Astragaloside and/or Hydroxysafflor Yellow A Attenuates Oxygen-Glucose Deprivation-Induced Cultured Brain Microvessel Endothelial Cell Death through Downregulation of PHLPP-1

The incidence of ischemic stroke, a life-threatening condition in humans, amongst Asians is high and the prognosis is poor. In the absence of effective therapeutics, traditional Chinese medicines have been used that have shown promising results. It is crucial to identify traditional Chinese medicine formulas that protect the blood-brain barrier, which is damaged by an ischemic stroke. In this study, we aimed to elucidate such formulas. Brain microvascular endothelial cells (BMECs) were used to establish an in vitro ischemia-reperfusion model for oxygen-glucose deprivation (OGD) experiments to evaluate the function of two traditional Chinese medicines, namely, astragaloside (AS-IV) and hydroxysafflor yellow A (HSYA), in protecting against BMEC. Our results revealed that AS-IV and HSYA attenuated the cell loss caused by OGD by increasing cell proliferation and inhibiting cell apoptosis. In addition, these compounds promoted the migration and invasion of BMECs in vitro. Furthermore, we found that BMECs rescued by AS-IV and HSYA could be functionally activated in vitro, with AS-IV and HSYA showing synergetic effects in rescuing BMECs survival in vitro by reducing the expression of PHLPP-1 and activating Akt signaling. Our results elucidated the potential of AS-IV and HSYA in the prevention and treatment of stroke by protecting against cerebral ischemia-reperfusion injury.


Introduction
Globally, over 15 million people are known to suffer from stroke annually. Although the treatment strategies for stroke have dramatically improved, it still ranks as the second leading cause of mortality and disability [1]. Recent reports indicate that other than the high stroke mortality in Asian countries compared with that in other countries, the effects are higher amongst Asians and include severe intracerebral hemorrhages [2]. Presently, there are no effective pharmacological therapies for the treatment of stroke [3,4]. Ischemic stroke accounts for more than 85% of all stroke cases, resulting in severe acute necrosis and neuronal cell apoptosis [5]. Moreover, stroke damages the blood-brain barrier (BBB), which protects the central nervous system. Several reports have shown that BBB dysfunction is associated with multiple neurological disorders and that its integrity is critical for normal neuronal function [6,7]. e integrity of the BBB primarily depends on a population of cells called brain microvascular endothelial cells (BMECs) [8,9]. us, it is crucial to identify drugs that protect BMECs against ischemia-reperfusion injury and promote their recovery after an ischemic incident.
For over 2000 years, traditional Chinese medicines have been studied and used in China. eir use in treating patients with cerebrovascular disease dates back to the Han dynasty (202 B. C.-220 A. D.). Moreover, certain reports state the use of some of its formulas for stroke treatment and recovery [10]. For example, astragaloside (AS-IV), extracted from Huang Qi (Radix Astragali Seu Hedysari), is a traditional Chinese medicine most popularly used in cerebrovascular diseases. Its molecular mechanisms have been studied for over two decades [11,12], with multiple studies in rats and mice showing that it exerts protective effects during ischemia-reperfusion injury by regulating inflammation and cell death via several signaling pathways [13][14][15][16][17][18]. Moreover, data from an in situ study in rats with ischemiareperfusion injury showed that it attenuated increased BBB permeability [18], suggesting its promising role in maintaining the integrity of the BBB. Hydroxysafflor yellow A (HSYA) is another traditional Chinese medicine with wide applications in the treatment of stroke. Interestingly, it is also an Iranian folklore medicine used to treat cerebral ischemia-reperfusion injury [19]. HSYA has long been known to protect against cerebral ischemia-reperfusion injury in vivo through its antioxidant activities [20]. Multiple studies in rats, mice, and rabbits have demonstrated that it protects against ischemia-reperfusion injury by regulating toll-like receptors (TLRs), extracellular signal-regulated kinase (ERK) signaling, and protein kinase B (Akt) signaling pathways [21][22][23][24][25][26][27][28][29][30]. However, the effects of AS-IV and HSYA need to be further elucidated, especially their ability to protect BMECs from ischemia-reperfusion injury. Moreover, although their combination has been used to promote the recovery of stroke patients, it is still unclear whether the combination therapy is more efficacious in protecting BMECs and recovering from a stroke.
We used BMECs to establish an in vitro ischemiareperfusion model for oxygen-glucose deprivation/recovery (OGD/R) experiments to evaluate the effect of AS-IV and HSYA on BMECs during OGD. Furthermore, we determined the viability and proliferation of BMECs during treatment and the role of these drugs in apoptosis and migration in OGD.

