute these anomalies to the failure of both assumptions underlying the classical description: i) the instantaneous potential field experienced by dopants becomes largely disordered due to thermal fluctuations and ii) elastic interactions cause strong dopant-dopant interactions even at low doping fractions. These results illustrate how describing non-classical dopant dynamics requires taking the effective disordered potential energy landscape of strongly excited crystals and dopant-dopant interactions into account., Comment: 16 pages, 14 figures. Includes Supplementary Information

Published

2016

44. Chemical Stability of α‐Tocopherol in Colloidal Lipid Particles with Various Morphologies

Author

Joris Sprakel, Claire C. Berton-Carabin, Anja Schröder, and Karin Schroën

Subjects

Antioxidant, 030309 nutrition & dietetics, medicine.medical_treatment, lipid crystallization, vitamin E, Industrial and Manufacturing Engineering, law.invention, 03 medical and health sciences, chemistry.chemical_compound, Colloid, 0404 agricultural biotechnology, law, Solid lipid nanoparticle, medicine, Tocopherol, Crystallization, Food Process Engineering, lipophilic bioactives, VLAG, 0303 health sciences, Chemistry, 04 agricultural and veterinary sciences, General Chemistry, 040401 food science, solid lipid nanoparticles, Polysorbates, Chemical engineering, Tripalmitin, encapsulation, Chemical stability, Physical Chemistry and Soft Matter, Food Science, Biotechnology

Abstract

Colloidal lipid particles (CLPs) are promising encapsulation systems for lipophilic bioactives, such as oil-soluble antioxidants that are applied in food and pharmaceutical formulations. Currently, there is no clear consensus regarding the relation between particle structure and the chemical stability of such bioactives. Using α-tocopherol as a model antioxidant, it is shown that emulsifier type (Tween 20 or 40, or sodium caseinate) and lipid composition (tripalmitin, tricaprylin, or combinations thereof) modulated particle morphology and antioxidant stability. The emulsifier affects particle shape, with the polysorbates facilitating tripalmitin crystallization into highly ordered lath-like particles, and sodium caseinate resulting in less ordered spherical particles. The fastest degradation of α-tocopherol is observed in tripalmitin-based CLPs, which may be attributed to its expulsion to the particle surface induced by lipid crystallization. This effect is stronger in CLPs stabilized by Tween 40, which may act as a template for crystallization. This work not only shows how the architecture of CLPs can be controlled through the type of lipid and emulsifier used, but also gives evidence that lipid crystallization does not necessarily protect entrapped lipophilic bioactives, which is an important clue for encapsulation system design. Practical Applications: Interest in enriching food and pharmaceutical products with lipophilic bioactives such as antioxidants through encapsulation in lipid particles is growing rapidly. This research suggests that for efficient encapsulation, the particle architecture plays an important role; to tailor this, the contribution of both the lipid carrier and the emulsifier needs to be considered.

Published

2020

45. Strand Plasticity Governs Fatigue in Colloidal Gels

Author

Jan Maarten van Doorn, Joris Sprakel, Jasper van der Gucht, and Joanne E. Verweij

Subjects

Materials science, Local plasticity, FOS: Physical sciences, General Physics and Astronomy, 02 engineering and technology, Condensed Matter - Soft Condensed Matter, Strain hardening exponent, Plasticity, 021001 nanoscience & nanotechnology, 01 natural sciences, Colloid, 0103 physical sciences, Soft solids, Life Science, Soft Condensed Matter (cond-mat.soft), Material failure theory, Geotechnical engineering, Composite material, 010306 general physics, 0210 nano-technology, Physical Chemistry and Soft Matter, VLAG

Abstract

Repeated loading of a solid leads to microstructural damage that ultimately results in catastrophic material failure. While posing a major threat to the stability of virtually all materials, the microscopic origins of fatigue, especially for soft solids, remain elusive. Here we explore fatigue in colloidal gels as prototypical inhomogeneous soft solids by combining experiments and computer simulations. Our results reveal how mechanical loading leads to irreversible strand stretching, which builds slack into the network that softens the solid at small strains and causes strain hardening at larger deformations. We thus find that microscopic plasticity governs fatigue at much larger scales. This gives rise to a new picture of fatigue in soft thermal solids and calls for new theoretical descriptions of soft gel mechanics in which local plasticity is taken into account., 5 pages, 4 figures

