Replicating human characteristics: A promising animal model of central fatigue

Yifei Zhang; Zehan Zhang; Qingqian Yu; Bijuan Lan; Qinghuan Shi; Ruting Li; Ziheng Jiao; Weiyue Zhang; Feng Li

doi:10.1016/j.brainresbull.2024.110951

Replicating human characteristics: A promising animal model of central fatigue

Brain Res Bull. 2024 Apr 19:212:110951. doi: 10.1016/j.brainresbull.2024.110951. Online ahead of print.

Authors

Yifei Zhang¹, Zehan Zhang¹, Qingqian Yu¹, Bijuan Lan¹, Qinghuan Shi¹, Ruting Li¹, Ziheng Jiao¹, Weiyue Zhang², Feng Li³

Affiliations

¹ Beijing University of Chinese Medicine, The northeast corner of the intersection of Sunshine South Street and Baiyang East Road, Beijing 102488, China.
² Beijing University of Chinese Medicine, The northeast corner of the intersection of Sunshine South Street and Baiyang East Road, Beijing 102488, China. Electronic address: 201901023@bucm.edu.cn.
³ Beijing University of Chinese Medicine, The northeast corner of the intersection of Sunshine South Street and Baiyang East Road, Beijing 102488, China. Electronic address: lifeng95@vip.sina.com.

PMID: 38642899
DOI: 10.1016/j.brainresbull.2024.110951

Abstract

Central fatigue is a common pathological state characterized by psychological loss of drive, lack of appetite, drowsiness, and decreased psychic alertness. The mechanism underlying central fatigue is still unclear, and there is no widely accepted successful animal model that fully represents human characteristics. We aimed to construct a more clinically relevant and comprehensive animal model of central fatigue. In this study, we utilized the Modified Multiple Platform Method (MMPM) combined with alternate-day fasting (ADF) to create the animal model. The model group rats are placed on a stationary water environment platform for sleep deprivation at a fixed time each day, and they were subjected to ADF treatment. On non-fasting days, the rats were allowed unrestricted access to food. This process was sustained over a period of 21 days. We evaluated the model using behavioral assessments such as open field test, elevated plus maze test, tail suspension test, Morris water maze test, grip strength test, and forced swimming test, as well as serum biochemical laboratory indices. Additionally, we conducted pathological observations of the hippocampus and quadriceps muscle tissues, transmission electron microscope observation of mitochondrial ultrastructure, and assessment of mitochondrial energy metabolism and oxidative stress-related markers. The results revealed that the model rats displayed emotional anomalies resembling symptoms of depression and anxiety, decreased exploratory behavior, decline in learning and memory function, and signs of skeletal muscle fatigue, successfully replicating human features of negative emotions, cognitive decline, and physical fatigue. Pathological damage and mitochondrial ultrastructural alterations were observed in the hippocampus and quadriceps muscle tissues, accompanied by abnormal mitochondrial energy metabolism and oxidative stress in the form of decreased ATP and increased ROS levels. In conclusion, our ADF+MMPM model comprehensively replicated the features of human central fatigue and is a promising platform for preclinical research. Furthermore, the pivotal role of mitochondrial energy metabolism and oxidative stress damage in the occurrence of central fatigue in the hippocampus and skeletal muscle tissues was corroborated.

Keywords: Animal model; Behavioral testing; Central fatigue; Mitochondrion; Oxidative stress.