Astragaloside IV Concentration in Huang Qi Injection.
e concentration of AS-IV in Huang Qi injection (HQI) was determined using a liquid chromatographic system from Shimadzu Instruments (Kyoto, Japan). e system consisted of an LC-10AVP binary pump and an evaporative lightscattering detector, connected to a computer system (for data acquisition) from LC-Solution. e analytical column used was the Agilent Zorbax Extend C18 column (250 mm × 4.6 mm, 5 μm) from Agilent Corporation. e mobile phase was a mixture of acetonitrile and water in a ratio of 36 : 64 at a flow rate of 1.0 mL/min. e injection volume, detector temperature, and pressure were 10 μL, 40°C, and 0.35 MPa, respectively.

Hydroxysafflor Yellow A Concentration in Honghua
Injection. Analyses were performed using the Agilent 1100 series system from Agilent Corporation (USA), coupled with a diode-array detector. e analytical column used was the Agilent Zorbax Extend C18 column (250 mm × 4.6 mm, 5 μm) from Agilent Corporation. e mobile phase was composed of a mixture of acetonitrile and 0.02 M NaH 2 PO 4 (adjusted to pH 3.5 with orthophosphoric acid). Gradient elution was performed as follows: initial (0 min), 10% acetonitrile and 0.02 M NaH 2 PO 4 ; 0 to 16 min, linear increase from 10 to 22% acetonitrile and 0.02 M NaH 2 PO 4 . e system was balanced for 5 min using the initial mobile phase (acetonitrile and 0.02 M NaH 2 PO 4 /orthophosphoric acid-� 1/9), after detecting each sample. e flow rate, injection volume, and detection wavelength were 0.8 mL/min, 10 μL, and 403 nm, respectively.

BMEC Cultures, OGD, and Drug Treatments.
Mouse primary BMECs were purchased from Cell Biologics Inc. (no. C57-6023; Chicago, IL, USA). e BMECs were plated and cultured to a confluence of 90% before oxygen-glucose deprivation (OGD) treatment. OGD treatment was established as follows: cells were rinsed once with glucose-free DMEM (Gibco, Rockville, MD) and transferred to an anaerobic chamber (Forma Scientific, Waltham, MA) containing a gas mixture composed of 7% CO 2 and 93% N 2 for 6 h at 37°C. en, the cells were returned to the normal culture condition. Control BMECs were cultured in complete DMEM under normal conditions. AS-IV, HSYA, HSYA + AS-IV, and HQI + HHI groups were treated with AS-IV, HSYA, HSYA + AS-IV, and HQI + HHI (dissolved in complete DMEM and filtered with a 0.22 μm membrane filter) for 12 h respectively after OGD treatment. Huang Qi injection (HQI) was purchased from Qingchunba (Chiatai, China) and Honghua injection (HHI) was purchased from Sanjiu (Ya'an, China). AS-IV and HSYA were purchased from the National Institute for Control of pharmaceutical and Biological Products. e groups and drug concentrations are listed in Table 1.

Cell Viability and Proliferation Analysis.
For cell counting kit-8 (CCK-8) assays, experiments were performed in 96-well plates. Posttreatment, CCK-8 assays were performed in accordance with the manufacturer's instructions (MCE, HY-K0301; Shanghai, China), and readings were measured with a microplate reader from ermo Scientific (Fremont, CA, USA). Cell proliferation was assessed using the BrdU cell proliferation assay kit from Biovision (Milpitas, CA, USA). Briefly, cells were plated in 12-well plates. After all the treatments mentioned, BrdU labeling was performed in accordance with the manufacturer's instructions. Next, the cells were analyzed with a MoFlo Astrios cell sorter from Beckman-Coulter (CA, USA).

