School of Engineering, Brown University, Providence, RI 02912, USA.
Int J Nanomedicine. 2011;6:343-50. doi: 10.2147/IJN.S16881. Epub 2011 Feb 11.
Consumer nanotechnology is a growing industry. Silver nanoparticles are the most common nanomaterial added to commercially available products, so understanding the influence that size has on toxicity is integral to the safe use of these new products. This study examined the influence of silver particle size on Drosophila egg development by comparing the toxicity of both nanoscale and conventional-sized silver particles.
The toxicity assays were conducted by exposing Drosophila eggs to particle concentrations ranging from 10 ppm to 100 ppm of silver. Size, chemistry, and agglomeration of the silver particles were evaluated using transmission electron microscopy, X-ray photoelectron spectroscopy, and dynamic light scattering.
This analysis confirmed individual silver particle sizes in the ranges of 20-30 nm, 100 nm, and 500-1200 nm, with similar chemistry. Dynamic light scattering and transmission electron microscope data also indicated agglomeration in water, with the transmission electron microscopic images showing individual particles in the correct size range, but the dynamic light scattering z-average sizes of the silver nanoparticles were 782 ± 379 nm for the 20-30 nm silver nanoparticles, 693 ± 114 nm for the 100 nm silver nanoparticles, and 508 ± 32 nm for the 500-1200 nm silver particles. Most importantly, here we show significantly more Drosophila egg toxicity when exposed to larger, nonnanometer silver particles. Upon exposure to silver nanoparticles sized 20-30 nm, Drosophila eggs did not exhibit a statistically significant (P < 0.05) decrease in their likelihood to pupate, but eggs exposed to larger silver particles (500-1200 nm) were 91% ± 18% less likely to pupate. Exposure to silver nanoparticles reduced the percentage of pupae able to emerge as adults. At 10 ppm of silver particle exposure, only 57% ± 48% of the pupae exposed to 20-30 nm silver particles became adults, whereas 89% ± 25% of the control group became adults, and 94% ± 52% and 91% ± 19% of the 500-1200 nm and 100 nm group, respectively, reached adulthood.
This research provides evidence that nanoscale silver particles (<100 nm) are less toxic to Drosophila eggs than silver particles of conventional (>100 nm) size.
消费者纳米技术是一个不断发展的行业。纳米银是最常见的添加到市售产品中的纳米材料,因此了解尺寸对毒性的影响对于安全使用这些新产品至关重要。本研究通过比较纳米级和常规尺寸银颗粒的毒性,研究了银颗粒尺寸对果蝇卵发育的影响。
通过将果蝇卵暴露于浓度范围为 10 ppm 至 100 ppm 的银粒子中,进行毒性测定。使用透射电子显微镜、X 射线光电子能谱和动态光散射评估银粒子的尺寸、化学性质和团聚情况。
该分析确认了 20-30nm、100nm 和 500-1200nm 范围内的单个银粒子尺寸,具有相似的化学性质。动态光散射和透射电子显微镜数据也表明了在水中的团聚,透射电子显微镜图像显示了正确尺寸范围内的单个颗粒,但动态光散射 z 均粒径为 20-30nm 的银纳米粒子为 782±379nm,100nm 的银纳米粒子为 693±114nm,500-1200nm 的银粒子为 508±32nm。最重要的是,在这里,我们显示出在暴露于更大的非纳米银粒子时,果蝇卵的毒性明显更高。当暴露于 20-30nm 大小的银纳米粒子时,果蝇卵的化蛹可能性没有统计学意义上的显著降低(P<0.05),但暴露于较大的银颗粒(500-1200nm)时,化蛹的可能性降低了 91%±18%。暴露于银纳米粒子会降低能够发育成成虫的蛹的百分比。在 10ppm 的银颗粒暴露下,仅 57%±48%暴露于 20-30nm 银纳米粒子的蛹发育成成虫,而对照组的成虫比例为 89%±25%,500-1200nm 和 100nm 组分别有 94%±52%和 91%±19%的蛹发育成成虫。
本研究提供的证据表明,与常规尺寸(>100nm)的银颗粒相比,纳米级银颗粒(<100nm)对果蝇卵的毒性更小。
