Adhesive and Injectable Hydrogel Microspheres for Inner Ear Treatment.

The least damaging and most economical method to deliver drugs or carriers into the inner ear for treatment of disease is through the middle ear. However, the retention of drug in the middle ear is an obstacle. Here, inspired by the adhesion of mussels, a methacrylate gelatin microspheres (GM) coupling polydopamine (PDA) layer (GM@PDA) with excellent adhesive ability is constructed, and Ebselen liposomes are further loaded into the GM@PDA (GM@PDA@Lipo-Ebselen). The loading capacity of GM@PDA for Ebselen liposomes is 25 ± 1 µg mg-1 microspheres. GM@PDA@Lipo-Ebselen could be injected on round windows membrane (RWM) and tightly adheres to the surface of RWM by PDA, and the microspheres are even still attached to the RWM after 360° rotation and inverted shaking. The in vivo imaging system shows that the adhesive microspheres can prolong the retention of the middle ear cavity for more than 7 days. The hearing of mice in the GM@PDA@Lipo-Ebselen group is significantly recovered, especially on day 14 after noise exposure, and the hearing of each frequency is restored to baseline level. At 32 kHz frequency, the survival of outer hair cells recovers from 48 0± 6% to 93 ± 2%. Therefore, the adhesive and injectable hydrogel microspheres provide a promising strategy for the treatment of hearing loss.

Recent trends on burn wound care: hydrogel dressings and scaffolds.

Acute and chronic wounds can cause severe physical trauma to patients and also result in an immense socio-economic burden. Thus, wound management has attracted increasing attention in recent years. However, burn wound management is still a major challenge in wound management. Autografts are often considered the gold-standard for burn care, but their application is limited by many factors. Hence, ideal burn dressings and skin substitute dressings are desirable. With the development of biomaterials and progress of tissue engineering technology, some innovative dressings and tissue engineering scaffolds, such as nanofibers, films, foams and hydrogels, have been widely used in the field of biomedicine, especially in wound management. Among them, hydrogels have attracted tremendous attention with their unique advantages. In this review, we discuss the challenges in burn wound management, several crucial design considerations with respect to hydrogels for burn wound healing, and available polymers for hydrogels in burn wound care. In addition, the potential application and plausible prospect of hydrogels are also highlighted.

Dual cure (thermal/photo) composite hydrogel derived from chitosan/collagen for in situ 3D bioprinting.

In situ 3D printing technologies is a new frontier for highly personalized medicine, which requires suitable bioink with rheology, biocompatibility, and gelation kinetics to support the right shape and mechanical properties of the printed construct. To this end, a facile design of thermo/photo dual cure composite hydrogel was proposed using MHBC and soluble collagen in this study. M/C composite hydrogel exhibited rapid thermo-induced sol-gel transition and contraction, tunable mechanical properties, proper microstructure and biodegradability for 3D cell culture, as well as improve cyto-compatibility, all of which were dependent upon the methacrylation degree of MHBC and M/C ratios. The printability of the optimal formulation (3% MHBC/1% collagen) was validated by its mild printing condition, rapid gelation of bioink at 37 °C and simple postprocessing manipulation. Both desirable printability and cyto-compatibility enable M/C composite hydrogel a potential candidate as bioink to be applied for in situ 3D bioprinting.

Research status of self-healing hydrogel for wound management: A review.

Wound management has attracted significant interest in view of the broad demand market. Dressings are playing crucial roles in wounds management because they can protect the wound from external infection, and accelerate the healing process. Among the various available dressing materials, hydrogels have appealed increasing attention for their tunable chemical, physical and biological properties, and three-dimensional cross-linked polymer networks which can absorb and retain large amount of water. Although hydrogels have become representative of soft dressing materials, the design of conventional hydrogel materials still needs improvement. Nowadays, novel self-healing hydrogel wound dressings hopefully optimize the defects of mechanical property over conventional hydrogel thus extend their usage lifespan due to their potential of autonomous self-recovery against damage, which have gained much momentum recently. This presented review mainly focuses on research status of self-healing hydrogel for wound management. The polymers suitable for hydrogel forming, and the appropriate molecular design of the hydrogel network for achieving self-healing properties are discussed, followed by the applications of self-healing hydrogel as wound dressing. Finally, we discuss the future perspectives of self-healing hydrogel as wound dressing, and provide the recommendations for its possible developing orientation.