@dboufidis.bsky.social
This paper shows robust viability and preserved astrocyte morphology and calcium activity after Ti₃C₂Tₓ MXene exposure. We establish a baseline of glial biocompatibility, expanding MXene research beyond neurons and paving the way for astrocyte-targeted bioelectronics ⚡️
doi.org/10.1002/admi.202500261
doi.org/10.1002/admi.202500261
Astrocyte Interactions With Ti3C2Tx MXene Flakes: Insights Into Viability, Morphology, and Functionality
This study presents the first systematic evaluation of interactions between astrocytes and Ti3C2TX MXene flakes, a 2D nanomaterial with emerging neuroelectronic applications. Using a multimodal appro...
doi.org
August 19, 2025 at 1:45 AM
This paper shows robust viability and preserved astrocyte morphology and calcium activity after Ti₃C₂Tₓ MXene exposure. We establish a baseline of glial biocompatibility, expanding MXene research beyond neurons and paving the way for astrocyte-targeted bioelectronics ⚡️
doi.org/10.1002/admi.202500261
doi.org/10.1002/admi.202500261
This work wouldn’t have been possible without my incredible co-authors Raghav Garg, Eugenia Angelopoulos, D. Kacy Cullen & Flavia Vitale – I’m deeply grateful for their insights, guidance, and support!
Full paper: doi.org/10.1038/s414...
@naturecomms.bsky.social @ragarg.bsky.social 🙏
Full paper: doi.org/10.1038/s414...
@naturecomms.bsky.social @ragarg.bsky.social 🙏
February 23, 2025 at 2:19 PM
This work wouldn’t have been possible without my incredible co-authors Raghav Garg, Eugenia Angelopoulos, D. Kacy Cullen & Flavia Vitale – I’m deeply grateful for their insights, guidance, and support!
Full paper: doi.org/10.1038/s414...
@naturecomms.bsky.social @ragarg.bsky.social 🙏
Full paper: doi.org/10.1038/s414...
@naturecomms.bsky.social @ragarg.bsky.social 🙏
We discuss:
🔹Advances in tissue-like bioelectronics, from soft to biohybrid and all-living platforms
🔹How cell-containing technologies are redefining neural interfaces
🔹Key terminology for this emerging field
🔹Challenges in clinical translation & future directions
doi.org/10.1038/s414...
🔹Advances in tissue-like bioelectronics, from soft to biohybrid and all-living platforms
🔹How cell-containing technologies are redefining neural interfaces
🔹Key terminology for this emerging field
🔹Challenges in clinical translation & future directions
doi.org/10.1038/s414...
February 23, 2025 at 2:19 PM
We discuss:
🔹Advances in tissue-like bioelectronics, from soft to biohybrid and all-living platforms
🔹How cell-containing technologies are redefining neural interfaces
🔹Key terminology for this emerging field
🔹Challenges in clinical translation & future directions
doi.org/10.1038/s414...
🔹Advances in tissue-like bioelectronics, from soft to biohybrid and all-living platforms
🔹How cell-containing technologies are redefining neural interfaces
🔹Key terminology for this emerging field
🔹Challenges in clinical translation & future directions
doi.org/10.1038/s414...
Neural interfaces are evolving toward bio-inspired designs for better integration and function. From soft bioelectronics to biohybrid neural interfaces and all-living solutions, our review maps this growing field and how biologically active technologies reshape neural interfaces.
February 23, 2025 at 2:19 PM
Neural interfaces are evolving toward bio-inspired designs for better integration and function. From soft bioelectronics to biohybrid neural interfaces and all-living solutions, our review maps this growing field and how biologically active technologies reshape neural interfaces.