Association of Serum Complement C1q and C3 Level with Age-Related Macular Degeneration in Women

Abstract

Purpose

To investigate the association between serum complement components and age-related macular degeneration (AMD).

Patients and Methods

A total of 118 AMD patients and age- and sex-matched 106 control subjects were included. Demographic data and the level of serum complement component (C)1q, C3 and C4 were evaluated. Based on sex, the subjects were stratified into male and female subgroups.

Results

The level of C1q (226.31±45.33mg/dL) was significantly higher and C3 (121.14±15.76mg/dL) was significantly lower than that in control group (200.03±38.54mg/dL) (128.42±19.81mg/dL) in the female AMD patients (p = 0.005, p = 0.045). Logistic regression showed that increased C1q (OR = 1.132, p = 0.016) and decreased C3 (OR = 0.960, p = 0.048) were independent risk factors for female AMD patients. No statistical significance was observed in the male.

Conclusion

Increased C1q and decreased C3 were associated with increased risk of AMD, suggesting that the complement classical pathway probably be involved in AMD, especially in female.

Introduction

Age-related macular degeneration (AMD) is one of the leading cause of irreversible visual impairment and disability among the elderly worldwide.^1,2 AMD is mainly characterized with the accumulation of drusen, retinal atrophy and the development of abnormal choroidal neovascularization. The pathogenesis of AMD is still not entirely clear, accumulating advances in the last decades have highlighted the contribution of dysregulation of the complement system to the pathology of AMD.³

Complement is a kind of protein existing in human serum, tissue fluid and cell surface, and after activation of the enzyme activity, can mediate immune reaction to eliminate pathogens.⁴ It is mainly activated by three independent but overlapping pathways, namely the classical pathway, the bypass pathway and the lectin pathway and all pathways lead to cleavage of complement C3, which leads to the formation of the membrane attack complex made up by C5b-C9. Overactivation of the complement system produces an immune inflammatory response that can result in tissue destruction.⁵

A large number of studies have shown that the activation of complement system is deeply involved in AMD.⁶ The increased expression of complement components including C3, CFB, CFH, CFI, and C1qA was found in atrophic regions of AMD patients.⁷ Whitcup et al found C3 and C3a and other immune substances accumulated under the retina and caused the activation of complement system and forming of drusen, which was associated with degeneration of retinal pigment epithelial (RPE) cells.⁸ The activators and regulatory proteins of complement have also been discovered to be constituents of drusen.⁹

Moreover, several scholars have proposed that the activation of the systemic complement system may make a contribution to AMD. Lechner et al found the increased systemic complement activation with increased C3a, C4a and C5a in AMD patients.¹⁰ Lynch et al discovered the elevated plasma levels of C3a and sC5b-9 were independent risk factors for wet AMD.¹¹ As shown, the complement activation occurs in peripheral blood of AMD patients; however, the contribution of each complement pathway to C3 activation is still unknown. Notably, accumulating research has suggested that C1q, which is the initiator of classical pathway of complement system is related to aging-related disease.¹²

It has been reported that C1q not only facilitates apoptotic debris removal but also gets involved in the damage of vascular endothelial cells and nerve cells.^13,14 Naito et al proved that the level of C1q in both serum and tissues increased with age and C1q could activate canonical Wnt signaling and promote aging-related phenotypes.¹⁵ In the study of Stasi et al, C1q expression was found to be upregulated in the retina of glaucomatous mice, monkey and human eyes, which preceded the time of extensive retinal ganglion cell death.¹⁶ In addition, Webster et al discovered that increased C1q was associated with amyloid-β accumulation in Alzheimer’s Disease.¹⁷

To date, the serum level of C1q has not been reported in AMD patients. Therefore, we aimed to detect serum complement mainly C1q and C3 to study the association of C1q and C3 with AMD to explore the contribution of the classical complement pathway to disease.

Patients and Methods

Study Population

This retrospective study was performed by the Eye and ENT Hospital of Fudan University in Shanghai and implemented according to the principles of Helsinki Declaration. In this project, patients diagnosed with AMD were collected from Ophthalmology Department of Eye and ENT Hospital of Fudan University from January 2019 to December 2020. During the study period, normal individuals were collected from a population that attended annual health screenings. At the same time, informed consent was obtained from AMD patients and normal controls. A structured questionnaire was used to determine their medical history, including current history of diabetes, hypertension, smoking and alcohol intake. Subjects were considered to have a smoking history if they were current or previous smokers ≥1 cigarette per day for ≥6 months. History of alcohol intake was considered if current or previous alcohol consumption was ≥3 times per week and the interval was ≥6 months.

