Controlled Origami Folding of Hydrogel Bilayers with Sustained Reversibility for Robust Microcarriers

Shim, Tae Soup; Kim, Shin‐Hyun; Heo, Chul‐Joon; Jeon, Haemin; Yang, Seung‐Man

doi:10.1002/anie.201106723

Cited by 197 publications

(154 citation statements)

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“…Such microparticles with core-shell structures are especially important for applications such as encapsulation and controlled release, 20 contrast enhancement in ultrasonic imaging and photonics [8][9][10][11][12][13][14]4,2,3 . In these applications, the mechanical properties of core-shell microcapsules are of key importance.…”

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confidence: 99%

“…In these applications, the mechanical properties of core-shell microcapsules are of key importance. Mechanical properties control the conditions under which the core-shell microcapsules are deformed elastically, plastically or even ruptured [15][16][17][18][19][20][21][22][23][24] . They 25 directly determine the volumetric and shape changes of the microcapsules under an applied external stress 25,26 , which for soft and biological materials can be surprisingly large.…”

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confidence: 99%

“…The overall properties of such particles will 15 depend on the bulk properties of both the shell and the core material, as well as the internal structure of the particles. To control and understand the mechanics of these systems, it is thus essential to investigate and understand the relationship between the respective properties of core and shell, their microstructures 20 and their effects on the overall mechanical properties of the microparticles. Based on such understanding, design principles can be established allowing us to precisely tailor the mechanical behavior of composite microparticles to a desired application.…”

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Capillary micromechanics for core–shell particles

et al. 2014

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In this work, we have developed a facile, economical microfluidic approach as well as a simple model 5 description to measure and predict the mechanical properties of composite core-shell microparticles made from materials with dramatically different elastic properties. By forcing the particles through a tapered capillary and analyzing their deformation, the shear and compressive moduli can be measured in one single experiment. We have also formulated theoretical models that accurately capture the moduli of the microparticles in both the elastic and the non-linear deformation regimes. Our results show how the 10 moduli of these core-shell structures depend on the material composition of the core-shell microparticles, as well as on their microstructures. The proposed technique and the understanding enabled by it also provide valuable insights into the mechanical behavior of analogous biomaterials, such as liposomes and cells.

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Capillary micromechanics for core–shell particles

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“…microscopic spheres, with potential applications as drug delivery devices or microrobots. [9] These spheres are composed of an active hydrogel layer, poly(2-hydroxyethyl methacrylate-coacrylic acid), and a passive hydrogel layer, poly(2-hydroxyethyl methacrylate). At basic pH levels, the active layer swelled, forming a closed hollow microsphere.…”

Section: Self-assembly Of Bioinspired Materialsmentioning

confidence: 99%

Biomimicry, Biofabrication, and Biohybrid Systems: The Emergence and Evolution of Biological Design

Raman

Bashir

2017

Adv Healthcare Materials

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how the concept of bioinspiration, or imitating biological design and functionality in synthetic materials, created a new class of "smart" biomimetic materials. Then, we shall discuss how the continuing development of enabling manufacturing technologies, such as 3D printing and microfluidics, has established the separate subdiscipline of biofabrication for tissue engineering, or "building with biology." Finally, we shall investigate the convergence of these two fields into the emerging discipline of biohybrid design, the use of biological materials to power non-natural functional behaviors in synthetic machines. Throughout this report, we will revisit a single class of materials, hydrogels, as a case study of biological design in the context of each subfield, and discuss how the constraints, underlying principles, and end-use applications differ in each case. We will also discuss ethical considerations of biological design, with a special focus on forward engineering non-natural or hypernatural functional behaviors in biohybrid systems. We will conclude with recommendations for implementing biological design into educational curricula, ensuring effective and responsible practices for the next generation of engineers and scientists. Biomimicry and Bioinspired DesignA deeper understanding of the underlying design principles that govern biological systems has inspired the field of biomimicry. [1,2] Observing adaptive phenomena in nature, scientists and engineers have sought to extract the components of biological design responsible for this behavior and replicate the behavior in synthetic materials. Fundamentally, this involves understanding the building blocks or base units from which a biological material is built, the hierarchical assembly of these building blocks, and the interactions and interfaces between them.In this section, we will discuss strategies that engineers and scientists have employed to engineer bioinspired hierarchy, from bottom-up self-assembly and top-down engineered assembly. We will present several key demonstrations of stimulus-responsive hydrogels ranging from the micro-to the macroscale, and investigate novel demonstrations in biomimetic actuation and movement. We will conclude with the remaining challenges in the field of biomimicry and discuss the potential future impact of bioinspired design.The discipline of biological design has a relatively short history, but has undergone very rapid expansion and development over that time. This Progress Report outlines the evolution of this field from biomimicry to biofabrication to biohybrid systems' design, showcasing how each subfield incorporates bioinspired dynamic adaptation into engineered systems. Ethical implications of biological design are discussed, with an emphasis on establishing responsible practices for engineering non-natural or hypernatural functional behaviors in biohybrid systems. This report concludes with recommendations for implementing biological design into educational curricula, ensuring effective and responsible practice...

