Autism is a serious neurodevelopmental disorder that has gained widespread social attention and often leads to lifelong mental disability in children. The prevalence of autism continues to climb, increasing 227-fold in the last 20 years. Anxiety disorders are common concomitant disorders of autism, often affecting the improvement of core symptoms in children with autism and increasing the difficulty of treatment. VPA-induced rat models of autism are widely used in basic and preclinical studies. A single intraperitoneal injection of 600 mg/kg of VPA to pregnant rats at day 12.5 of the rodent embryonic period, a critical period for neural tube development, induces neurogenic inflammation in neonatal rats, which exhibit ASD-like behavior and affects skeletal development, resulting in tail curvature and limb deformities in neonatal rats[28].
Studies have shown that there is a correlation between the severity of behaviors such as communication disorders and central neuroinflammation in patients with ASD[29]. There is an important link between neuroinflammation and the development of autistic anxiety[30]. Therefore, suppression of neuroinflammation has become one of the directions of neuroprotection. The basic pathogenesis of anxiety disorders is the disorder of emotion and the loss of drainage of the liver in traditional Chinese medicine. Modern pharmacological studies have shown that the main components of XYS contain chai hu saponin, angelica polysaccharide, glycyrrhetinic acid, etc., which have anti-inflammatory, immune function regulation, and antioxidant effects[18, 20]. Numerous studies have confirmed the effectiveness of XYS in the treatment of autism and anxiety disorders; therefore, the present study explores XYS from the perspective of its anti-neuroinflammatory mechanism based on the above.
The act of burying marbles has been used to study repetitive stereotypic behavior in animals[21], and our findings showed increased stereotypic behavior in rats with autism. Rats rely on the larynx to emit ultrasound for communication over short distances in underground burrows; therefore, the USV test can be used to assess the social competence of rats[22], and our findings show vocalization deficits in autistic rats with a reduced number of vocalizations at 50 kHz, indicating reduced social communication in autistic rats. TST is widely used to assess the social behavior of animals in studies[23], and the results of our experiments showed that autistic rats exhibited significant social impairment. The cognitive functions of animals are generally evaluated by learning and memory abilities, which became significantly worse in autistic rats in the NOR task[24]. All of the above findings indicate that the autistic rats were successfully modeled in this study.
The OFT used the animals' nature to explore novel environments and avoid open environments to evaluate the animals' alertness and anxiety status[25], and the reduced time spent in the central area by rats in the VPA group indicated a high level of anxiety. The EPM uses the animal's exploratory nature and fear of heights to evaluate the anxiety level of the animal[26]. The results of our study showed that rats in the VPA group spent significantly less time in the open arms and entered the closed arms more often. In addition, the sucrose consumption rate was a valid indicator of the response to the animals' lack of pleasure due to anxiety[27]. The results of our study showed that the sucrose consumption rate of rats in the VPA group was significantly lower, indicating a reduced interest and higher anxiety level. These indicators reflect the increased anxiety behavior of rats in the VPA group. In contrast, the use of XYS played a significant role in alleviating the autistic and anxious behaviors of rats.
Symptoms of ASD, such as stereotypic behaviors and difficulties with mood and emotion recognition, are closely related to autonomic nervous system (ANS) dysfunction[31]. The ANS is a pathway system connecting the heart to the central nervous system, mediated by a variety of chemicals that maintain the body's ability to adapt acutely to stress, through parasympathetic and sympathetic stability to maintain homeostasis[32]. ANS indicators can assist in assessing the severity of ASD, and patients with ASD tend to have elevated heart rate, decreased parasympathetic activity, increased sympathetic activity, and decreased cardiac vagal activity[33]. The vagus nerve is the longest in the body and represents the physiological basis of the parasympathetic nervous system. Heart rate is mainly controlled by sympathetic and parasympathetic nerves. Heart rate variability (HRV) is a commonly used measure of peripheral ANS activity[34], and HRV testing in the ASD patients has shown that patients exhibit reduced autonomic flexibility to environmental changes and reduced control of the heart due to a lack of stability of the biological system[35]. In the present study, our findings showed that rats in the VPA group had reduced HRV and autonomic dysfunction, while XYS improved autonomic function in rats with autism.
Microglia are the resident immune cells of the central nervous system, and the morphology is divided into branched and amoeboid forms. In the resting state, microglia appear as branching cells with small cytosomes and long protrusions, and in response to neuroinflammatory stimuli, microglia are activated and appear as amoeboid cells with larger cytosomes and shorter protrusions[36]. Activated microglia can promote the release of cytotoxic factors, leading to neuronal damage. Studies have shown increased neuroinflammation, microglial activation, and increased density in hippocampal and amygdala tissues of rats with autism[37]. Ionized calcium-binding adaptor molecule 1 (Iba-1) is a protein marker specifically expressed by microglia[38]. In the current study, Iba-1 positive cells were increased and showed activation in the brain tissues of rats in the VPA group. In the VPA + XYS group, the brain Iba-1 levels of rats tended to normalize, suggesting that after 21 days of XYS treatment, the autistic and anxious behaviors of the rats were improved, suggesting that XYS inhibits the excessive activation of microglia, alleviates inflammation in brain tissues, and reduces the accumulation of neurotoxic products.
The hippocampus is located in the medial temporal lobe of the brain and is responsible for functions such as memory, learning, and emotion management. The four hippocampal subregions are CA1, CA2, CA3, and CA4. The CA3 region and CA2 region are adjacent to the dentate gyrus on both sides. The CA3 region is the largest in the hippocampus, which receives nerve fibers from the dentate granule cells on its proximal dendrites[38]. Previous studies have shown that impaired axonal activation of pyramidal cells in the CA1 region of the rodent hippocampus and abnormalities in presynaptic neurotransmitter release in the CA3 region may contribute to anxiety behavior[3]. In addition, there is a complex relationship between the amygdala and core symptoms of ASD and anxiety. The basolateral amygdala (BLA) region and the central amygdala (CeA) region are the most critical regions for generating anxiety and fear. Increased excitability in the BLA region leads to increased anxiety and further exacerbates social deficits in children with autism[39]. The dendritic density of neurons in the CeA region is reduced in anxious rats[40]. This study investigated the positive number and morphology of microglia in hippocampal and amygdala brain regions as well as the effect of XYS on microglia number and activation. Our findings indicated that XYS could alleviate autistic behaviors and anxiety behaviors in valproic acid-induced autistic rats, which could be mediated by the inhibition of microglial activation.
In conclusion, XYS can significantly improve anxiety behavior, improve autonomic function, inhibit microglial activation in the hippocampus and amygdala in rats with autism, and thus reduce central nervous system inflammation, which has potential for clinical application. However, XYS has a complex composition, and its molecular mechanism for neuroinflammation deserves further exploration.