Wound
Healing and Transwell Analysis. Wound healing and transwell analyses were performed as previously described [31]. Briefly, cells were plated in 6-well plates. A wound on the cell monolayer was created by scratching the layer with pipette tips. Images were taken immediately and 24 h after scratching. e wound-closure percentages were calculated using the following formula: 1 − current wound size/initial wound size × 100; Costar (Cambridge, MA, USA) was added into 24-well culture plates. All cells were starved overnight in FBS-free DMEM. e cells (1 × 10 5 ) were next seeded in the upper chamber in 200 μL DMEM, whereas the lower chamber was flooded with DMEM (10% FBS). After 18 h, the wells were fixed with 4% polyoxymethylene and stained with crystal violet.

Cell Adhesion and Tube Formation.
Cell adhesion and tube formation experiments were performed as previously described [32]. After treatments, BMECs (1,000 cells) were added to 24-well plates coated with fibronectin. BMECs that had adhered to fibronectin were counted under a phasecontrast microscope. Experiments were performed in triplicate.
BMECs (100,000 cells per well) were seeded into 24-well plates (100,000 cells per well) coated with 200 μL of growth factor-reduced Matrigel from BD Biosciences. Branches were quantified after a 24 h incubation at 37°C. Images were taken with the SteREO Discovery.V20 microscope from Carl Zeiss (Jena, Germany), equipped with a plan apochromat 1.0x and the AxioCam HRc digital microscope camera from Carl Zeiss, automated with the AxioVision Rel.4.8 software from Carl Zeiss. Experiments were performed in triplicate.

Cell Apoptosis.
Terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) assays were performed using the TransDetect In Situ Fluorescein TUNEL Cell Apoptosis Detection Kit (FA201-02) (Beijing, China). Briefly, cells were plated onto cover glasses in 6-well plates. After treatments, TUNEL experiments were performed and images were taken with the SteREO Discovery.V20 microscope from Carl Zeiss (Jena, Germany), equipped with a plan apochromat 1.0x and the AxioCam HRc digital microscope camera from Carl Zeiss, automated with the AxioVision Rel.4.8 software (Carl Zeiss).
Cell apoptosis was also analyzed using the Annexin V-FITC Apoptosis Kit (K101) from Biovision (Milpitas, CA, USA), in accordance with the manufacturer's instructions. After labeling, the cells were analyzed using a MoFlo Astrios cell sorter from Beckman-Coulter.

Protein Collection and Western
Blotting. RIPA lysis buffer (60 μL) from Solarbio (Beijing, China) was added to the wells of a 6-well plate. At least three independent experiments were performed. e cell lysate was centrifuged at 14,000 rpm for 15 min. e resultant supernatant was mixed with 2x SDS-loading buffer and then subjected to western blotting. e protein samples were analyzed using SDS-PAGE. Western blotting was performed using standard procedures, and immune-reactive proteins were visualized using the SuperSignal ™ chemiluminescence kit from ermo Scientific. Anti-BCL-2 antibody, anti-Bax antibody, anti-VEGF antibody, anti-VEGFR2 antibody, anti-eNOS antibody, and anti-p-eNOS antibody were purchased from CST (Woburn, USA), whereas anti-GAPDH antibody, anti-Caspase-3 antibody, anti-cleaved Caspase-3 antibody, anticaveolin-1 antibody, anti-Akt, anti-p-Akt, anti-GSK3β, antip-GSK3β, anti-PHLPP-1, and anti-actin antibody were purchased from Santa Cruz Biotechnology (CA, USA).

2.10.
Intracellular Calcium Level Measurement. Intracellular calcium levels were measured as previously described [34]. Briefly, the cells were incubated in DMEM containing 10 μM fluo 3-AM for 30 min at room temperature in the dark. Next, excess fluo 3-AM was removed and the intracellular calcium level of BMECs receiving various treatments was measured using the MoFlo Astrios cell sorter from Beckman-Coulter at an excitation wavelength of 488 nm and an emission wavelength of 505 nm.

Statistical Analysis.
e SPSS version 18.0 (IBM Corporation, USA) was used for statistical analysis. Data were generated from at least three replicates and student's ttest or one-way analysis of variance (ANOVA) followed by Tukey's post-hoc test was performed. Data are presented as mean ± standard deviation, and p < 0.05 was considered significant.