Inclusion and Exclusion Criteria

Each subject underwent standardized ophthalmic examinations, including an assessment of refractive status and slit-lamp biomicroscopy. Patients with AMD underwent fundus fluorescein angiography and/or choroidal indocyanine green angiography and diagnosed by experienced ophthalmologist.

Inclusion Criteria of AMD Group

(1) ≥18 years old;

(2) non-pregnant women;

(3) had macular damage in one or both eyes: including fundus manifestation of vitreous warts, choroidal neovascularization, subretinal hemorrhage and disc-like fiber scar.

Exclusion Criteria of AMD Group

(1) had other diseases causing neovascularization and hemorrhage in macular area;

(2) had glaucoma, diabetic retinopathy, uveitis and other ocular disease;

(3) had tumor, heart disease, liver disease, nephropathy, nervous system disease, autoimmune diseases, hematonosis, severe infectious diseases and other systemic diseases;

(4) had missing data.

Inclusion Criteria of Control Group

(1) ≥18 years old;

(2) non-pregnant women;

(3) had no clinical manifestations of AMD or other eye diseases were confirmed by ophthalmic examination.

Exclusion Criteria of Control Group

(1) had tumor, heart disease, liver disease, nephropathy, nervous system disease, autoimmune diseases, hematonosis, severe infectious diseases and other systemic diseases;

(2) had missing data.

According to inclusion and exclusion criteria, as shown in Figure 1, a total of 418 AMD patients and 180 control subjects were collected. Three hundred AMD patients and 74 control subjects were excluded, and 118 AMD patients and 106 control subjects were eventually included in this study.

Figure 1.

The study population flowchart.

Sample Collection and Testing

After fasting for 8 hours, 4.5mL blood samples were collected in the morning using standard anterior cubital fossa vein puncture (anterior cubital vein) and yellow cap vacuum vascularization (including coagulant). Centrifugation at 1700g for 10 min to separate the serum. The levels of C1q, C3 and C4 were determined by immunoturbidimetry with Cobas 8000 automatic biochemical analyzer (Roche Cobas, Basel, Switzerland). Normalized values for C1q are 159 to 233mg/dL, for C3 components are 90 to 180mg/dL and for C4 are 10 to 40mg/dL. The coefficient of variation for indoor quality control was 3% to 7% on a daily basis during the study period, with no significant change in values.

Data Analysis

Sample Evaluation

This study was a case-control study, with AMD patients in the case group, and healthy subjects in the control group, and C1q was considered as the main observation factor. The matching principle was that the age difference between the subjects in the case and control group was within ±3 years, and the matching ratio was 1:1. PASS 15 software was used to calculate the sample size. According to reports in the previous literature, we set the OR = 2.7, p = 0.2, α= 0.05, β= 0.10 and obtained the sample size of each group was 115. After strictly excluding, our research basically met the requirements.

Calculating

Statistical software (SPSS 25.0 version; SPSS, Inc., NewYork City, NY, USA). Independent sample t test, Mann–Whitney U-test and Pearson’s chi-square test were used to analyze differences in basic characteristics between AMD group and normal control group. Binary logistic regression analysis was used to evaluate the correlation between C1q, C3, C4 and AMD after adjusting for age, gender, history of diabetes, hypertension, smoking and alcohol consumption. P < 0.05 was considered statistically significant.

Results

Demographic Data

As shown in Table 1, there were no significant differences in age, gender and diabetes history between the control group and the AMD group (p > 0.05). The age distribution of AMD and control group is shown in Supplementary Figure 1. There were significant differences in history of hypertension (p < 0.001), smoking (p < 0.001) and alcohol intake (p < 0.001) between the control group and the AMD group.

Table 1.

Demographic and Clinical Characteristics of AMD Patients and Controls

	AMD	Control	t value	P value
	(n = 118)	(n = 106)
Age (mean ± SD), years	62.47±12.64	62.62±8.47	−1.43	0.153a
Sex, M/F (number (%))	58 (49.2)/60 (50.8)	59 (55.7)/47 (44.3)	0.948	0.330 c
History of hypertension (number (%))	56 (25)	11 (4.9)	24.683	<0.001 c
History of diabetes (number (%))	13 (5.8)	4 (1.8)	3.208	0.073 c
Smoking (number (%))	33 (14.7)	1 (0.4)	29.607	<0.001 c
Alcohol intake (number (%))	18 (8.0)	1 (0.4)	12.946	<0.001 c
C1q (mg/dL)	209.52±43.87	190.63±44.18	−3.422	0.001 a
C3 (mg/dL)	120.30±16.17	122.84±20.44	−1.031	0.304 b
C4 (mg/dL)	27.68±7.33	29.89±20.68	−1.085	0.279 b

Notes: ^aMann Whitney U-test. ^bIndependent samples t-test. ^cPearson’s chi-square test. The bold figures indicate p < 0.05.

