Self-recovering dual cross-linked hydrogels based on bioorthogonal click chemistry and ionic interactions.

The biocompatible, injectable and high water-swollen nature of hydrogels makes them a popular candidate to imitate the extracellular matrix (ECM) for tissue engineering both in vitro and in vivo. However, commonly used covalently cross-linked hydrogels, despite their stability and tunability, are elastic and deteriorate as bulk material degrades which would impair proper cell function. To improve these deficiencies, here, we present a self-recovering cross-linked hydrogel formed instantaneously with functionalized poly(ethylene glycol) as a basis. We combine covalent cross-links introduced via a strain-promoted azide-alkyne cycloaddition (SPAAC) click reaction and non-covalent links between phosphonate groups and calcium ions. By adjusting the ratios of non-covalent and covalent cross-links, we synthesized these dual cross-linked (DC) hydrogels that displayed storage moduli below ∼2000 Pa and relaxation times from seconds to minutes. The gels recovered to 41-96% of their initial mechanical properties after two subsequent strain failures. Cryo-scanning electron microscopy revealed that DC hydrogels containing approximately equal amounts of covalent and non-covalent cross-links displayed phase separation. Finally, we functionalized the DC hydrogels by incorporating an integrin binding motif, RGDS, to provide a biocompatible environment for human mesenchymal stem cells (HMSCs) by facilitating adhesion inside the gel network. Inside these DC gels HSMCs displayed a viability up to 73% after five days of cell culture.

Comparison of Bioorthogonally Cross-Linked Hydrogels for in Situ Cell Encapsulation.

Hydrogels are water-saturated polymer networks and extensively used in drug delivery, tissue repair engineering, and cell cultures. For encapsulation of drugs or cells, the possibility to form hydrogels in situ is very much desired. This can be achieved in numerous ways, including use of bioorthogonal chemistry to create polymer networks. Here we report a set of bioorthogonally clickable polymers that was designed with the aim to find a combination that could rapidly encapsulate cells in a three-dimensional manner to improve the preparation of hydrogels as tissue mimics. To this end, tetrazine (Tet), trans-cyclooctene (TCO), azide (N3), dibenzocyclooctyne (DBCO), bicyclo[6.1.0]nonyne (BCN), 3,4-dihydroxyphenylacetic acid (DHPA), and norbornene (Norb) were grafted to four-armed poly(ethylene)glycol (star-PEG) polymers of 10 kDa. Inverted vial tests and rheology demonstrated that hydrogels formed within seconds from combinations of TCO-Tet, BCN-DHPA, and BCN-Tet. Hydrogels from DBCO-N3, DBCO-DHPA, and BCN-N3 formed in the range of minutes, whereas the Norb-Tet ligation required multiple hours to form a gel. After this comparison, we chose to prepare hydrogels via DBCO-N3 and BCN-N3 and employed them for human mesenchymal stem cell (HMSC) cultures for a period of 5 days. We additionally incorporated RGDS and MMP cleavable peptide (MMPcp) motifs in these gels to stimulate cell adhesion and add degradability. Both DBCO and BCN gel systems including the functional peptide motifs allowed HMSCs to be viable and spread in 5 days. The DBCO-based hydrogel could trap cells at different depths due to its fast gelation process, while the slower gelation of the BCN-based hydrogel led to cell sedimentation.

Preparation and Performance of Poly(D,L-lactic acid)­Polyethylene Glycol­Poly(D,L-lactic acid) Electrospun Fibrous Membranes for Drug Release.

In this study, poly(D,L-lactic acid)­polyethylene glycol­poly(D,L-lactic acid), hereafter referred to as PDLLA­PEG­PDLLA, triblock copolymer membranes were prepared by electrospinning. Scanning electron microscopy images revealed the morphology of the microfibers, which had a diameter ranging from 300 to 900 nm. Fourier transform infrared spectroscopy was employed for structural analysis of the PDLLA­PEG­PDLLA/florfenicol (FF) membranes, which exhibited three absorption peaks at 3455, 1684, and 1533 cm−1, respectively, indicating that the triblock copolymer and FF are very well blended in the composite membranes. Differential scanning calorimetry revealed that weak interaction possibly decreased the activity of the segment and elevated the T g from 43 °C to 46 °C. From the in vitro dissolution tests, PDLLA as a biodegradable and biocompatible polymer can improve the solubility of FF. The rate of drug release increased with increasing PEG proportion. Furthermore, tensile and nanoindentation tests demonstrated that nanofibers exhibit mechanical properties such as tensile stress (700­2800 KPa), strain (40­120%), and good toughness (0.28­0.98 GPa). In conclusion, PDLLA­PEG­PDLLA nanofibers as a carrier improve the solubility of FF and control drug release.