Age-related macular degeneration: Epidemiology, genetics, pathophysiology, diagnosis, and targeted therapy.

Age-related macular degeneration (AMD) is a complex eye disorder and is the leading cause of incurable blindness worldwide in the elderly. Clinically, AMD initially affects the central area of retina known as the macula and it is classified as early stage to late stage (advanced AMD). The advanced AMD is classified into the nonexudative or atrophic form (dry AMD) and the exudative or neovascular form (wet AMD). More severe vision loss is typically associated with the wet form. Multiple genetic factors, lipid metabolism, oxidative stress and aging, play a role in the etiology of AMD. Dysregulation in genetic to AMD is established to 46%-71% of disease contribution, with CFH and ARMS2/HTRA1 to be the two most notable risk loci among the 103 identified AMD associated loci so far. Chronic cigarette smoking is the most proven consistently risk living habits for AMD. Deep learning algorithm has been developed based on image recognition to distinguish wet AMD and normal macula with high accuracy. Currently, anti-vascular endothelial growth factor (VEGF) therapy is highly effective at treating wet AMD. Several new generation AMD drugs and iPSC-derived RPE cell therapy are in the clinical trial stage and are promising to improve AMD treatment in the near future.

Introduction

The macula is a circular area of diameter 5.5 mm with a center located 17°, or 4.0–5.0 mm, temporal, and 0.53–0.8 mm inferior to the center of the optic disc. The fovea centralis is a small, central pit composed of closely packed cones in the human eye. The fovea is responsible for sharp central vision. The fovea is surrounded by the parafovea belt and the perifovea outer region (Fig. 1A, B). Macular degeneration is the leading cause of severe, irreversible vision loss in people over age 55. It occurs when the macula deteriorates. Because the disease develops as a person ages, it is often referred to as age-related macular degeneration (AMD).

Figure 1

Neovascularization and drusen formation. (A) A cross section of a normal human eye showing the location of the macula. An oval area with a diameter of 1.5 mm near the fovea is known as the macula. (B) It shows the important structure of the retina in the macular area. RPE cells have the function of removing metabolites produced by photoreceptors. The blood vessels in the choroid can transport nutrients and nourish the outer retina. (C) The formation and location of drusen is shown. Drusen formation will lead to retinal tissue atrophy and Bruch membrane calcification rupture, further leading to AMD. (D) This picture describes a choroid polypoid lesion. (E) This picture shows the proliferation of new blood vessels.

AMD can be classified into four stages.1, 2, 3 The first stage is normal ageing changes with only small - drusen and no pigment abnormalities. At this stage, the diameter of the drusen is < 63 μm. In the second stage (early AMD), there are some intermediate drusen whose diameter is ≥ 63 μm and ≤124 μm but with no retinal pigment epithelium (RPE) cell abnormalities. Stage 3rd is extensive, moderate, at least one large drusen (diameter ≥125 μm; intermediate AMD) and RPE abnormalities. Stage 4th, also known as advanced AMD, is concerned with the geographic atrophy (GA) of the fovea or any age-related characteristics of neovascular macular degeneration, as well as resulting in visual loss. Liew confirmed the robustness of the age-related eye disease study (AREDS) simplified severity scale. Early AMD has the smallest visual impairment, usually accompanied by decreased reading ability, visual distortion, and a black or gray spot in the central vision. Mid-term AMD is characterized by large or moderate vitreous wart membranes or imperfect pigmentation. The central vision of patients with advanced AMD is significantly affected.

Clinically, besides disciform scar which is at the end stage of advanced AMD, advanced AMD is also divided into two categories: dry AMD (Fig. 1C) and wet AMD. Dry AMD is also known as GA, which does not involve blood or serum leakage. It is characterized by symmetrical eyes, distorted vision, disordered macular pigmentation in both eyes, the disappearance of foveal reflex, varying posterior poles with yellowish-white drusen between Bruch's membrane (BrM) and RPE. In some advanced patients, map-like atrophy of the posterior retina can be observed. Wet AMD can be divided into choroidal neovascularization (CNV, Fig. 1D) and polypoidal choroidal vasculopathy (PCV, Fig. 1E), which involve blood or serum leakage. (At present, it is still controversial whether PCV belongs to wet AMD. On the one hand, PCV and CNV have different characteristics in clinical characteristics and epidemiology. On the other hand, PCV and CNV have similarities in environmental and genetic risk factors. In this review, PCV, and CNV are regarded as subtypes of wet AMD). Compared with dry AMD, the visual acuity of patients with wet AMD decreased more rapidly. Most patients with wet AMD suffer from one eye first, and the other eye may not develop for a long time. In CNV, choroidal capillaries grow to the RPE and BrM lesions, resulting in choroidal neovascularization. Because the structure of neovascularization is not perfect, it will lead to a series of pathological changes such as exudation, bleeding and scar, which will further lead to the loss of central vision. PCV is more prevalent in Asians. The clinical course of PCV is more stable and visual outcomes are more favorable from those of CNV and therefore been described as a separate clinical entity differing from CNV. In PCV condition, the polypoid neovascularization from the choroid layer can pass through the BrM but would not penetrate the RPE layer. PCV can be divided into type I and type II according to the morphology of the lesions. Type I had abnormal branching vascular network (BVN) and polypoid lesions at the end of the vascular network. Type II had isolated or clustered polypoid lesions, but no obvious branching vascular network or fine reticular vessels. In this condition, secondary subretinal hemorrhage or submacular hemorrhage may occur.