Comparison of Complement Level Between Control Group and AMD Group

As shown in Table 1 and Figure 2, the level of C1q in AMD group (209.52±43.87mg/dL) was significantly higher than that in control group (190.63±44.18mg/dL) (p = 0.001). The level of C3 (120.30±16.17mg/dL) in AMD group was not significant lower than that in control group (C3: 122.84±20.44mg/dL) (p = 0.304). The level of C4 in AMD group (27.68±7.33mg/dL) was not significantly lower than that in control group (C4: 29.89±20.68mg /dL) (p = 0.279).

Figure 2.

Comparison of complement levels between AMD patients and control group.

Subgroup Analysis of Complement Components in Control Group and AMD Group

A total of 118 patients were in AMD group, including 58 males and 60 females. A total of 106 subjects were in the normal control group, including 59 males and 47 females. As Table 2 and Figure 3 displays, there were no significant differences in C1q (p = 0.193), C3 (p = 0.756) and C4 (p = 0.409) levels between male AMD patients and control subjects. C1q in female AMD patients (226.31±45.33mg/dL) was significantly higher than that in the control group (200.03±38.54mg/dL) (p = 0.005). C3 in female AMD group (121.14±15.76mg/dL) was significantly lower than that in control group (128.42±19.81mg/dL) (p = 0.045).

Table 2.

Comparison of Complement Levels Between Male and Female AMD Patients and Controls

	AMD	Control	t value	P value
Male
C1q (mg/dL)	193.31±35.89	183.15±47.19	−1.309	0.193a
C3 (mg/dL)	119.45±16.68	118.39±19.99	−0.312	0.756a
C4 (mg/dL)	27.21±7.60	30.17±26.14	0.829	0.409a
Female
C1q (mg/dL)	226.31±45.33	200.03±38.54	−2.821	0.005a
C3 (mg/dL)	121.14±15.76	128.42±19.81	−2.003	0.045a
C4 (mg/dL)	28.14±7.09	29.53±10.73	0.805	0.422a

Notes: ^aIndependent samples t-test. The bold figures indicate p < 0.05.

Figure 3.

Gender subgroup comparison of complement levels between AMD patients and control group. (A) the comparison between male AMD patients and control subjects; (B) the comparison between female AMD patients and control subjects.

Male and female AMD patients and the control subjects were divided into four subgroups according to the age quartile of AMD patients: Q1≤56, 56<Q2≤65, 65<Q3≤71, Q4>71 retrospectively. As Table 3 shown, there was no difference in the C1q, C3 and C4 levels between male AMD patients and control subjects in the four subgroups. As Table 4 shows, the level of C1q in Q1 (218.83±33.48mg/dL), Q2 (228.96±39.72mg/dL), Q3 (221.55±41.48mg/dL) and Q4 (220.40±44.60mg/dL) in female AMD patients was significantly higher than that in the control group (Q1:159.31±19.37mg/dL, Q2:186.88±38.67mg/dL, Q3:205.74±35.83mg/dL, Q4: 210.61±39.49mg/dL) (p < 0.001, p = 0.006, p = 0.041, p = 0.028; retrospectively). The level of C3 in Q1 (114.96±15.01mg/dL), Q2 (119.44±9.64mg/dL) and Q3 (119.44±10.64mg/dL) in female AMD patients was significantly lower than that in the control group (Q1:124.88±21.66mg/dL, Q2:129.39±18.40mg/dL, Q3:128.39±12.40mg/dL) (p = 0.045, p = 0.039, p = 0.036; retrospectively).

Table 3.

