3D printing technology has been widely explored for the rapid design and fabrication of hydrogels, as required by complicated soft structures and devices. Here, a new 3D printing method is presented based on the rheology modifier of Carbomer for direct ink writing of various functional hydrogels. Carbomer is shown to be highly efficient in providing ideal rheological behaviors for multifunctional hydrogel inks, including double network hydrogels, magnetic hydrogels, temperature-sensitive hydrogels, and biogels, with a low dosage (at least 0.5% w/v) recorded. Besides the excellent printing performance, mechanical behaviors, and biocompatibility, the 3D printed multifunctional hydrogels enable various soft devices, including loadable webs, soft robots, 4D printed leaves, and hydrogel Petri dishes. Moreover, with its unprecedented capability, the Carbomer-based 3D printing method opens new avenues for bioprinting manufacturing and integrated hydrogel devices.
Hydrogels—natural or synthetic polymer networks that swell in water—can be made mechanically, chemically, and electrically compatible with living tissues. There has been intense research and development of hydrogels for medical applications since the invention of the hydrogel contact lenses in 1960. More recently, functional hydrogel coatings with controlled thickness and tough adhesion have been achieved on various substrates. Hydrogel-coated substrates combine the advantages of hydrogels, such as lubricity, biocompatibility, and anti-biofouling properties, with the advantages of the substrates, such as stiffness, toughness, and strength. In this review, we focus on three aspects of functional hydrogel coatings: (1) applications and functions enabled by hydrogel coatings, (2) methods of coating various substrates with different functional hydrogels with tough adhesion, and (3) tests to evaluate the adhesion between functional hydrogel coatings and substrates. Conclusions and outlook are given at the end of this review.
As
one of the most promising drug delivery carriers, hydrogels have received
considerable attention in recent years. Many previous efforts have
focused on diffusion-controlled release, which allows hydrogels to
load and release drugs in vitro and/or in vivo. However, it hardly
applies to lipophilic drug delivery due to their poor compatibility
with hydrogels. Herein, we propose a novel method for lipophilic drug
release based on a dual pH-responsive hydrogel actuator. Specifically,
the drug is encapsulated and can be released by a dual pH-controlled
capsule switch. Inspired by the deformation mechanism of Drosera leaves,
we fabricate the capsule switch with a double-layer structure that
is made of two kinds of pH-responsive hydrogels. Two layers are covalently
bonded together through silane coupling agents. They can bend collaboratively
in a basic or acidic environment to achieve the “turn on”
motion of the capsule switch. By incorporating an array of parallel
elastomer stripes on one side of the hydrogel bilayer, various motions
(e.g., bending, twisting, and rolling) of the hydrogel bilayer actuator
were achieved. We conducted an in vitro lipophilic drug release test.
The feasibility of this new drug release method is verified. We believe
this dual pH-responsive actuator-controlled drug release method may
shed light on the possibilities of various drug delivery systems.
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