Published

2018

46. Laser Speckle Strain Imaging reveals the origin of delayed fracture in a soft solid

Author

Gea T. van de Kerkhof, Jasper van der Gucht, Hanne M. van der Kooij, Raoul A. M. Frijns, Simone Dussi, and Joris Sprakel

Subjects

Materials science, genetic structures, Materials Science, Nucleation, 02 engineering and technology, 01 natural sciences, Stress (mechanics), Speckle pattern, Experimental proof, Long period, 0103 physical sciences, Life Science, 010306 general physics, Research Articles, VLAG, Multidisciplinary, Physics, Strain imaging, SciAdv r-articles, Mechanics, 021001 nanoscience & nanotechnology, eye diseases, Fracture (geology), Delayed fracture, sense organs, 0210 nano-technology, Physical Chemistry and Soft Matter, Research Article

Abstract

An optical method to detect nanoscale damage makes unpredictable fracture predictable., Stresses well below the critical fracture stress can lead to highly unpredictable delayed fracture after a long period of seemingly quiescent stability. Delayed fracture is a major threat to the lifetime of materials, and its unpredictability makes it difficult to prevent. This is exacerbated by the lack of consensus on the microscopic mechanisms at its origin because unambiguous experimental proof of these mechanisms remains absent. We present an experimental approach to measure, with high spatial and temporal resolution, the local deformations that precipitate crack nucleation. We apply this method to study delayed fracture in an elastomer and find that a delocalized zone of very small strains emerges as a consequence of strongly localized damage processes. This prefracture deformation zone grows exponentially in space and time, ultimately culminating in the nucleation of a crack and failure of the material as a whole. Our results paint a microscopic picture of the elusive origins of delayed fracture and open the way to detect damage well before it manifests macroscopically.

Published

2018

47. Linking slow dynamics and microscopic connectivity in dense suspensions of charged colloids

Author

Johannes Krausser, Jasper van der Gucht, Alessio Zaccone, Ruben Higler, Joris Sprakel, van der Gucht, Jasper [0000-0001-5525-8322], Zaccone, Alessio [0000-0002-6673-7043], and Apollo - University of Cambridge Repository

Subjects

0306 Physical Chemistry (incl. Structural), Materials science, 02 engineering and technology, General Chemistry, Static structure, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Local structure, Upper and lower bounds, Microscopic scale, Condensed Matter::Soft Condensed Matter, Colloid, Rigidity (electromagnetism), Chemical physics, 0103 physical sciences, Life Science, Vitrification, 010306 general physics, 0210 nano-technology, Glass transition, Physical Chemistry and Soft Matter, VLAG

Abstract

The quest to unravel the nature of the glass transition, where the viscosity of a liquid increases by many orders of magnitude, while its static structure remains largely unaffected, remains unresolved. While various structural and dynamical precursors to vitrification have been identified, a predictive and quantitative description of how subtle changes at the microscopic scale give rise to the steep growth in macroscopic viscosity is missing. It was recently proposed that the presence of long-lived bonded structures within the liquid may provide the long-sought connection between local structure and global dynamics. Here we directly observe and quantify the connectivity dynamics in liquids of charged colloids en route to vitrification using three-dimensional confocal microscopy. We determine the dynamic structure from the real-space van Hove correlation function and from the particle trajectories, providing upper and lower bounds on connectivity dynamics. Based on these data, we extend Dyre's model for the glass transition to account for particle-level structural dynamics; this results in a microscopic expression for the slowing down of relaxations in the liquid that is in quantitative agreement with our experiments. These results indicate how vitrification may be understood as a dynamical connectivity transition with features that are strongly reminiscent of rigidity percolation scenarios.

Published

2018

48. Dissipative disassembly of colloidal microgel crystals driven by a coupled cyclic reaction network

Author

Joris Sprakel, Alexander J. C. Kuehne, Dirk Rommel, Dennis Go, Yi Liao, and Tamás Haraszti

Subjects

Materials science, Structure formation, 02 engineering and technology, General Chemistry, Colloidal crystal, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Colloid, chemistry.chemical_compound, External energy, chemistry, Chemical physics, On demand, Photoacid, Dissipative system, Life Science, 0210 nano-technology, Realization (systems), Physical Chemistry and Soft Matter

Abstract

A plethora of natural systems rely on the consumption of chemical fuel or input of external energy to control the assembly and disassembly of functional structures on demand. While dissipative assembly has been demonstrated, the control of structural breakdown using a dissipative cycle remains almost unexplored. Here, we propose and realize a dissipative disassembly process using two coupled cyclic reactions, in which protons mediate the interaction between the cycles. We show how an ordered colloidal crystal, can cyclically transform into a disordered state by addition of energy to a chemical cycle, reversibly activating a photoacid. This cycle is coupled to the colloidal assembly cycle via the exchange of protons, which in turn trigger charging of the particles. This system is an experimental realization of a cyclic reaction-assembly network and its principle can be extended to other types of structure formation.

