Threshold for Maximal Electroshock Seizures (MEST) at Three Developmental Stages in Young Mice

Overview

Journal Zool Res

Publisher Science Press

Specialties Biology
Veterinary Medicine

Date 2019 Apr 24

PMID 31011134

Citations 3

Authors

Cheng Xiang

Zhi-Na Li

Tian-Zhuang Huang

Jing-Hui Li

Lei Yang

Jing-Kuan Wei

Affiliations

Soon will be listed here.

Abstract

Early brain development after birth is extremely dynamic, suggesting that potential functional changes occur during this period. In this study, the maximal electroshock seizure threshold (MEST) was used to explore the electrophysiological variation among three developmental stages in young mice (no more than 5 weeks old). The induced electroshock seizure (ES) behavior of early postnatal mice (1-2-weeks old) differed from that during weaning (3 weeks old) and early puberty (4-5-weeks old). Thus, we further explored their respective characteristic responses to the ES parameters. When the stimulation current (SC) was limited to 4.0 mA, only the 1-2-week-old mice were induced to exhibit ES behavior at voltages of 30 V and 40 V, indicating they were more sensitive to maximal electroshock seizure (MES) (response to lower voltage). Surprisingly, however, they showed substantially lower mortality than the older groups under higher voltage conditions (60, 100, 160, and 200 V), suggesting better tolerance to the SC. We also found that when the current limit decreased to 3.5 mA, the 4-5-week-olds mice exhibited stable ES behavior with low mortality, while for 3-week-olds mice, the SC limit required to be reduced to 1.5 mA. In conclusion, our findings showed that neural sensitivity to MES was significantly different in young mice before puberty. Thus, greater attention should be given to distinguishing the developmental period of mice, especially in electrophysiological examination.

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