Epidemiology

Prevalence

The population of AMD is increasing with ethnic and regional differences. From 1990 to 2010, the incidence of blindness and visual impairment caused by AMD was increased. With population aging worldwide, it is estimated that the number of AMD patients will be increased to 196 million in 2020, 288 million in 2040. Since Asia accounts for more than half of the world's population, the number of cases is expected to reach 113 million by 2040. Because of the highest prevalence of AMD in Europe, the number of future cases in this region is predicted to be second after Asia (Fig. 2)., AMD is more common in whites than in blacks.12, 13, 14 The prevalence rate of AMD in European was 12.33%, Asian was 7.38%, and African was 7.53% Michele Reibaldi reported that latitude or longitude was negatively correlated with the original or age-standardized prevalence of AMD in the early and late stages (P < 0.001). Chinese population accounts for about one-fifth of the world's population. Song Peige reported that the prevalence of AMD varies in different geographical backgrounds in China; the prevalence of AMD is concentrated in the most populous areas of south-central China, at 6.64% (95% CI = 5.12–8.52) and 6.74% (95% CI = 5.20–8.65) in 2000 and 2010, respectively, and increases with the decrease of latitude.

Figure 2

The predicted global prevalence of AMD in 2040. TThis figure shows the estimated number of people worldwide with AMD in 2040. Data from REF.10.

General risk factors

There are several risk factors for AMD, such as ageing, race, blood pressure, and lifestyle. Ageing is a strong risk factor for the development of AMD. Blue iris is more likely to develop AMD than the brown iris. Systemic factors such as cardiovascular disease are also risk factors for AMD; elevated blood pressure, and atherosclerosis can increase the risk of AMD. The presence of diabetic retinopathy (DR), high-density lipoprotein (HDL), obesity and high systolic blood pressure increase the risk of AMD in diabetic patients. Also, Ronald et al reported that the baseline level of serum cystatin C was associated with the incidence of early AMD and wet AMD. Studies show that smoking and heavy drinking increase the risk of AMD.24, 25, 26 Lutein and zeaxanthin can reduce the risk of AMD, vitamin C, vitamin E, vitamin D, zinc oxide can prevent the occurrence of AMD., Increase fish intake can reduce the risk of AMD,29, 30, 31 DHA and EPA may slow the occurrence of AMD., In addition, lunch break is associated with a lower incidence of advanced AMD. People who divorced or separated were three times more likely to have advanced AMD than married people.

Genetics

Associated loci

Genetic factors had a strong impact on the pathogenesis of AMD, totally 103 AMD-related genes or loci have been reported. CFH and HTRA1 loci are the two major associated loci for AMD. In 2005, researchers first linked the 402H allele of CFH to an increased risk of AMD.36, 37, 38 CFH is a key regulator of the complement pathway, located in chromosome 1q32. CFH 402H disable to transport oxidative lipids out of the RPE layer, destroys the regulatory function of CFH in inhibiting the activation of C3 to C3b and degrading C3b, leading to the over-activation of complement, thus increasing the risk of AMD.35, 36, 37, 38, 39, 40 CFB and C2 are activators of alternative and classical pathways, respectively. CFB R32Q and R32Q/IVS10 haplotype has a protective effect for AMD. The mutation R102G (rs2230199) of C3 is involved in the process of AMD from early to late. Lysate C3a of C3 exists in the vitreous verruca membrane. C3a can induce the expression of VEGF and promote the formation of CNV. CFI is regulated by CFH and is a cofactor of inactivation of C3b. Study showed that rs10033900, rs11728699, rs6854876, rs7439493 and rs13117504 had protective effects, while rs2285714 was associated with increased risk for AMD. HTRA1 is another major effect locus for AMD.45, 46, 47, 48, 49, 50, 51, 52, 53, 54 Rs10490924 in HTRA1 promoter region can increase the risk of AMD 15 times.,, HTRA1 transgenic mice showed BrM and choroid damage, with some pathological features of CNV and PCV.

Some AMD genes related to lipid metabolism. APOE is a key regulator of lipid and cholesterol transport in the central nervous system. Allele haplotypes of APOE were ε2, ε3 and ε4. The risk of AMD in carriers of ε4 is lower than that in people with ε3 genotype. The good mobility of ε4 enables lipid, cholesterol and RPE degradation products to better cross BrM from RPE, otherwise, these substances accumulate in BrM to cause drusen and AMD.55, 56, 57 APOE ε2 seems to enhance the expression of vascular growth factor and fibroblast growth factor RPE cells. Therefore, APOE ε4 can reduce the incidence and progression of AMD compared with APOE ε2. In addition, TIMP3 is involved in RPE aging and sorbite dystrophy., The rs9621532 allele and nearby TIMP3 variants were associated with increased AMD risk. LIPC is also associated with AMD, among which rs10468017 is most related. CETP, LPL, and ABA1 have been demonstrated to express in the retina,, which is associated with AMD may through affecting the formation of dursen. Rs2511989 encodes C1INH in SEPRING1 gene. C1INH is a suppressor of complement classic and lectin pathway activation. It is highly genotypically related to AMD.

