Multi-material bio-fabrication of hydrogel cantilevers and actuators with stereolithography

Chan, Vincent; Jeong, Jae Hyun; Bajaj, Preeti; Collens, Mitchell B.; Saif, Taher A.; Kong, Hyunjoon; Bashir, Rashid

doi:10.1039/c1lc20688e

Cited by 158 publications

(146 citation statements)

References 51 publications

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“…For example, Morris et al fabricated ear-shaped scaffolds consisting of chitosan and polyethylene glycol diacrylate (PEGDA) that contained a macroporous interconnective pore structure, [93] Elomaa et al created photocrosslinkable PEG-co-polydepsipeptide macromer to fabricate cell-laden hydrogels, [94] and Chan et al used a commercial stereolithographic printer to prepare 3D structured PEG-based hydrogels. [95,96] The clear advantage of 3D printing over all other described techniques is the precise detail on pore shape, alignment, size, and structure that can be designed into the product, as the resulting pore structure is neither the product of thermodynamics (emulsification), fluid mechanics (porogen distribution in the matrix), nor random events (nucleate evaporation in gas foaming, whipping in electrospinning). Such level of control may be particularly useful in tissue engineering applications to create well-defined geometric niches to direct cell behavior [88] in a way not possible with other techniques for fabricating structured macroporous hydrogels.…”

Section: D Printingmentioning

confidence: 99%

Structured Macroporous Hydrogels: Progress, Challenges, and Opportunities

Hoare

2017

Adv Healthcare Materials

155

163

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Structured macroporous hydrogels that have controllable porosities on both the nanoscale and the microscale offer both the swelling and interfacial properties of bulk hydrogels as well as the transport properties of “hard” macroporous materials. While a variety of techniques such as solvent casting, freeze drying, gas foaming, and phase separation have been developed to fabricate structured macroporous hydrogels, the typically weak mechanics and isotropic pore structures achieved as well as the required use of solvent/additives in the preparation process all limit the potential applications of these materials, particularly in biomedical contexts. This review highlights recent developments in the field of structured macroporous hydrogels aiming to increase network strength, create anisotropy and directionality within the networks, and utilize solvent‐free or additive‐free fabrication methods. Such functional materials are well suited for not only biomedical applications like tissue engineering and drug delivery but also selective filtration, environmental sorption, and the physical templating of secondary networks.

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Section: D Printingmentioning

confidence: 99%

Structured Macroporous Hydrogels: Progress, Challenges, and Opportunities

Hoare

2017

Adv Healthcare Materials

155

163

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“…This advantageous property has helped to produce machines that include selfassembling microelectromechanical-system-based cantilevers (15), 2D biohybrid "muscular thin films" (16), and "crab-like" robots (17). These systems were powered by applied electric field stimulation or spontaneous contraction of engineered cardiac muscle, which have also been used as power sources for locomotive machines such as a swimming muscle-elastomer "jellyfish" (18), a self-propelled swimming robot (19), and a walking millimeter-scale "biological bimorph" cantilever (20,21), respectively.…”

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confidence: 99%

Three-dimensionally printed biological machines powered by skeletal muscle

Cvetkovic

Raman

Chan

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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337

371

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Combining biological components, such as cells and tissues, with soft robotics can enable the fabrication of biological machines with the ability to sense, process signals, and produce force. An intuitive demonstration of a biological machine is one that can produce motion in response to controllable external signaling. Whereas cardiac cell-driven biological actuators have been demonstrated, the requirements of these machines to respond to stimuli and exhibit controlled movement merit the use of skeletal muscle, the primary generator of actuation in animals, as a contractile power source. Here, we report the development of 3D printed hydrogel "bio-bots" with an asymmetric physical design and powered by the actuation of an engineered mammalian skeletal muscle strip to result in net locomotion of the bio-bot. Geometric design and material properties of the hydrogel bio-bots were optimized using stereolithographic 3D printing, and the effect of collagen I and fibrin extracellular matrix proteins and insulin-like growth factor 1 on the force production of engineered skeletal muscle was characterized. Electrical stimulation triggered contraction of cells in the muscle strip and net locomotion of the bio-bot with a maximum velocity of ∼156 μm s −1 , which is over 1.5 body lengths per min. Modeling and simulation were used to understand both the effect of different design parameters on the bio-bot and the mechanism of motion. This demonstration advances the goal of realizing forward-engineered integrated cellular machines and systems, which can have a myriad array of applications in drug screening, programmable tissue engineering, drug delivery, and biomimetic machine design.bioactuator | stereolithography

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“…For instance, photopatterning methods, in which the cell/prepolymer (e.g., PEG diacrylate) solution is exposed to UV light through a photomask, have been utilized to create constructs with a spectrum of shapes and sizes as well as multilayer hydrogels with different cell types and modular architectures , Hahn et al 2006, Liu Tsang et al 2007, Liu & Bhatia 2002, Revzin et al 2001, Underhill et al 2007). Laser-based stereolithography techniques also have been applied to the fabrication of multilayer PEG hydrogels, including composite systems incorporating tethered ECM molecules such as collagen (Chan et al 2010(Chan et al , 2012. Microscale patterning of 3D hydrogels has been shown to improve the viability of encapsulated cells by mitigating the nutrient-delivery limitations present in a bulk gel configuration (Liu Tsang et al 2007).…”

Section: Fabrication and Patterning Of Complex Architecturesmentioning

confidence: 99%

Bioengineering Methods for Analysis of Cells In Vitro

Underhill¹,

Galie

Chen

et al. 2012

Annu. Rev. Cell Dev. Biol.

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Efforts in the interdisciplinary field of bioengineering have led to innovative methods for investigating the complexities of cell responses in vitro. These approaches have emphasized the reduction of complex multicomponent cellular microenvironments into distinct individual signals as a means to both (a) better construct mimics of in vivo microenvironments and (b) better deconstruct microenvironments to study them. Microtechnology tools, together with advances in biomaterials, have been fundamental to this progress by enabling the tightly controlled presentation of environmental cues and the improved systematic analysis of cellular perturbations. In this review, we describe bioengineering approaches for controlling and measuring cell-environmental interactions in vitro, including strategies for high-throughput analysis. We also describe the mechanistic insights gained by the use of these novel tools, with associated applications ranging from fundamental biological studies, in vitro modeling of in vivo processes, and cell-based therapies.

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Multi-material bio-fabrication of hydrogel cantilevers and actuators with stereolithography

Cited by 158 publications

References 51 publications

Structured Macroporous Hydrogels: Progress, Challenges, and Opportunities

Structured Macroporous Hydrogels: Progress, Challenges, and Opportunities

Three-dimensionally printed biological machines powered by skeletal muscle

Bioengineering Methods for Analysis of Cells In Vitro

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