掺入硝基的多层石墨烯纳米颗粒的急性神经毒性及其改变镉2+/铅2+/汞2+诱导的脑干神经末梢损伤的能力评估

M. Dudarenko
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引用次数: 0

摘要

石墨烯材料被广泛应用于不同的技术领域,并作为环境污染成分释放到水体和空气中。掺氮石墨烯纳米材料具有巨大的应用潜力,尤其是在能量存储、电化学传感器和废水处理方面。目标:评估石墨烯的神经毒性风险评估掺氮多层石墨烯的神经毒性风险。方法。在此,通过在以 NaN3 为基质的电解液中电化学剥离高纯度石墨棒的方法合成了氮掺杂多层石墨烯纳米粒子(N-MLG),并使用 TEM、AFM 和紫外可见光谱对其进行了表征。通过分析细胞外兴奋性神经递质 L-[14C] 谷氨酸和抑制性神经递质 [3H]GABA 的水平,评估了 N-MLG 在离体皮层神经末梢(突触体)中的神经活性特征。结果显示结果显示,在 0.01-0.5 毫克/毫升的浓度范围内,N-MLG 不会影响 L-[14C] 谷氨酸和[3H]GABA 的细胞外突触体水平。为了分析 N-MLG 在生物系统中与重金属相互作用的能力,研究人员利用 Cd2+/Pb2+/Hg2+ 诱导的神经末梢急性神经中毒模型对 N-MLG 进行了研究。结果表明,N-MLG 不会改变 Cd2+/Pb2+/Hg2+ 诱导的 L-[14C] 谷氨酸和 [3H]GABA 细胞外水平的增加。结论。N-MLG 不具有神经毒性,在 0.01-1 毫克/毫升的浓度范围内具有生物相容性。在生物系统中,N-MLG 不会减轻或加重 Cd2+/Pb2+/Hg2+ 诱导的神经末梢神经毒性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
ASSESSMENT OF ACUTE NEUROTOXICITY OF NITROGEN-DOPED MULTILAYER GRAPHENE NANOPARTICLES AND THEIR CAPABILITY TO CHANGE Cd2+/Pb2+/Hg2+-INDUCED INJURY IN BRAIN CORTEX NERVE TERMINALS
Graphene materials are widely used in different technologies and certainly released into aquatic and air surroundings being environmental pollution components. Nitrogen‑doped graphene nanomaterials have great potential for application, in particular, in energy storage, as electrochemical sensors and waste water treatment. Aim. Evaluate neurotoxic risk of nitrogen-doped multilayer graphene. Methods. Here, nitrogen-doped multilayer graphene nanoparticles (N-MLG) were synthesized by means of electrochemical exfoliation of high-purity graphite rods in NaN3-based electrolyte and characterised using TEM, AFM and UV-vis spectroscopy. Neuroactive features of N-MLG were assessed in isolated cortex nerve terminals (synaptosomes) analysing the extracellular level of excitatory neurotransmitter L-[14C] glutamate and inhibitory one [3H]GABA. Results. It was revealed that N-MLG did not affect the extracellular synaptosomal levels of L-[14C] glutamate and [3H]GABA within the concentration range 0.01–0.5 mg/ml, and an increase in a concentration up to 1 mg/ml caused an insignificant increase (tendency to increase) in these levels for both neurotransmitters. To analyse a capability of interaction with heavy metals in biological system, N-MLG was investigated using model of acute Cd2+/Pb2+/Hg2+-induced neurotoxicity in nerve terminals. In was revealed that Cd2+/Pb2+/Hg2+-induced increase in the extracellular level of L-[14C] glutamate and [3H]GABA was not changed by N-MLG. Conclusions. N-MLG does not possess neurotoxic signs and is biocompatible within the concentration range 0.01–1 mg/ml. In biological system, N-MLG did not mitigate/aggravate Cd2+/Pb2+/Hg2+-induced neurotoxicity in nerve terminals.
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