So far, at least 103 AMD associated loci have been identified according to GWAS Catalog (https://www.ebi.ac.uk/gwas/) and other publications (Table 1). They are involved in complement factors, lipid metabolism, angiogenesis, immune, cell motion, cytoskeleton, apoptosis and proliferation, cell junction, collagen and etc. Most of the reported genes are associated with all types of AMD and involved in multiple functions (Fig. 3 and Supplementary materials 1). TLR3 is only associated with dry AMD, which can participate in innate immunity and plays a role as pathogen recognition receptors in RPE, leading to apoptosis when induced by cytokines. A rare SNP rs77466370 in FGD6 is only associated with PCV.

Table 1

Classification of AMD related genes.

Type	Genes (region, SNP)
Complement factors	C9 (5p13.1, rs62358361), C3 (19p13.3, rs2230199), C2 (6p21.33, rs116503776), CFHR4 (1q31.3, rs2171106), CFH(1q31.3, rs10922109), MBL2 (10q21.1, rs6480975), CFI(4q25, rs10033900),CFB(6p21.33, rs116503776),CFHR2 (1q31.3, rs2171106)
Lipid metabolism	CETP (16q13, rs5817082), APOE (19q13.32, rs429358), LIPC(15q21.3, rs2043085), ABCA1(9q31.1, rs2740488), LHFP (13q14.11, rs8002574), ABHD2 (15q26.1, rs4932480), TIMP3(22q12.3, rs9621532)
Angiogenesis	FILIP1L (3q12.1, rs13081855), VEGFA (6p21.1, rs943080)
Immune	PVRL2 (19q13.32, rs6857), CD34 (1q32.2, rs1967689), PILRB (7q22.1, rs7803454), SDK1 (7p22.2, rs55869773), ACKR3(2q37.3, rs56072732)
Cell motion	POSTN (13q13.3, rs9646096), TNXB (6p21.32, rs12153855), CNN2(19p13.3, rs67538026)
Cytoskeleton	CCSER2(10q23.1, rs113544501), POC5(5q13.3, rs79069165), HTRA1 (10q26.13, rs3750846), ARMS2(10q26.13, rs3750846)
Apoptosis and proliferation	TNFRSF10A (8p21.3, rs13278062), CTRB2 (16q23.1, rs72802342), NOTCH4 (6p21.32, rs2071277), FRK (6q22.1, rs1999930), PHACTR3 (20q13.32, rs843818), PKNOX2 (11q24.2, rs1077952), KRAS (12p12.1, rs73296436), IER3(6p21.33, rs3130783), TRIM29 (11q23.3, rs61900473), TGFBR1(9q22.33, rs334353)
Cell junction	GJA1 (6q22.31, rs9482193), CDH22 (20q13.12, rs6032755)
Mitochondrial	NDUFC2(11q14.1, rs113553030), XRCC6BP1(12q14.1, rs12368533), UQCRFS1 (19q12, rs741449),TOMM40 (19q13.32, rs6857), SOD2 (6q25.3, rs2842992), ACAD10 (12q24.12, rs61941274), MT–ND5 x ABHD2 (15q26.1, rs267606894 x rs4932480)
Ionic channel	KCNMA1 (10q22.3, rs76150532), KCNJ3 (2q24.1, rs1445653), TRPM1 (15q13.3, rs7182946), EFCAB14 (1p33, rs59182762), KCTD15 (19q13.11, rs10404384), TRPM3 (9q21.12, rs71507014)
Ubiquitination	NPLOC4(17q25.3, rs6565597)
Transcription	PCF11(11q14.1, rs4293143),TRIM24 (chr7:138166004,hg19), NELFE (6p21.33, rs116503776), RREB1 (6p24.3, rs11755724), GLI3 (7p14.1, rs2049622), KLF6 (10p15.1, rs12411753), ATF7IP2(16p13.13, rs28368872), BAZ1A (14q13.2, rs6571690), EFCAB14 (1p33, rs59182762), KHDRBS3(8q24.23, rs200534628), LYAR(4p16.3, rs150938341), NUPR1L (7p11.2, rs148800247), TLE4 (9q21.31, rs11545434)
Transport	SLC16A8 (22q13.1, rs8135665), SLC29A3 (10q22.1, rs7091537), SLC44A4 (6p21.33, rs12661281), TRAPPC9(8q24.3, rs117659209), ADAMTS9 (3p14.1, rs6795735)
Nerve	SYN3(22q12.3, rs5754227), CELSR1 (22q13.31, rs2337055), CNTN6 (3p26.3, rs77360121), DPF3(14q24.2, rs12887388), MBP(18q23, rs1789110), TNR (1q25.1, rs58978565), HERC1 (15q22.31, 15q22.31)
Cluster protein family	PLXNC1(12q22, rs17296444)
Helicases	SKIV2L (6p21.33, rs406936)
Adenylate cyclase	ADCY5(3q21.1, rs6762009)
GTPase or ATPase	ARHGAP21 (10p12.1, rs12357257), ATP6V0D1 (16q22.1, rs1471142), FGD(12q22, rs10507047)
Tyrosinase	TYR (11q14.3, rs621313)
BBSsome	BBS9(7p14.3, rs202162020)
Transmembrane protein	TMEM97 (17q11.2, rs11080055), TSPAN11 (12p11.21, rs55916253)
DNA binding protein	RAD51B (14q24.1, rs61985136), TSN(2q14.3, rs72837798)
Transferase	KMT2E (7q22.3, rs1142), B3GALTL (13q12.3, rs9564692), UGT2B7 (4q13.2, rs112243525), HS3ST4 (16p12.1, rs79590629)
Collagen	COL8A1 (3q12.1, rs140647181), COL10A1 (6q22.1, rs1999930), COL4A3 (2q36.3, rs11884770)
Noncoding RNA	ADAMTS9-AS2 (3p14.1, rs62247658), LINC00470(18p11.32, rs2186849), LINC00588(8q12.1, rs72657107), LINC00900(11q23.3, rs431911), PCDH9-AS3 (13q21.32, rs1359191), LOC101060498(4p14, rs12498917), LOC101927280 (5q23.1, rs61287758), LOC101927797(21q21.1, rs2205502), LOC101929681 (5p13.3, rs139161960), LOC153910(6q24.2, rs63337561), LOC729987(1p21.3, rs12727789)
Others	INHBB(2q14.2,rs6721654), ZPLD1 (3q12.3, rs17822656), HORMAD2 (22q12.2, rs713875), CST5 (20p11.21, rs4815244), CTRB2 (16q23.1, rs72802342), EXOC5(14q22.3, rs75165563), IGFBP6(12q13.13, rs11170417), PDHA2 (4q22.3, rs62315917), PRLR (5p13.2, rs114092250), RDH5 (12q13.2, rs3138141), STOX2 (4q35.1, rs11132213), TRIB2(2p24.3, rs10191751), C20orf85 (20q13.32, rs201459901), C4orf14 (4q12, rs1713985), C6orf223 (6p21.1, rs2295334), C80rf42 (8p23.3, rs722782), C9orf91 (9q32, rs41278671)

