Mechanically primed cells transfer memory to fibrous matrices for invasion across environments of distinct stiffness and dimensionality.

Cells sense and migrate across mechanically dissimilar environments throughout development and disease progression. However, it remains unclear whether mechanical memory of past environments empowers cells to navigate new, three-dimensional extracellular matrices. Here, we show that cells previously primed on stiff, compared with soft, matrices generate a higher level of forces to remodel collagen fibers and promote invasion.

A novel 3D vascular assay for evaluating angiogenesis across porous membranes.

Microfluidic technology has been extensively applied to model the functional units of human organs and tissues. Since vasculature is a key component of any functional tissue, a variety of techniques to mimic vasculature in vitro have been developed to address complex physiological and pathological processes in 3D tissues. Herein, we developed a novel, in vitro, microfluidic-based model to probe microvasculature growth into and across implanted porous membranes.

Longer collagen fibers trigger multicellular streaming on soft substrates via enhanced forces and cell-cell cooperation.

Grouped cells often leave large cell colonies in the form of narrow multicellular streams. However, it remains unknown how collective cell streaming exploits specific matrix properties, like stiffness and fiber length. It is also unclear how cellular forces, cell-cell adhesion and velocities are coordinated within streams.

Predicting Collective Migration of Cell Populations Defined by Varying Repolarization Dynamics.

Collective migration of heterogeneous cell populations is an essential aspect of fundamental biological processes, including morphogenesis, wound healing, and tumor invasion. Through experiments and modeling, it has been shown that cells attain front-rear polarity, generate forces, and form adhesions to migrate. However, it remains unclear how the ability of individual cells in a population to dynamically repolarize themselves into new directions could regulate the collective response.

Encapsulation of Rat Bone Marrow Derived Mesenchymal Stem Cells in Alginate Dialdehyde/Gelatin Microbeads with and without Nanoscaled Bioactive Glass for In Vivo Bone Tissue Engineering.

Alginate dialdehyde (ADA), gelatin, and nano-scaled bioactive glass (nBG) particles are being currently investigated for their potential use as three-dimensional scaffolding materials for bone tissue engineering. ADA and gelatin provide a three-dimensional scaffold with properties supporting cell adhesion and proliferation. Combined with nanocristalline BG, this composition closely mimics the mineral phase of bone.

Direct Micropatterning of Extracellular Matrix Proteins on Functionalized Polyacrylamide Hydrogels Shows Geometric Regulation of Cell-Cell Junctions.

Microcontact printing of extracellular matrix (ECM) proteins in defined regions of a substrate allows spatial control over cell attachment and enables the study of cellular response to irregular ECM geometries. Over the past decade, numerous micropatterning techniques have emerged that conjugate ECM proteins on hydrogel substrates of tunable stiffness, which have revealed a range of cellular responses to varying matrix stiffness and geometry. However, micropatterning of ECM proteins on polyacrylamide (PA) hydrogel remains inconsistent due to its unreliable conjugation with the commonly used protein cross-linkers, particularly at low stiffness.

Hydrogel matrices based on elastin and alginate for tissue engineering applications.

Hydrogels from natural polymers are widely used in tissue engineering due to their unique properties, especially when regarding the cell environment and their morphological similarity to the extracellular matrix (ECM) of native tissues. In this study, we describe the production and characterization of novel hybrid hydrogels composed of alginate blended with elastin from bovine neck ligament. The properties of elastin as a component of the native ECM were combined with the excellent chemical and mechanical stability as well as biocompatibility of alginate to produce two hybrid hydrogels geometries, namely 2D films obtained using sonication treatment and 3D microcapsules produced by pressure-driven extrusion.

Oxidized Alginate-Gelatin Hydrogel: A Favorable Matrix for Growth and Osteogenic Differentiation of Adipose-Derived Stem Cells in 3D.

