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Introduction

With the continuous development of society and the improvement of the quality of life of individuals, the aging population has exhibited an increasing trend in developed countries. Statistics have indicated that the elderly >60 years of age account for 12% of the total population worldwide (1). Due to the increase in age, metabolism and immune function gradually decline, leading to an increase in basic diseases (2). Alzheimer's disease (AD) is a clinically common chronic progressive neurodegenerative disease affecting the elderly (3). There are approximately 5.3 million patients with AD in the United States, >96% of whom are >65 years of age, and it is estimated that there will be >10 million patients with AD by the year 2050. Moreover, patients with AD suffer from aphasia, amnesia and memory dysfunction, resulting in impatience, anxiety and behavioral and psychological symptoms of dementia (BPSD), which severely affect their quality of life (4); therefore, the effective treatment of AD is of utmost importance.

Drug control is the main treatment method used clinically. Donepezil is a preferred second-generation drug for the treatment of AD, which enhances the biological function of acetylcholine by inhibiting its hydrolysis in the central nervous system, thus improving the patient's condition (5). Patients with AD also suffer from mental disorders and display hostile and aggressive behaviors (6). Therefore, adjuvant therapy with anti-epileptic and anti-psychotic drugs is necessary in the treatment process (7). Quetiapine, an atypical anti-psychotic drug of dibenzoxazepines, improves the neurological status of patients with AD and is effective in the treatment of BPSD by blocking certain dopamine receptors. Moreover, it can also regulate the mood of patients (8). Sodium valproate is a commonly used anti-epileptic drug, which can reduce the activities of γ-aminobutyric acid transaminase (GABA-T) and succinate semialdehyde dehydrogenase (SSADH) in the brain, increase the content of GABA and reduce neuronal excitation (9). Although previous studies have indicated that (10,11) quetiapine and sodium valproate, respectively combined with donepezil, significantly improve the condition of patients with AD presenting with BPSD, the difference in the efficacy of the 2 therapies has not yet been investigated.

At present, there is a lack of potential indicators to observe the prognosis of patients with AD with BPSD clinically. Vascular endothelial growth factor (VEGF), a highly specific mitogen of vascular endothelial cells, is expressed at low levels in the central nervous system normally; however, its expression markedly increases after damage caused by dementia or AD. There is also evidence to indicate that VEGF is closely related to the occurrence and development of AD (12); however, whether it has an association with the prognosis of AD remains unknown.

Therefore, the present study aimed to provide a reference for clinicians by exploring the efficacy of donepezil combined with quetiapine and with sodium valproate in patients AD presenting with BPSD, as well as to examine the changes in and clinical value of VEGF.

Patients and methods

Clinical data

A total of 131 patients with AD admitted to Infirmary of Shandong Agricultural University from January 2017 to January 2019 were enrolled as the research subjects. A total of 60 patients treated with donepezil combined with quetiapine were designated as group A, and 71 patients treated with donepezil combined with sodium valproate were designated as group B. The present study was approved by the Medical Ethics Committee of Infirmary of Shandong Agricultural University.

Inclusion and exclusion criteria

The inclusion criteria were as follows: Patients diagnosed with AD by the National Institute of Neurological and Communication Disorders and Stroke and the Alzheimer's Disease and Related Diseases Association (NINCDS-ADRDA) (13); patients assessed with the Diagnostic and Statistical Manual for Mental Disorders (DSM-IV) (14); patients with BPSD and psychopathological symptoms; patients with obvious brain atrophy by cranial magnetic resonance imaging (MRI) scans, and with no cerebrovascular diseases; patients and their families were informed of the study and signed the informed consent forms.

The exclusion criteria were as follows: Patients allergic to the treatment drugs; patients not participating in the treatment due to personal issues; patients with malignant tumors; patients with genetic immunodeficiency diseases; patients with severe infections or trauma prior to treatment; patients who had received AD drugs 1 month prior to treatment.

Sources of drugs and kits

Donepezil (Hansoh Pharmaceutical Co., Ltd.; SFDA approval no. H20030472, 5 mg/tablet), quetiapine (Dongting Pharmaceutical Co., Ltd.; SFDA approval no. H20000466, 100 mg/tablet), sodium valproate [Sanofi (Hangzhou) Pharmaceutical Co., Ltd.; SFDA approval no. H20010595, 500 mg/tablet], VEGF ELISA kit (PV963; Beyotime Institute of Biotechnology, Inc.).

