Hydrogels such as poly(N-isopropylacrylamide-co-acrylic acid) (pNIPAM-AAc)
can be photopatterned to create a wide range of actuatable and self-folding
microstructures. Mechanical motion is derived from the large and reversible
swelling response of this cross-linked hydrogel in varying thermal
or pH environments. This action is facilitated by their network structure
and capacity for large strain. However, due to the low modulus of
such hydrogels, they have limited gripping ability of relevance to
surgical excision or robotic tasks such as pick-and-place. Using experiments
and modeling, we design, fabricate, and characterize photopatterned,
self-folding functional microgrippers that combine a swellable, photo-cross-linked
pNIPAM-AAc soft-hydrogel with a nonswellable and stiff segmented polymer
(polypropylene fumarate, PPF). We also show that we can embed iron
oxide (Fe2O3) nanoparticles into the porous
hydrogel layer, allowing the microgrippers to be responsive and remotely
guided using magnetic fields. Using finite element models, we investigate
the influence of the thickness and the modulus of both the hydrogel
and stiff polymer layers on the self-folding characteristics of the
microgrippers. Finally, we illustrate operation and functionality
of these polymeric microgrippers for soft robotic and surgical applications.
We describe the self-folding of photopatterned poly (ethylene glycol) (PEG)-based hydrogel bilayers into curved and anatomically relevant micrometer-scale geometries. The PEG bilayers consist of two different molecular weights (MWs) and are photocrosslinked en masse using conventional photolithography. Self-folding is driven by differential swelling of the two PEG bilayers in aqueous solutions. We characterize the self-folding of PEG bilayers of varying composition and develop a finite element model which predicts radii of curvature that are in good agreement with empirical results. Since we envision the utility of bio-origami in tissue engineering, we photoencapsulate insulin secreting β-TC-6 cells within PEG bilayers and subsequently self-fold them into cylindrical hydrogels of different radii. Calcein AM staining and ELISA measurements are used to monitor cell proliferation and insulin production respectively, and the results indicate cell viability and robust insulin production for over eight weeks in culture.
We describe a photolithographic approach to create functional stimuli responsive, self-folding, microscale hydrogel devices using thin, gradient cross-linked hinges and thick, fully cross-linked panels. The hydrogels are composed of poly (N-isopropylacrylamide-co-acrylic acid) (pNIPAM-AAc) with reversible stimuli responsive properties just below physiological temperatures. We show that a variety of three-dimensional structures can be formed and reversibly actuated by temperature or pH. We experimentally characterized the swelling and mechanical properties of pNIPAM-AAc and developed a finite element model to rationalize self-folding and its variation with hinge thickness and swelling ratio. Finally, we highlight applications of this approach in the creation of functional devices such as self-folding polymeric micro-capsules, untethered micro-grippers and thermally steered micro-mirror systems.
4D printing is an emerging fabrication technology that enables 3D printed structures to change configuration over “time” in response to an environmental stimulus. Compared with other soft active materials used for 4D printing, shape‐memory polymers (SMPs) have higher stiffness, and are compatible with various 3D printing technologies. Among them, ultraviolet (UV)‐curable SMPs are compatible with Digital Light Processing (DLP)‐based 3D printing to fabricate SMP‐based structures with complex geometry and high‐resolution. However, UV‐curable SMPs have limitations in terms of mechanical performance, which significantly constrains their application ranges. Here, a mechanically robust and UV‐curable SMP system is reported, which is highly deformable, fatigue resistant, and compatible with DLP‐based 3D printing, to fabricate high‐resolution (up to 2 µm), highly complex 3D structures that exhibit large shape change (up to 1240%) upon heating. More importantly, the developed SMP system exhibits excellent fatigue resistance and can be repeatedly loaded more than 10 000 times. The development of the mechanically robust and UV‐curable SMPs significantly improves the mechanical performance of the SMP‐based 4D printing structures, which allows them to be applied to engineering applications such as aerospace, smart furniture, and soft robots.
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