Cellular Toxicity of Nanoparticles By Amber Cardell Nanoparticles
Cellular Toxicity of Nanoparticles By: Amber Cardell
Nanoparticles l l 10 -9 m – very small 1 -100 nm in size Characteristics different from bulk material to nanoscale Changes chemical and/or physical properties http: //www. sas. muohio. edu/pse/ppsfacu lty/kerr. html
Nanoparticles- High Surface Area to Volume Ratio l l l High surface tension Tendency to adhere and clump Increases solubility Drives diffusion Reduces melting temp Increases catalytic activity
Problems with Nanoparticles l l l l Readily pass through cell membranes Can penetrate RBCs Can penetrate nuclei Can pass the blood-brain barrier Increased mobility and reactivity Can overload phagocytes Can adhere to macromolecules, altering biochemical pathways
Regulation of Nanoparticles l l Not regulated by the EPA or FDA MSDS does not differentiate nanosize material Causes pollution as byproducts Commonly used in commercial products l l l Cosmetics Protective coatings Toothpaste Stain resistant clothing Suntan lotion
Materials and Methods l Cell culture l Chinese Hamster Ovary Cells (CHO-K 1) l l Transformed immortal cell line Sensitive to toxic agents Centrifuge cells Aseptic technique l l 70% ethanol- to sanitize all supplies UV light under hood to eliminate microbial contaminants in the work area
Materials and Methods l Controlled environment l l Culture plates and flasks 5% CO 2, 95% air 37°C Liquid Media l 90% Kaighn’s Modification § l l Essential nutrients for CHO cells 10% fetal bovine serum Penicillin-Streptomycin solution
Materials and Methods l Trypsin l l Hanks Balanced Salt Solution l l Detaches cells Rinses cells p. H indicator Solvent for nanoparticles PBS l Rinses cells
Particles Used l Latex Beads l l 800 nm- fine particulate matter Dyed blue 10 μl Talc particles l l 15 nm diameter Concentrations l l 0. 1 mg/ml 1. 0 mg/ml 10 mg/ml (protein content) Silica l l 7 nm diameter Concentrations l l l 0. 1 mg/ml 1. 0 mg/ml 10 mg/ml (protein content)
Toxicity Assays l l Phase Contrast Microscope Trypan Blue l l l Dead cells uptake dye Stored in nucleus Total Protein Content l l l Bradford assay Spectrophotometer l Standard curve Lower shows toxicity
CHO Cells- Control Cells treated with Media 24 hr exposure 100 x Normal Healthy Cell 400 x 1, 000 x
Experimental Results Cells treated with Latex Beads 10μl 24 hr exposure 100 x Beads inside cell 400 x 1, 000 x Beads outside cell
Experimental Results Cells treated with 1. 0 mg/ml talc 24 hr exposure 100 x 400 x 1, 000 x Dead cell
Experimental Results Cells treated with 1. 0 mg/ml Silica 24 hr exposure 100 x 400 x Dead Cell 1, 000 x
Cellular Toxicity
Total Cell Protein Content
Total Protein Content
Conclusions l l Nanoparticles were uptaken by the cells Cell mortality increased with exposure to nanoparticles Silica seemed to be the most toxic agent Further toxicity research is needed before continuing the use of nanoparticles in commercial products
Acknowledgements l l l Dr. Jacqueline Jordan- CSU Rishit Patel and Samantha Stuckey- CSU Derek Truyen Pham- Emory
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