ABSTRACT
Research in the field of nanotechnology has witnessed rapid increase in the synthesis of Engineered nanoparticles (ENPs). This has even led to development of new discipline of Nanotoxicology. Advances in the field of Nanotoxicology further led to development of new domain-nanoinformatics. This new domain of nanoinformatics provides a computational perspective to biology and nanotechnology addressing multi level integration. Nanoinformatics not only helps in predicting nanoparticle structure, composition and behaviour but also covers raw data management, analysis of data derived from biomedical applications and simulation of nanoparticle interactions with biological systems. In addition, it accelerates nano-related research and applications into clinical practice. There are various computational models developed to study the key steps in nano-medicine like drug encapsulation and release, nanoparticle targeting, delivery and uptake and nanoparticle effects on cells and tissues. These prospects have opened up a large domain enabling possibilities of nanomedicine and frontiers for clinical practice and biomedical research in a cost-effective manner along with various applications including studies in clinical trials, toxicity assays, drug delivery systems. This review highlights new approaches for Engineered nanoparticles (ENP) risk assessment and regulation.
ABSTRACT
After the progress made during the genomics era, bioinformatics was tasked with supporting the flow of information generated by nanobiotechnology efforts. This challenge requires adapting classical bioinformatic and computational chemistry tools to store, standardize, analyze, and visualize nanobiotechnological information. Thus, old and new bioinformatic and computational chemistry tools have been merged into a new sub-discipline: nanoinformatics. This review takes a second look at the development of this new and exciting area as seen from the perspective of the evolution of nanobiotechnology applied to the life sciences. The knowledge obtained at the nano-scale level implies answers to new questions and the development of new concepts in different fields. The rapid convergence of technologies around nanobiotechnologies has spun off collaborative networks and web platforms created for sharing and discussing the knowledge generated in nanobiotechnology. The implementation of new database schemes suitable for storage, processing and integrating physical, chemical, and biological properties of nanoparticles will be a key element in achieving the promises in this convergent field. In this work, we will review some applications of nanobiotechnology to life sciences in generating new requirements for diverse scientific fields, such as bioinformatics and computational chemistry.