Thermally actuated hydrogel bead based braided artificial muscle

Salahuddin, Bidita; Spinks, Geoffrey M.

doi:10.1088/1361-665x/ab79ba

Cited by 19 publications

(14 citation statements)

References 30 publications

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“…Artificial muscle can also be made of a gel sample inserted into a macroscopic system inspired by pneumatic soft robotics [39][40][41] . The gel act as the pressurized fluid for pneumatic muscle: when the gel swells, it applies a pressure on the walls of the soft muscle inducing its displacement.…”

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confidence: 99%

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A macroporous smart gel based on a pH-sensitive polyacrylic polymer for the development of large size artificial muscles with linear contraction

Mansard

2021

Soft Matter

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confidence: 99%

“…Only few prototypes of muscle integrate a porous material [39][40][41]48,63,64 . Tondu et al 40,41 built a muscle with large size and high strength based on porous gel.…”

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confidence: 99%

A macroporous smart gel based on a pH-sensitive polyacrylic polymer for the development of large size artificial muscles with linear contraction

Mansard

2021

Soft Matter

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“…Particles made up of natural polymers, such as alginate, chitosan, and gelatin, have found a wide range of applications in the food, cosmetic, biomedicine, agriculture, and pharmaceutical industries due to their abundance, biodegradability, low toxicity, high binding capacity to specific chemical species, and biocompatibility, and their ability to adsorb or release molecules in response to external stimuli. They have been used extensively in drug delivery [11], e.g., encapsulation of islet cells capable of releasing insulin [12,13]; biosensors [14] and actuators [15]; scaffolds for cell culture in tissue engineering [16][17][18]; sorbents [19]; and encapsulation of enzymes and cells [20,21]. Different structures of microparticles are paving the way to a wide variety of applications.…”

Section: Introductionmentioning

confidence: 99%

Characterization of Fluidic-Barrier-Based Particle Generation in Centrifugal Microfluidics

et al. 2022

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The fluidic barrier in centrifugal microfluidic platforms is a newly introduced concept for making multiple emulsions and microparticles. In this study, we focused on particle generation application to better characterize this method. Because the phenomenon is too fast to be captured experimentally, we employ theoretical models to show how liquid polymeric droplets pass a fluidic barrier before crosslinking. We explain how secondary flows evolve and mix the fluids within the droplets. From an experimental point of view, the effect of different parameters, such as the barrier length, source channel width, and rotational speed, on the particles' size and aspect ratio are investigated. It is demonstrated that the barrier length does not affect the particle's ultimate velocity. Unlike conventional air gaps, the barrier length does not significantly affect the aspect ratio of the produced microparticles. Eventually, we broaden this concept to two source fluids and study the importance of source channel geometry, barrier length, and rotational speed in generating two-fluid droplets.

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“…10 The flexibility of hydrogels is similar to biological tissues and reduces the material's stimulation on surroundings, which makes hydrogel an ideal biological material. Stimulus-responsive hydrogels have been extensively applied as biosensors for detecting RNA, 11 artificial muscles for the rehabilitation of sports injuries, 12 and controllable drug delivery carriers for disease treatment. 13,14 The mechanism of pH response is mostly related to the pendant groups on the polymer network.…”

Section: Introductionmentioning

confidence: 99%

Self‐crosslinked poly‐L‐ornithine and poly‐L‐arginine networks: Synthesis, characterization, pH‐responsibility, biocompatibility, and AIE‐functionality

Tong

Bai

et al. 2021

J of Applied Polymer Sci

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A pH‐responsive hydrogel consists of polypeptides only is a promising biomaterial with the advantages of good biocompatibility and non‐toxicity. This work reports the synthesis of poly‐L‐ornithine(poc) (polyLOpoc) serving as the precursor for hydrogels of poly‐L‐ornithine (polyOrn) and poly(L‐arginine‐r‐L‐ornithine) (poly(Arg‐r‐Orn)). Their controllable degree of crosslinking, good mechanical properties, good biocompatibility, and pH‐responsibility are detailedly investigated. The swelling ratio of polyOrn hydrogel in acidic aqueous solution is 5.7 times higher than that in a basic environment. In the deprotection of phenoxycarbonyl group, polyLOpoc releases amino pendant groups, which attack the remaining poc‐protected amino groups to fulfill self‐crosslinking without any crosslinking agent. In addition, the pH‐responsive behavior of hydrogels is visualized by aggregation‐induced emission phenomena with polyOrn and poly(Arg‐r‐Orn) containing tetrakis(4‐aminophenyl)ethene moisture.

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Thermally actuated hydrogel bead based braided artificial muscle

Cited by 19 publications

References 30 publications

A macroporous smart gel based on a pH-sensitive polyacrylic polymer for the development of large size artificial muscles with linear contraction

A macroporous smart gel based on a pH-sensitive polyacrylic polymer for the development of large size artificial muscles with linear contraction

Characterization of Fluidic-Barrier-Based Particle Generation in Centrifugal Microfluidics

Self‐crosslinked poly‐L‐ornithine and poly‐L‐arginine networks: Synthesis, characterization, pH‐responsibility, biocompatibility, and AIE‐functionality

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