4D Multimaterial Printing of Soft Actuators with Spatial and Temporal Control

Zhou, Kun; Sun, Rujie; Wojciechowski, Jonathan P.; Wang, Richard; Yeow, Jonathan; Zuo, Yuyang; Song, Xin; Wang, Chunliang; Shao, Yue; Stevens, Molly M.

doi:10.1002/adma.202312135

Cited by 8 publications

(2 citation statements)

References 50 publications

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“…Magnetic hydrogels (MHGs) have extensive tissue engineering and biomedical applications and possess the advantages of quick response, biocompatibility, tunable mechanical properties, porosity, and internal morphology ( Asadi et al, 2024 ; Liu et al, 2024 ). MHGs can be fabricated by blending exogenous additives (e.g., paramagnetic, ferromagnetic) in the polymeric matrix and placing the matrix in a magnetic field (static or oscillating) ( Zhou K. et al, 2024 ; Zhang K. et al, 2024 ).…”

Section: Application Of Exogenous Stimulus-responsive In Si...mentioning

confidence: 99%

Smart responsive in situ hydrogel systems applied in bone tissue engineering

Wu,

Gai,

Chen

et al. 2024

Front. Bioeng. Biotechnol.

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The repair of irregular bone tissue suffers severe clinical problems due to the scarcity of an appropriate therapeutic carrier that can match dynamic and complex bone damage. Fortunately, stimuli-responsive in situ hydrogel systems that are triggered by a special microenvironment could be an ideal method of regenerating bone tissue because of the injectability, in situ gelatin, and spatiotemporally tunable drug release. Herein, we introduce the two main stimulus-response approaches, exogenous and endogenous, to forming in situ hydrogels in bone tissue engineering. First, we summarize specific and distinct responses to an extensive range of external stimuli (e.g., ultraviolet, near-infrared, ultrasound, etc.) to form in situ hydrogels created from biocompatible materials modified by various functional groups or hybrid functional nanoparticles. Furthermore, “smart” hydrogels, which respond to endogenous physiological or environmental stimuli (e.g., temperature, pH, enzyme, etc.), can achieve in situ gelation by one injection in vivo without additional intervention. Moreover, the mild chemistry response-mediated in situ hydrogel systems also offer fascinating prospects in bone tissue engineering, such as a Diels–Alder, Michael addition, thiol-Michael addition, and Schiff reactions, etc. The recent developments and challenges of various smart in situ hydrogels and their application to drug administration and bone tissue engineering are discussed in this review. It is anticipated that advanced strategies and innovative ideas of in situ hydrogels will be exploited in the clinical field and increase the quality of life for patients with bone damage.

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Section: Application Of Exogenous Stimulus-responsive In Si...mentioning

confidence: 99%

Smart responsive in situ hydrogel systems applied in bone tissue engineering

Wu,

Gai,

Chen

et al. 2024

Front. Bioeng. Biotechnol.

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show abstract

“…The fourth dimension refers to the capability of a 3D-printed object to transform over time when subjected to external stimuli. Through the design of material systems and control of the manufacturing process, 4D-printed products are programmed with the self-morphing functionality that can be activated by various environmental changes such as heat [2][3][4][5][6][7][8][9], moisture [10][11][12][13][14][15], pH [16][17][18][19][20], electricity [21][22][23][24], and magnetic field [25][26][27][28][29][30]. It offers the possibilities to fabricate objects that can self-transform from simple into complex geometries, reducing the need for support structures, minimizing the production time, and saving manufacturing costs.…”

Section: Introductionmentioning

confidence: 99%

Interrelations between Printing Patterns and Residual Stress in Fused Deposition Modelling for the 4D Printing of Acrylonitrile Butadiene Styrene and Wood–Plastic Composites

Huang,

Löschke,

Gan

et al. 2024

JMMP

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Four dimensional printing enables the advanced manufacturing of smart objects that can morph and adapt shape over time in response to stimuli such as heat. This study presents a single-material 4D printing workflow which explores the residual stress and anisotropy arising from the fused deposition modelling (FDM) printing process to create heat-triggered self-morphing objects. In particular, the study first investigates the effect of printing patterns on the residual stress of FDM-printed acrylonitrile butadiene styrene (ABS) products. Through finite element analysis, the raster angle of printing patterns was identified as the key parameter influencing the distribution of residual stresses. Experimental investigations further reveal that the non-uniform distribution of residual stress results in the anisotropic thermal deformation of printed materials. Thus, through the design of printing patterns, FDM-printed materials can be programmed with desired built-in residual stresses and anisotropic behaviours for initiating and controlling the transformation of 4D-printed objects. Using the proposed approach, any desktop FDM printers can be turned into 4D printers to create smart objects that can self-morph into target geometries. A series of 4D printing prototypes manufactured from conventional ABS 3D printing feedstock are tested to illustrate the use and reliability of this new workflow. Additionally, the custom-made wood–plastic composite (WPC) feedstocks are explored in this study to demonstrate the transposability of the 4D printing approach.

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Advances in 4D Bioprinting: The Next Frontier in Regenerative Medicine and Tissue Engineering Applications

Abolhassani,

fattahi,

Safshekan

et al. 2024

Adv Healthcare Materials

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Abstract4D bioprinting is a critical advancement in tissue engineering and regenerative medicine (TERM), enabling the creation of structures that dynamically respond to environmental stimuli over time. This review investigates various fabrication techniques and responsive materials that are central to these fields. It underscores the integration of multi‐material and biocomposite approaches in 4D bioprinting, which is crucial for fabricating complex and functional constructs with heterogeneous properties. Using 4D bioprinting techniques enhances the mimicry of natural tissue characteristics, offering tailored responses and improved integration with biological systems. Furthermore, this study highlights the synergy between 4D bioprinting and tissue engineering and demonstrates the technology's potential for developing tissues and organs. In regenerative medicine, 4D bioprinting's applications extend to creating smart implants and advanced drug delivery systems that adapt to the body's changes, promoting healing and tissue regeneration. Finally, the challenges and future directions of 4D bioprinting are also explored and emphasize its transformative impact on biomedical engineering and the future of healthcare.

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4D Multimaterial Printing of Soft Actuators with Spatial and Temporal Control

Cited by 8 publications

References 50 publications

Smart responsive in situ hydrogel systems applied in bone tissue engineering

Smart responsive in situ hydrogel systems applied in bone tissue engineering

Interrelations between Printing Patterns and Residual Stress in Fused Deposition Modelling for the 4D Printing of Acrylonitrile Butadiene Styrene and Wood–Plastic Composites

Advances in 4D Bioprinting: The Next Frontier in Regenerative Medicine and Tissue Engineering Applications

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