Figure 3

Schematic diagram of AMD genetics related genes/proteins. Some of these genes are distributed in the nucleus to participate in the regulation of transcription process, the methylation of histone and so on, some are distributed in the mitochondria to participate in the electron transmission of respiratory chain, and some are distributed in the cytoplasmic matrix and serve as the cytoskeleton used in the cytoskeleton to participate in the regulation of cell life activities. AG: arachidonic acid glyceride.

Interaction between genes and environmental factors

Some AMD-related genes and environmental factors (such as smoking and so on) interact together to influence the occurrence and development of AMD. Smoking changed the binding of CFH to C3, lowered the level of CFH in plasma,, and the rs1061170 variant changed the binding ability of CFH to C3b. Therefore, rs1061170 carriers have a stronger impact on AMD risk among smokers.,,67, 68, 69, 70 Smoking also increases the risk of all people with the HTRA1 genotype. AREDS reported a significant interaction between CFH 402H and BMI. Blue Mountains Eye Study (BMES) found that increasing fish intake in CFH 402Y carriers had a stronger protective effect on late AMD. Intake of antioxidant nutrients also reduced the risk of early AMD in people with high genetic risk of CFH and HTRA1 loci., Similar to CFH variants, when both HTRA1 variants and higher C-reactive protein (CRP) levels are present, the risk of AMD increases. In addition, the potential interaction between chromosome 6q16.2 and 18q22.1 and smoking significantly increased the risk of AMD in long-term smokers. Schmidt et al found that APOE genotype had an impact on the smoking-related risk of AMD, and had a greater impact on CNV, and smoking was the most harmful to carriers of apolipoprotein ε2.,

Mechanism/pathophysiology

RPE cell senescence

A series of changes caused by aging of RPE cells can lead to AMD. The ageing RPE cells break the balance of enzymes in the extracellular matrix in the macular area gathers on the BrM., Metabolites accumulate on the BrM, forming vitreous warts, damaging adjacent retinal tissues, reducing the blood supply of retina. RPE cell senescence leads the immune cells to produce VEGF. Calcification, rupture, and phagocytosis of the Bruch membrane produce blood vessels which eventually leads to AMD (Fig. 4).

Figure 4

The formation of AMD during aging. This diagram shows the non-genetic mechanisms of AMD induced by RPE cell senescence, oxidative stress, hemodynamics and so on during aging.