Treatment

Donepezil was used as the basic drug for AD treatment in both groups and the specific method was as follows: Donepezil was administered orally 5 mg/time, 1 day/time before bedtime, for a continuous period of 12 weeks. Additionally, quetiapine was administered orally with the initial dose of 50 mg/time, 1 day/time, increased by 25 mg every 1-3 days to the maximum dose of 350 mg/day, for a continuous period of 12 weeks. In addition to donepezil, patients in group B were administered sodium valproate, with an initial oral dose of 200 mg/day. In the case of discomfort, the dose was increased to 600 mg/day in the following 2 weeks, for a continuous period of 12 weeks.

Detection of VEGF levels

Peripheral blood samples (5 ml) were collected before treatment and after 12 weeks of treatment, allowed to stand for 30 min and centrifuged at 1,500 x g and 25˚C for 10 min. The supernatant was collected and the serum VEGF expression was detected using an ELISA kit. The specific ELISA detection method was as follows: A total of 50 µl of standard solution at various concentrations were added into blank wells of a 96-well plate, 50 µl of distilled water and 50 µl of sample analysis buffer (PV963-2; Beyotime Institute of Biotechnology, Inc.) were added to the blank control well, and 40 µl of sample followed by 10 µl of biotin-labeled antibody (human VEGF biotinylated antibody; PV963-5; Beyotime Institute of Biotechnology, Inc.; incubation for 120 min at 25˚C) were added to the remaining wells. When washing the plate, the washing liquid in each well was kept full without overflowing and discarded after standing for 30 sec, then the plate was patted dry. The process was repeated 5 times. Following the addition of 50 µl of enzyme-labeled solution, the plate was sealed and incubated at 37˚C for 60 min. Afterwards, it was washed 5 times with the diluted detergent for 1 min each time, and patted dry on a thick absorbent paper at the last time. Horseradish peroxidase-labeled antibody (streptavidin; PV963-6; Beyotime Institute of Biotechnology, Inc.; incubation for 20 min at 25˚C in the dark; 100 µl/well) and the chromogenic substrate, tetramethylbenzidine (TMB; 100 µl/well; Beyotime Institute of Biotechnology, Inc.) were adopted and the plate was incubated at room temperature in dark for 20 min. Finally, stop solution (50 µl/well; Beyotime Institute of Biotechnology, Inc.) was added, and a microplate reader was used to determine the maximum absorption at the wavelength of 450 nm within 15 min. Each sample was tested in 3 repeat wells, and the experiment was performed 3 times.

Outcome measures

The main outcome measures were as follows: The patients in the 2 groups were scored by behavioral pathology in the AD rating scale (BEHAVE-AD) (15) to evaluate the clinical efficacy (Table I). The brief psychiatric rating scale (BPRS) (16) was used for the mental state assessment, and the mini-mental state examination (MMSE) (17) for the assessment of cognitive performance. The expression of VEGF in the 2 groups and the correlation between VEGF and BEHAVE-AD before and after treatment were compared.

Table I Efficacy evaluation criteria of BEHAVE-AD.

Table I

Efficacy evaluation criteria of BEHAVE-AD.

Therapeutic effect	Standard
Markedly effective	Reduction rate of BEHAVE-AD after treatment was >60%
Effective	Reduction rate of BEHAVE-AD after treatment was 30-60%
Ineffective	Reduction rate of BEHAVE-AD after treatment was <25%

[i] BEHAVE-AD, behavioral pathology in Alzheimer's disease rating scale.

Secondary outcome measures: The adverse reactions were recorded and the drug treatment costs in the 2 groups were compared. According to the curative effects following treatment, the patients were divided into the excellent efficacy group and the poor efficacy group. The predictive value of VEGF before treatment was analyzed.

Statistical analysis

In the present study, SPSS 20.0 was used to analyze the collected data, and GraphPad Prism 7 was used to draw relevant images. The Kolmogorov-Smirnov (K-S) was employed to analyze data distribution. Count data expressed as percentage (%) were analyzed using the Chi-squared (χ2) test. Ranked data were analyzed using a non-parametric test (denoted by Z), and the measurement data were expressed as the means ± standard deviation (means ± SD). The Students' t-test was used for data conforming to normal distribution, a paired t-test was used for intra-group comparisons before and after treatment, and an independent samples t-test was used for inter-groups comparison (denoted by t values). Data not conforming to normal distribution were analyzed by the rank sum test (denoted by Z values) and two-way ANOVA was adopted for multi-group comparisons (denoted by F values); the Bonferroni test was adopted as a post hoc test. Multivariate logistic regression was applied to analyze risk factors affecting the curative effect, and receiver operating characteristic (ROC) curve was used to analyze the predictive value of VEGF on the clinical efficacy before treatment. Spearman's correlation analysis was applied to analyze the correlation between VEGF and BEHAVE-AD score. A value of P<0.05 was considered to indicate a statistically significant difference.

