Abstract
Electrical activity underpins all life, but it is perhaps most familiar in the nervous system, where long range electrical signalling is essential for function. When this is lost (e.g., traumatic injury) or it becomes inefficient (e.g., demyelination), the use of external fields can compensate for at least some functional deficits, but its potential to also promote biological repair at the cell level is underplayed despite abundant in vitro evidence of control of neuron growth. This perspective article considers specifically the emerging possibility of achieving cell growth through the interaction of external electric fields using conducting materials as unwired bipolar electrodes and without intending stimulation of neuron electrical activity to be the primary consequence. The use of a wireless method to create electrical interactions represents a paradigm shift and may allow new applications in vivo where physical wiring is not possible. Within that scheme of thought an evaluation of specific materials and their dynamic responses as bipolar unwired electrodes is summarized and correlated with changes in dynamic nerve growth during stimulation, suggesting possible future schemes to achieve neural growth using bipolar unwired electrodes. This strategy emphasizes how nerve growth can be encouraged at injury sites wirelessly to induce repair , as opposed to replacing electrical nerve signals to restore function
Original language | English |
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Journal | Biomaterials Science |
Early online date | 7 Feb 2024 |
DOIs | |
Publication status | E-pub ahead of print - 7 Feb 2024 |
Bibliographical note
AcknowledgementsThe authors want to thank financial contribution from Grants from Fundacion MARATO TV3 2011 (110131), AEI (ref MAT2015-65192-R, RTI2018-097753-B-I00, PID2021-123276OB-I00, CEX2019-000917-S).