Kneading-Dough-Inspired Quickly Dispersing of Hydrophobic Particles into Aqueous Solutions for Designing Functional Hydrogels.

Hydrogels containing hydrophobic materials have attracted great attention for their potential applications in drug delivery and biosensors. This work presents a kneading-dough-inspired method for dispersing hydrophobic particles (HPs) into water. The kneading process can quickly mix HPs with polyethyleneimine (PEI) polymer solution to form "dough", which facilitates the formation of stable suspensions in aqueous solutions. Combining with photo or thermal curing processes, one type of HPs incorporated PEI-polyacrylamide (PEI/PAM) composite hydrogel exhibiting good self-healing ability, tunable mechanical property is synthesized. The incorporating of HPs into the gel network results in the decrease in the swelling ratio, as well as the enhancement of the compressive modulus by more than five times. Moreover, the stable mechanism of polyethyleneimine-modified particles has been investigated using surface force apparatus, where the pure repulsion during approaching contributes to the good stability of the suspension. The stabilization time of the suspension is dependent on the molecular weight of PEI: the higher the molecular weight is, the better the stability of the suspension will be. Overall, this work demonstrates a useful strategy to introduce HPs into functional hydrogel networks. Future research can be focused on understanding the strengthening mechanism of HPs in the gel networks.

Manufacturing and post-engineering strategies of hydrogel actuators and sensors: From materials to interfaces.

Living bodies are made of numerous bio-sensors and actuators for perceiving external stimuli and making movement. Hydrogels have been considered as ideal candidates for manufacturing bio-sensors and actuators because of their excellent biocompatibility, similar mechanical and electrical properties to that of living organs. The key point of manufacturing hydrogel sensors/actuators is that the materials should not only possess excellent mechanical and electrical properties but also form effective interfacial connections with various substrates. Traditional hydrogel normally shows high electrical resistance (~ MΩ•cm) with limited mechanical strength (<1 MPa), and it is prone to fatigue fracture during continuous loading-unloading cycles. Just like iron should be toughened and hardened into steel, manufacturing and post-treatment processes are necessary for modifying hydrogels. Besides, advanced design and manufacturing strategies can build effective interfaces between sensors/actuators and other substrates, thus enhancing the desired mechanical and electrical performances. Although various literatures have reviewed the manufacture or modification of hydrogels, the summary regarding the post-treatment strategies and the creation of effective electrical and mechanically sustainable interfaces are still lacking. This paper aims at providing an overview of the following topics: (i) the manufacturing and post-engineering treatment of hydrogel sensors and actuators; (ii) the processes of creating sensor(actuator)-substrate interfaces; (iii) the development and innovation of hydrogel manufacturing and interface creation. In the first section, the manufacturing processes and the principles for post-engineering treatments are discussed, and some typical examples are also presented. In the second section, the studies of interfaces between hydrogels and various substrates are reviewed. Lastly, we summarize the current manufacturing processes of hydrogels, and provide potential perspectives for hydrogel manufacturing and post-treatment methods.

Ferroferric oxide loaded near-infrared triggered photothermal microneedle patch for controlled drug release.

HYPOTHESIS: The drug release efficiency of microneedle is usually slower than that of oral delivery or hypodermic injection, which severely restricts its widespread use. Herein, a Fe3O4-loaded photothermal microneedle (Fe3O4@MN) patch is developed for controlled drug delivery. Under near infrared (NIR) irradiation, the drug loaded on Fe3O4@MN can be quickly released, achieving an enhanced drug release efficiency. EXPERIMENTS: The mechanical property and characterization of Fe3O4@MN were systematically investigated, and the photothermal performance of Fe3O4@MN was also conducted. Moreover, the model-drug-releasing tests and doxycycline hydrochloride releasing tests were carried out to evaluate the drug release performance of Fe3O4@MN under NIR irradiation. FINDINGS: Fe3O4@MN has enough mechanical strength to pierce into skins, and the temperature of Fe3O4@MN patch could rapidly increase by 40 â„ƒ in 1 min under NIR irradiation. In vitro experiment, the release rate of model drug in Fe3O4@MN reached âˆ¼ 80 % in 20 min and the doxycycline hydrochloride release rate of Fe3O4@MN reached âˆ¼ 70 % after 20 min of NIR irradiation, indicating the potential application of the synthesized microneedle patch for transdermal drug delivery. Further penetration test showed that the penetration depth of model drugs carried by Fe3O4@MN patch on the porcine skin under NIR irradiation was 150 - 200 µm longer than that of the patch without Fe3O4 nanoparticles.