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“…The shape transformation of soft materials also has potential applications in tissue engineering 23 : differential swelling or shrinkage creates internal stresses in the composite hydrogel sheet and transforms its shape in a specific manner. Biocompatible bilayer structures are used to fabricate tunable micro-capsules applied as robust micro-carriers 24 . Controlled motion of functional materials has various technical applications.…”

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confidence: 99%

Pine cone scale-inspired motile origami

Song

Lee

2017

NPG Asia Mater

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Stimuli-sensitive hydrogels have received attention because of their potential applications in various fields. Stimuli-directed motion offers many practical applications, such as in drug delivery systems and actuators. Directed motion of asymmetric hydrogels has long been designed; however, few studies have investigated the motion control of symmetric hydrogels. We designed a pine cone scale-inspired movable temperature-sensitive symmetric hydrogel that contains Fe 3 O 4 . Alignment of Fe 3 O 4 along the magnetic force is key in motion control in which Fe 3 O 4 acts like fibers in a pine cone scale. Although a homogeneous temperature-sensitive hydrogel cannot respond to a temperature gradient, the Fe 3 O 4 -containing hydrogel demonstrates considerable bending motion. Varying degrees and directions of motion are easily facilitated by controlling the amount and alignment angle of the Fe 3 O 4 . The shape of the hydrogel layer also influences the morphological structure. This study introduced facile and low-cost methods to control various bending motions. These results can be applied to many fields of engineering, including industrial engineering. NPG Asia Materials (2017) 9, e389; doi:10.1038/am.2017.79; published online 16 June 2017 INTRODUCTION Stimuli-responsive hydrogels have received considerable attention in recent decades because of their potential application in the development of multifunctional devices. Various types of stimuli-responsive hydrogels with applications in engineering have been introduced 1-7 . Stimuliresponsive hydrogels can change their shape, surface characteristics, solubility and form. These hydrogels have been used in various practical applications such as in drug delivery systems, cell culture, sensors, pumps and actuators 7-11 . They have been elaborately developed using various fabrication methods to broaden their applications 12,13 .One of the most important advancements in this field is the application of stimuli-responsive hydrogels in motion control in smart functional materials. Stimuli-responsive hydrogels have typically been utilized for motion control, especially in actuators [14][15][16][17][18][19][20] . Motion control is also important in many microscale engineering applications such as flow control in micro-fluidic devices and design of micro actuators 14,21,22 . The shape transformation of soft materials also has potential applications in tissue engineering 23 : differential swelling or shrinkage creates internal stresses in the composite hydrogel sheet and transforms its shape in a specific manner. Biocompatible bilayer structures are used to fabricate tunable micro-capsules applied as robust micro-carriers 24 . Controlled motion of functional materials has various technical applications. Most developed movable hydrogels have anisotropic structures. A typical method of inducing motion is the combination of two different materials into a bilayer structure [25][26][27][28][29] . Owing to the varying volume changes of the two materials, the bilayer exhibits bending/unben...

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Controlled Origami Folding of Hydrogel Bilayers with Sustained Reversibility for Robust Microcarriers

Cited by 197 publications

References 21 publications

Capillary micromechanics for core–shell particles

Capillary micromechanics for core–shell particles

Biomimicry, Biofabrication, and Biohybrid Systems: The Emergence and Evolution of Biological Design

Pine cone scale-inspired motile origami

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