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  • 标题:Unmodified CdSe Quantum Dots Induce Elevation of Cytoplasmic Calcium Levels and Impairment of Functional Properties of Sodium Channels in Rat Primary Cultured Hippocampal Neurons
  • 作者:Mingliang Tang ; Tairan Xing ; Jie Zeng
  • 期刊名称:Environmental Health Perspectives
  • 印刷版ISSN:0091-6765
  • 电子版ISSN:1552-9924
  • 出版年度:2008
  • 卷号:116
  • 期号:7
  • 页码:915-922
  • DOI:10.1289/ehp.11225
  • 语种:English
  • 出版社:OCR Subscription Services Inc
  • 摘要:Background The growing applications of nanotechnologic products, such as quantum dots (QDs), increase the likelihood of exposure. Furthermore, their accumulation in the bioenvironment and retention in cells and tissues are arousing increasing worries about the potentially harmful side effects of these nanotechnologic products. Previous studies concerning QD cytotoxicity focused on the reactive oxygen species produced by QDs. Cellular calcium homeostasis dysregulation caused by QDs may be also responsible for QD cytotoxicity. Meanwhile the interference of QDs with voltage-gated sodium channel (VGSC) current (INa) may lead to changes in electrical activity and worsen neurotoxicologic damage. Objective We aimed to investigate the potential for neurotoxicity of cadmium selenium QDs in a hippocampal neuronal culture model, focusing on cytoplasmic calcium levels and VGSCs function. Methods We used confocal laser scanning and standard whole-cell patch clamp techniques. Results We found that a ) QDs induced neuron death dose dependently; b ) cytoplasmic calcium levels were elevated for an extended period by QD treatment, which was due to both extracellular calcium influx and internal calcium release from endoplasmic reticulum; and c ) QD treatment enhanced activation and inactivation of INa, prolonged the time course of activation, slowed INa recovery, and reduced the fraction of available VGSCs. Conclusion Results in this study provide new insights into QD toxicology and reveal potential risks of their future applications in biology and medicine.
  • 关键词:calcium overload; cell viability; nanoparticles; QD; voltage-gated sodium channels
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