Oxidative stress

The retina is one of the tissues with the highest oxygen consumption in the human body. Accumulation of oxidative stress plays an important role in the pathophysiological process of AMD. The cumulative oxidative damage of RPE is mainly caused by the imbalance between the production and elimination of reactive oxygen species (ROS). The presence of high oxygen metabolism, high concentration of polyunsaturated fatty acids, and photosensitizers can lead to the excessive production of ROS in the retina., Lipofuscin is the main source of reactive oxygen species, which accumulates in the RPE with age, further enhancing oxidative stress in the retina. Excessive lipofuscin is associated with AMD. In addition, the incidence of AMD in people exposed to sunlight for a longer period was significantly higher than that in the local general population., Antioxidative damage may be the goal of the prevention and treatment of related diseases. However, it was also reported that the mixture of antioxidants had little effect on reducing the rate of progression to CNV. Hyttinen and others suggested that modeling of AMPK-mTOR axis might prevent the development of AMD by helping cells adapt to oxidative stress.,

Lipid metabolism

High-density lipoprotein cholesterol (HDL-C) levels were associated with increased risk of AMD, while high total cholesterol (TC), low-density lipoprotein cholesterol (LDL-C) were associated with reduced risk of AMD. Researchers have found advanced lipid peroxidation end products (ALEs) in lipofuscin,, vitreous warts, and BrM of AMD patients. Accumulation of advanced lipid ALEs interferes with protein stability and leads to apoptosis of photoreceptors and RPE cells.,,

Inflammation and immunity

AMD drusen contain a variety of pro-inflammatory factors, which indicates that local inflammation is a marker of early AMD. The complement system is a component of the innate immune system, which plays an important role in monitoring and maintaining homeostasis of the intraocular microenvironment. It was found that the level of CRP was higher in AMD patients. CRP can recruit CFH to destroy necrotic tissue and prevent the release of pro-inflammatory cytokines. When the risk protein 402H is combined with CRP, the binding ability between 402H and CRP is much lower than that between 402Y in CFH and CRP, which leads to complement activation and inflammation. Most complement proteins do not diffuse through BrM, but C5a released after the activation of complements of AMD pass through BrM, leading to inflammation and angiogenesis. There is growing evidence that the targeted regulation of complement-specific proteins is expected to become a therapeutic method for AMD. Local inhibition of complement activation is considered a promising treatment for advanced AMD. At present, some studies have found potential complement cascade inhibitors, which may slow down the progress of AMD. Also, Calippe et al found that the combination of CFH and mononuclear phagocytes (MP) inhibited CD47-mediated MPs clearance, while MPs maintained the steady state of subretinal space. Therefore, inflammation and immunity are also closely related to the occurrence of AMD.

Neovascularization

VEGF is one of the main risks of wet AMD, which plays an important role in the occurrence of CNV and PCV., Overexpression of vascular-promoting cytokines (such as VEGF, PDGF) and reduction of expression of inhibitory cytokines (ES, TIMP and so on) can lead to excessive proliferation of neovascularization. Studies have shown that the Pulsatile ocular blood flow (POBF) and pulse amplitude (PA) in exudative AMD patients are lower than those in non-exudative AMD patients. The thickening of BrM may lead to increased choroidal vascular resistance, and the decrease of choroidal blood flow may be related to the formation of CNV.99, 100, 101, 102 In addition, choroidal vitreous warts and abnormal pigmentation also increase the risk of AMD. After one eye progresses to advanced AMD, the five-year risk of occurrence of AMD of the second eye is estimated to be between 30% and 40%, which is much higher than that in the normal population.

Other mechanisms

In addition to the above factors that are closely related to the occurrence and development of AMD, other factors, such as autophagy, hemodynamics and circadian rhythm, are also believed to be related to AMD. Autophagy is a lysosomal pathway for the degradation of cytoplasmic proteins and damaged organelles. Protein aggregates are transported to lysosomes via autophagy. With the increase of age and RPE cells aging, lysosomal enzyme activity decreased. Autophagy was reduced to remove mitochondria and protein aggregates, outside cells, thus accelerating the accumulation of lipofuscin, further leading to the development of AMD., Golestaneh et al found that the autophagic flux of RPE in AMD patients was lower than that in normal RPE controls.

There is a classical theory about the occurrence and development of AMD, namely hemodynamics, which holds that choroidal vascular dysfunction is the basis of AMD. Atherosclerotic changes in the blood supply to the eye are now known as neovascular AMD. The modern hemodynamic theory proposed by Friedman in 1997 that AMD occurs because of the change of choroidal blood flow caused by the increase of choroidal and scleral sclerosis. Blood lipid deposition and atherosclerosis result in thickening of the vascular wall, stenosis of vascular lumen, and decreased compliance of vascular wall, resulting in decreased choroidal blood flow and abnormal choroidal perfusion, resulting in insufficient perfusion of RPE cells or Bruch membrane injury, which ultimately leads to AMD. The view that choroidal hemodynamics contributes to the progress of AMD has been supported by recent clinical and experimental data.

