Acute ischemic stroke (AIS) accounts for 70% of all stroke cases and is associated with markedly high patient disability and mortality rates (1). Early diagnosis and timely intervention would significantly reduce these rates and improve the prognostic outcomes and quality of life of patients with AIS (2,3). Currently, AIS is diagnosed using computed tomography (CT). However, in the early stages of the disease, CT cannot identify any abnormalities in approximately 40-50% of the patients with AIS (4). Although interleukin-6 (5,6), neuron-specific enolase (NSE) (7), glial fibrillary acidic protein (8), and 25-hydroxyvitamin D (9) are associated with the onset of AIS, additional markers are needed owing to the low specificity and sensitivity of these markers.

MicroRNAs (miRNAs)—small endogenous RNAs comprising 18-24 noncoding bases (10)—have been found to be involved in various pathophysiological processes (i.e., cell proliferation, immunity, metabolism, and tumorigenesis) via the post-transcriptional regulation of mRNAs (11). miRNAs have been detected in the cerebrospinal fluid, urine, serum, and plasma samples of patients with AIS, suggesting their diagnostic value (12). Their expression levels change significantly during the pathogenesis of AIS, a process that involves platelet aggregation, endothelial dysfunction, and neuronal injury. Previous studies have found that mir-424 and miRNA-15a are closely correlated with the occurrence of stroke (13,14). Indeed, the development of AIS has been found to correlate with changes in miRNA levels in the peripheral blood of patients (15).

The miRNA miR-9-5p is likely involved in the development of AIS, although its exact role is unclear. It has been shown to attenuate ischemic stroke by directly targeting endoplasmic reticulum metallopeptidase 1 (ERMP1)-mediated endoplasmic reticulum stress (16). However, other in vivo and in vitro studies have revealed that blocking of miR-9-5p and miR-128-3p activity could result in reduced ischemic stroke-induced neuronal cell death and infract volume (17). Given that the relationship between AIS and serum miR-9-5p and miR-128-3p levels has not yet been fully explored, the present study was carried out to investigate whether assessment of the serum levels of these two miRNAs has clinical utility in the early diagnosis and treatment of this type of stroke.

AIS, which is the most prevalent cerebrovascular disease, has a morbidity and mortality rate of approximately 3-5% and a disability rate of 34-37% (1,18). Early diagnosis and treatment would effectively reduce the death and disability rates associated with this disease and significantly improve the quality of life of patients (19).

Brain tissues contain diverse types of miRNAs (20). Due to their very low molecular mass, miRNAs are readily secreted into the blood, and their levels in the serum are highly correlated with those in the brain tissue (21). Peripheral blood miRNAs are easily detected and have been widely used in the clinical diagnosis of various diseases because of their various advantages, such as the low invasiveness of the methods used for their analysis (22-27). In this study, the serum miR-9-5p and miR-128-3p levels were quantified using qPCR and were found to be significantly higher in patients with AIS than those in healthy individuals. Serum miR-9-5p and miR-128-3p levels exhibited a significant negative correlation with the prognostic outcomes in AIS. Therefore, the serum levels of these two miRNAs exhibit clinical utility in the early diagnosis and prevention of AIS.

Previous studies have focused on the relationships between endoplasmic reticulum stress, miRNAs, and cerebral ischemia (28). For example, miR-335 was found to be downregulated during AIS pathogenesis. Additionally, miR-335 overexpression was found to promote stress granule formation and inhibit apoptosis by targeting Rho-associated protein kinase 2 (29). The ischemic zone in rats has been shown to have reduced miR-9-5p expression. Furthermore, another study showed that the upregulation of miR-9-5p expression could improve cell viability and inhibit both lactate dehydrogenase activity and neuronal apoptosis by directly targeting ERMP1 (16). miR-9-5p expression in the brain can assist in the growth and proliferation of the nerves (30). Additionally, miR-9a-5p levels were significantly reduced in a rat model of middle cerebral artery occlusion (31). However, Sørensen et al. found that the levels of miR-9-5p and miR-128-3p were increased in the cerebrospinal fluid of patients with infarcts greater than 2 cm3 in volume (15). Such differences may be attributed to the different sample types used for miRNA detection. Previous studies that have compared the distribution of the same miRNA in different samples revealed that the levels are different in various types of samples and that many factors can affect their detection (32). In our study, miR-9-5p was found to be upregulated during AIS pathogenesis, which is similar to the findings of Sørensen et al. (15). We hypothesize that during the onset of acute stroke, the viability of neuronal, glial, and other cells is reduced, and in severe cases, apoptosis occurs in response to ischemia and hypoxia. By targeting B-cell lymphoma 2-like 11, miR-9-5p can inhibit neuronal apoptosis in AIS (33), and the upregulation of miR-9-5p promotes neuronal self-repair. In a comparison of 65 patients with stroke and 66 healthy individuals, researchers found a significant increase in exosome-derived miR-9 levels in the stroke group, suggesting that brain exosomes can cross the blood-brain barrier and enter the peripheral circulation (34). Other researchers found that miR-9-3p levels in the hippocampus and exosomes were increased in mice in which the central nervous system neurons had been selectively damaged, indicating the potential of this miRNA as a marker of brain injury (35). Therefore, in the early stages of stroke, detection of miR-9-5p in the blood of patients using relevant experimental technology could help clarify the diagnosis of early brain injury in stroke, and provide insights for developing efficient treatment strategies for AIS.

It has been reported that miR-128b is significantly upregulated in the plasma of patients with ischemic stroke compared to that in healthy individuals (36). Another study demonstrated a significant increase in the level of miR-128-3p in the cerebrospinal fluid of patients with AIS compared to that in the cerebrospinal fluid of the control patients (15). Our finding of a significant increase in serum miR-128-3p levels in patients with AIS is consistent with the results of the aforementioned studies. Although our results are not entirely comparable owing to the different types of samples used in various studies, our findings are supported to some extent. Therefore, in the early stages of stroke, the detection of high serum miR-128-3p levels can also be used as an important criterion for predicting the occurrence of neuronal apoptosis in patients, thus providing clues for the early diagnosis of ischemic stroke.

Our study has several limitations. First, the severity of AIS was not categorized, which may have led to study bias. Second, our cohort of patients with AIS was small; therefore, further validation in a larger multicenter study is warranted. Finally, the patients need to be followed up for a prolonged period.

In conclusion, serum miR-9-5p and miR-128-3p levels exhibit clinical utility in the early diagnosis of acute cerebral infarction and can therefore be used as potential markers for the diagnosis and treatment of AIS.

Wang Q, Wang F and Chen Y conceived the project and designed and performed the experiments. Fu F, Liu J, and Sun W analyzed the data. Wang Q and Chen Y wrote and revised the manuscript.