Comparison of Complement Levels in Age Subgroups of Male AMD Patients and Controls

	AMD	Control	t value	P value
Male
Age≤56
C1q(mg/dL)	206.85±22.40	173.52±50.85	2.074	0.056a
C3(mg/dL)	121.02±16.51	119.93±19.85	0.158	0.875a
C4(mg/dL)	29.01±6.46	33.10±39.03	−0.342	0.734a
56<age≤65
C1q(mg/dL)	176.01±34.39	172.35±35.36	0.309	0.759a
C3(mg/dL)	120.05±15.62	114.13±17.49	1.045	0.304a
C4(mg/dL)	25.61±8.18	26.28±7.81	−0.247	0.806a
65<age≤71
C1q(mg/dL)	201.21±42.47	214.05±16.90	−0.413	0.685a
C3(mg/dL)	112.91±13.88	133.56±11.27	−2.046	0.059a
C4(mg/dL)	29.07±8.51	26.69±25.07	0.302	0.767a
Age>71
C1q(mg/dL)	195.46±33.86	220.03±44.93	−1.742	0.092a
C3(mg/dL)	121.38±18.67	120.23±25.80	0.145	0.886a
C4(mg/dL)	26.21±6.37	31.59±7.89	−1.955	0.067a

Note: ^aIndependent samples t-test.

Table 4.

Comparison of Complement Levels in Age Subgroups of Female AMD Patients and Controls

	AMD	Control	t value	P value
Female
Age ≤56
C1q (mg/dL)	218.83±33.48	159.31±19.37	5.637	<0.001a
C3 (mg/dL)	114.96±15.01	124.88±21.66	−1.161	0.045a
C4 (mg/dL)	26.58±6.59	24.85±8.54	0.614	0.544a
56<age≤65
C1q (mg/dL)	228.96±39.72	186.88±38.67	2.985	0.006a
C3 (mg/dL)	119.44±9.64	129.39±18.40	−1.753	0.039a
C4 (mg/dL)	24.19±8.19	27.72±8.42	−1.175	0.249a
65<age≤71
C1q (mg/dL)	221.55±41.48	205.74±35.83	1.179	0.041a
C3 (mg/dL)	119.44±10.64	128.39±12.40	−1.69	0.036a
C4 (mg/dL)	29.58±6.82	28.07±11.08	0.399	0.693a
Age>71
C1q (mg/dL)	220.40±44.60	210.61±39.49	0.560	0.028a
C3 (mg/dL)	120.73±9.22	124.29±12.8	−0.803	0.103
C4 (mg/dL)	27.82±5.78	31.92±12.34	−1.030	0.310a

Notes: ^aIndependent samples t-test. The bold figures indicate p < 0.05.

Furthermore, AMD patients and control subjects were divided into subgroups according to the mean of C1q and C3—Q1 (lower C1q group, C1q≤200.43mg/dL), Q2 (higher C1q group, C1q>200.43mg/dL), Q3 (lower C3 group, C3≤121.51mg/dL), and Q4 (higher C3 group, C3>121.51mg/dL). The number of AMD patients and control subjects each group was counted and compared between Q1 and Q2, Q3 and Q4. As shown in Figure 4, the proportion of AMD patients in the Q2 group was significantly higher than that in Q1 (p = 0.004). The proportion of AMD patients in the Q3 group was not significantly different from that in Q4 (p = 0.535).

Figure 4.

The proportion of AMD patients and control subjects in subgroups defined by the mean of C1q and C3. (A) subgroup defined by the mean of C1q. Q1: C1q≤200.43mg/dL, and Q2: C1q>200.43mg/dL; (B) subgroup defined by the mean of C3. Q3: C3≤121.51mg/dL, Q4: C3>121.51mg/dL.

Binary Logistic Regression Analysis

As shown in Table 5, after adjusting for age, history of hypertension, diabetes, smoking and alcohol consumption, binary logistic regression analysis showed the OR of C1q was 1.120 (95% CI: 1.009–1.132; p = 0.001). In male, there was no correlation between C1q (OR = 1.011), C3 (OR = 0.990), C4 (OR=0.952), and AMD (p > 0.05). In female, the OR of C1q was 1.132 (95% CI: 1.106–1.159, p = 0.016) and the OR of C3 was 0.960 (95% CI: 0.923–1.000; p = 0.048). The increased C1q and decreased C3 were risk factors for AMD.

Table 5.

