Is polymer advantageous for bioelectronics?
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Polymer materials are advantageous for bioelectronics due to their unique electronic properties, such as low ionization potential, optical transitions at lower energies, and reversible redox reactions . These properties make polymers suitable for applications in sensors, energy storage and harvesting devices, display devices, and flexible electrodes . Additionally, organic electronic materials, including conducting polymers, have a lower Young's modulus and can uptake ions from electrolytes, leading to mixed electronic/ionic conductivity . This property allows for the scaling of electrodes to smaller dimensions and enhances the interaction between ionic and electronic currents, resulting in decreased impedance and high signal-to-noise ratio neural recordings . Furthermore, water-soluble conjugated polymers have been employed as ideal interface materials in bioelectronic processes, offering satisfying ionic conductivity, water-solubility, and good biocompatibility . These polymers have shown promising applications in biosynthetic systems, photosynthetic systems, biophotovoltaic systems, and bioelectronic devices . Therefore, polymers, especially conducting and water-soluble conjugated polymers, offer significant advantages for bioelectronics .
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| Papers (5) | Insight |
|---|---|
| The paper mentions that conducting polymers are one of the materials used in bioelectronics, suggesting that polymers can be advantageous for bioelectronics. | |
5 Citations | Yes, water-soluble conjugated polymers (WSCPs) are advantageous for bioelectronics as they can regulate bioelectronic processes between biological systems and electronic systems due to their satisfying ionic conductivity, water-solubility, and good biocompatibility. |
| The paper states that the use of conjugated polymers, specifically poly[3-(3′-N,N,N-triethylamino-1′-propyloxy)-4-methyl-2,5-thiophene chloride] (PMNT), in living materials can optimize the bioelectronic process. | |
| Yes, conducting polymers are advantageous for bioelectronics as they possess unique electronic properties and can be used for the development of sensors, energy storage devices, display devices, and flexible electrodes. | |
| Polymer materials are advantageous for bioelectronics as they have a lower Young's modulus, allowing for flexible substrates and smaller foreign body response. |
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