扩展核酸存储器作为数据存储技术的未来

Q4 Chemistry

International Journal of Nano and Biomaterials Pub Date : 2020-05-26 DOI:10.1504/ijnbm.2020.10029630

S. Biswas, Subhrapratim Nath, J. Sing, S. Sarkar

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引用次数: 2

摘要

在各种计算领域中，以指数速率生成的操作数据量反过来又导致可用硅存储器受到其有限容量的限制而承受压力。近年来，已经对DNA计算用于存储器技术进行了研究，其中核酸存储器（NAM）被配制并被发现是在分子空间中存储大量数字数据的有效替代方案。这项工作提出了一种新的编码方案，该方案将二进制数据有效地映射到标准和非标准遗传核苷酸的混合系统中，以实现更高的数据容量。已经与现有的编码方案进行了比较研究，此外，这项工作证明了使用非天然碱基对，如Ds-Px和Im-Na，它们在DNA分子中表现出高稳定性和高选择性。

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Extended nucleic acid memory as the future of data storage technology

The amount of operational data being generated at an exponential rate in various spheres of computing, in turn, has culminated in a pressure on the available silicon memory-constrained by its limited capacity. In recent times, research has been undertaken on DNA computing for memory technology where nucleic acid memory (NAM) was formulated and found to be an efficient alternative for storing a large amount of digital data in the molecular space. This work presents a new encoding scheme which efficiently maps the binary data into a hybrid system of standard as well as non-standard genetic nucleotides to achieve a higher data capacity. Comparative studies have been done with existing encoding schemes, moreover, this work demonstrates the use of unnatural base pairs like Ds-Px and Im-Na which exhibit high stability and high selectivity in a DNA molecule.

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来源期刊

International Journal of Nano and Biomaterials Chemistry-Physical and Theoretical Chemistry

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： In recent years, frontiers of research in engineering, science and technology have been driven by developments in nanomaterials, encompassing a diverse range of disciplines such as materials science, biomedical engineering, nanomedicine and biology, manufacturing technology, biotechnology, nanotechnology, and nanoelectronics. IJNBM provides an interdisciplinary vehicle covering these fields. Advanced materials inspired by biological systems and processes are likely to influence the development of novel technologies for a wide variety of applications from vaccines to artificial tissues and organs to quantum computers. Topics covered include Nanostructured materials/surfaces/interfaces Synthesis of nanostructures Biological/biomedical materials Artificial organs/tissues Tissue engineering Bioengineering materials Medical devices Functional/structural nanomaterials Carbon-based materials Nanomaterials characterisation Novel applications of nanomaterials Modelling of behaviour of nanomaterials Nanomaterials for biomedical applications Biological response to nanomaterials.