Applications

The nanorobotics is the technology of the creating machines or the robots at or close to a scale of the  10-9metres[nanometre] nanorobots. The  nanobots or nanoids[nanorobots] are constructed of the nanoscale or the molecular components. At this time, as no artificial non-biological nanorobots have been created so far, they remain the hypothetical concept. This articles focuses on history of nanorobots, composition of nanorobots, mechanism of nanorobots & applications of nanorobots.

Hydrogels are three-dimensional, hydrophilic & polymeric networks capable of absorbing large amounts of water or biological fluids. Due to their high water content, porosity & soft consistency, they closely simulate natural living tissues, more so than any other class of synthetic biomaterials. Hydrogels can be formulated in a variety of physical forms, including slabs, micro-particles, Nano-particles, coatings and films. As a result, hydrogels are commonly used in clinical practice & medicine for a wide range of applications, including Tissue engineering & Regenerative medicine, Diagnostics, Cellular immobilization, separation of biomolecules or cells, & barrier materials to regulate biological adhesions. Hydrogels are also relatively deformable & can conform to the shape of the surface to which they are applied. In the latter context, the bioadhesive properties of some hydrogels can be advantageous in immobilizing them at the site of application or in applying them on surfaces that aren’t horizontal. They have started to create a niche in several fields of medicine like in specific site drug delivery, tissue reconstruction & tissue engineering and even as biosensors. In this review article an attempt has been made to explain the properties of hydrogels, their methods of preparation & its applications.

Hydrogel product constitute a group of polymeric material, the hydrophilic structure of which render them capable of holding large amount of water in their three dimensional networks. Due to their high water content, porosity and soft consistency, they closely simulate natural living tissue, more so than any other class of synthetic biomaterials. Furthermore, hydrogels can be formulated in a variety of physical forms, including slabs, microparticles, nanoparticles, coatings, and films. As a result, hydrogels are commonly used in clinical practice and medicine for a wide range of applications, including Tissue engineering and Regenerative medicine, Diagnostics, Cellular immobilization, separation of biomolecules or cells, and barrier materials to regulate biological adhesions. This biomaterial can hold large amount of biological fluids and swell. When swell, they are soft and rubbery and resemble the living tissue exhibiting excellent biocompatibility. The prime objective of this article is to concern the classification of hydrogel on different bases, properties of hydrogel and its method of preparation and physical and chemical characteristics of these products.

This present review is progress in selected nanotechnology topics and some possible applications. This attempt mainly focused on Different Classes of Nanoparticles (Ceramic nanoparticles, Metallic particles, Carbon nanomaterials, Quantum dots) and Applications of Nanotechnology in Pharmaceuticals (Diagnosis, Pharmacology and Therapy, Molecular Diagnosis) and Nanoparticle Drug Delivery Systems and Toxicity of Nanoparticles. Nanoparticles mainly use aims to minimize drug degradation upon administration, prevent undesirable side effects, and increase drug bioavailability and the fraction of the drug accumulated in the pathological area.