Hydrogels that can be rapidly cross-linked under physiological conditions are beneficial for the engineering of vascularized 3-dimensional (3D) tissues and organs, in particular when cells are embedded at a high cell density or tissues are fabricated using bottom-up processes, including bioprinting and micromolding. Here, we prepared a gelatin-carboxymethylcellulose (CMC) hydrogel that cross-linked rapidly (<30 s) by mixing hydrazide-modified gelatin (gelatin-ADH) and aldehyde-modified CMC (CMC−CHO). Vascular endothelial cells encapsulated in the gelatin-CMC hydrogels were viable and sprouted readily, indicating that the hydrogels and their crosslinking reactions were cytocompatible and provided a suitable microenvironment for angiogenesis. Sprouting length of the vascular endothelial cells was modulated by altering the stiffness of the hydrogels and varying the concentrations of the two hydrogel components. Furthermore, we used an electrochemical reaction to detach cells from a gold electrode surface. In this approach, cells that were seeded on a gold surface via the oligopeptide layer, detached rapidly along with the electrochemical desorption of the layer and transferred to the hydrogel. Owing to the rapid gelation of the hydrogels and rapid electrochemical detachment of cells, cell transfer was completed within 10 min (including 30 s of gelation and 5 min of potential application). Rapid cell transfer was observed not only on a flat surface but also on different shapes, such as cylindrical needles. Vascular endothelial cells were transferred from needles onto the hydrogel to fabricate endothelial cell-enveloped microchannels. In subsequent perfusion culture, the transferred endothelial cells migrated and formed luminal structures in the hydrogel. This in situ cross-linkable hydrogel may be useful for the rapid fabrication of perfusable vascular networks to engineer vascularized and cell-dense 3D tissues and organs.
This paper reviews the primary literature reporting the use of ionic liquids (ILs) in optical sensing technologies. The optical chemical sensors that have been developed with the assistance of ILs are classified according to the type of resultant material. Key aspects of applying ILs in such sensors are revealed and discussed. They include using ILs as solvents for the synthesis of sensor matrix materials; additives in polymer matrices; matrix materials; modifiers of the surfaces; and multifunctional sensor components. The operational principles, design, texture, and analytical characteristics of the offered sensors for determining CO2, O2, metal ions, CN -, and various organic compounds are critically discussed. The key advantages and disadvantages of using ILs in optical sensing technologies are defined. Finally, the applicability of the described materials for chemical analysis is evaluated, and possibilities for their further modernization are outlined.
We developed a gold-coated membrane substrate modified with an oligopeptide layer that can be used to grow and subsequently detach a thick cell sheet through an electrochemical reaction. The oligopeptide CCRRGDWLC was designed to contain a cell adhesive domain (RGD) in the center and cysteine residues at both terminals. Cysteine contains a thiol group that forms a gold–thiolate bond on a gold surface. Cells attached to gold-coated membrane substrates via the oligopeptide layer were readily and noninvasively detached by applying a negative electrical potential to cleave the gold–thiolate bond. Because of the effective oxygen supply, fibroblasts vigorously grew on the membrane substrate and the thickness of the cell sheets was ∼60 μm at 14 days of culture, which was 2.9-fold greater than that of cells grown on a conventional culture dish. The cell sheets were detached after 7 min of electrical potential application. Using this approach, five layers of cell sheets were stacked sequentially with thicknesses reaching >200 μm. This approach was also beneficial for rapidly and readily transplanting cell sheets. Grafted cell sheets secreted collagen and remained at the transplanted site for at least 2 months after transplantation. This simple electrochemical cell sheet engineering technology is a promising tool for tissue engineering and regenerative medicine applications.
Diabetes is one of the most common metabolic disorders, and is characterized by the inability to secrete/sense insulin and abnormal blood glucose concentration. Many researchers have concentrated their efforts on improving islet transplantation, in particular by fabricating bioartificial pancreatic islets in vitro. One of the critical points for the success of this research direction is the improvement of culture conditions, such as oxygen supply, in the engineering of bioartificial pancreatic islets to ensure their viability and functionality after transplantation. In this work, we fabricated microwell spheroid culture devices made of oxygen-permeable polydimethylsiloxane (PDMS), with which hypoxia in the core of bioartificial islets was alleviated and glucose-stimulated insulin secretion was increased ~2.5-fold compared to a device with the same configuration but made of non-oxygen-permeable plastic. We also demonstrated that antioxidants, such as ascorbic acid-2-phosphate (AA2P), could neutralize islet damage caused by increased reactive oxygen species (ROS) in the cell culture environment. These results suggest that supply of oxygen together with removal of ROS may lead to a better approach to prepare highly viable and functional bioartificial pancreatic islets.
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