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Positron emission tomography imaging of cerebral glucose metabolism and type 1 cannabinoid receptor availability during temporal lobe epileptogenesis in the amygdala kindling model in rhesus monkeys
Author(s) -
Cleeren Evy,
Casteels Cindy,
Goffin Karolien,
Koole Michel,
Van Laere Koen,
Janssen Peter,
Van Paesschen Wim
Publication year - 2018
Publication title -
epilepsia
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.687
H-Index - 191
eISSN - 1528-1167
pISSN - 0013-9580
DOI - 10.1111/epi.14059
Subject(s) - kindling , epileptogenesis , amygdala , neuroscience , endocrinology , medicine , temporal lobe , epilepsy , psychology , chemistry
Summary Objective We investigated changes in the endocannabinoid system and glucose metabolism during temporal lobe epileptogenesis. Methods Because it is rarely possible to study epileptogenesis in humans, we applied the electrical amygdala kindling model in nonhuman primates to image longitudinal changes in type 1 cannabinoid receptor ( CB 1R) binding and cerebral glucose metabolism. Two rhesus monkeys received [ 18 F]‐ MK ‐9470 and fluorodeoxyglucose–positron emission tomography ([ 18 F]‐ FDG ‐PET) scans in each of the 4 kindling stages to quantify relative changes over time of CB 1R binding and cerebral glucose metabolism in vivo. We constructed z ‐score images relative to a control group (n = 8), and considered only those changes measured in both kindled animals by calculating the binary conjunction image per kindling stage. Results The seizure‐onset zone exhibited an increased CB 1R binding and a decreased glucose metabolism, which both aggravated gradually in extent and intensity throughout kindling. The ipsilateral thalamus and insula showed hypometabolism that coincided with an increase and a decrease in CB 1R binding, respectively. These changes also became gradually more severe throughout kindling and overlapped with ictal perfusion changes during the final stage of amygdala kindling, with hyperperfusion in the ipsilateral thalamus and hypoperfusion in the ipsilateral insula. Significance The observed changes in CB 1R binding may reflect a combination of a protective mechanism of neurons against seizure activity that becomes stronger over time to combat more severe seizures, and on the other hand, a process of epileptogenesis that facilitates seizure activity and generalization, depending on the cell type involved in those specific regions. This study provides unique evidence that the CB 1R is dynamically and progressively involved from the start of mesial temporal lobe epileptogenesis.