Some studies have found that cyclic genes may play a role in regulating retinal vascularization signals in retinopathy. In proliferative neovascularization, the expression of retinal rhythm genes is destroyed. Whether circadian rhythm disorder will affect the occurrence and development of AMD remains to be further studied. In addition, the imbalance of protein homeostasis may be one of the potential mechanisms leading to AMD.

Diagnosis

The diagnostic methods of AMD include fundus imaging, fluorescein angiogenesis (FA), indocyanine green angiography (ICGA), optical coherence tomography (OCT), Optical coherence tomography angiography (OCTA) and artificial intelligence (AI). These techniques play an important role in the diagnosis of AMD and have their unique advantages.

Fundus imaging

Fundus imaging methods include color photography, monochromatic photography, automatic fluorescence imaging, and fundus angiography, which are useful for AMD diagnosis. Microperimetry is a non-invasive visual function test for the analysis of fixation and central visual field defects, especially for AMD. Compared with standard automated perimetry (SAP), microperimetry has the advantages of real-time imaging of fundus and eye tracking. GA can be observed in the eyes of patients with dry AMD drusen, subretinal hemorrhage and pigment epithelial detachment (PED) are common in the eyes of patients with wet AMD. These phenotypes can be easily observed in fundus imaging.

FA and indocyanine green angiography (ICGA)

Dyes used for fundus angiography include sodium fluorescein and indocyanine green. FA is a useful method for detecting wet AMD. Indocyanine green angiography (ICGA) is the gold standard diagnostic tool for PCV. Both FA and ICGA are safe, but occasionally serious reactions may occur. Therefore, the potential risk factors of patients must be carefully screened and the risk of angiography should be informed. Under FA, compared with CNV, serous PED or atypical serous PED is more common in PCV. Under ICGA, CNV showed a neovascularization network without polypoid structure, while abnormal vessels in PCV were more robust with terminal polypoid or aneurysmal cluster with high fluorescence.

Optical coherence tomography (OCT)

OCT is a non-invasive method that can display anatomical cross-sectional information about retina, RPE, and choroid. In early AMD, abnormalities in drusen and RPE can be observed by OCT, which helps doctors to determine the annual signs of disease activity and the risk of progression. In advanced AMD, the activity of disease was monitored by qualitative and quantitative analysis of fluid pools, such as intraluminal cystic fluid, subretinal fluid, and PED, by using OCT. Spectral OCT (SD-OCT) has the advantage of sampling information of multiple locations in the optical path at the same time, which improves the speed of diagnosis. It can easily detect and measure the changes in the photoreceptor layer (PRL) on verruca vitreosa. Under OCT, the choroid thickness of wet AMD is greater than that of normal human, while that of dry AMD is less than that of normal human.

Optical coherence tomography angiography (OCTA)

Optical Coherence Tomography Angiography (OCTA) is a new non-invasive imaging technology, which provides non-invasive characterization and quantification of microvascular system under different retinal conditions. OCTA can be used to observe chorionic changes in patients with dry AMD, to detect the presence of CNV and PCV. OCTA has a good resolution of CNV structure in patients with wet AMD, and can observe and classify the orientation of CNV from cross-section., Overall sensitivity of active CNV detection by OCTA was 80.7%. Compared with FA, OCTA is less occluded by subretinal hemorrhage., For PCV, a combination of structural OCT and OCTA can be used to screen for PCV with 82.6% sensitivity and 100% specificity. Therefore, OCTA can provide clearer vascular details and better detect and quantify CNV lesions in AMD patients. The superficial and deep vascular density of dry AMD patients was significantly lower than that of healthy people. In patients with wet AMD, significant loss of deep choroid vessels and villi muscle was observed. Among them, CNV patients have reduced chorionic capillary perfusion and deeper choroid.

Artificial intelligence diagnosis technology

With the development of artificial intelligence (AI) technology, AI has great potential in the diagnosis of ophthalmic diseases. Kermany et al have proved that the classification effect of the model based on the neural network resume on AMD and diabetic macular edema is equivalent to that of human experts. Similarly, Treder et al used deep learning to train and verify 1112 SD-OCT images of AMD to distinguish exudative macula and normal macula. The classifier model established has achieved good results (the training accuracy and validation accuracy are 100%, the average score of AMD experimental group and control group are more than 0.9). With the development of network technology and the advent of 5G era, AI technology will be constantly optimized. The advantages of AI technology in assisting ophthalmologists to judge the patient's condition and to assist doctors to formulate the optimal treatment plan will also become increasingly prominent. However, the application of AI depends on database, so the establishment of high-quality database is still a challenge for the application of AI in disease diagnosis.

Treatment

Laser and radiotherapy

In 1999, Reichel et al began to treat CNV by transpupillary thermotherapy (TTT). Because its therapeutic effect is only to block the existing CNV, it will also produce complications, such as choroidal atrophy. It is easy to recur, so it is seldom used at present. In addition, studies, have shown that TTT combined with other angiogenic drugs, such as triamcinolone acetonide or ranibizumab, can be used as a therapeutic regimen for wet AMD, but its efficacy needs further evaluation. Besides TTT, laser therapy includes photodynamic therapy (PDT). PDT can be combined with ranibizumab. PDT combined with anti-vascular therapy for PCV is an effective method. Although laser therapy can inhibit the growth of new blood vessels, it can not ensure that no new blood vessels grow. The laser may also destroy normal tissue around the retina. Therefore, it is necessary and important to improve the existing treatment methods and develop new treatment methods for AMD.