AS-IV and HSYA Promote BMEC Proliferation.
We first analyzed the contents of HQI (Huang Qi injection) and HHI (Honghua injection) using HPLC. In comparison with standard samples, our results showed that the concentration of AS-IV in HQI was 0.15 mg/mL and that of HSYA in HHI was 0.24 mg/mL (data not shown). To evaluate the functions of AS-IV and HSYA, we first established an in vitro ischemia-reperfusion model with BMECs. BMECs were cultured in glucose-free DMEM in a hypoxia incubator with a 95% N 2 and 5% CO 2 mixture for 2 h. After a 24 h recovery period, cell viability was determined with CCK-8 assays. Our results showed that the BMEC quantity was 50% less after OGD treatment as compared with the control group, suggesting that OGD treatment largely resulted in cell death (Figures 1(a)-1(c)). As expected, a supplement of AS-IV attenuated cell death. AS-IV (920 μg/mL) rescued the cell viability ( Figure 1(a)). HSYA (100 μg/ml) rescued the cell viability, whereas 10 and 50 μg/mL had little effects on cell viability (Figure 1(b)). In addition, treatment with AS-IV (20 μg/mL) or HSYA (100 μg/mL) after OGD significantly increased the viability, suggesting that both AS-IV and HSYA attenuated OGD-induced cell death (Figure 1(c)). Moreover, we found that the combination of HSYA and AS-IV (20 μg/mL AS-IV + 100 μg/mL HSYA) further rescued BMECs from the effects of OGD. For example, a combination of 2% HQI and 2% HHI (2 g/mL HQI + 0.5 g/mL HHI) significantly attenuated the OGD-induced decreased cell viability (Figure 1(c)). We further examined BMEC proliferation after treatment with various protectors through BrdU labeling, showing that the percentage of proliferating cells decreased from 58.7 to 25.5% after OGD (Figure 1(d)). However, the percentage of proliferating cells increased to 35.9% and 37.3% after treatment with AS-IV and HSYA, respectively. Treatment with a combination of AS-IV and HSYA further rescued proliferation (44.9%) (Figure 1(d)). For example, treatment with a combination of 2% HQI and 2% HHI increased the proliferation to 43.9%. ese results suggested that AS-IV and HSYA attenuated the OGD-induced decrease in the proliferation.

AS-IV and HSYA Attenuate OGD-Induced Apoptosis.
We next examined the OGD-induced BMEC apoptosis. As expected, the apoptosis of OGD BMECs significantly increased, as revealed by TUNEL staining (Figure 2(a)). However, BMEC culturing with AS-IV or HSYA significantly decreased apoptosis (Figure 2(a)). Moreover, the combination of AS-IV and HSYA provided a better protective effect against OGD (Figure 2(a)). Flow cytometry experiments further validated these results (Figure 2(b)). us, OGD reduced the viability by decreasing proliferation and increasing apoptosis, and AS-IV and HSYA attenuated this loss by increasing cell proliferation and inhibiting apoptosis. To further elucidate how AS-IV and HSYA inhibited BMEC apoptosis, we examined the expression of antiapoptotic gene Bcl-2 and proapoptotic gene Bax. Our results showed that OGD significantly induced the expression of Bax, Caspase 3, and cleaved Caspase 3 (cle-Cas 3) protein levels (Figure 2(c)). However, it downregulated the expression of the antiapoptotic gene Bcl-2 (Figure 2(c)). Culturing OGD BMECs with AS-IV or HSYA attenuated the decreased expression of Bcl-2 and decreased Bax, Caspase 3, and cle-Cas 3 levels (Figure 2(c)), indicating that AS-IV and HSYA inhibited OGD-induced BMEC apoptosis by directly regulating the expression of apoptosis-related genes.

AS-IV and HSYA Promote BMEC Migration and Invasion.
Because AS-IV and HSYA promoted the proliferation and inhibited the apoptosis of BMECs, we explored the functioning of rescued cells using cell migration and invasion assays. Results of a wound-healing assay showed that OGD significantly impaired the migration ability of BMECs. However, OGD BMECs cultured with AS-IV and/or HSYA showed partially restored migration ability (Figures 3(a) and  3(b)). In addition, BMEC invasion decreased significantlyafter OGD; however, it was rescued by supplementation of AS-IV and/or HSYA (Figures 3(c) and 3(d)).

