The fabrication of electrically conductive hydrogels is challenging as the introduction of an electrically conductive filler often changes mechanical hydrogel matrix properties. Here, we present an approach for the preparation of hydrogel composites with outstanding electrical conductivity at extremely low filler loadings (0.34 S m −1 , 0.16 vol %). Exfoliated graphene and polyacrylamide are microengineered to 3D composites such that conductive graphene pathways pervade the hydrogel matrix similar to an artificial nervous system. This makes it possible to combine both the exceptional conductivity of exfoliated graphene and the adaptable mechanical properties of polyacrylamide. The demonstrated approach is highly versatile regarding porosity, filler material, as well as hydrogel system. The important difference to other approaches is that we keep the original properties of the matrix, while ensuring conductivity through graphene-coated microchannels. This novel approach of generating conductive hydrogels is very promising, with particular applications in the fields of bioelectronics and biohybrid robotics.
High-grade gliomas are the most common and most malign primary brain tumors. Current therapy approaches only reach unsatisfactory results, still not providing a long-lasting time to relapse or a curative treatment. A novel approach to overcome the present challenges of medical attendance, as drug resistance, systemic side effects, and limited drug availability due to the blood-brain barrier, are localized drug delivery systems (DDSs), which are already used in clinical trials. Further development of this therapy regime may clearly improve patient's outcomes. In order to design compact, biocompatible, robust, and highly flexible systems which permit a prolonged drug release, a broad knowledge of the technical and medical field is required. Thus, this interdisciplinary article reviews different designs, testing, and validation models, and finally, clinical applications of localized DDSs, to utilize this available experience as a basis for the desperately needed reform of glioma treatment.
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