Results

Clinical data

The comparison of clinical data revealed that there were no statistical differences in sex, age, body mass index (BMI), course of the disease, previous medical history, smoking history, history of alcohol consumption, educational level and residence between the 2 groups (P>0.05) (Table II).

Table II Comparison of clinical data of the patients.

Table II

Comparison of clinical data of the patients.

Factors	Group A (n=60), n (%)	Group B (n=71), n (%)	t/χ2 value	P-value	OR (95 CI%)
Sex			0.409	0.523	1.138 (0.755-1.644)
Male	20 (33.33)	20 (28.17)
Female	40 (66.67)	51 (71.83)
Age (years)	65.1±8.7	64.7±7.1	0.290	0.773
BMI (kg/m2)	22.15±1.22	22.44±1.30	1.308	0.193
Course of the disease (years)	3.52±0.80	3.23±1.41	1.412	0.160
Previous medical history
Hypertension	12 (20.00)	17 (23.94)	0.293	0.588	0.879 (0.523-1.351)
Diabetes	8 (13.33)	12 (16.90)	0.320	0.572	0.854 (0.455-1.389)
Hyperlipemia	4 (6.67)	7 (9.86)	0.431	0.512	0.779 (0.319-1.451)
COPD	1 (1.67)	2 (2.82)	0.192	0.661	0.723 (0.133-1.795)
Smoking history			1.078	0.299	1.227 (0.826-1.761)
Yes	22 (36.67)	20 (28.17)
No	38 (63.33)	51 (71.83)
Alcohol consumption history			0.313	0.576	0.825 (0.724-1.456)
Yes	5 (8.33)	8 (11.27)
No	55 (91.67)	63 (88.73)
Education level			0.293	0.588	0.879 (0.523-1.351)
≥High school	12 (20.00)	17 (23.94)
<High school	48 (80.00)	54 (76.06)
Residence			1.109	0.292	1.364 (0.800-2.700)
Urban	53 (88.33)	58 (81.69)
Rural	7 (11.67)	13 (18.31)

Changes in BEHAVE-AD, BPRS and MMSE scores before and after treatment

The BEHAVE-AD and MMSE scores following treatment were significantly lower than those before treatment in the 2 groups, and the BPRS score after treatment was significantly higher than that before treatment (P<0.05). However, no significant differences were observed in the scores between the 2 groups following treatment (P>0.05) (Tables III-V).

Adverse reactions and treatment costs

Adverse reactions in the 2 groups were observed during the treatment period, and the results revealed that there were 2 cases of nausea, 2 cases of dizziness, 3 cases of somnolence, 1 case of akathisia and 1 case of hypermyotonia in group A, while those in group B were 3, 2, 4, 1 and 1, respectively. No statistically significant differences were observed between the 2 groups in terms of single adverse reactions and the total incidence of adverse reactions (P>0.05) (Table VI). The drug treatment costs in group A (913.52±125.09 yuan) were significantly higher than those in group B (795.61±136.56 yuan) (t=5.116, P<0.001) (Table VII).

Table VI Incidence of adverse reactions in patients.

Table VI

Incidence of adverse reactions in patients.

Group	Nausea	Dizziness	Somnolence	Akathisia	Hypermyotonia	Total incidence
Group A (n=60)	2 (3.33)	2 (3.33)	3 (5.00)	1 (1.67)	1 (1.67)	9 (15.00)
Group B (n=71)	3 (4.23)	2 (2.82)	4 (5.63)	1 (1.41)	2 (2.82)	12 (16.90)
χ2 value	0.037	0.115	0.053	0.354	0.022	0.087
P-value	0.848	0.735	0.819	0.552	0.883	0.768

[i] Data are presented as number and percentage [n (%)].

Table VII Comparison of treatment costs.

Table VII

Comparison of treatment costs.

Group	Treatment costs (yuan)	t value	P-value
Group A (n=60)	913.52±125.09	5.116	<0.001
Group B (n=71)	795.61±136.56

Expression of VEGF in the 2 groups before and after treatment

The expression of VEGF in serum following treatment was significantly higher than that before treatment (P<0.05), while there was no significant difference between the 2 groups following treatment (P>0.05) (Fig. 1).