AS-IV-and HSYA-Rescued BMECs Are Functionally
Activated In Vitro. During the stroke, BMECs or leucocytes adhere to the vessel wall to allow binding of activated platelets to the wall of inflamed microvessels [35,36]. us, we examined the adhesion ability of AS-IV-and/or HSYArescued BMECs by plating them in wells coated with fibronectin. e results showed that OGD severely impaired the adhesion ability of BMECs, which was significantly attenuated by supplementation with AS-IV and/or HSYA (Figure 4(a)), suggesting that AS-IV-and/or HSYA-rescued BMECs were functionally activated. e transendothelial, electrically resistant BBB is associated with intracellular calcium in the brain microvascular endothelial cells in vitro [34,37]. However, AS-IV inhibits spontaneous synaptic transmission and synchronized Ca 2+ oscillations in neuronal cells [38]. We assessed the intracellular Ca 2+ concentration of fluo 3-AM-treated BMECs via flow cytometry. e results showed a significant increase in the intracellular Ca 2+ concentration of OGD BMECs, which was attenuated by treatment with AS-IV and/or HSYA, suggesting the protective function of both AS-IV and HSYA in ischemia-induced BBB damage (Figure 4(b)).
To further explore the role of AS-IV and HSYA in ischemia-reperfusion injury, we plated BMECs on Matrigel and evaluated tube formation in vitro. Our results demonstrated that OGD significantly decreased the tube formation as the tube length of OGD BMECs decreased to approximately 20% of that of the control BMECs (Figures 4(c) and 4(d)). However, OGD BMECs cultured with AS-IV and/or HSYA showed significantly recovered tube formation, with their combination exerting a synergistic effect (Figures 4(c) and 4(d)). association with vascular endothelial growth factor (VEGF) signaling. VEGF and VEGF receptor 2 (VEGFR 2) levels were found to be significantly upregulated following treatment with AS-IV and/or HSYA, despite their unaltered levels in OGD BMECs ( Figure 5).

AS-IV and HSYA Protect BMECs via Regulating
In BMECs, nitric oxide (NO) can be derived from intracellular endothelial NO (eNOS), which serves as a hypoxia signal in these cells [39]. Increased phosphorylated eNOS (p-eNOS) levels subsequently activated the antioxidant signaling, which protected the BMECs [40]. Interestingly, our results indicate that eNOS levels in BMECs were unaltered although treatment with AS-IV and/or HSYA significantly increased the levels of p-eNOS, activating antioxidant signaling in BMECs ( Figure 5). e caveolin pathway plays a critical role in preserving the integrity of BBB [41]. Our results showed that OGD significantly decreased caveolin-1 protein levels, which was significantly attenuated by treatment with AS-IV and/or HSYA, suggesting that AS-IV and HSYA protected BMECs by stimulating the caveolin-1 pathway ( Figure 5).
We further analyzed the potential molecular alteration caused by AS-IV and HSYA treatment and found that AS-IV and/or HSYA treatment led to increased levels of phosphorylated Akt and phosphorylated GSK3β, but not total Akt or GSK3β, which were significantly increased in comparison to the OGD treatment-alone group (Figure 6(a)). In addition, HHI and HQI treatment showed identical effects (Figure 6(a)) suggesting the involvement of Akt signaling. Recently, reports showed that PHLPP-1 as a novel phosphatase negatively regulates the Akt activity [42][43][44]. Hence, we analyzed the expression of PHLPP-1 in AS-IV and/or HSYA-treated OGD. Surprisingly, our results showed that PHLPP-1 levels increased following OGD treatment and decreased following AS-IV and/or HSYA treatment (Figure 6(a)).
us, we established PHLPP-1-knockout  BMECs ( Figure 6(b)) to further study the role PHLPP-1 plays in AS-IV and HSYA protection. Importantly, we found that the protective effects of AS-IV, HSYA, HQI, and HHI in PHLPP-1 knockout BMECs were attenuated as revealed by cell viability and apoptosis (Figures 6(c) and 6(d)). ese data further suggested that AS-IV and HSYA-mediated ischemia-reperfusion protection was dependent on PHLPP-1/ Akt.

