Introduction Nanotechnology is the new phase of approach to modern solutions. In this analysis, the documentation would focus on the application of nanotechnology in the medical industry. A lot of research has been recently done to reduce the incompatibility of the nano particles to host optimization and target tissues. Nanotechnology in the medical industry has varied in application from drug delivery to the level of direction treatment incorporation. The analysis will therefore focus on the different sub disciplines with varied technical dimensions to facilitate nanomedical procedures. Nano diagnostics The nanoparticles have been incorporated in nano devices giving them a reliability to determine and predispose diseases in the cellular level. With the help of in vivo diagnosis, nanomedical devises can predetermine toxic or disease exposure, therefore providing an early solution before full blown impact of the infection (Park, 2016). Nanotechnology in Cell regeneration Regenerative medicine is another subfield in medicine that has put a lot of nanotechnology into practice. According to research, a lot of cellular and tissue regeneration is done in the field, which requires a lot of dorsal procedures to ensure maximum impact with limited struggle. Nanotechnology has facilitated medical atomic interaction with cellular component and manipulation of the cell components. In another context, the medical expertise has developed dendrimer and carbon fullerenes nanoparticle with intentions of interacting with specific tissue components which may serve as regenerative, diagnostic and anticancer mediators. More importantly, the human body system contains molecules which allows interactive reaction between the body cells and the nanoparticles, permitting progressive interaction with cellular components of the tissues (Re Gregori & Masserini, 2012). Medical monitoring Nanotechnology has also been incorporated in medical systems to monitor the medication and dosage. In the recent discovery it has been possible constructing micrometer scales which transmits information to Nano computers tracing the medication patterns and levels of drugs in the blood system. In another context, nanorobotic components facilitates determination of precise tissues and cells that needs operation, which in turn enhances accuracy during operations. The Nanotechnology uses bio intelligence and pseudo mimicry principles to trace the molecular vibration at the index level comparing to the corresponding patterns to determine the irregularity and monitoring of the cellular operation (Wilson, 2006). Nano dentistry The researchers have also had focus on Nano dentistry, Nanoparticles synthetic materials have been used to maintain healthy dental system. Nanomaterial engineering has facilitated dental naturalization, inducing materials with normal behavior including response to stimuli. Nanoparticles can also be fused in the dental system, monitoring the dental behavior during dental surgery. Nanotechnology in drug delivery Drug delivery has also been another concern in the medical industry, most of the tablets and syrup seems to be disturbing when administering. However, with nanotechnology, it has been possible to administer vaccines without a trace but still with the right component of the nutrients and ingredients. Consequently, nano robotics has been used to induce antiviral medication directly to the stem cells, having a sporadic response in countering the impacts of the viral infections from the stem cell. Nanotechnology has also been used for visualization purposes. Determination of drug metabolism, scientists tracked drug movement in the body by dying nanoparticles with different lights of varied wavelengths. The quantum of the medicine was determined with the lighting traced by a group of nanoparticles in the blood stream (Park, 2016). Cancer infection has been the most challenging factor in the recent generation. However, metallic nanotechnology which use metallic components which are bioactive and less reactive can deliver non-inflammatory effect to growing tumor. In the same way, nanotechnology will be used for therapeutic purposes. Research shows, nanotechnology is currently used for simulation and optimization which works in the protection of the neuron. The induction of metallic nano materials enhances the flow of neurons, where the Nano carriers also supports the delivery of proteins to the brain via the Central Nervous System.
functional gold nano particle
The application of antibacterial textile is the advanced approach to treatment of bacteria. The textile has been developed with antibacterial nanoparticles. The nanoparticles have a high level of organic specificity which focus on the restriction of bacterial growth. In another context, nanotechnology has reduced bacterial to antibiotic resistance. Researchers have invested in commercial production of Zinc Oxide nanoparticles which decreases the level of bacterial antibiotic resistance. Conclusion Therefore, from the analysis, nanotechnology is expanding its effectiveness and scale of operation especially in medicine. The dependence level on the nanotechnology develops from the great properties of nanoparticles enhancing the molecule compatibility to that of human cells. This explains the effectiveness of nanotechnology especially in emergency and hybrid medication process in the recent generation. With this in mind, nanotechnology can be much useful to the entire human life including control of chronic and viral diseases which still posses a challenge to the medical industry
References Park, T. H. (2016). Bioelectronic nose: Integration of biotechnology and nanotechnology. Nanomedicine: Nanotechnology, Biology and Medicine, 12(2), 453. doi:10.1016/j.nano.2015.12.015
Re, F., Gregori, M., & Masserini, M. (2012). Nanotechnology for neurodegenerative disorders. Nanomedicine: Nanotechnology, Biology and Medicine, 8, S51-S58. doi:10.1016/j.nano.2012.05.007
Wilson, R. (2006). Nanotechnology: the challenges of regulating known unknowns. Nanomedicine: Nanotechnology, Biology and Medicine, 2(4), 318. doi:10.1016/j.nano.2006.10.156
Outline
Introduction
Nanotechnology is the new phase of approach to modern solutions. In this analysis, the documentation would focus on the application of nanotechnology in the medical industry. A lot of research has been recently done to reduce the incompatibility of the nano particles to host optimization and target tissues. Nanotechnology in the medical industry has varied in application from drug delivery to the level of direction treatment incorporation. The analysis will therefore focus on the different sub disciplines with varied technical dimensions to facilitate nanomedical procedures.
