A generic method is used for compartmentalization of supramolecular hydrogels by using water-in-water emulsions based on aqueous multi-phase systems (AMPS). By forming the low-molecular-weight hydrogel throughout all phases of all-aqueous emulsions, distinct, micro-compartmentalized materials were created. This structuring approach offers control over the composition of each type of the compartments by directing the partitioning of objects to be encapsulated. Moreover, this method allows for barrier-less, dynamic exchange of even large hydrophilic solutes (MW≈60kDa) between separate aqueous compartments. These features are expected to find use in the fields of, for instance, micro-structured catalysts, templating, and tissue engineering.@en

A generic method is used for compartmentalization of supramolecular hydrogels by using water-in-water emulsions based on aqueous multi-phase systems (AMPS). By forming the low-molecular-weight hydrogel throughout all phases of all-aqueous emulsions, distinct, micro-compartmentalized materials were created. This structuring approach offers control over the composition of each type of the compartments by directing the partitioning of objects to be encapsulated. Moreover, this method allows for barrier-less, dynamic exchange of even large hydrophilic solutes (MW≈60kDa) between separate aqueous compartments. These features are expected to find use in the fields of, for instance, micro-structured catalysts, templating, and tissue engineering.@en

Researchers investigated the effect of various (bio)polymeric crosslinkers on the self-assembly process of this reaction-coupled hydrazide-aldehyde gelator into hydrogel materials as a model system. They selected duplex DNA, which acted as a stiff, negatively charged rigid rod below its persistence length ideal for the construction of (nano)materials,[38–40] and compared it against a soft, neutral poly(ethylene glycol) (PEG) polymer of comparable size. Aldehyde moieties were specifically incorporated at the terminal ends of the (bio)polymers to introduce them during the self-assembly of the reaction-coupled network composed another set of (bio)polymers. The researchers also examined the effect of these two crosslinkers on the gelation of the reaction-coupled monomers into hydrogels over several length scales and compared their resultant materials properties.@en

Researchers investigated the effect of various (bio)polymeric crosslinkers on the self-assembly process of this reaction-coupled hydrazide-aldehyde gelator into hydrogel materials as a model system. They selected duplex DNA, which acted as a stiff, negatively charged rigid rod below its persistence length ideal for the construction of (nano)materials,[38–40] and compared it against a soft, neutral poly(ethylene glycol) (PEG) polymer of comparable size. Aldehyde moieties were specifically incorporated at the terminal ends of the (bio)polymers to introduce them during the self-assembly of the reaction-coupled network composed another set of (bio)polymers. The researchers also examined the effect of these two crosslinkers on the gelation of the reaction-coupled monomers into hydrogels over several length scales and compared their resultant materials properties.@en

Researchers investigated the effect of various (bio)polymeric crosslinkers on the self-assembly process of this reaction-coupled hydrazide-aldehyde gelator into hydrogel materials as a model system. They selected duplex DNA, which acted as a stiff, negatively charged rigid rod below its persistence length ideal for the construction of (nano)materials,[38–40] and compared it against a soft, neutral poly(ethylene glycol) (PEG) polymer of comparable size. Aldehyde moieties were specifically incorporated at the terminal ends of the (bio)polymers to introduce them during the self-assembly of the reaction-coupled network composed another set of (bio)polymers. The researchers also examined the effect of these two crosslinkers on the gelation of the reaction-coupled monomers into hydrogels over several length scales and compared their resultant materials properties.@en

Researchers investigated the effect of various (bio)polymeric crosslinkers on the self-assembly process of this reaction-coupled hydrazide-aldehyde gelator into hydrogel materials as a model system. They selected duplex DNA, which acted as a stiff, negatively charged rigid rod below its persistence length ideal for the construction of (nano)materials,[38–40] and compared it against a soft, neutral poly(ethylene glycol) (PEG) polymer of comparable size. Aldehyde moieties were specifically incorporated at the terminal ends of the (bio)polymers to introduce them during the self-assembly of the reaction-coupled network composed another set of (bio)polymers. The researchers also examined the effect of these two crosslinkers on the gelation of the reaction-coupled monomers into hydrogels over several length scales and compared their resultant materials properties.@en

Researchers investigated the effect of various (bio)polymeric crosslinkers on the self-assembly process of this reaction-coupled hydrazide-aldehyde gelator into hydrogel materials as a model system. They selected duplex DNA, which acted as a stiff, negatively charged rigid rod below its persistence length ideal for the construction of (nano)materials,[38–40] and compared it against a soft, neutral poly(ethylene glycol) (PEG) polymer of comparable size. Aldehyde moieties were specifically incorporated at the terminal ends of the (bio)polymers to introduce them during the self-assembly of the reaction-coupled network composed another set of (bio)polymers. The researchers also examined the effect of these two crosslinkers on the gelation of the reaction-coupled monomers into hydrogels over several length scales and compared their resultant materials properties.@en

