Anran Zhang
A5009169522- MXene and MAX Phase Materials
- Advanced Memory and Neural Computing
- Advanced Sensor and Energy Harvesting Materials
- Nutrition and Health in Aging
- Gastric Cancer Management and Outcomes
- Nutritional Studies and Diet
- Esophageal and GI Pathology
- Obesity, Physical Activity, Diet
- Modular Robots and Swarm Intelligence
- Esophageal Cancer Research and Treatment
Applied Physical Sciences (United States)
2024
University of North Carolina at Chapel Hill
2024
Bioelectronic implants featuring soft mechanics, excellent biocompatibility, and outstanding electrical performance hold promising potential to revolutionize implantable technology. These biomedical can record electrophysiological signals execute direct therapeutic interventions within internal organs, offering transformative in the diagnosis, monitoring, treatment of various pathological conditions. However, challenges remain improving excessive impedance at bioelectronic-tissue interface...
Symmetry lies at the heart of two-dimensional (2D) bioelectronics, determining material properties fundamental level. Breaking symmetry allows emergent functionalities and effects. However, modulation in 2D bioelectronics resultant applications have been largely overlooked. Here, we devise an oxidized architectural MXene, referred to as MXene (OXene), that couples orbit symmetric breaking with inverse entitle optimized interfacial impedance Schottky-induced piezoelectric The resulting OXene...
Bioelectronic implants with soft mechanics, biocompatibility, and excellent electrical performance enable biomedical to record electrophysiological signals execute interventions within internal organs, promising revolutionize the diagnosing, monitoring, treatment of various pathological conditions. However, challenges remain in improving excessive impedance at bioelectronic-tissue interface thus efficacy signaling intervention. Here, we devise orbit symmetry breaking MXene (a low-cost...