Figure 1 Changes in the levels of VEGF before and after treatment in the 2 groups. (A) Expression of VEGF in group A after treatment (541.06±50.85 pg/ml) was significantly increased compared with that before treatment (415.12±15.19 pg/ml) (t=18.836, ***P<0.001). (B) Expression of VEGF in group B after treatment (527.26±49.26 pg/ml) was significantly higher than that before treatment (412.61±16.58 pg/ml) (t=17.647, ***P<0.001). (C) There were no marked differences in serum VEGF expression between the 2 groups before and after treatment (P>0.05). VEGF, vascular endothelial growth factor.

Clinical efficacy of treatment in the patients

By comparing the clinical efficacy in the 2 groups, it was found that in group A, the treatment was markedly effective in 32 patients, effective in 22 patients and ineffective in 6 patients. In group B treatment was markedly effective in 38 patients, effective in 25 and ineffective in 8 patients. Non-parametric analysis revealed that there was no statistically significant difference in the clinical treatment efficacy between the 2 groups (P>0.05) (Table VIII).

Table VIII Comparison of clinical efficacy of the treatment in the patients.

Table VIII

Comparison of clinical efficacy of the treatment in the patients.

Group	Markedly effective	Effective	Ineffective	Z value	P-value
Group A (n=60)	32 (53.33)	22 (36.67)	6 (10.00)	-0.046	0.963
Group B (n=71)	38 (53.52)	25 (35.21)	8 (11.27)

[i] Data are presented as number and percentage [n (%)].

Value of VEGF in predicting the clinical efficacy before treatment

According to the clinical efficacy following treatment, the patients exhibiting a markedly effective treatment response were enrolled into the excellent efficacy group (n=70), and the patients exhibiting an effective and ineffective treatment response were enrolled into the poor efficacy group (n=61). When comparing VEGF expression before treatment between the 2 groups, it was found that its expression in the excellent efficacy group was significantly higher than that in the poor efficacy group (P<0.05). In addition, ROC curve analysis revealed that the area under the curve (AUC) of VEGF was 0.828, and the optimal sensitivity and specificity were 68.85 and 87.14%, respectively when the cut-off point was <409.86 pg/ml, with a Youden's index of 56.00% (Fig. 2).

Figure 2 expression and predictive value of VEGF in the excellent efficacy group and poor efficacy group. (A) VEGF expression in the excellent efficacy group (421.87±12.62 pg/ml) was significantly higher than that in the poor efficacy group (404.46±14.25 pg/ml), with a significant difference (t=7.412, ***P<0.001). (B) ROC curve analysis of the AUC of VEGF. The red mark in the black line represents the optimal cut-off point, where the optimal specificity and sensitivity were 87.14 and 68.85%, respectively. VEGF, vascular endothelial growth factor; AUC, area under the curve.

Correlation between VEGF and the BEHAVE-AD score before and after treatment

Spearman's correlation analysis revealed that the BEHAVE-AD score gradually increased with the decrease in VEGF expression both before and after treatment, exhibiting a negative correlation (P<0.05) (Fig. 3).

Figure 3 Correlation between VEGF and the BEHAVE-AD score before and after treatment. (A) VEGF expression negatively correlated with the BEHAVE-AD score before treatment (r2=0.594, P<0.001). (B) VEGF expression negatively correlated with the BEHAVE-AD score after treatment (r2=0.638, P<0.001). VEGF, vascular endothelial growth factor; BEHAVE-AD, behavioral pathology in Alzheimer's disease rating scale.

Discussion

With the improvement in living standards and the extension of life expectancy, the incidence rate of AD, one of the diseases affecting the elderly, has also exhibited a significantly increasing trend (18). As a common neurological disorder in clinical practice, AD affects cognitive function, memory and the self-care ability of patients, accompanied by BPSD (19). There is no cure for patients with AD with BPSD, with only drug treatment available to alleviate the condition. Clinically, donepezil combined with sedative drugs is the most commonly applied treatment for such cases (20); however, the difference in the clinical efficacy of different sedative drugs combined with donepezil has not been extensively investigated. Therefore, in the present study, quetiapine and sodium valproate were respectively combined with donepezil to observe their clinical efficacy in patients with AD with PBSD, so as to provide references for clinicians.

