Arnt Johnsen scite author profile

Fluoroacetate and its toxic metabolite fluorocitrate cause inhibition of aconitase. In brain tissue, both substances are preferentially taken up by glial cells and leads to inhibition of the glial TCA cycle. It is important to realise, however, that the glia‐specificity of these compounds depends both on the dosage and on the model used. The glia‐inhibitory effect of fluorocitrate as obtained by intracerebral microinjection in vivo is reversible within 24 h. A substantial inhibition of the glial TCA cycle by systemic administration of fluoroacetate requires a lethal dose. Inhibition of the glial aconitase leads to accumulation of citrate and to a reduction in the formation of glutamine. Whereas the former is likely to be responsible for the main toxic effect of these compounds possibly by chelation of free calcium ions, it is the latter that has received most attention in the study of glial‐neuronal interactions, since glutamine is an important precursor for transmitter glutamate and GABA. GLIA 21: 106–113, 1997. © 1997 Wiley‐Liss, Inc.

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Use of fluorocitrate and fluoroacetate in the study of brain metabolism

Fonnum¹,

Johnsen²,

Hassel³

1997

Glia

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Fluoroacetate and its toxic metabolite fluorocitrate cause inhibition of aconitase. In brain tissue, both substances are preferentially taken up by glial cells and leads to inhibition of the glial TCA cycle. It is important to realise, however, that the glia-specificity of these compounds depends both on the dosage and on the model used. The glia-inhibitory effect of fluorocitrate as obtained by intracerebral microinjection in vivo is reversible within 24 h. A substantial inhibition of the glial TCA cycle by systemic administration of fluoroacetate requires a lethal dose. Inhibition of the glial aconitase leads to accumulation of citrate and to a reduction in the formation of glutamine. Whereas the former is likely to be responsible for the main toxic effect of these compounds possibly by chelation of free calcium ions, it is the latter that has received most attention in the study of glial-neuronal interactions, since glutamine is an important precursor for transmitter glutamate and GABA.

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Why biota still accumulate high levels of PCB after removal of PCB contaminated sediments in a Norwegian fjord

2002

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Environmental risk assessment of white phosphorus from the use of munitions — A probabilistic approach

Voie

Johnsen

Strømseng

et al. 2010

Science of The Total Environment

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Arnt Johnsen

Selective inhibition of glial cell metabolism in vivo by fluorocitrate

Use of fluorocitrate and fluoroacetate in the study of brain metabolism

Use of fluorocitrate and fluoroacetate in the study of brain metabolism

Why biota still accumulate high levels of PCB after removal of PCB contaminated sediments in a Norwegian fjord

Environmental risk assessment of white phosphorus from the use of munitions — A probabilistic approach

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