4D Printed Actuators with Soft‐Robotic Functions

López-Valdeolivas, María; Liu, Danqing; Broer, Dirk J.; Sánchez‐Somolinos, Carlos

doi:10.1002/marc.201700710

Cited by 291 publications

(331 citation statements)

References 27 publications

(62 reference statements)

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“…The locally different responsive properties of the hydrogels can be achieved by local adjusting the compositions and/or structures of the hydrogels. Among the reported methods, photolithographic 55,56 and three-dimensional (3D) printing methods [57][58][59][60][61] can produce hydrogels with macroscale inhomogeneous structures by introducing a double-network hydrogel or inducing different orientations of additive cellulose fibrils, respectively. Photolithographic, 62-66 electrochemical ionprinting, [67][68][69][70] ion-transfer-printing (ITP), 50 and ion-inkjetprinting (IIP) 71 methods can prepare hydrogels with molecular scale inhomogeneity by introducing crosslinking gradients into as-prepared hydrogels.…”

Section: Hydrogels With Locally Different Responsive Propertiesmentioning

confidence: 99%

Shape changing hydrogels and their applications as soft actuators

Peng

Wang

2018

J Polym Sci B Polym Phys

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In nature, plants or animals change their geometric shapes and hence realize different functions or movements. Inspired by the shape changes of plants and animals, several hydrogels that can change their geometric shapes upon external stimuli have been developed. This article provides a brief overview of shape changing hydrogels. First, two strategies to realize the shape changes of hydrogels, that is, preparing hydrogels with inhomogeneous structures and applying inhomogeneous stimuli onto homogeneous hydrogels, are discussed. Then, external stimuli that can actuate the shape changes of the stimuli-responsive hydrogels are presented. The applications of shape changing hydrogels such as soft machines, soft robotics, drug carriers, microfluidic valves, and sensors have been provided in third part. Finally, we offer our perspective on open challenges and future areas of interest for the shape changing hydrogel actuators.

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Section: Hydrogels With Locally Different Responsive Propertiesmentioning

confidence: 99%

Shape changing hydrogels and their applications as soft actuators

Peng

Wang

2018

J Polym Sci B Polym Phys

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“…Additive manufacturing techniques, such as two‐photon lithography and 3D printing, are becoming more and more relevant in biotechnology, giving the possibility to produce complex 3D structures on different length‐scales and becoming amenable to many different materials . It has been shown that LC materials can be utilized with these techniques with the characteristic molecular order remaining preserved during the photo‐crosslinking process, or even induced and patterned due to shear forces in the 3D printing process . Van Oosten et al achieved the construction of bioinspired artificial cilia for mixing applications and microfluidic pumping (Figure d) .…”

Section: Polymeric Photoactuators: Moving Toward Artificial Musclesmentioning

confidence: 99%

Photoreversible Soft Azo Dye Materials: Toward Optical Control of Bio‐Interfaces

Chang

Fedele

Priimägi

et al. 2019

Advanced Optical Materials

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systems interact with artificial materials, researchers have now assembled a versatile toolkit of materials and processes that allows one to fine-tune interactions at the interface, tailoring specific biological responses on demand. These strategies for biocontrol can be broadly categorized as chemical (charge, ligand presence, surface groups), material changes (moisture content, stiffness), or morphological changes (molecular orientation, surface topography, or mechanical actuation). Rational design of materials for biological interface applications has a unique set of challenges due to the unique requirements of a wide range of biological systems, since different tissues present specific compositions, with their own elasticity, structural organization, and triggering mechanisms. Even within a single organ or tissue, mechanical properties can vary widely depending on the region. A recent study of viscoelasticity in live mouse brain tissue for example found a tenfold difference within the brain depending on the region and morphological structure studied. [2] However, most biological tissues are far less stiff, and far more viscoelastic than typical artificial materials employed at their interface, especially early artificial cell culture materials, which can be much stiffer than in vivo extracellular matrix by many orders of magnitude. [3] In vivo, cells interface with a surrounding microenvironment consisting of an intricate macromolecular network of proteins and sugars swollen in an aqueous media gel. Therefore, the interaction between cells and the extracellular matrix (ECM) in the body is complex and involves a variety of cues related to topography, chemical markers, protein composition, solubility factors, and mechanical properties such as stiffness and elasticity (Figure 1a). [4] Yet much research over the past decades was focused on studying in vitro the effects of each of these signals on cell behavior, with a particular interest on the chemical factors, whereas only recently more advanced biomaterials with controlled physicomechanical properties have been developed, such as those with tunable and variable stiffness, alignment and orientation of key functional groups, and mechanical actuation. There is a large range of stiffness in human tissue, where bone (≈100 GPa) is nine orders of magnitude harder than brain tissue (≈0.1 kPa). [4] Therefore, biomaterial researchers assume a complex task of providing materials and processing technologies for controlling stiffness and micro-and nanostructures in Photoreversible optically switchable azo dye molecules in polymer-based materials can be harnessed to control a wide range of physical, chemical, and mechanical material properties in response to light, that can be exploited for optical control over the bio-interface. As a stimulus for reversibly influencing adjacent biological cells or tissue, light is an ideal triggering mechanism, since it can be highly localized (in time and space) for precise and dynamic control over a biosystem, and low-power visible light...

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“…López‐Valdeolivas et al prepared cross‐linkable liquid crystal polymers as inks and used them to print stimuli‐responsive structures. The printed elastomers were able to undergo shape changes in response to thermal stimulus and served as actuators or soft‐robots . Nishiguchi et al used a direct laser writing method to generate sophisticated and controlled folding of thermosensitive hydrogels.…”

Section: Applicationsmentioning

confidence: 99%

“…The printed elastomers were able to undergo shape changes in response to thermal stimulus and served as actuators or soft-robots. [97] Nishiguchi et al [98] used a direct laser writing method to generate sophisticated and controlled folding of thermosensitive hydrogels. The designed hydrogels were capable of biomimetic actuation.…”

Section: Bioactuators and Bioroboticsmentioning

confidence: 99%

Advances and Future Perspectives in 4D Bioprinting

Ashammakhi

Ahadian

Fan

et al. 2018

Biotechnology Journal

187

106

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Three-dimensionally printed constructs are static and do not recapitulate the dynamic nature of tissues. Four-dimensional (4D) bioprinting has emerged to include conformational changes in printed structures in a predetermined fashion using stimuli-responsive biomaterials and/or cells. The ability to make such dynamic constructs would enable an individual to fabricate tissue structures that can undergo morphological changes. Furthermore, other fields (bioactuation, biorobotics, and biosensing) will benefit from developments in 4D bioprinting. Here, the authors discuss stimuli-responsive biomaterials as potential bioinks for 4D bioprinting. Natural cell forces can also be incorporated into 4D bioprinted structures. The authors introduce mathematical modeling to predict the transition and final state of 4D printed constructs. Different potential applications of 4D bioprinting are also described. Finally, the authors highlight future perspectives for this emerging technology in biomedicine.

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4D Printed Actuators with Soft‐Robotic Functions

Cited by 291 publications

References 27 publications

Shape changing hydrogels and their applications as soft actuators

Shape changing hydrogels and their applications as soft actuators

Photoreversible Soft Azo Dye Materials: Toward Optical Control of Bio‐Interfaces

Advances and Future Perspectives in 4D Bioprinting

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