BEHAVE-AD, BPRS and MMSE scores have been confirmed to be important indicators of the clinical evaluation of patients with AD with BPSD (21). Therefore, in the present study, the changes in these scores were compared before and after the patients were treated with donepezil combined with either quetiapine or sodium valproate. The results revealed that the scores following treatment were significantly improved compared with those before treatment, although no differences were found between the 2 groups following treatment, which indicated that the two schemes achieved good clinical efficacy in treating the disease. This is due to the fact that quetiapine exerts a potent anti-psychotic effect by blocking dopamine, serotonin and other neurotransmitter receptors in the brain (22). Sodium valproate can promote the production of GABA and can also inhibit its degradation, thus inhibiting the excitement and reducing the agitation of patients with AD (23). Although the two drugs act on different targets, they have a similar effect on improving the patient's condition. In the present study, no marked differences were observed in clinical efficacy and adverse reactions between the two groups. However, the treatment costs in group A were significantly higher than those in group B, which indicated that the costs associated with the use of donepezil combined with quetiapine were higher than those of donepezil combined with sodium valproate. Through the above research, donepezil combined with either quetiapine or sodium valproate improved the treatment efficacy of patients with AD with PBSD. However, compared with donepezil combined with quetiapine, donepezil combined with sodium propionate had a lower treatment cost and may thus be worthy of future application and promotion.

The clinical assessment of the improvement of patients with AD with BPSD is mainly based on various scale scores (24), which are susceptible to subjective factors. Compared with the scoring criteria, serological tests are more objective. Clinically, there are few criteria for predicting the treatment response of patients with AD with BPSD. VEGF is a highly biologically active vascular growth promoting factor with neurotrophic, neuroprotective and angiogenic effects (25). It has been reported (26) that VEGF and β amyloid protein can promote each other in patients with AD, and β amyloid deposition is the main cause of the degeneration and death of peripheral neurons of senile plaques. The study by Mateo et al (27) demonstrated that VEGF expression in the serum of patients with AD was significantly decreased, while the study by Kakinuma et al (28) demonstrated that donepezil promoted cardiovascular growth and VEGF expression in mice. The above-mentioned studies indicate that VEGF expression changes during the occurrence of AD; however, whether it can be used as a potential observation index remains unknown. In the present study, it was found the expression of VEGF in groups A and B following treatment was significantly higher than that before treatment, which suggested that both combined therapies increased the expression of VEGF. However, it is not clear whether VEGF can be used as a potential indicator for predicting the clinical efficacy; thus the patients were further divided into the excellent efficacy group and poor efficacy group. The analysis revealed that the excellent efficacy group had a higher VEGF expression than the poor efficacy group before treatment, suggesting that VEGF was expected to be a predictor for the treatment response of patients with AD with BPSD. Moreover, ROC analysis demonstrated that the AUC of the VEGF was 0.828, exhibiting a high clinical value. At the end of the study period, the correlation between VEGF and BEHAVE-AD score was analyzed before and after treatment, and it was found that there was a negative correlation between them; that is, the expression of VEGF gradually increased with the decrease in the BEHAVE-AD score. Therefore, VEGF may be used as a potential predictive factor of the clinical efficacy of treatment in patients with AD with PBSD.

However, there are some limitations to the present study. First, it is not clear how the two therapies improved the expression of VEGF in patient serum. Second, the correlation between VEGF, and the BPRS and MMSE scores was not analyzed. Third, this was not a randomized controlled study, which may lead to some bias in the results. Fourth, whether a single serological test can be used as a predictor of treatment efficacy warrants further clinical verification. Therefore, further basic trials are required to detect the expression of VEGF in the cerebrospinal fluid of patients, and to observe the correlation between serum and VEGF, in order to improve the sensitivity and specificity of prediction, so as to address the deficiencies of the present research results.

In conclusion, both quetiapine and sodium valproate, respectively combined with donepezil improved the clinical efficacy in patients with AD with PBSD, of which the latter was relatively more cost-effective and may thus be worthy of clinical promotion. In addition, VEGF expression negatively correlated with the BEHAVE-AD score and may thus be used as a potential predictive factor for the treatment of patients with AD with PBSD.

Acknowledgements

Not applicable.

Funding

No funding was received.

Availability of data and materials

The datasets used and/or analyzed during the present study are available from the corresponding author on reasonable request.

Authors' contributions

XY analyzed and interpreted the patient general data and QC was responsible for observation indicators analysis. XY and QC wrote the manuscript, and read and approved the final manuscript.

Ethics approval and consent to participate

The study was approved by the Ethics Committee of Infirmary of Shandong Agricultural University. Patients who participated in this research, signed the informed consent and had complete clinical data. Signed written informed consents were obtained from the patients and/or guardians.

Patient consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

References