Logistic Regression Models Evaluating the Risk Factors for AMD

	Odds Ratio	95% Confidence Interval for Odds Ratio	P value
Overall
C1q (mg/dL)	1.120	1.009 to 1.132	0.001a
C3 (mg/dL)	0.984	0.962 to 1.008	0.185a
C4 (mg/dL)	0.976	0.926 to 1.028	0.353a
Male
C1q (mg/dL)	1.011	0.994 to 1.028	0.200a
C3 (mg/dL)	0.990	0.953 to 1.029	0.626a
C4 (mg/dL)	0.952	0.868 to 1.043	0.287a
Female
C1q (mg/dL)	1.132	1.106 to 1.159	0.016a
C3 (mg/dL)	0.960	0.923 to 1.000	0.048a
C4 (mg/dL)	0.964	0.889 to 1.047	0.386a

Notes: ^aBinary logistic regression adjusted for age, gender, hypertension, smoking and alcohol intake. The bold figures indicate p < 0.05.

Discussion

In this study, we found a significant increased C1q and decreased C3 level in serum in the female AMD patients compared with the control subjects. In contrast, there was no significant difference between male AMD patients and control subjects in the level of C1q and C3. Moreover, we found increased C1q and decreased C3 were risk factors for developing AMD in females, which to our knowledge has not been reported previously.

Several authors demonstrated elevated concentrations of numerous complement compounds, for example C3a, C3d, C5a, Ba, Bb, factor D and the complex C5b-9 in peripheral blood of patients with AMD, suggesting the activation of systemic complement system, which was consistent with our findings.^3,18,19 Recent studies also showed a significant correlation between the SERPING-1 gene responsible for expression of C1 inhibitor factor and AMD, which may strongly indicate the activation of the classical complement pathway in the pathogenesis of AMD.²⁰ In our study, C1q was found to be elevated and was accompanied by decreased C3, which suggested the classical pathway in peripheral blood may be activated, leading to more activation and cleavage of C3, and hence a decrease in its level. Therefore, we speculated that classical pathway of systemic complement system may be activated and probably contribute to the development of AMD.

It is well noteworthy that there is accumulating evidence indicating the upregulation of C1q in tissue in AMD patients.^21–23 Jiao et al discovered that subretinal macrophages could produce classical complement activator C1q leading to the progression of focal retinal degeneration.²² Demirs et al demonstrated that in macular RPE/choroid tissue, complement mRNA and protein expression levels are about 15–100 times higher than in normal neuroretinas, and C1qA was one of the components detectable in atrophic areas.⁷

Moreover, some scholars found that there was some correlation between AMD and several disease related to systemic complement system. Nitsch et al performed a case-control study including 18,007 AMD patients and 81,869 normal controls.²³ They reported that AMD patients were more likely to have systemic lupus erythematosus, glomerulonephritis, and there was a strong and independent association between diabetic nephropathy and AMD after excluding the effect of diabetes. Acosta et al found that the progression from diabetes to diabetic nephropathy may be in part mediated by disorders of the complement system²⁴ and a rat model with arterial hypertension and albuminuria proved that the expression of C1q was found to be significantly higher glomerular than controls.²⁵ Combining with the above reports, it was reasonable to give a speculation that the upregulation of C1q was not only located in retina, but also involved in whole system in AMD patients.

How this may contribute to the development of AMD is currently not well understood. Firstly, circulating complement C1q may be recruited to the macular in AMD. Previous studies showed that C1q and classical pathway were involved in the drusen formation which was the most important pathological feature of AMD.^26,27 Johnson et al established a human RPE cell-culture model that mimicked several key aspects of early-stage AMD.²⁶ They found drusen formation involved an activation of the complement cascade, which appeared to be mediated via the classical pathway by the binding of C1q to ligands in APOE-rich deposits, triggering the deposition of terminal complement complexes and inflammatory response. Another study performed by Doyle et al indicated that C1q could activate the inflammasome NLRP3, leading to lysosome rupture and eventual release into the extracellular matrix and damage of surrounding RPE cells.⁹ Furthermore, C1q was suggested to be involved in the progressive photoreceptor loss and neuroinflammation in retinal degenerations, facilitating the progression of late-stage retinal atrophy.²²

Secondly, accumulated complement activated products such as C3a, C5a, and membrane attack complex was found to be involved in the formation of drusen and may also be related to the new blood vessels as reported.^7,11 The following question is what is the cause of complement activation. A growing body of evidence indicates that AMD pathogenesis involves ocular autoimmunity.²⁸ It has been reported that 94% of patients with early-stage AMD and 83% of patients with late-stage AMD displayed elevated levels of retinal autoantibodies.²⁹ Moreover, the reactivity pattern of serum IgG antibodies of AMD patients with retinal tissue was relatively correlated with the disease stage.³⁰ Since the Fc segment of IgG binds to C1q to activate the complement system, activation of autoantibodies in AMD patients may lead to depletion of C3⁴.

