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Project description:Transcriptome comparison to assess the responses of human monocytic cells (THP-1) to gold-nanoparticles (Au-NPs) of two different diameter sizes (5 or 20 nm) with different surface functional groups, i.e., alkylammonium bromide, alkyl sodium carboxylate, or poly(ethylene glycol) (PEG)-terminated thiolate Au-NPs.

Project description:Gold nanoparticles (Au NPs) are uniquely suited for various biomedical applications due to the combination of their optical properties with their easily functionalized surfaces. The Au NP surface can be tailored to improve biocompatibility while also attaching targeting ligands or drugs. However, information on how these tailored surface chemistries may affect cell gene expression is scarce. Using two model human cells line, human dermal fibroblasts and prostate cancer cells, microarray experiments measured gene expression over 27,000 human genes. Each of the cell lines was exposed to four related types of surface-modified Au NPs at two different concentrations, and the microarray data was analyzed by weighted gene correlation network analysis and gene functional annotation. Au NPs were shown to affect genes associated with a variety of cellular functions, and surface charge and chemistry were linked with the types of parthways changed and the degree of which those changes occured.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Gold nanoparticles (Au NPs) are uniquely suited for various biomedical applications due to the combination of their optical properties with their easily functionalized surfaces. The Au NP surface can be tailored to improve biocompatibility while also attaching targeting ligands or drugs. However, information on how these tailored surface chemistries may affect cell gene expression is scarce. Using two model human cells line, human dermal fibroblasts and prostate cancer cells, microarray experiments measured gene expression over 27,000 human genes. Each of the cell lines was exposed to four related types of surface-modified Au NPs at two different concentrations, and the microarray data was analyzed by weighted gene correlation network analysis and gene functional annotation. Au NPs were shown to affect genes associated with a variety of cellular functions, and surface charge and chemistry were linked with the types of parthways changed and the degree of which those changes occured. Nanoparticle induced gene expression in PC3 and HDF cells was measured after 24 hour exposure to nanoparticles of four different surface coating types. RNA from three separate culture samples were used for each nanoparticle-cell combinations, along with three control samples not exposed to nanoparticles at all.

Project description: Not available

Project description:Previous studies have shown that TiO2NPs induce lung inflammation in mice and have suggested that the degree of inflammation varies with their size and other physical and chemical properties, e.g., shapes, surface modifications and surface charge. It is currently unknown if the observed inflammation in mouse lungs following exposure to TiO2NPs will cause any disease in the long term. This study examined mouse lung responses to six individual TiO2NPs of varying sizes (10, 20 and 300 nm), surface modifications and shapes. C57BL/6 mice were exposed to 18 µg, 54 µg, 162 µg or 486 µg of TiO2NPs/mouse via direct deposition of particles in lungs. Lung fluid and lung tissue were sampled on day 1, day 28 and day 90. Changes in inflammation and gene expression in lung were profiled. Histopathological changes in lungs indicative of diseases were examined by microscopic techniques. The results confirmed that all TiO2NPs induce lung inflammation immediately after exposure. At the highest dose tested, this particular TiO2NPs with surface modification induced signs of lung fibrosis (a disease of regulatory importance for NMs. Although lung response induced by TiO2NPs is influenced by many of their properties, the results of the study indicated that certain surface modification may play role in causing a disease.