Nurses are in a prime position to influence and advocate for the safe and ethical use of nanotechnologies in the workplace. Nurses will need to create care plans to assist patients in their more independent roles. Nurses need to be educated on occupational safety guidelines regarding the safe handling of nanomaterial in the workplace. Research is in progress and is a high priority for federal agencies, such as NIOSH, National Institute for Occupational Safety and Health (which is a division of the CDC, Center for Disease Control), EPA (Environmental Protection Agency), and the Depts. Of Energy and Defense are all contributing to a body of knowledge regarding the potential effects of engineered nanomaterials and nanopharmaceuticals on humans, animals, and the environment. NIOSH is the lead federal agency for conducting research on occupational safety and health with regard to nanopharmaceuticals and nanomaterials.

Pharmaceutical Nanotechnology is concerned with the development of personalized drug delivery systems using innovative technologies. The drug delivery mechanism has a favorable impact on the medication's distribution, metabolism, absorption rate, and excretion. The drug delivery mechanism also enables the drug to bind to and impact the signaling and activity of the target receptor. Pharmaceutical nanotechnology includes nanomaterials and devices for medication delivery, diagnostics, imaging, and biosensors, as well as applications of nanoscience to the pharmacy as nanomaterials.

Nanotechnology cancer treatments include the detection and eradication of cancer cells before they form tumors, as well as the destruction of cancer tumors with little damage to healthy tissue and organs. Nanotechnology offers enormous opportunities in cancer therapy, diagnostics, and imaging, but bridging the translational gap is a difficult task. The majority of nanomedicine research is focused on cancer. The enhanced permeability and retention effect causes nanoparticles to selectively concentrate in solid tumors due to the presence of leaky vasculature and reduced lymphatic drainage. As a result, nanoparticles are ideal for delivering diagnostic and/or imaging agents, chemotherapeutics, oligonucleotides, and immune regulators in order to improve their therapeutic index. The majority of nanotechnology cancer treatment attempts are still in the research or development stages. Many colleges and businesses around the world, however, are working in this field.

Green nanotechnology can be defined as how nanotechnology can enhance environmental sustainability and benefit the environment. It includes making green nano-products, using less energy during the manufacturing process, eco-friendly materials, the ability to recycle products after use, and using nano-products in support of sustainability.

Nanotechnology application in food includes nanofood when nanoparticles, nanotechnology techniques, or tools are used during the cultivation, production, processing, or packaging of the food. It does not mean atomically modified food or food produced by nanomachines. Future applications of nanotechnologies could include nanostructured food products, nanoscale or nano-encapsulated food additives, or food packaging with improved properties. There are, however, certain foods including food additives that naturally contain nanoscale particles.

Nanobiotechnology is the emerging technology on a consolidated stream of biotechnology and applied science. It is the management of helping modern medicine progress from treating symptoms to generating cures and regenerating biological tissues. Nanotoxicology analyses the toxicity of nanomaterials and has been widely applied in biomedical research to explore the toxicity of various biological systems of life. The scope of nanotoxicology is focused on identifying potential hazards that are useful for the safety evaluation of nanomedicine.

Nanomagnetism and Spintronics aim at magnetic, magnetic-optical, and spin-transport phenomenon experiments on innovative materials and hybrid nanoscale structures. Spintronics manages individual magnetic timing to combine consistent logic functions and data storage on a single platform. As is often the case in short science, advances have been made in combining nanomaterials and novel high-quality materials.

Nanotechnology is used in a variety of applications to improve the environment and to produce more efficient and less expensive energy sources, such as generating fewer pollutants, producing solar cells at a competitive price, reducing natural groundwater pollutants, etc. Purifying and purifying organic matter (VOC) Climate.

Recent modeling results suggest that dendritic polymers may provide the key to creating a reliable and economical structure and a production route for nanoscale active materials that can have various properties (electronic, optical, optoelectronic, magnetic, chemical, or biological).

Nanotechnology in Dermatology focuses on the safety of nanotechnology in principle including its use in consumer skin care products, dermatological screening, and skin disease therapy. Applications for the early detection, diagnosis, and targeted treatment of chronic diseases have been constantly being implemented in healthcare and dermatology, and it is anticipated that nano-designed materials and devices will outperform their conventional counterparts in terms of speed, size, power, efficiency, and versatility.

Nanotechnology examines fibers and particles with dimensions as low as 10e-9 m. The application of nanotechnology in medical science has been significantly impacted by numerous developments, the material availability of industrial and manufacturing technology, and advancements in targeted-delivery capabilities. However, no other sector has revealed a benefit as significant as cardiology. The complication of cardiovascular disease is emphasized by the nanotechnologies, which also reveal the size and targeted delivery constraints. An extensive description of the materials and a potential classification system accompany specific examples of innovation achievements, including the production of Drug Eluting Stents. cardiovascular imaging technologies based on nanotechnology are also used in diagnostic and preventive medicine, in addition to scaffolds for the design of 3D artificial constructs that could someday take the place of transplant hearts.

Nanotechnology is now extensively utilized in various aspects of modern business and has been recognized as the most up-to-date method for manufacturing products with a greater extent of functionality. The application of nanotechnology using nanocatalysis in the stages of catalytic cracking, oxidative dehydrogenation of alkanes, and desulfurization in the refinement of petroleum. The primary advantages of using nanoscience in catalytic reactions are built on presenting a large contact area for activation, hence minimizing the susceptibility of negative and secondary interactions.

Nanotechnology in neuroscience harnesses the power of manipulating materials at the nanoscale to revolutionize brain research and treatments. It enables targeted drug delivery to specific brain regions, advanced imaging techniques for nanoscale visualization, and improved neural prosthetics with sensitive nanoelectrodes. Nanosensors detect biomarkers for diagnosis and monitoring, while nanoparticles aid in brain repair and regeneration. Nanoelectronics interface with neurons for precise neural activity studies. The emerging field of nanotheranostics combines therapy and imaging for personalized treatments. Ethical considerations and safety remain vital in realizing the potential of nanotechnology to advance neuroscience and improve neurological disorder treatments.

In the world of Nanotechnology, several phases have been identified that are emerging. It helps us to visualize the evolution of Nanotechnology in applications like Agriculture/ Food, electrochemistry, electronics, biology, textiles, Material Sciences, Optics, and Security Systems.

Stem cell nanotechnology is an emerging field that combines the principles of stem cell biology with nanotechnology, the study, and application of materials and devices at the nanoscale. In the field of stem cell research, stem cell nanotechnology is being explored as a potential approach to improve the delivery and therapeutic potential of Mesenchymal stem cells. For example, researchers are developing nanoparticles and nanocarriers that can target specific tissues or cells in the body, allowing stem cells to be delivered to specific locations in the body in a controlled and targeted manner. In addition, stem cell nanotechnology is being used to develop new materials and devices that can support the growth and differentiation of stem cells in the laboratory, potentially leading to the development of new stem cell based therapies and treatments.