Researchers investigated the effect of various (bio)polymeric crosslinkers on the self-assembly process of this reaction-coupled hydrazide-aldehyde gelator into hydrogel materials as a model system. They selected duplex DNA, which acted as a stiff, negatively charged rigid rod below its persistence length ideal for the construction of (nano)materials,[38–40] and compared it against a soft, neutral poly(ethylene glycol) (PEG) polymer of comparable size. Aldehyde moieties were specifically incorporated at the terminal ends of the (bio)polymers to introduce them during the self-assembly of the reaction-coupled network composed another set of (bio)polymers. The researchers also examined the effect of these two crosslinkers on the gelation of the reaction-coupled monomers into hydrogels over several length scales and compared their resultant materials properties.@en

Researchers investigated the effect of various (bio)polymeric crosslinkers on the self-assembly process of this reaction-coupled hydrazide-aldehyde gelator into hydrogel materials as a model system. They selected duplex DNA, which acted as a stiff, negatively charged rigid rod below its persistence length ideal for the construction of (nano)materials,[38–40] and compared it against a soft, neutral poly(ethylene glycol) (PEG) polymer of comparable size. Aldehyde moieties were specifically incorporated at the terminal ends of the (bio)polymers to introduce them during the self-assembly of the reaction-coupled network composed another set of (bio)polymers. The researchers also examined the effect of these two crosslinkers on the gelation of the reaction-coupled monomers into hydrogels over several length scales and compared their resultant materials properties.@en

Researchers investigated the effect of various (bio)polymeric crosslinkers on the self-assembly process of this reaction-coupled hydrazide-aldehyde gelator into hydrogel materials as a model system. They selected duplex DNA, which acted as a stiff, negatively charged rigid rod below its persistence length ideal for the construction of (nano)materials,[38–40] and compared it against a soft, neutral poly(ethylene glycol) (PEG) polymer of comparable size. Aldehyde moieties were specifically incorporated at the terminal ends of the (bio)polymers to introduce them during the self-assembly of the reaction-coupled network composed another set of (bio)polymers. The researchers also examined the effect of these two crosslinkers on the gelation of the reaction-coupled monomers into hydrogels over several length scales and compared their resultant materials properties.@en

Cells can react to their environment by changing the activity of enzymes in response to specific chemical signals. Artificial catalysts capable of being activated by chemical signals are rare, but of interest for creating autonomously responsive materials. We present an organocatalyst that is activated by a chemical signal, enabling temporal control over reaction rates and the formation of materials. Using self-immolative chemistry, we design a deactivated aniline organocatalyst that is activated by the chemical signal hydrogen peroxide and catalyses hydrazone formation. Upon activation of the catalyst, the rate of hydrazone formation increases 10-fold almost instantly. The responsive organocatalyst enables temporal control over the formation of gels featuring hydrazone bonds. The generic design should enable the use of a large range of triggers and organocatalysts, and appears a promising method for the introduction of signal response in materials, constituting a first step towards achieving communication between artificial chemical systems.@en

ConspectusOne often thinks of catalysts as chemical tools to accelerate a reaction or to have a reaction run under more benign conditions. As such, catalysis has a role to play in the chemical industry and in lab scale synthesis that is not to be underestimated. Still, the role of catalysis in living systems (cells, organisms) is much more extensive, ranging from the formation and breakdown of small molecules and biopolymers to controlling signal transduction cascades and feedback processes, motility, and mechanical action. Such phenomena are only recently starting to receive attention in synthetic materials and chemical systems. "Smart" soft materials could find many important applications ranging from personalized therapeutics to soft robotics to name but a few. Until recently, approaches to control the properties of such materials were largely dominated by thermodynamics, for instance, looking at phase behavior and interaction strength. However, kinetics plays a large role in determining the behavior of such soft materials, for instance, in the formation of kinetically trapped (metastable) states or the dynamics of component exchange. As catalysts can change the rate of a chemical reaction, catalysis could be used to control the formation, dynamics, and fate of supramolecular structures when the molecules making up these structures contain chemical bonds whose formation or exchange are susceptible to catalysis.In this Account, we describe our efforts to use synthetic catalysts to control the properties of supramolecular hydrogels. Building on the concept of synthesizing the assembling molecule in the self-assembly medium from nonassembling precursors, we will introduce the use of catalysis to change the kinetics of assembler formation and thereby the properties of the resulting material. In particular, we will focus on the synthesis of supramolecular hydrogels where the use of a catalyst provides access to gel materials with vastly different appearance and mechanical properties or controls localized gel formation and the growth of gel objects. As such, catalysis will be applied to create molecular materials that exist outside of chemical equilibrium. In all, using catalysts to control the properties of soft materials constitutes a new avenue for catalysis far beyond the traditional use in industrial and lab scale synthesis.@en