Alginate-based hydrogels are extensively used matrices for cell encapsulation, but they need to be modified to recapitulate chemical, microstructural, and mechanical properties of the native extracellular matrix. Like other cell types, mesenchymal stem cells exhibit rounded and clustered morphologies when they are embedded in alginate hydrogels. In this study, we use covalently cross-linked oxidized alginate-gelatin hydrogels to encapsulate human adipose-derived stem cells in order to investigate cell growth, viability, and morphology during osteogenic differentiation taking advantage of the different physicochemical properties of this modified alginate-based hydrogel in comparison to those of the pristine alginate hydrogel.

Designing Porous Bone Tissue Engineering Scaffolds with Enhanced Mechanical Properties from Composite Hydrogels Composed of Modified Alginate, Gelatin, and Bioactive Glass.

The combination of biodegradable polymers and bioactive inorganic materials is being widely used for designing bone tissue engineering scaffolds. Here we report a composite hydrogel system composed of bioactive glass incorporated in covalently cross-linked oxidized alginate-gelatin hydrogel (ADA-GEL) for designing porous scaffolds with tunable stiffness and degradability using freeze-drying technique. Because of the presence of bioactive glass, the cross-linking kinetic and cross-linking degree of the hydrogels are significantly increased, which is the main factor for the measured enhanced mechanical strength of the bioactive glass containing ADA-GEL scaffolds.

Bioplotting of a bioactive alginate dialdehyde-gelatin composite hydrogel containing bioactive glass nanoparticles.

Alginate dialdehyde-gelatin (ADA-GEL) constructs incorporating bioactive glass nanoparticles (BGNPs) were produced by biofabrication to obtain a grid-like highly-hydrated composite. The material could induce the deposition of an apatite layer upon immersion in a biological-like environment to sustain cell attachment and proliferation. Composites were formulated with different concentrations of BGNPs synthetized from a sol-gel route, namely 0.

Biofabrication of 3D Alginate-Based Hydrogel for Cancer Research: Comparison of Cell Spreading, Viability, and Adhesion Characteristics of Colorectal HCT116 Tumor Cells.

Hydrogels are an important class of biomaterials as they could mimic the extracellular matrix (ECM). Among the naturally occurring biopolymers, alginate and gelatin are extensively used for many biomedical applications. For developing biofabrication constructs as three-dimensional (3D) cell culture models, realistic imaging of cell spreading and proliferation inside the hydrogels represents a major challenge.

Soft-matrices based on silk fibroin and alginate for tissue engineering.

Soft tissue regeneration requires the use of matrices that exhibit adequate mechanical properties as well as the ability to supply nutrients and oxygen, and to remove metabolic bio-products. In this work, we describe the development of hydrogels based on the blend between alginate (Alg) and silk fibroin (SF). Herein, we report two main strategies to combine cells with biomaterials: cells are either seeded onto prefabricated hydrogels films (2D), or encapsulated during hydrogel microcapsules formation (3D).

Evaluation of hydrogel matrices for vessel bioplotting: Vascular cell growth and viability.

Developing matrices biocompatible with vascular cells is one of the most challenging tasks in tissue engineering. Here, we compared the growth of vascular cells on different hydrogels as potential materials for bioplotting of vascular tissue. Formulations containing alginate solution (Alg, 2%, w/v) blended with protein solutions (silk fibroin, gelatin, keratin, or elastin) at 1% w/v were prepared.

Evaluation of an alginate-gelatine crosslinked hydrogel for bioplotting.

Using additive manufacturing to create hydrogel scaffolds which incorporate homogeneously distributed, immobilized cells in the context of biofabrication approaches represents an emerging and expanding field in tissue engineering. Applying hydrogels for additive manufacturing must consider the material processing properties as well as their influence on the immobilized cells. In this work alginate-dialdehyde (ADA), a partially oxidized alginate, was used as a basic material to improve the physico-chemical properties of the hydrogel for cell immobilization.

Alginate-based hydrogels with improved adhesive properties for cell encapsulation.

