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Scholarly Publications by Integral Academia

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Has files: YesSubject: search.filters.subject.Biomedical Applications

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    A Futuristic Approach on the Multifunctionality of Nanomaterials: Relevance of Nanoparticles
    (IGI Gobal, 2024) Faria Fatima
    The realm of analytical chemistry has been invigorated by the advent of multifunctional nanoparticles. Nanomaterials, with their distinct properties stemming from quantum effects and high surface-to-volume ratios, are poised to reshape industries ranging from electronics to medicine and environmental sustainability as they deliver unprecedented performance by integrating semiconducting, plasmonic, and piezoelectronic properties. Furthermore, multifunctional nano species play a pivotal role in personalized medicine and targeted therapies. Magnetic nanoparticles respond to magnetic fields and are employed in hyperthermia therapy and targeted drug delivery. The utilization of nanostructures for promoting environmental sustainability is highly commendable. They have the remarkable ability to pinpoint pollutants and their degradation. Therefore, as the research progresses, there are transformative breakthroughs to harness the multifunctionality of nanomaterials across scientific domains, driving society towards a future characterized by technological marvels and sustainable progress.
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    Exploring the Transformative Potential of Hybrid Nanoparticles in Biomedical Applications: Relevance of Hybrid Nanoparticles
    (IGI Gobal, 2024) Faria Fatima
    Hybrid nanoparticles are nanoscale particles that are composed by interaction between the different components, resulting in enhanced properties that can be harnessed for wide range of application across fields like medicine, electronics energy, and more. These nanoparticles are typically in the size range from 1-100 nanometers, which is advantageous. Because at this scale, they often exhibit novel behavior due to their quantum and surface effects. The choice of material and the way they are combined can be tailored to achieve specific goals. For example, in biomedical applications, hybrid nanoparticles can be engineered to have specific targeting abilities such as targeted drug delivery, theranostics, gene therapy, phototherapy, tissue regeneration, vaccines, antibacterial, biomolecules detection, imaging probes, tissue engineering, biosensing, and cancer treatment. They have enhanced qualities with increased target specificity and sensitivity, extended circulation times, and resistance to biological barriers.