Organic electronic materials have been considered for a wide-range of technological
applications. More recently these organic (semi) conductors (encompassing both conducting …

The field of organic electronics continues to be driven by new charge-transporting materials
that are typically processed from toxic organic solvents incompatible with biological …

Protein-bound uremic toxins (PBUTs) can cause noxious effects in patients suffering from
renal failure as a result of inhibiting the transport of proteins and inducing their structural …

Organic semiconductors are being increasingly used for a variety of biological applications,
such as biochemical sensors, drug delivery, and neural interfaces. However, the poor …

π-Conjugated peptide materials are attractive for bioelectronics due to their unique
photophysical characteristics, biofunctional interfaces, and processability under aqueous …

Research over the past four decades has highlighted the importance of certain brain cells,
called glial cells, and has moved the neurocentric vision of structure, function, and pathology …

Organic semiconductors have emerged as promising neural interfacing materials due to
their innate biocompatibility, soft mechanical properties, and mixed electron/ion conduction …

Cardiac tissue regeneration strategies are increasingly taking advantage of electroactive
scaffolds to actively recreate the tissue microenvironment. In this context, this work reports …

As a step toward the realization of neuroprosthetics for vision restoration, we follow an
electrophysiological patch-clamp approach to study the fundamental photoelectrical …

Organic bioelectronics have a huge potential to generate interfaces and devices for the
study of brain functions and for the therapy of brain pathologies. In this context, increasing …