Nanobiotechnology

About: Nanobiotechnology is a research topic. Over the lifetime, 796 publications have been published within this topic receiving 46309 citations. The topic is also known as: bionanotechnology & nanobiology.

DNA-based applications in nanobiotechnology.

Abstract: Biological molecules such as deoxyribonucleic acid (DNA) have shown great potential in fabrication and construction of nanostructures and devices. The very properties that make DNA so effective as genetic material also make it a very suitable molecule for programmed self-assembly. The use of DNA to assemble metals or semiconducting particles has been extended to construct metallic nanowires and functionalized nanotubes. This paper highlights some important aspects of conjugating the unique physical properties of dots or wires with the remarkable recognition capabilities of DNA which could lead to miniaturizing biological electronics and optical devices, including biosensors and probes. Attempts to use DNA-based nanocarriers for gene delivery are discussed. In addition, the ecological advantages and risks of nanotechnology including DNA-based nanobiotechnology are evaluated.

Plenty of Room for Biology at the Bottom: An Introduction to Bionanotechnology

Abstract: Introduction: Nanobiotechnology and Bionanotechnology A Brief Introduction to Nanotechnology Natural Biological Assembly at the Nano-Scale Nanometric Biological Assemblies: Molecular and Chemical Basis for Interaction Molecular Recognition and the Formation of Biological Structures Self-Assembly of Biological and Bio-Inspired Nano-Materials Application of Biological Assemblies in Nanotechnology Medical and Other Applications of Bionanotechnology Future Prospects for Nanobiotechnology and Bionanotechnology Concluding Remarks: The Prospects and Dangers of the Nanobiological Revolution.

Solid-State and Biological Nanopore for Real-Time Sensing of Single Chemical and Sequencing of DNA

Abstract: Sensitivity and specificity are two most important factors to take into account for molecule sensing, chemical detection and disease diagnosis. A perfect sensitivity is to reach the level where a single molecule can be detected. An ideal specificity is to reach the level where the substance can be detected in the presence of many contaminants. The rapidly progressing nanopore technology is approaching this threshold. A wide assortment of biomotors and cellular pores in living organisms perform diverse biological functions. The elegant design of these transportation machineries has inspired the development of single molecule detection based on modulations of the individual current blockage events. The dynamic growth of nanotechnology and nanobiotechnology has stimulated rapid advances in the study of nanopore based instrumentation over the last decade, and inspired great interest in sensing of single molecules including ions, nucleotides, enantiomers, drugs, and polymers such as PEG, RNA, DNA, and polypeptides. This sensing technology has been extended to medical diagnostics and third generation high throughput DNA sequencing. This review covers current nanopore detection platforms including both biological pores and solid state counterparts. Several biological nanopores have been studied over the years, but this review will focus on the three best characterized systems including et-hemolysin and MspA, both containing a smaller channel for the detection of single stranded DNA, as well as bacteriophage phi29 DNA packaging motor connector that contains a larger channel for the passing of double stranded DNA. The advantage and disadvantage of each system are compared; their current and potential applications in nanonnedicine, biotechnology, and nanotechnology are discussed. (C) 2013 Elsevier Ltd. All rights reserved.

Microfluidic Synthesis of Nanoparticles and their Biosensing Applications

Abstract: We present an extensive overview of the evolution and progress made in the field of microstructures and nanostructures preparation using microfluidic techniques in recent times. A microfluidic system creates particles that are within a narrow range of shape and size distribution. It enables controlling the shape, size and composition of nanomaterials (NMs) for various applications. A brief evaluation of the advantages of both droplet-based and continuous flow synthesis of nanoparticles (NPs) is discussed in detail and compared with the traditional wet chemical batch synthesis approach. Due to increasing applications of biosensing, nanobiotechnology, nanomedicine and diagnostics devices, special attention should be paid to metal NPs developed through microfluidic routes.

Designer Nanomaterials Using Chiral Self‐Assembling Peptide Systems and Their Emerging Benefit for Society

Abstract: Chirality is absolutely central in chemistry and biology. The recent findings of chiral self-assembling peptides’ remarkable chemical complementarity and structural compatibility make it one of the most inspired designer materials and structures in nanobiotechnology. The emerging field of designer chemistry and biology further explores biological and medical applications of these simple D,L- amino acids through producing marvellous nanostructures under physiological conditions. These self-assembled structures include well-ordered nanofibers, nanotubes and nanovesicles. These structures have been used for 3-dimensional tissue cultures of primary cells and stem cells, sustained release of small molecules, growth factors and monoclonal antibodies, accelerated wound-healing in reparative and regenerative medicine as well as tissue engineering. Recent advances in molecular designs have also led to the development of 3D fine-tuned bioactive tissue culture scaffolds. They are also used to stabilize membrane proteins including difficult G-protein coupled receptors for designing nanobiodevices. One of the self-assembling peptides has been used in human clinical trials for accelerated wound-healings. It is our hope that these peptide materials will open doors for more and diverse clinical uses. The field of chiral self-assembling peptide nanobiotechnology is growing in a number of directions that has led to many surprises in areas of novel materials, synthetic biology, clinical medicine and beyond.