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In the past few decades there has been incredible growth in "bionano"-related research, which has been accompanied by numerous publications in this field. Although various compilations address topics related to deoxyribonucleic acid (DNA) and protein, there are few books that focus on determining the structure of ribonucleic acid (RNA) and using RNA as building blocks to construct nanoarchitectures for biomedical and healthcare applications. RNA Nanotechnology is a comprehensive volume that details both the traditional approaches and the latest developments in the field of RNA-related technology. This book targets a wide audience: a broad introduction provides a solid academic background for students, researchers, and scientists who are unfamiliar with the subject, while the in-depth descriptions and discussions are useful for advanced professionals. The book opens with reviews on the basic aspects of RNA biology, computational approaches for predicting RNA structures, and traditional and emerging experimental approaches for probing RNA structures. This section is followed by explorations of the latest research and discoveries in RNA nanotechnology, including the design and construction of RNA-based nanostructures. The final segment of the book includes descriptions and discussions of the potential biological and therapeutic applications of small RNA molecules, such as small/short interfering RNAs (siRNAs), microRNAs (miRNAs), RNA aptamers, and ribozymes.
This book provides a compelling overall update on current status of RNA interference
Overall recent research on TLRs has led to tremendous increase in our understanding of early steps in pathogen recognition and will presumably lead to potent TLR targeting therapeutics in the future. This book reviews and highlights our recent understanding on the function and ligands of TLRs as well as their role in autoimmunity, dendritic cell activation and target structures for therapeutic intervention.
New Antisense Strategies: Chemical Synthesis of RNA Oligomers, by Junichi Yano und Gerald E. Smyth Development and Modification of Decoy Oligodeoxynucleotides for Clinical Application, by Mariana Kiomy Osako, Hironori Nakagami und Ryuichi Morishita Modulation of Endosomal Toll-Like Receptor-Mediated Immune Responses by Synthetic Oligonucleotides, by Ekambar R. Kandimalla und Sudhir Agrawal Delivery of Nucleic Acid Drugs, by Yan Lee und Kazunori Kataoka Aptamer: Biology to Applications, by Yoshikazu Nakamura Development and Clinical Applications of Nucleic Acid Therapeutics, by Veenu Aishwarya, Anna Kalota und Alan M. Gewirtz
We have surpassed the omics era and are truly in the Age of Molecular Therapeutics. The fast-paced development of SARS-CoV-2 vaccines, such as the mRNA vaccines encoding the viral spike protein, demonstrated the need for and capability of molecular therapy and nanotechnology-based solutions for drug delivery. In record speed, the SARS-CoV-2 viral RNA genome was sequenced and shared with the scientific community, allowing the rapid design of molecular therapeutics. The mRNA vaccines exploit the host cell endoplasmic reticulum to produce viral spike proteins for antigen presentation and recognition by the innate and adaptive immune system. Lipid nanoparticles enable the delivery of the fragile, degradation-sensitive nucleic acid payloads. Molecular-based therapeutics and nanotechnology solutions continue to drive the scientific and medical response to the COVID-19 pandemic as new mRNA, DNA, and protein-based vaccines are developed and approved and the emergency use approved vaccines are rapidly manufactured and distributed throughout the globe. The need for molecular therapies and drug delivery solutions is clear, and as these therapies progress and become more specialized there will be important advancements in organelle targeting. For example, using organelle targeting to direct lipid nanoparticles with mRNA payloads to the endoplasmic reticulum would increase the efficacy of mRNA vaccines, reducing the required dose and therefore the biomanufacturing demand. Likewise, improving the delivery of DNA therapeutics to the nucleus would improve efficacy. Organelles and molecules have always been drug targets, but until recently we have not had the tools or capability to design and develop such highly specific therapeutics. Organelle targeting has far-reaching implications. For example, mitochondria are central to both energy production and intrinsic apoptosis. Effectively targeting and manipulating mitochondria has therapeutic applications for diseases such as myopathies, cancer, neurodegeneration, progerias, diabetes, and the natural aging process. The SARS-CoV-2 vaccines that exploit the endoplasmic reticulum (for mRNA vaccines) and the nucleic translational process (DNA vaccines) attest to the need for organelle and molecular therapeutics. This book covers the status, demand, and future of organelle- and molecularly targeted therapeutics that are critical to the advancement of modern medicine. Organelle and molecular targeting is the drug design and drug delivery approach of today and the future; understanding this approach is essential for students, scientists, and clinicians contributing to modern medicine.
Spherical nucleic acids (SNAs) comprise a nanoparticle core and a densely packed and highly oriented nucleic acid shell, typically DNA or RNA. They have novel architecture-dependent properties that distinguish them from all other forms of nucleic acids and make them useful in materials synthesis, catalysis, diagnostics, therapeutics, and optics/plasmonics. This book covers over two decades of Dr. Mirkin’s research on SNAs and their anisotropic analogues, including synthesis and fundamental properties, and applications in colloidal crystallization, adaptive matter, and nanomedicine, spanning extra- and intracellular diagnostics, gene regulation, and immunomodulation. It is a reprint volume that compiles 101 key papers from high-impact journals in this research area published by the Mirkin Group at Northwestern University, Illinois, USA, within the International Institute for Nanotechnology, and collaborators. Volume 1 provides an overview and a historical framework of engineering matter from DNA-modified constructs and discusses the enabling features of nucleic acid–functionalized nanomaterials. Volume 2 covers design rules for colloidal crystallization, building blocks for crystal engineering, and DNA and RNA as programmable bonds. Volume 3 discusses colloidal crystallization processes and routes to hierarchical assembly, dynamic nanoparticle superlattices, surface-based and template-confined colloidal crystallization, optics and plasmonics with nanoparticle superlattices, and postsynthetic modification and catalysis with nanoparticle superlattices. Volume 4 covers diagnostic modalities, and intracellular therapeutic and diagnostic schemes based upon nucleic acid–functionalized nanomaterials.
This book takes a systematic approach to address the gaps relating to nanomedicine and bring together fragmented knowledge on the advances on nanomaterials and their biomedical applicability. In particular, it demonstrates an exclusive compilation of state of the art research with a focus on fundamental concepts, current trends, limitations, and future directions of nanomedicine.
This first title on the topic provides complete coverage, including the molecular basis, production and possible biomedical applications. Written by the most prominent academic researchers in the field as well as by researchers at one of the world's leading companies in industrial production of minicircle DNA, this practical book is aimed at everyone who is directly or indirectly involved in the development of gene therapies.