Mark W. Tibbitt

Hydrogels as extracellular matrix mimics for 3D cell culture

Methods for culturing mammalian cells ex vivo are increasingly needed to study cell and tissue physiology and to grow replacement tissue for regenerative medicine. Two-dimensional culture has been the paradigm for typical in vitro cell culture; however, it has been demonstrated that cells behave more natively when cultured in three-dimensional environments. Permissive, synthetic hydrogels and promoting, natural hydrogels have become popular as three-dimensional cell culture platforms; yet, both of these systems possess limitations. In this perspective, we discuss the use of both synthetic and natural hydrogels as scaffolds for three-dimensional cell culture as well as synthetic hydrogels that incorporate sophisticated biochemical and mechanical cues as mimics of the native extracellular matrix. Ultimately, advances in synthetic-biologic hydrogel hybrids are needed to provide robust platforms for investigating cell physiology and fabricating tissue outside of the organism.

Mechanical memory and dosing influence stem cell fate

We investigated whether stem cells remember past physical signals and whether these can be exploited to dose cells mechanically. We found that the activation of the Yes-associated protein (YAP) and transcriptional coactivator with PDZ-binding domain (TAZ) as well as the pre-osteogenic transcription factor RUNX2 in human mesenchymal stem cells (hMSCs) cultured on soft poly(ethylene glycol) (PEG) hydrogels (Young’s modulus E ~ 2 kPa) depended on prior culture time on stiff tissue culture polystyrene (TCPS; E ~ 3 GPa). Additionally, mechanical dosing of hMSCs cultured on initially stiff (E ~ 10 kPa) and then soft (E ~ 2 kPa) phototunable PEG hydrogels resulted in either reversible - or above a threshold mechanical dose, irreversible - activation of YAP/TAZ and RUNX2. We also found that increased mechanical dosing on supraphysiologically stiff TCPS biases hMSCs toward osteogenic differentiation. We conclude that stem cells possess mechanical memory - with YAP/TAZ acting as an intracellular mechanical rheostat - that stores information from past physical environments and influences the cells’ fate.

Emerging Frontiers in Drug Delivery

Medicine relies on the use of pharmacologically active agents (drugs) to manage and treat disease. However, drugs are not inherently effective; the benefit of a drug is directly related to the manner by which it is administered or delivered. Drug delivery can affect drug pharmacokinetics, absorption, distribution, metabolism, duration of therapeutic effect, excretion, and toxicity. As new therapeutics (e.g., biologics) are being developed, there is an accompanying need for improved chemistries and materials to deliver them to the target site in the body, at a therapeutic concentration, and for the required period of time. In this Perspective, we provide an historical overview of drug delivery and controlled release followed by highlights of four emerging areas in the field of drug delivery: systemic RNA delivery, drug delivery for localized therapy, oral drug delivery systems, and biologic drug delivery systems. In each case, we present the barriers to effective drug delivery as well as chemical and materials advances that are enabling the field to overcome these hurdles for clinical impact.

Synthesis of photodegradable hydrogels as dynamically tunable cell culture platforms

We describe a detailed procedure to create photolabile, polyethylene glycol (PEG)-based hydrogels and manipulate material properties in situ. The cytocompatible chemistry and degradation process enable dynamic, tunable changes for applications in two-dimensional (2D) or 3D cell culture. The materials are created by synthesizing an o-nitrobenzylether-based photodegradable monomer that can be coupled to primary amines. In this study, we provide coupling procedures to PEG-bis-amine to form a photodegradable cross-linker or to the fibronectin-derived peptide RGDS to form a photoreleasable tether. Hydrogels are synthesized with the photodegradable cross-linker in the presence or absence of cells, allowing direct encapsulation or seeding on surfaces. Cell-material interactions can be probed in 2D or 3D by spatiotemporally controlling the gel microenvironment, which allows unique experiments to be performed to monitor cell response to changes in their niche. Degradation is readily achieved with cytocompatible wavelengths of low-intensity flood irradiation (365–420 nm) in minutes or with high-intensity laser irradiation (405 nm) in seconds. In this protocol, synthesis and purification of photodegradable monomers take approximately 2 weeks, but the process can be substantially shortened by purchasing the o-nitrobenzylether precursor. Preparation of sterile solutions for hydrogel fabrication takes hours, whereas the reaction to form the final hydrogel is complete in minutes. Hydrogel degradation occurs on demand, in seconds to minutes, with user-directed light exposure. This comprehensive protocol is useful for controlling peptide presentation and substrate modulus during cell culture on or within an elastic matrix. These PEG-based materials are useful for probing the dynamic influence of cell-cell and cell-material interactions on cell function in 2D or 3D. Although other protocols are available for controlling peptide presentation or modulus, few allow manipulation of material properties in situ and in the presence of cells down to the micrometer scale.

Tunable Hydrogels for External Manipulation of Cellular Microenvironments through Controlled Photodegradation

Hydrogels provide a unique environment for three-dimensionalcell culture, but typically, the material properties are fixed uponformation. Given the growing interest in understanding howmaterialmicroenvironmentsinfluencecellularfunctions,numer-ous approaches have emerged to control not only the initialbiochemicalandbiophysicalpropertiesofgels,butalsohowtheseproperties change with degradation. While these strategies allowthe synthesis of hydrogels with predictable degradation profilesand property changes, a material system that allows externalmanipulation of the properties of a cell-laden gel at any point intime or space would fill a unique niche. For example, such a cellculture system would allow real-time manipulation of theextracellular microenvironment and simultaneous monitoringof cellular processes in three-dimensional culture. In thiscontribution, photocleavable linkers were integrated into thecrosslinks of a poly(ethylene glycol)-based (PEG) hydrogel,allowing the network structure to be tuned exogeneously andpredictably with irradiation under cytocompatible conditions.Such a material system will enable new opportunities to testhypotheses about how precise variations in the local gelenvironment direct important cellular functions, such as processextension, migration, and mechanotransduction.There is a growing interest in the development of hydrogels asa platform for encapsulating cells and their application in fieldsranging from tissue engineering to three-dimensional cellculture.