Anti-VEGF treatment

The key to the treatment of exudative AMD is to inhibit the formation of neovascularization, and intraocular injection of drugs to inhibit VEGF has become the main treatment for wet AMD.130, 131, 132 Blindness and the density of choroidal capillaries decreases in patients treated with anti-vascular therapy., The main drugs include pegaptanib, ranibizumab, bevacizumab, afiibercept and conbercept (Table 2). Pegaptanib, and ranibizumab are anti-VEGF monoclonal antibody fragment. Afiibercept is a fusion protein of VEGF binding. It is formed by the second binding of human VEGF receptor (VEGFR) −1 to the third binding domain of human VEGF receptor-2 (VEGFR2), and then binding to the Fc region of human immunoglobulin G-1. Afiibercept can bind to all subtypes of VEGFA and VEGFB. It is a new generation of anti-VEGF after pegaptanib and ranibizumab were approved by the FDA in November 2011. Intravitreal injection of afiibercept two months or monthly after the initial dose of three months was similar safety and tolerance to that of ranibizumab monthly., Conbercept is composed of the binding domain of human VEGFR-1 and VEGFR-2 and the Fc part of human immunoglobulin G-1. It had a strong anti-angiogenesis effect.139, 140, 141 Intravitreal injection of conbercept was safe and effective and could prevent the growth of lesions and CNV. Brolucizumab is A humanized, single-stranded antibody that targets VEGF and binds to the VEGF-A subtype. It showed good results in phase 3 clinical trials. It was approved by the FDA for the treatment of wet AMD. Faricimab is a bispecific antibody drug that can bind and inactivate angiopoietin-2 (Ang-2) and VEGF-A. The effect of faricimab is similar to that of ranibizumab. Abicipar pegol is an anti VEGF molecule that uses the designed ankyrin repeat protein (darpin) technology to reduce the level of VEGF. Its half-life in the eye is longer and the effect is more lasting. At keast 13 drugs for VEGF related targets are still in developing. Abicipar pegol, Faricimab, TypeOPT-302 and Dorzolamide-timolol are in their phase III clinical trials; RGX-314, GB-102 (Sunitinib), X-82 (Vorolanib), HMR59 (AAVCAGsCD59), CM082 tablets and RG7716 are in their phase II clinical trials; IBI302, ADVM-022 and TAB014 are in their phase I clinical trials. For dry AMD, there is no effective treatment method currently. However, Heavy dietary intake of specific antioxidants such as carotene, vitamin C, D, E, and zinc may have been shown to slow the progression of a few dry AMD patients.

Table 2

Current therapeutic drugs for wet AMD.

