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Polyamidoamine dendrimer impairs mitochondrial oxidation in brain tissue

Nyitrai, Gabriella and Héja, László and Jablonkai, István and Pál, Ildikó and Benéné Visy, Júlia and Kardos, Julianna (2013) Polyamidoamine dendrimer impairs mitochondrial oxidation in brain tissue. JOURNAL OF NANOBIOTECHNOLOGY, 11 (1). ISSN 1477-3155

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Abstract

Background: The potential nanocarrier polyamidoamine (PAMAM) generation 5 (G5-NH2) dendrimer has been shown to evoke lasting neuronal depolarization and cell death in a concentration-dependent manner. In this study we explored the early progression of G5-NH2 action in brain tissue on neuronal and astroglial cells.Results: In order to describe early mechanisms of G5-NH2 dendrimer action in brain tissue we assessed G5-NH2 trafficking, free intracellular Ca2+ and mitochondrial membrane potential (ΨMITO) changes in the rat hippocampal slice by microfluorimetry. With the help of fluorescent dye conjugated G5-NH2, we observed predominant appearance of the dendrimer in the plasma membrane of pyramidal neurons and glial cells within 30 min. Under this condition, G5-NH2 evoked robust intracellular Ca2+ enhancements and ΨMITO depolarization both in pyramidal neurons and astroglial cells. Intracellular Ca2+ enhancements clearly preceded ΨMITO depolarization in astroglial cells. Comparing activation dynamics, neurons and glia showed prevalence of lasting and transient ΨMITO depolarization, respectively. Transient as opposed to lasting ΨMITO changes to short-term G5-NH2 application suggested better survival of astroglia, as observed in the CA3 stratum radiatum area. We also showed that direct effect of G5-NH2 on astroglial ΨMITO was significantly enhanced by neuron-astroglia interaction, subsequent to G5-NH2 evoked neuronal activation.Conclusion: These findings indicate that the interaction of the PAMAM dendrimer with the plasma membrane leads to robust activation of neurons and astroglial cells, leading to mitochondrial depolarization. Distinguishable dynamics of mitochondrial depolarization in neurons and astroglia suggest that the enhanced mitochondrial depolarization followed by impaired oxidative metabolism of neurons may be the primary basis of neurotoxicity. © 2013 Nyitrai et al.; licensee BioMed Central Ltd.

Item Type: Article
Uncontrolled Keywords: PAMAM dendrimer; Nanotoxicity; Mitochondrial depolarization; Calcium enhancement; brain tissue
Subjects: R Medicine / orvostudomány > RM Therapeutics. Pharmacology / terápia, gyógyszertan
SWORD Depositor: MTMT SWORD
Depositing User: MTMT SWORD
Date Deposited: 16 Jul 2013 12:01
Last Modified: 16 Jul 2013 12:01
URI: http://real.mtak.hu/id/eprint/5965

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