Nano diagnostics
The nanoparticles have been incorporated in nano devices giving them a reliability to determine and predispose diseases in the cellular level. With the help of in vivo diagnosis, nanomedical devises can predetermine toxic or disease exposure, therefore providing an early solution before full blown impact of the infection (Park, 2016).
Nanotechnology in Cell regeneration
Regenerative medicine is another subfield in medicine that has put a lot of nanotechnology into practice. According to research, a lot of cellular and tissue regeneration is done in the field, which requires a lot of dorsal procedures to ensure maximum impact with limited struggle. Nanotechnology has facilitated medical atomic interaction with cellular component and manipulation of the cell components. In another context, the medical expertise has developed dendrimer and carbon fullerenes nanoparticle with intentions of interacting with specific tissue components which may serve as regenerative, diagnostic and anticancer mediators. More importantly, the human body system contains molecules which allows interactive reaction between the body cells and the nanoparticles, permitting progressive interaction with cellular components of the tissues (Re Gregori & Masserini, 2012).
Medical monitoring
Nanotechnology has also been incorporated in medical systems to monitor the medication and dosage. In the recent discovery it has been possible constructing micrometer scales which transmits information to Nano computers tracing the medication patterns and levels of drugs in the blood system. In another context, nanorobotic components facilitates determination of precise tissues and cells that needs operation, which in turn enhances accuracy during operations. The Nanotechnology uses bio intelligence and pseudo mimicry principles to trace the molecular vibration at the index level comparing to the corresponding patterns to determine the irregularity and monitoring of the cellular operation (Wilson, 2006).
Nano dentistry
The researchers have also had focus on Nano dentistry, Nanoparticles synthetic materials have been used to maintain healthy dental system. Nanomaterial engineering has facilitated dental naturalization, inducing materials with normal behavior including response to stimuli. Nanoparticles can also be fused in the dental system, monitoring the dental behavior during dental surgery.
Nanotechnology in drug delivery
Drug delivery has also been another concern in the medical industry, most of the tablets and syrup seems to be disturbing when administering. However, with nanotechnology, it has been possible to administer vaccines without a trace but still with the right component of the nutrients and ingredients. Consequently, nano robotics has been used to induce antiviral medication directly to the stem cells, having a sporadic response in countering the impacts of the viral infections from the stem cell. Nanotechnology has also been used for visualization purposes. Determination of drug metabolism, scientists tracked drug movement in the body by dying nanoparticles with different lights of varied wavelengths. The quantum of the medicine was determined with the lighting traced by a group of nanoparticles in the blood stream (Park, 2016).
Cancer infection has been the most challenging factor in the recent generation. However, metallic nanotechnology which use metallic components which are bioactive and less reactive can deliver non-inflammatory effect to growing tumor. In the same way, nanotechnology will be used for therapeutic purposes. Research shows, nanotechnology is currently used for simulation and optimization which works in the protection of the neuron. The induction of metallic nano materials enhances the flow of neurons, where the Nano carriers also supports the delivery of proteins to the brain via the Central Nervous System.
Conclusion
Therefore, from the analysis, nanotechnology is expanding its effectiveness and scale of operation especially in medicine. The dependence level on the nanotechnology develops from the great properties of nanoparticles enhancing the molecule compatibility to that of human cells. This explains the effectiveness of nanotechnology especially in emergency and hybrid medication process in the recent generation. With this in mind, nanotechnology can be much useful to the entire human life including control of chronic and viral diseases which still posses a challenge to the medical industry
References
Park, T. H. (2016). Bioelectronic nose: Integration of biotechnology and nanotechnology. Nanomedicine: Nanotechnology, Biology and Medicine, 12(2), 453. doi:10.1016/j.nano.2015.12.015
Re, F., Gregori, M., & Masserini, M. (2012). Nanotechnology for neurodegenerative disorders. Nanomedicine: Nanotechnology, Biology and Medicine, 8, S51-S58. doi:10.1016/j.nano.2012.05.007
Wilson, R. (2006). Nanotechnology: the challenges of regulating known unknowns. Nanomedicine: Nanotechnology, Biology and Medicine, 2(4), 318. doi:10.1016/j.nano.2006.10.156
Application of Nanotechnology in Medicine