Integrated Micro/Nanoengineered Functional Biomaterials for Cell Mechanics and Mechanobiology: A Materials Perspective

Shao, Yue; Fu, Jianping

doi:10.1002/adma.201304431

Cited by 130 publications

(103 citation statements)

References 357 publications

(1,423 reference statements)

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“…This fact is relevant because different biological mechanisms can be activated only by means of forces in the order of hundreds of pN. 1 In agreement with Eq. (2), H ext affects the force experimented by beads.…”

supporting

confidence: 72%

Towards an on-chip platform for the controlled application of forces via magnetic particles: A novel device for mechanobiology

Monticelli

Albisetti

Petti

et al. 2015

Journal of Applied Physics

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supporting

confidence: 72%

Towards an on-chip platform for the controlled application of forces via magnetic particles: A novel device for mechanobiology

Monticelli

Albisetti

Petti

et al. 2015

Journal of Applied Physics

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“…15 Cells can sense the mechanical properties of their environment and as a response to perceived mechanical stimuli, they generate biochemical activity along with the signal transduction mechanism called mechanotransduction. 16,17 The matrix stiffness can regulate cellular functions including adhesion, 18 spreading, 19 migration, 20 proliferation, 21 and differentiation. 13,22 One of the most commonly used synthetic polymers to investigate the effects of mechanical stimuli on cellular behavior is poly(ethylene glycol) (PEG), which provides precise control of material stiffness.…”

Section: ■ Introductionmentioning

confidence: 99%

Self-Assembled Peptide Amphiphile Nanofibers and PEG Composite Hydrogels as Tunable ECM Mimetic Microenvironment

Göktas

Çınar

Orujalipoor³

et al. 2015

Biomacromolecules

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Natural extracellular matrix (ECM) consists of complex signals interacting with each other to organize cellular behavior and responses. This sophisticated microenvironment can be mimicked by advanced materials presenting essential biochemical and physical properties in a synergistic manner. In this work, we developed a facile fabrication method for a novel nanofibrous self-assembled peptide amphiphile (PA) and poly(ethylene glycol) (PEG) composite hydrogel system with independently tunable biochemical, mechanical, and physical cues without any chemical modification of polymer backbone or additional polymer processing techniques to create synthetic ECM analogues. This approach allows noninteracting modification of multiple niche properties (e.g., bioactive ligands, stiffness, porosity), since no covalent conjugation method was used to modify PEG monomers for incorporation of bioactivity and porosity. Combining the self-assembled PA nanofibers with a chemically cross-linked polymer network simply by facile mixing followed by photopolymerization resulted in the formation of porous bioactive hydrogel systems. The resulting porous network can be functionalized with desired bioactive signaling epitopes by simply altering the amino acid sequence of the self-assembling PA molecule. In addition, the mechanical properties of the composite system can be precisely controlled by changing the PEG concentration. Therefore, nanofibrous self-assembled PA/ PEG composite hydrogels reported in this work can provide new opportunities as versatile synthetic mimics of ECM with independently tunable biological and mechanical properties for tissue engineering and regenerative medicine applications. In addition, such systems could provide useful tools for investigation of how complex niche cues influence cellular behavior and tissue formation both in two-dimensional and three-dimensional platforms.

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“…Additive patterning of biomaterials with high resolution in three dimensions may enable controlled cellular environments that are central to tissue engineering [ 248 ] and biology. [249][250][251] Direct and high-resolution printing of individual cells and components of an extracellular matrix may play a key role in further developments in this area. [ 252 ] A relatively unexplored but growing area of opportunity is in the fabrication of photonic and plasmonic devices, where patterning of nanomaterials at high resolution is important.…”

Section: Discussionmentioning

confidence: 99%

Mechanisms, Capabilities, and Applications of High‐Resolution Electrohydrodynamic Jet Printing

Önses

Sutanto

Ferreira

et al. 2015

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This review gives an overview of techniques used for high-resolution jet printing that rely on electrohydrodynamically induced flows. Such methods enable the direct, additive patterning of materials with a resolution that can extend below 100 nm to provide unique opportunities not only in scientific studies but also in a range of applications that includes printed electronics, tissue engineering, and photonic and plasmonic devices. Following a brief historical perspective, this review presents descriptions of the underlying processes involved in the formation of liquid cones and jets to establish critical factors in the printing process. Different printing systems that share similar principles are then described, along with key advances that have been made in the last decade. Capabilities in terms of printable materials and levels of resolution are reviewed, with a strong emphasis on areas of potential application.

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Integrated Micro/Nanoengineered Functional Biomaterials for Cell Mechanics and Mechanobiology: A Materials Perspective

Cited by 130 publications

References 357 publications

Towards an on-chip platform for the controlled application of forces via magnetic particles: A novel device for mechanobiology

Towards an on-chip platform for the controlled application of forces via magnetic particles: A novel device for mechanobiology

Self-Assembled Peptide Amphiphile Nanofibers and PEG Composite Hydrogels as Tunable ECM Mimetic Microenvironment

Mechanisms, Capabilities, and Applications of High‐Resolution Electrohydrodynamic Jet Printing

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