Self-assembled hydrogels utilizing polymer–nanoparticle interactions

Mouldable hydrogels that flow upon applied stress and rapidly self-heal are increasingly utilised as they afford minimally invasive delivery and conformal application. Here we report a new paradigm for the fabrication of self-assembled hydrogels with shear-thinning and self-healing properties employing rationally engineered polymer-nanoparticle interactions. Biopolymer derivatives are linked together by selective adsorption to nanoparticles. The transient and reversible interactions between biopolymers and nanoparticles enable flow under applied shear stress, followed by rapid self-healing when the stress is relaxed. We develop a physical description of polymer-nanoparticle gel formation that is utilised to design biocompatible gels for minimally-invasive drug delivery. Owing to the hierarchical structure of the gel, both hydrophilic and hydrophobic drugs can be entrapped and delivered with differential release profiles, both in vitro and in vivo. The work introduces a facile and generalizable class of mouldable hydrogels amenable to a range of biomedical and industrial applications.

Dynamic Microenvironments: The Fourth Dimension

Four-dimensional cell matrices that recapitulate tissue and organ function will aid in the translation of cell-based therapies. The extracellular space, or cell microenvironment, choreographs cell behavior through myriad controlled signals, and aberrant cues can result in dysfunction and disease. For functional studies of human cell biology or expansion and delivery of cells for therapeutic purposes, scientists must decipher this intricate map of microenvironment biology and develop ways to mimic these functions in vitro. In this Perspective, we describe technologies for four-dimensional (4D) biology: cell-laden matrices engineered to recapitulate tissue and organ function in 3D space and over time.

Mechanical Properties and Degradation of Chain and Step Polymerized Photodegradable Hydrogels.

The relationship between polymeric hydrogel microstructure and macroscopic properties is of specific interest to the materials science and polymer science communities for the rational design of materials for targeted applications. Specifically, research has focused on elucidating the role of network formation and connectivity on mechanical integrity and degradation behavior. Here, we compared the mechanical properties of chain- and step-polymerized, photodegradable hydrogels. Increased ductility, tensile toughness, and shear strain to yield were observed in step-polymerized hydrogels, as compared to the chain-polymerized gels, indicating that increased homogeneity and network cooperativity in the gel backbone improves mechanical integrity. Furthermore, the ability to degrade the hydrogels in a controlled fashion with light was exploited to explore how hydrogel microstructure influences photodegradation and erosion. Here, the decreased network connectivity at the junction points in the step-polymerized gels resulted in more rapid erosion. Finally, a relationship between the reverse gelation threshold and erosion rate was developed for the general class of photodegradable hydrogels. In all, these studies further elucidate the relationship between hydrogel formation and microarchitecture with macroscale behavior to facilitate the future design of polymer networks and degradable hydrogels, as well as photoresponsive materials such as cell culture templates, drug delivery vehicles, responsive coatings, and anisotropic materials.

Controlled two-photon photodegradation of PEG hydrogels to study and manipulate subcellular interactions on soft materials.

Cell adhesion and detachment to and from the extracellular matrix (ECM) are critical regulators of cell function and fate due to the exchange of mechanical signals between the cell and its microenvironment. To study this cell mechanobiology, researchers have developed several innovative methods to investigate cell adhesion in vitro; however, most of these culture platforms are unnaturally stiff or static. To better capture the soft, dynamic nature of the ECM, we present a PEG-based hydrogel in which the context and geometry of the extracellular space can be precisely controlled in situ via two-photon induced erosion. Here, we characterize the two-photon erosion process, demonstrate its efficacy in the presence of cells, and subsequently exploit it to induce subcellular detachment from soft hydrogels. A working space was established for a range of laser powers required to induce complete erosion of the gel, and these data are plotted with model predictions. From this working space, two-photon irradiation parameters were selected for complete erosion in the presence of cells. Micron-scale features were eroded on and within a gel to demonstrate the resolution of patterning with these irradiation conditions. Lastly, two-photon irradiation was used to erode the material at the cell-gel interface to remove cell adhesion sites selectively, and cell retraction was monitored to quantify the mesenchymal stem cell (MSC) response to subcellular detachment from soft materials.

Human Neutrophil Elastase Responsive Delivery from Poly(ethylene glycol) Hydrogels

A novel enzyme-responsive hydrogel drug delivery system was developed with the potential to treat inflammation locally. Human neutrophil elastase (HNE) is a serine protease secreted by neutrophils which are the first cells recruited to inflammatory sites. We exploited this cell-secreted enzyme as a biological cue for controlled release. HNE sensitive peptide linkers were immobilized within poly(ethylene glycol) hydrogels using photopolymerization techniques. The kinetics of the enzyme reaction within the gel was tailored by varying the amino acid residues present in the P1 and P1′ substrate positions (immediately adjacent to cleavage location). A novel FRET-based hydrogel platform was designed to characterize the accessibility of the substrate within the cross-linked, macroscopic hydrogel. Lastly, a diffusion-reaction mathematical model with Michaelis−Menten kinetics was developed to predict the overall release profile and captured the initial 80% of the experimentally observed release. The hydrogel platform presented shows highly controlled release kinetics with potential applications in cellular responsive drug delivery.