In addition, gene polymorphisms of complement components including C3 may also cause the activation of complement.^31,32 Yates et al reported the common functional polymorphism rs2230199 (Arg80Gly) in the C3 gene resulting in overactivation of complement system, was strongly associated with age-related macular degeneration.³³ Interestingly, complement variants also confer susceptibility to invasive infection with several bacteria in AMD patients.³⁴ Javed et al considered that periodontal diseases which was mainly caused by the periodontal infection may be a plausible risk factor for AMD and may have a potential role in the earlier stages of this eye disease.³⁵ Robman et al found that AMD patients with high antibody titers of C. pneumoniae were also found to have a 2- to 3-fold increased risk of disease progression.³⁶ In our study, AMD subjects with acute infectious diseases were excluded; however, chronic subclinical inflammation in AMD subjects was usually difficult to detect through medical screenings. Therefore, we speculated that AMD patients who had lower levels of C3 were likely to be more susceptible to infection as well which can in turn cause a further decrease in C3 levels.

In our study, we found the difference in serum of C1q and C3 concentrations between female but not male AMD patients and control subjects. The influence of gender on developing AMD is not fully understood.³⁷ Several studies concluded that AMD had no significant relationship with gender, but a meta-analysis of gender of AMD showed that the incidence of exudative AMD was higher in women than in men, despite the fact that women tend to live longer and pay more attention to health care.³⁸ A survey in Japanese cohort demonstrated the differential associations of early AMD with both systemic and genetic factors by sex, which suggested that disease process of early AMD could be different by sex.³⁹

As reported by Nuzzi et al, the risk of AMD was increased in women with early menopause.⁴⁰ Our team previously investigated the relationship between complement system and primary angle-closure glaucoma (PACG) and also found the sex difference in terms of the level of C3 in elder female PACG patients.^41,42 According to related study, the differences may be due to the hormone levels especially estrogen and menopausal status between men and women.^43,44 In our study, most of the female subjects were aged more than 50 years old so most of them were in postmenopausal with lower levels of sex hormones.

Many mechanisms have been proposed for the role of female sex hormones in AMD.⁴⁵ Estrogen is a multifunctional hormone that regulates the inflammatory process. Premenopausal women are thought to be more protected from inflammation than men due to higher estrogen concentrations.⁴⁶ Shepherd et al concluded that a drop of menopausal estrogen level was associated with increased concentrations of pro-inflammatory cytokines and chemokines such as IL-1β, IL-6, IL-8 and TNF-α, which were related to the damage of RPE cells.^3,47 Additionally, the decrease of estrogen was associated with the increase of reactive oxygen species and lipid peroxidation end products, which was also correlated with decreased lysosomal activity, RPE damage and choroidal neovascularization.^48–50

Meanwhile, estrogen levels may influence the complement system as well. Researchers discovered that postmenopausal women who received a sex hormone replacement therapy regimen had significantly higher levels of C3 than control subjects, suggesting plasma C3 context had a positive and strong correlation with sex hormone concentrations.⁵¹ Supporting to this, Yilmazer et al found that the mean values of C3 in healthy postmenopausal women with oral conjugated equine estrogen treatment was significantly higher than those with untreated.⁵²

This study still has some limitations. Firstly, there were differences in the baseline data including hypertension smoking history although they were strictly adjusted for in the logistic regression. Secondly, AMD subtypes cannot be identified for further analysis based on available data. Thirdly, all participants were recruited from one location and the data only represent results from areas around Shanghai. Replication of the study findings in other locations and with a much improved larger population is necessary to confirm our results. Lastly, we did not show the downstream molecules of complement activation in the classical pathway. We will continue to conduct in-depth studies on this part in the future to better reveal the systemic activation of complement system in AMD.

Conclusion

In conclusion, our data suggested that increased C1q and decreased C3 were independent risk factors for female AMD patients, indicating the activation of the complement system in classical pathway may be involved in the pathology of AMD. To our best knowledge, it is the first time to report an elevated C1q and decreased C3 level in female AMD patients, which is helpful for more comprehensive understanding of the complement activation in peripheral blood of AMD. Large and multi-center studies are needed to explore whether complement components can be considered as novel biomarkers to diagnose and/or predict progression of AMD.^53–55

Abbreviations

AMD, age-related macular degeneration; C, complement component; RPE, retinal pigment epithelial; PACG, primary angle-closure glaucoma.

Disclosure

The authors report no conflicts of interest in this work.