{"title":"Glu-Phe-Asp蛋白的多态性。","authors":"Panagiotis Mougkogiannis, Andrew Adamatzky","doi":"10.3390/biomimetics10060360","DOIUrl":null,"url":null,"abstract":"<p><p>Glu-Phe-Asp (GFD) proteinoids represent a class of synthetic polypeptides capable of self-assembling into microspheres, fibres, or combinations thereof, with morphology dramatically influencing their electrical properties. Extended recordings and detailed waveforms demonstrate that microspheres generate rapid, nerve-like spikes, while fibres exhibit consistent and gradual variations in voltage. Mixed networks integrate multiple components to achieve a balanced output. Electrochemical measurements show clear differences. Microspheres have a low capacitance of 1.926±5.735μF. They show high impedance at 6646.282±178.664 Ohm. Their resistance is low, measuring 15,830.739 ± 652.514 mΩ. This structure allows for quick ionic transport, leading to spiking behaviour. Fibres show high capacitance (9.912±0.171μF) and low impedance (209.400±0.286 Ohm). They also have high resistance (163,067.613 ± 9253.064 mΩ). This combination helps with charge storage and slow potential changes. The 50:50 mixture shows middle values for all parameters. This confirms that hybrid electrical properties have emerged. The differences come from basic structural changes. Microspheres trap ions in small, round spaces. This allows for quick release. In contrast, fibers spread ions along their length. This leads to slower wave propagation. In mixed systems, diverse voltage zones emerge, suggesting cooperative dynamics between morphologies. This electrical polymorphism in simple proteinoid systems may explain complexity in biological systems. This study shows that structural polymorphism in GFD proteinoids affects their electrical properties. 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Extended recordings and detailed waveforms demonstrate that microspheres generate rapid, nerve-like spikes, while fibres exhibit consistent and gradual variations in voltage. Mixed networks integrate multiple components to achieve a balanced output. Electrochemical measurements show clear differences. Microspheres have a low capacitance of 1.926±5.735μF. They show high impedance at 6646.282±178.664 Ohm. Their resistance is low, measuring 15,830.739 ± 652.514 mΩ. This structure allows for quick ionic transport, leading to spiking behaviour. Fibres show high capacitance (9.912±0.171μF) and low impedance (209.400±0.286 Ohm). They also have high resistance (163,067.613 ± 9253.064 mΩ). This combination helps with charge storage and slow potential changes. The 50:50 mixture shows middle values for all parameters. This confirms that hybrid electrical properties have emerged. The differences come from basic structural changes. Microspheres trap ions in small, round spaces. This allows for quick release. In contrast, fibers spread ions along their length. This leads to slower wave propagation. In mixed systems, diverse voltage zones emerge, suggesting cooperative dynamics between morphologies. This electrical polymorphism in simple proteinoid systems may explain complexity in biological systems. This study shows that structural polymorphism in GFD proteinoids affects their electrical properties. 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引用次数: 0
摘要
glu - ph - asp (GFD)类蛋白是一类能够自组装成微球、纤维或其组合的合成多肽,其形态显著影响其电学性质。扩展的记录和详细的波形表明,微球产生快速的、类似神经的尖峰,而纤维则表现出一致的、渐进的电压变化。混合网络将多个组件集成在一起,实现输出均衡。电化学测量显示出明显的差异。微球的电容较低,为1.926±5.735μF。它们在6646.282±178.664欧姆处表现出高阻抗。其电阻低,测量值为15,830.739±652.514 mΩ。这种结构允许快速离子传输,导致尖峰行为。光纤具有高电容(9.912±0.171μF)和低阻抗(209.400±0.286欧姆)特性。它们还具有高电阻(163,067.613±9253.064 mΩ)。这种组合有助于电荷存储和减缓电位变化。50:50的混合物显示所有参数的中间值。这证实了混合电特性已经出现。这些差异来自于基本的结构变化。微球将离子捕获在小而圆的空间里。这允许快速释放。相反,纤维沿着其长度扩散离子。这导致波的传播速度变慢。在混合系统中,不同的电压区出现,表明形态之间的合作动态。简单类蛋白系统中的这种电多态性可以解释生物系统的复杂性。本研究表明,GFD类蛋白的结构多态性影响其电学性质。这一发现对仿生计算具有重要意义,并揭示了益生元信息处理系统。
Glu-Phe-Asp (GFD) proteinoids represent a class of synthetic polypeptides capable of self-assembling into microspheres, fibres, or combinations thereof, with morphology dramatically influencing their electrical properties. Extended recordings and detailed waveforms demonstrate that microspheres generate rapid, nerve-like spikes, while fibres exhibit consistent and gradual variations in voltage. Mixed networks integrate multiple components to achieve a balanced output. Electrochemical measurements show clear differences. Microspheres have a low capacitance of 1.926±5.735μF. They show high impedance at 6646.282±178.664 Ohm. Their resistance is low, measuring 15,830.739 ± 652.514 mΩ. This structure allows for quick ionic transport, leading to spiking behaviour. Fibres show high capacitance (9.912±0.171μF) and low impedance (209.400±0.286 Ohm). They also have high resistance (163,067.613 ± 9253.064 mΩ). This combination helps with charge storage and slow potential changes. The 50:50 mixture shows middle values for all parameters. This confirms that hybrid electrical properties have emerged. The differences come from basic structural changes. Microspheres trap ions in small, round spaces. This allows for quick release. In contrast, fibers spread ions along their length. This leads to slower wave propagation. In mixed systems, diverse voltage zones emerge, suggesting cooperative dynamics between morphologies. This electrical polymorphism in simple proteinoid systems may explain complexity in biological systems. This study shows that structural polymorphism in GFD proteinoids affects their electrical properties. This finding is significant for biomimetic computing and sheds light on prebiotic information-processing systems.
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