Hydrogel-based biomaterials are ideal scaffolding matrices for microencapsulation, but they need to be modified to resemble the mechanical, structural and chemical properties of the native extracellular matrix. Here, we compare the mechanical properties and the degradation behavior of unmodified and modified alginate hydrogels in which cell adhesive functionality is conferred either by blending or covalently cross-linking with gelatin. Furthermore, we measure the spreading and proliferation of encapsulated osteoblast-like MG-63 cells.

Evaluation of fibroblasts adhesion and proliferation on alginate-gelatin crosslinked hydrogel.

Due to the relatively poor cell-material interaction of alginate hydrogel, alginate-gelatin crosslinked (ADA-GEL) hydrogel was synthesized through covalent crosslinking of alginate di-aldehyde (ADA) with gelatin that supported cell attachment, spreading and proliferation. This study highlights the evaluation of the physico-chemical properties of synthesized ADA-GEL hydrogels of different compositions compared to alginate in the form of films. Moreover, in vitro cell-material interaction on ADA-GEL hydrogels of different compositions compared to alginate was investigated by using normal human dermal fibroblasts.

Hybrid hydrogels based on keratin and alginate for tissue engineering.

Novel hybrid hydrogels based on alginate and keratin were successfully produced for the first time. The self-assembly properties of keratin, and its ability to mimic the extracellular matrix were combined with the excellent chemical and mechanical stability and biocompatibility of alginate to produce 2D and 3D hybrid hydrogels. These hybrid hydrogels were prepared using two different approaches: sonication, to obtain 2D hydrogels, and a pressure-driven extrusion technique to produce 3D hydrogels.

Combining collagen and bioactive glasses for bone tissue engineering: a review.

Collagen (COL), the most abundant protein in mammals, offers a wide range of attractive properties for biomedical applications which are the result of its biocompatibility and high affinity to water. However, due to the relative low mechanical properties of COL its applications are still limited. To tackle this disadvantage of COL, especially in the field of bone tissue engineering, COL can be combined with bioactive inorganic materials in a variety of composite systems.

Behavior of encapsulated MG-63 cells in RGD and gelatine-modified alginate hydrogels.

Achieving cell spreading and proliferation inside hydrogels that are compatible with microencapsulation technology represents a major challenge for tissue engineering scaffolding and for the development of three-dimensional cell culture models. In this study, microcapsules of 650-900 μm in diameter were fabricated from oxidized alginate covalently cross-linked with gelatine (AlGel). Schiff's base bond formed in AlGel, detected by Fourier transform infrared spectroscopy, which confirmed the cross-linking of oxidized alginate with gelatine.

Fabrication of alginate-gelatin crosslinked hydrogel microcapsules and evaluation of the microstructure and physico-chemical properties.

Microencapsulation of cells by using biodegradable hydrogels offers numerous attractive features for a variety of biomedical applications including tissue engineering. This study highlights the fabrication of microcapsules from an alginate-gelatin crosslinked hydrogel (ADA-GEL) and presents the evaluation of the physico-chemical properties of the new microcapsules which are relevant for designing suitable microcapsules for tissue engineering. Alginate di-aldehyde (ADA) was synthesized by periodate oxidation of alginate which facilitates crosslinking with gelatin through Schiff's base formation between the free amino groups of gelatin and the available aldehyde groups of ADA.

and Biocompatibility of Alginate Dialdehyde/Gelatin Hydrogels with and without Nanoscaled Bioactive Glass for Bone Tissue Engineering Applications.

In addition to good mechanical properties needed for three-dimensional tissue engineering, the combination of alginate dialdehyde, gelatin and nano-scaled bioactive glass (45S5) is supposed to combine excellent cellular adhesion, proliferation and differentiation properties, good biocompatibility and predictable degradation rates. The goal of this study was to evaluate the and biocompatibility as a first step on the way to its use as a scaffold in bone tissue engineering. evaluation showed good cell adherence and proliferation of bone marrow derived mesenchymal stem cells seeded on covalently crosslinked alginate dialdehyde-gelatin (ADA-GEL) hydrogel films with and without 0.