In recent years, we have developed a low molecular weight hydrogelator system that is formed in situ under ambient conditions through catalysed hydrazone formation between two individually non-gelating components. In this contribution, we describe a molecular toolbox based on this system which allows us to (1) investigate the limits of gel formation and fine-tuning of their bulk properties, (2) introduce multicolour fluorescent probes in an easy fashion to enable high-resolution imaging, and (3) chemically modify the supramolecular gel fibres through click and non-covalent chemistry, to expand the functionality of the resultant materials. In this paper we show preliminary applications of this toolbox, enabling covalent and non-covalent functionalisation of the gel network with proteins and multicolour imaging of hydrogel networks with embedded mammalian cells and their substructures. Overall, the results show that the toolbox allows for on demand gel network visualisation and functionalisation, enabling a wealth of applications in the areas of chemical biology and smart materials.@en

In recent years, we have developed a low molecular weight hydrogelator system that is formed in situ under ambient conditions through catalysed hydrazone formation between two individually non-gelating components. In this contribution, we describe a molecular toolbox based on this system which allows us to (1) investigate the limits of gel formation and fine-tuning of their bulk properties, (2) introduce multicolour fluorescent probes in an easy fashion to enable high-resolution imaging, and (3) chemically modify the supramolecular gel fibres through click and non-covalent chemistry, to expand the functionality of the resultant materials. In this paper we show preliminary applications of this toolbox, enabling covalent and non-covalent functionalisation of the gel network with proteins and multicolour imaging of hydrogel networks with embedded mammalian cells and their substructures. Overall, the results show that the toolbox allows for on demand gel network visualisation and functionalisation, enabling a wealth of applications in the areas of chemical biology and smart materials.@en

In this contribution we show that biological membranes can catalyze the formation of supramolecular hydrogel networks. Negatively charged lipid membranes can generate a local proton gradient, accelerating the acid-catalyzed formation of hydrazone-based supramolecular gelators near the membrane. Synthetic lipid membranes can be used to tune the physical properties of the resulting multicomponent gels as a function of lipid concentration. Moreover, the catalytic activity of lipid membranes and the formation of gel networks around these supramolecular structures are controlled by the charge and phase behavior of the lipid molecules. Finally, we show that the insights obtained from synthetic membranes can be translated to biological membranes, enabling the formation of gel fibers on living HeLa cells.@en

In this contribution we show that biological membranes can catalyze the formation of supramolecular hydrogel networks. Negatively charged lipid membranes can generate a local proton gradient, accelerating the acid-catalyzed formation of hydrazone-based supramolecular gelators near the membrane. Synthetic lipid membranes can be used to tune the physical properties of the resulting multicomponent gels as a function of lipid concentration. Moreover, the catalytic activity of lipid membranes and the formation of gel networks around these supramolecular structures are controlled by the charge and phase behavior of the lipid molecules. Finally, we show that the insights obtained from synthetic membranes can be translated to biological membranes, enabling the formation of gel fibers on living HeLa cells.@en

In this contribution we show that biological membranes can catalyze the formation of supramolecular hydrogel networks. Negatively charged lipid membranes can generate a local proton gradient, accelerating the acid-catalyzed formation of hydrazone-based supramolecular gelators near the membrane. Synthetic lipid membranes can be used to tune the physical properties of the resulting multicomponent gels as a function of lipid concentration. Moreover, the catalytic activity of lipid membranes and the formation of gel networks around these supramolecular structures are controlled by the charge and phase behavior of the lipid molecules. Finally, we show that the insights obtained from synthetic membranes can be translated to biological membranes, enabling the formation of gel fibers on living HeLa cells.@en

In this contribution we show that biological membranes can catalyze the formation of supramolecular hydrogel networks. Negatively charged lipid membranes can generate a local proton gradient, accelerating the acid-catalyzed formation of hydrazone-based supramolecular gelators near the membrane. Synthetic lipid membranes can be used to tune the physical properties of the resulting multicomponent gels as a function of lipid concentration. Moreover, the catalytic activity of lipid membranes and the formation of gel networks around these supramolecular structures are controlled by the charge and phase behavior of the lipid molecules. Finally, we show that the insights obtained from synthetic membranes can be translated to biological membranes, enabling the formation of gel fibers on living HeLa cells.@en

In this contribution we show that biological membranes can catalyze the formation of supramolecular hydrogel networks. Negatively charged lipid membranes can generate a local proton gradient, accelerating the acid-catalyzed formation of hydrazone-based supramolecular gelators near the membrane. Synthetic lipid membranes can be used to tune the physical properties of the resulting multicomponent gels as a function of lipid concentration. Moreover, the catalytic activity of lipid membranes and the formation of gel networks around these supramolecular structures are controlled by the charge and phase behavior of the lipid molecules. Finally, we show that the insights obtained from synthetic membranes can be translated to biological membranes, enabling the formation of gel fibers on living HeLa cells.@en