来自用户 Jarvi Coa 的文献。
当前共找到 2 篇文献分享。
1.
Jarvi Coa (2023-12-28 11:25):
#paper doi:10.1021/jacs.2c04325,JACS,2022,DNA Strand-Displacement Temporal Logic Circuits 这篇文章通过时间记忆的策略,结合DNA电路链置换反应,实现逻辑与门,用n个输入可以得到附带时序信息的n!个组合,对比传统电路只能得到n个输出结果的电路,很大程度提高了可拓展性,并在研究过程中发现改进门中杂交链的错配可用于降低电路设计的复杂性,缩短特定的立足点可用于提高电路行为的鲁棒性。为以后在更复杂的DNA计算提供了可能,该作者也正在研发此此类电路与神经网路和机器学习结合的新方法。
Abstract:
Molecular circuits capable of processing temporal information are essential for complex decision making in response to both the presence and history of a molecular environment. A particular type of temporal … >>>
Molecular circuits capable of processing temporal information are essential for complex decision making in response to both the presence and history of a molecular environment. A particular type of temporal information that has been recognized to be important is the relative timing of signals. Here we demonstrate the strategy of temporal memory combined with logic computation in DNA strand-displacement circuits capable of making decisions based on specific combinations of inputs as well as their relative timing. The circuit encodes the timing information on inputs in a set of memory strands, which allows for the construction of logic gates that act on current and historical signals. We show that mismatches can be employed to reduce the complexity of circuit design and that shortening specific toeholds can be useful for improving the robustness of circuit behavior. We also show that a detailed model can provide critical insights for guiding certain aspects of experimental investigations that an abstract model cannot. We envision that the design principles explored in this study can be generalized to more complex temporal logic circuits and incorporated into other types of circuit architectures, including DNA-based neural networks, enabling the implementation of timing-dependent learning rules and opening up new opportunities for embedding intelligent behaviors into artificial molecular machines. <<<
翻译
2.
Jarvi Coa (2023-11-30 09:39):
#paper DOI : 10.1021/jacs.2c11504 Pub Date  : 2023-01-26 Self-Stacking Autocatalytic Molecular Circuit with Minimal Catalytic DNA Assembly 本文提出了一种可扩展的自组装自催化DNNA电路(AAD),它由一个简单而有效的诱导序列反应组成。该系统由一小部分DNA分子序列反应和少量复制触发组成,且反应过程中可生成能够继续催化自身的trigger。通过深层理论模拟和系统实验演示,这些重新生成的trigger效率能够达到预期目标且具有较高特异性,因此可以很容易地改进以达到更有效且具有特征的DNA电路的信号放大。基于其指数级高信号感知性和最小反应组件,这种DNA分子电路大大加快了生物医学诊断和治疗评估的进程。
Abstract:
Isothermal autocatalytic DNA circuits have been proven to be versatile and powerful biocomputing platforms by virtue of their self-sustainable and self-accelerating reaction profiles, yet they are currently constrained by their … >>>
Isothermal autocatalytic DNA circuits have been proven to be versatile and powerful biocomputing platforms by virtue of their self-sustainable and self-accelerating reaction profiles, yet they are currently constrained by their complicated designs, severe signal leakages, and unclear reaction mechanisms. Herein, we developed a simpler-yet-efficient autocatalytic assembly circuit (AAC) for highly robust bioimaging in live cells and mice. The scalable and sustainable AAC system was composed of a mere catalytic DNA assembly reaction with minimal strand complexity and, upon specific stimulation, could reproduce numerous new triggers to expedite the whole reaction. Through in-depth theoretical simulations and systematic experimental demonstrations, the catalytic efficiency of these reproduced triggers was found to play a vital role in the autocatalytic profile and thus could be facilely improved to achieve more efficient and characteristic autocatalytic signal amplification. Due to its exponentially high signal amplification and minimal reaction components, our self-stacking AAC facilitated the efficient detection of trace biomolecules with low signal leakage, thus providing great clinical diagnosis and therapeutic assessment potential. <<<
翻译
回到顶部