Discussion
Several traditional Chinese medicines have been demonstrated to inhibit ischemia-induced excitotoxicity and apoptosis and promote proliferation and angiogenesis [45]. Among these, AS-IV protects against ischemia-reperfusion injury, as demonstrated using several in vivo and in vitro models [18,46,47]. Results from the present study showed that AS-IV treatment significantly promoted BMEC proliferation in vitro, which is in agreement with the findings of a previous study in mesenchymal stem cell-derived endothelial cell-like cells that showed AS-IV-induced endothelial cell-like cell proliferation [48]. We found that AS-IV inhibited BMEC apoptosis by upregulating the expression of BCL2 and downregulating the expression of Bax, which is in line with the findings from a previous study in rats that showed AS-IV-inhibited cell apoptosis via TLR-4 signaling in vivo [14]. us, AS-IV exerts dual protective effects in BMECs in vitro; it increases proliferation and decreases cell death. HSYA was found to have a proproliferation role, as it inhibited ischemia-reperfusion injury-induced apoptosis [26,27,49]. Results from the present study demonstrate that this process is at least partially dependent on BCL2/Bax because HSYA treatment significantly attenuated the OGDinduced BCL2 reduction and Bax stimulation. Cotreatment with AS-IV and HSYA ameliorated cerebral infarction with Qi deficiency and blood stasis syndrome [50]. It was recently shown that Buyang Huanwu decoction, containing both AS-IV and HSYA, ameliorated the effects of ischemic stroke [51]. Our study results demonstrate that the combination of AS-IV and HSYA synergistically promoted proliferation and inhibited apoptosis, elucidating their benefits in ischemiareperfusion injury. Further elucidation of the pathology of stroke, similar to the illumination of that of ischemiareperfusion injury after induction of acute myocardial infarction [52], is required to facilitate a more precise use of these traditional Chinese medicines.
To validate the functioning of AS-IV and/or HSYA in rescuing BMECs in vitro, we first addressed both the migration and invasion abilities of AS-IV-and HSYA-treated BMECs and found significant improvement when compared with the OGD group. In addition, the synergistic migration and invasion ability increasing the effect of cotreatment with AS-IV and HSYA was stronger than the synergetic proliferation promotion and apoptosis inhibition effect, suggesting that the rescued BMECs were functioning. Furthermore, previous studies have shown that AS-IV and HSYA promoted migration and invasion [53,54]. Moreover, our results demonstrated that the impaired cell adhesion ability, intracellular calcium levels, and tube formation in OGD BMECs in vitro were attenuated by treatment with AS-IV and/or HSYA, further validating the functional activation of AS-IV-and/or HSYA-rescued BMECs.
AS-IV and HSYA protect the central nervous system via multiple mechanisms. Our study demonstrated that VEGF signaling was activated in ODG BMECs treated with AS-IV and HSYA, explaining the attenuated tube formation ability. VEGF signaling is tightly regulated in BMECs. is, in turn, regulates BMECs, alleviating BBB disruption, cerebral edema,  Evidence-Based Complementary and Alternative Medicine and neuronal injury [10,55,56]. Furthermore, we observed significantly increased P-eNOS levels rather than eNOS levels in OGD BMECs treated with AS-IV and/or HSYA, suggesting that AS-IV and/or HSYA treatment facilitates stroke recovery by modulating endothelial nitric oxide synthase. In addition, it was reported that caveolin signaling is one of the downstream targets of P-eNOS [41]. Our results showed that OGD significantly reduced the protein levels of caveolin-1, which was ameliorated by AS-IV and/or HSYA treatment. More importantly, our data revealed that AS-IV and HSYA mediated ischemia-reperfusion protection in a PHLPP-1/Akt-dependent manner. However, a detailed mechanism of how AS-IV and HSYA modulate the expression of PHLPP-1 requires further investigations. It is of special significance to check this protective mechanism of AS-IV and/or HSYA treatment in myocardial ischemia-reperfusion because PHLPP-1 plays crucial roles in myocardial ischemia-reperfusion [30,43,44].

Conclusions
Treatment with AS-IV and/or HSYA protected BMECs against ischemia-reperfusion injury by promoting proliferation and inhibiting apoptosis in vitro. In addition, it rescued the functioning of BMECs. Treatment with AS-IV and/or HSYA protected BMECs against ischemia-reperfusion injury by stimulating VEGF and eNOS signaling. ese results further illustrate the benefits of AS-IV and HSYA in stroke prevention and treatment, which may not only be advantageous in stroke cases but other ischemia-reperfusion injury cases.

Data Availability
e data used to support the findings of this study are included within the article.

Conflicts of Interest
e authors declare that they have no conflicts of interest.

Authors' Contributions
Jinyi Cao, Kai Wang, Lu Lei, and Lu Bai contributed equally to this work.