{"title":"社论:DNA分子是纳米技术的对象,螺旋结构超材料和超表面的创造","authors":"I. Semchenko, S. Khakhomov, Jicheng Wang","doi":"10.3389/fnano.2023.1217459","DOIUrl":null,"url":null,"abstract":"The spring of 2023 marks the 70th anniversary of the discovery of the DNA structure by eminent scientists, later Nobel laureates James Watson and Francis Crick (Watson and Crick, 1953). The years that followed confirmed the importance of a great scientific discovery, which gave a real impetus to endless research on the DNA molecule, its structure, properties and possible applications. It is no exaggeration to say that the DNA molecule is the source and basis of numerous technologies in various fields of human activity. This Research Topic compiles a variety of contributions (very few have been published recently) highlighting new types of analysis and methods for more effective work with DNA data, simulated and real, obtained via different methods. These approaches let us shed light on the mechanisms of DNA organization, focusing on the relationship between DNA structure, function and dynamics, as well as consider The DNA molecule as an object of nanotechnology and the creation of helical-structured metamaterials and metasurfaces. The Research Topic is between biophysics, nanotechnology, chemical and biomedical engineering, and the articles presented by scientists from various fields make it possible to convey to the reader a variety of research methods related to this Research Topic, as well as to put this into a broader context. The first article on this Research Topic (Hu et al.) presents a mini-review summarizing the latest advances in the development of endogenous stimulus-sensitive DNA nanostructures featuring precise self-assembly, targeted delivery and controlled release of drugs for cancer theranostics. This mini review briefly discusses the diverse dynamic DNA nanostructures aiming at bioimaging and biomedicine, including DNA self-assembling materials, DNA origami structures, DNA hydrogels, etc., elaborate the working principles of DNA nanostructures activated by biomarkers (e.g., miRNA, mRNA, and proteins) in tumor cells and microenvironments of tumor tissue (e.g., pH, ATP, and redox gradient). Applications of the endogenous stimuli-responsive DNA nanostructures in biological imaging probes for detecting cancer hallmarks as well as intelligent carriers for drug release in vivo are discussed. 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The Research Topic is between biophysics, nanotechnology, chemical and biomedical engineering, and the articles presented by scientists from various fields make it possible to convey to the reader a variety of research methods related to this Research Topic, as well as to put this into a broader context. The first article on this Research Topic (Hu et al.) presents a mini-review summarizing the latest advances in the development of endogenous stimulus-sensitive DNA nanostructures featuring precise self-assembly, targeted delivery and controlled release of drugs for cancer theranostics. This mini review briefly discusses the diverse dynamic DNA nanostructures aiming at bioimaging and biomedicine, including DNA self-assembling materials, DNA origami structures, DNA hydrogels, etc., elaborate the working principles of DNA nanostructures activated by biomarkers (e.g., miRNA, mRNA, and proteins) in tumor cells and microenvironments of tumor tissue (e.g., pH, ATP, and redox gradient). Applications of the endogenous stimuli-responsive DNA nanostructures in biological imaging probes for detecting cancer hallmarks as well as intelligent carriers for drug release in vivo are discussed. 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引用次数: 0
摘要
2023年春天是著名科学家,后来的诺贝尔奖获得者詹姆斯·沃森和弗朗西斯·克里克发现DNA结构70周年(沃森和克里克,1953年)。随后的几年证实了一项伟大科学发现的重要性,这一发现真正推动了对DNA分子、其结构、性质和可能的应用的无休止研究。可以毫不夸张地说,DNA分子是人类活动各个领域众多技术的来源和基础。本研究主题汇集了各种贡献(最近发表的很少),强调了通过不同方法获得的模拟和真实DNA数据的新型分析和方法,以更有效地进行工作。这些方法使我们能够阐明DNA组织的机制,关注DNA结构、功能和动力学之间的关系,并将DNA分子视为纳米技术的对象,以及螺旋结构超材料和超表面的创建。研究主题介于生物物理学、纳米技术、化学和生物医学工程之间,来自各个领域的科学家发表的文章使我们能够向读者传达与该研究主题相关的各种研究方法,并将其置于更广泛的背景中。关于这一研究主题的第一篇文章(Hu et al.)概述了内源性刺激敏感DNA纳米结构开发的最新进展,该纳米结构具有癌症治疗药物的精确自组装、靶向递送和控释。这篇小综述简要讨论了针对生物成像和生物医学的各种动态DNA纳米结构,包括DNA自组装材料、DNA折纸结构、DNA水凝胶等。,阐述了肿瘤细胞和肿瘤组织微环境(如pH、ATP和氧化还原梯度)中生物标志物(如miRNA、mRNA和蛋白质)激活的DNA纳米结构的工作原理。讨论了内源性刺激响应DNA纳米结构在检测癌症特征的生物成像探针以及体内药物释放的智能载体中的应用。总之,DNA开放存取的当前挑战
Editorial: The DNA molecule as an object of nanotechnology and the creation of helical-structured metamaterials and metasurfaces
The spring of 2023 marks the 70th anniversary of the discovery of the DNA structure by eminent scientists, later Nobel laureates James Watson and Francis Crick (Watson and Crick, 1953). The years that followed confirmed the importance of a great scientific discovery, which gave a real impetus to endless research on the DNA molecule, its structure, properties and possible applications. It is no exaggeration to say that the DNA molecule is the source and basis of numerous technologies in various fields of human activity. This Research Topic compiles a variety of contributions (very few have been published recently) highlighting new types of analysis and methods for more effective work with DNA data, simulated and real, obtained via different methods. These approaches let us shed light on the mechanisms of DNA organization, focusing on the relationship between DNA structure, function and dynamics, as well as consider The DNA molecule as an object of nanotechnology and the creation of helical-structured metamaterials and metasurfaces. The Research Topic is between biophysics, nanotechnology, chemical and biomedical engineering, and the articles presented by scientists from various fields make it possible to convey to the reader a variety of research methods related to this Research Topic, as well as to put this into a broader context. The first article on this Research Topic (Hu et al.) presents a mini-review summarizing the latest advances in the development of endogenous stimulus-sensitive DNA nanostructures featuring precise self-assembly, targeted delivery and controlled release of drugs for cancer theranostics. This mini review briefly discusses the diverse dynamic DNA nanostructures aiming at bioimaging and biomedicine, including DNA self-assembling materials, DNA origami structures, DNA hydrogels, etc., elaborate the working principles of DNA nanostructures activated by biomarkers (e.g., miRNA, mRNA, and proteins) in tumor cells and microenvironments of tumor tissue (e.g., pH, ATP, and redox gradient). Applications of the endogenous stimuli-responsive DNA nanostructures in biological imaging probes for detecting cancer hallmarks as well as intelligent carriers for drug release in vivo are discussed. In conclusion, the current challenges of DNA OPEN ACCESS
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