Published

2018

49. Apparent strength versus universality in glasses of soft compressible colloids

Author

Ruben Higler and Joris Sprakel

Subjects

Multidisciplinary, lcsh:R, lcsh:Medicine, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Swell, Article, Colloid, Fragility, Chemical physics, 0103 physical sciences, Volume fraction, Compressibility, Life Science, Osmotic pressure, lcsh:Q, Particle size, lcsh:Science, 010306 general physics, 0210 nano-technology, Glass transition, Physical Chemistry and Soft Matter

Abstract

Microgel colloids, solvent swollen hydrogel particles of microscopic size, are in osmotic equilibrium with their surroundings. This has a profound effect on the behaviour of dense solutions of these polymeric colloids, most notably their ability to swell and deswell depending on the osmotic pressure of the system as a whole. Here we develop a minimal simulation model to treat this intrinsic volume regulation in order to explore the effects this has on the properties of dense solutions close to a liquid-solid transition. We demonstrate how the softness dependent volume regulation of particles gives rise to an apparent change in the fragility of the colloidal glass transition, which can be scaled out through the use of an adjusted volume fraction that accounts for changes in particle size. Moreover, we show how the same model can be used to explain the selective deswelling of soft microgels in a crystalline matrix of harder particles leading to robust crystals free of defects. Our results not only highlight the non-trivial effects of osmotic regulation in governing the apparent physics of microgel suspensions, but also provides a platform to efficiently account for particle deswelling in simulations.

Published

2018

50. Light from Within: Sensing Weak Strains and FemtoNewton Forces in Single Molecules

Author

Jasper van der Gucht, Jan Maarten van Doorn, Ties van de Laar, Joris Sprakel, Pieter van der Scheer, and Hent Schuurman

Subjects

Materials science, single-molecule spectroscopy, General Chemical Engineering, High resolution, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biochemistry, Molecular mechanics, Fluorescence spectroscopy, Force sensor, Materials Chemistry, conjugated polymers, Environmental Chemistry, Molecule, molecular force sensors, VLAG, chemistry.chemical_classification, Biochemistry (medical), Resolution (electron density), General Chemistry, Polymer, 021001 nanoscience & nanotechnology, Biological materials, 0104 chemical sciences, chemistry, 13. Climate action, 0210 nano-technology, Physical Chemistry and Soft Matter, mechanochromism

Abstract

Weak mechanical forces acting on molecules are in control of a wide variety of (bio)chemical and physical processes. The spatially inhomogeneous nature of these forces has a profound effect on the structure and mechanics of soft and biological materials. Yet, the lack of methods for probing sub-picoNewton forces at high resolution leaves our understanding of these effects incomplete. Here, we solve this challenge by engineering semiconducting polymers to act as ultraweak force sensors. Combining simulations, chemical synthesis, and single-molecule fluorescence spectroscopy, we demonstrate force sensing in single molecules. We achieve grayscale force detection, at a resolution as low as 300 fN, down to the molecular scale. Our approach opens the way to illuminating and quantifying molecular mechanics with unprecedented resolution. Mechanical stress at the molecular scale plays a crucial role in a wide variety of (bio)chemical processes, ranging from the sensing of the mechanical environment by cells to the failure of high-tech engineering materials. Although we know these molecular forces exist, making them visible and quantifying them at the molecular scale have remained impossible to date. This lack of direct insight at the molecular level has precluded a deeper understanding of how mechanics govern these problems. Here, we demonstrate quantitative force sensing in individual molecules at an unprecedented force resolution. Our approach is completely non-invasive and thus opens the way to visualizing and quantifying mechanical stresses in molecular materials and complex biological scenarios. Weak forces acting on molecules govern a vast range of physical, chemical, and biological phenomena. To date, it has not been possible to measure these forces directly because force-sensing methods at the nanoscale have lacked the resolution to resolve ultraweak forces at the scale of single molecules deep within complex materials. Here, we solve this challenge by demonstrating single-molecule force sensing with engineered light-emitting molecules and reporting forces as small as one trillionth of a Newton.

Published

2018