Cell Migration on Planar and Three-Dimensional Matrices: A Hydrogel-Based Perspective

Vu, Lucas; Jain, Gaurav; Veres, Brandon D.; Rajagopalan, Padmavathy

doi:10.1089/ten.teb.2013.0782

Cited by 58 publications

(46 citation statements)

References 98 publications

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“…Microfluidic Device Coating : All channels in the microfluidic devices were treated with collagen or fibronectin to enhance attachment of the fibroblasts, HUVECs, and macrophages to the device . Collagen I (Corning Collagen I, Rat Tail, 100 mg (#354236) solution with a final concentration of 2 mg mL −1 (23 µL acetic acid + 20 mL water + 280 µL collagen) was prepared on ice and used for device coating.…”

Section: Methodsmentioning

confidence: 99%

Simulating Inflammation in a Wound Microenvironment Using a Dermal Wound‐on‐a‐Chip Model

Biglari

Tan

et al. 2018

Adv Healthcare Materials

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Considerable progress has been made in the field of microfluidics to develop complex systems for modeling human skin and dermal wound healing processes. While microfluidic models have attempted to integrate multiple cell types and/or 3D culture systems, to date they have lacked some elements needed to fully represent dermal wound healing. This paper describes a cost‐effective, multicellular microfluidic system that mimics the paracrine component of early inflammation close to normal wound healing. Collagen and Matrigel are tested as materials for coating and adhesion of dermal fibroblasts and human umbilical vein endothelial cells (HUVECs). The wound‐on‐chip model consists of three interconnecting channels and is able to simulate wound inflammation by adding tumor necrosis factor alpha (TNF‐α) or by triculturing with macrophages. Both the approaches significantly increase IL‐1β, IL‐6, IL‐8 in the supernatant (p < 0.05), and increases in cytokine levels are attenuated by cotreatment with an anti‐inflammatory agent, Dexamethasone. Incorporation of M1 and M2 macrophages cocultured with fibroblasts and HUVECs leads to a stimulation of cytokine production as well as vascular structure formation, particularly with M2 macrophages. In summary, this wound‐on‐chip system can be used to model the paracrine component of the early inflammatory phase of wound healing and has the potential for the screening of anti‐inflammatory compounds.

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Section: Methodsmentioning

confidence: 99%

Simulating Inflammation in a Wound Microenvironment Using a Dermal Wound‐on‐a‐Chip Model

Biglari

Tan

et al. 2018

Adv Healthcare Materials

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“…Hydrogel networks are comprised of polymer or peptide chains. They have a high content of water, ideal for absorbing high levels of nutrients and oxygen [65] , allowing cells to migrate within the scaffold [66] and the waste to diffuse out [67] . Synthesised materials, such as those based on polyethylene glycol and polyacrylamide, offer more control over modification than naturally derived materials such as alginate, collagen, fibrin and hyaluronic acid [62,64] .…”

Section: Using Hydrogels For 3d Bioprintingmentioning

confidence: 99%

3D bioprinting for tissue engineering: Stem cells in hydrogels

Mehrban¹,

Teoh²,

Birchall³

2024

IJB

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Surgical limitations require alternative methods of repairing and replacing diseased and damaged tissue. Regenerative medicine is a growing area of research with engineered tissues already being used successfully in patients. However, the demand for such tissues greatly outweighs the supply and a fast and accurate method of production is still required. 3D bioprinting offers precision control as well as the ability to incorporate biological cues and cells directly into the material as it is being fabricated. Having precise control over scaffold morphology and chemistry is a significant step towards controlling cellular behaviour, particularly where undifferentiated cells, i.e., stem cells, are used. This level of control in the early stages of tissue development is crucial in building more complex systems that morphologically and functionally mimic in vivo tissue. Here we review 3D printing hydrogel materials for tissue engineering purposes and the incorporation of cells within them. Hydrogels are ideal materials for cell culture. They are structurally similar to native extracellular matrix, have a high nutrient retention capacity, allow cells to migrate and can be formed under mild conditions. The techniques used to produce these materials, as well as their benefits and limitations, are outlined.

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“…Spatiotemporal monitoring of cell migration, self‐assembly, and morphogenesis in both synthetic and natural hydrogels has received significant attention owing to its importance in numerous physiological phenomena including organ and tissue development, cardiovascular diseases, and cancer progression . Two broad approaches have been adopted to investigate these processes: (1) self‐assembly of cells (including multiple cell types) from a “zero‐state” initial encapsulation condition and (2) directed organization of cells into desired configurations using a predefined architecture .…”

Section: Part 2: Applications Of Laser‐based Hydrogel Degradation Inmentioning

confidence: 99%

Fundamentals of Laser‐Based Hydrogel Degradation and Applications in Cell and Tissue Engineering

Pradhan

Keller

Sperduto

et al. 2017

Adv Healthcare Materials

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The cell and tissue engineering fields have profited immensely through the implementation of highly-structured biomaterials. The development and implementation of advanced biofabrication techniques has established new avenues for generating biomimetic scaffolds for a multitude of cell and tissue engineering applications. Among these, laser-based degradation of biomaterials has been implemented to achieve user-directed features and functionalities within biomimetic scaffolds. This review offers an overview of the physical mechanisms that govern laser-material interactions and specifically, laser-hydrogel interactions. The influence of both laser and material properties on efficient, high-resolution hydrogel degradation are discussed and the current application space in cell and tissue engineering is reviewed. This review aims to acquaint readers with the capability and uses of laser-based degradation of biomaterials, so that it may be easily and widely adopted.

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Cell Migration on Planar and Three-Dimensional Matrices: A Hydrogel-Based Perspective

Cited by 58 publications

References 98 publications

Simulating Inflammation in a Wound Microenvironment Using a Dermal Wound‐on‐a‐Chip Model

Simulating Inflammation in a Wound Microenvironment Using a Dermal Wound‐on‐a‐Chip Model

3D bioprinting for tissue engineering: Stem cells in hydrogels

Fundamentals of Laser‐Based Hydrogel Degradation and Applications in Cell and Tissue Engineering

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