Drug	Attribute	Mechanism of action	Date of approval	Note
Pegaptanib (Macugen)	Anti-VEGF aptamer	Binding to vascular endothelial growth factor 165 prevents its binding to vascular endothelial growth factor receptor	FDA approved it for wAMD treatment in 2004	Visual acuity can not be stabilized well after treatment.
Ranibizumab	Anti-VEGF monoclonal antibody	Binding with VEGF 165, 121 and 110	It was approved by FDA in 2006 for DR and in Europe in 2009 for visual impairment caused by wAMD, RVO, DR and CNV.	Therapeutic effect is better than photodynamic therapy.
Bvacizumab	Humanized anti-VEGF monoclonal antibody	Inhibition of angiogenesis	FDA approved it as a cancer inhibitor in 2004, but it has not yet been approved for ophthalmic treatment	Target molecule and effect are similar to those of ranibizumab
Afiibercept (Eylea)	Humanized anti-VEGF fusion protein	Binding to VEGF-A, VEGF-Band PGF	FDA approval for diabetic macular edema and DR in 2011	It has the same effect as ranibizumab
Conbercept	Anti-VEGF Fusion Protein	Binding to VEGF-A, VEGF-Band PGF	In 2013, it was approved by CFDA for the treatment of wAMD, and was awarded “the most innovative drug with clinical value” in phase III clinic of USA.	Adverse reactions are weak and can be recovered without treatment, which is more economical than ranibizumab
Triamcinolone acetonide	Glucocorticoid	Inhibition of angiogenesis, the specific mechanism of action is not yet clear.	On February 4, 2019, the FDA accept the application for new drug triamcinolone acetonide suspension (xipere)	The effect of single use is not significant.
Brolucizumab (Beovu, RTH258)	anti-VEGF antibody	binds to the VEGF-A subtype	approved in the United States in 2019	After one year of treatment, patients treated with BEOVU showed similar visual improvement as patients treated with aflibercept.
Abicipar pegol	anti-VEGF molecule	Using DARP in technique to mimic antibody, target VEGF	Not yet approved, phase III completed
Faricimab	Bi-specific antiboy	anti-Ang-2 antibody and anti-VEGF-A antibody	Not yet approved, phase III completed
OPT-302	A fusion protein composed of the 1–3 of VEGFR-3 and Fc	By binding to VEGF-C or VEGF-D, they block their binding to VEGFR-2 or VEGFR-3 on the surface of endothelial cells in blood vessels or lymphatic vessels.	Phase III clinical trials are planned for 2021	The effect of combination with ranibizumab is better than that of using alone
Dorzolamide-timolol	Carbonic anhydrase inhibitor	Acting by decreasing the production of aqueous humour	phase III clinical trials are underway	Combined with anti-VEGF Drugs to reduce retinal effusion
RGX-314	A gene vector containing anti-VEGF gene	Adenovirus AAV8 carries the monoclonal antibody gene of VEGF and is injected under the retina	Phase II clinical trials are underway. Good results have been achieved in phase I/IIa clinical trials.	A gene therapy method
GB-102 (Sunitinib)	multi-target receptor tyrosine kinase inhibitors	VEGF is blocked by inhibiting the VEGF receptor ((VEGFR1, VEGFR2, VEGFR3)	Phase II clinical trials begin in September 2019.
X-82 (Vorolanib)	VEGFR and PDGFR inhibitors	Antiangiogenesis is achieved by inhibiting VEGFR and PCGFR	Phase I clinical trials were completed in December 2019, phase II clinical trials are underway
HMR59 (AAVCAGsCD59)	Adenovirus vector containing e soluble protein CD59 (sCD59)	Making the retinal cells continue to produc (sCD59) soluble proteins to block the final step of the complement cascade	phase II clinical trials are plan for 2020
CM082 tablets	VEGFR/PDGFR dual inhibitors	Antiangiogenesis is achieved by inhibiting VEGFR and PCGFR	Phase II clinical trials began in 2019	Oral drug
RG7716	Bi-specific monoclonal antibody	Binds and inactivates VEGF-A and ang-2	Phase II clinical trials were completed in 2018 and phase III clinical trials are planned	Vitreous injection, it works better in combination with ranibizumab
IBI302	Dual target antibody	Both VEGF and complement are targeted	Phase I clinical trials began in 2019
ADVM-022	A gene vector containing anti-VEGF gene	AAV-anti-VEGF therapy method	Phase I clinical trials. are underway, start to collect participants in the second half of 2020	It's injected into the vitreous instead of under the retina
TAB014	anti-VEGF antibody	Blocking the signal transmission mediated by VEGF can inhibit the growth of new blood vessels	Phase I clinical trials have been completed in January 2020	Registered as a class 1 new drug in China

PDGF: platelet-derived growth factor; PGF: placental growth factor; wAMD: wet age-related macular degeneration; DR: diabetic retinopathy; RVO: retinal vein occlusion; CNV: choroidal neovascularization; Ang-2: angiopoietin-2; DARP: designed ankyrin repeat protein; PDGFR: platelet-derived growth factor receptor, VEGFR: vascular endothelial growth factor receptor.

RPE transplantation

Because AMD is mainly related to damage RPE cells which are easy to cultivate and independent of synaptic connections,146, 147, 148 RPE cells can be transplanted to repair or replace RPE cells in patients. RPE transplantation mainly includes macular translocation, autologous RPE-choroidal transplantation, and RPE cell suspension injection. Macular translocation refers to the displacement of macula on RPE, which can be regarded as functional RPE transplantation. Although it has been proved that the operation can bring long-term visual stability, there will be pigment epithelial cell atrophy under the displaced macula, and it is prone to complications. The advantage of autologous RPE-choroidal transplantation is that the graft can attach to the choroidal vessels in a short time, and the pigment epithelium usually does not grow excessively. Transplantation remains a major challenge for eye surgeons. Researchers also tried traditional clamp, aspiration reflux tube into the subretinal space to release implants, micro-thermal gripper using heat-induced graft attachment and peeling, and even using customized devices to deliver implants., RPE cell suspension injection has much fewer complications than macular translocation, but the transport of cell suspension is still an issue. Researchers have tried to inject cell suspension through scleral choroidal pathway with blunt needle and transport cell suspension, through glass cannula. Although RPE cell transplantation is a way for AMD treatment in the clinic, there are still some problems to be solved urgently, such as the transportation of cell suspension and implant delivery, source of cells, the residual RPE removal, the prevention and control of PVR, and the quality of transplanted cells. In addition to RPE transplantation, there are artificial cone transplantation, lower localized macular displacement, 360° macular transposition, and macular transposition combined with 360° retinotomy.158, 159, 160 Doctors often treat patients differently depending on the severity and type of AMD (Fig. 5).

Figure 5

Suggestions on treatment and follow-up of AMD. This is the treatment strategy for AMD. Routine ophthalmic examination and follow-up were the main methods for early and middle stage AMD patients, while appropriate treatment was adopted for advanced AMD patients according to their characteristics.

Stem cell therapy

Stem cell therapy is a new potential therapeutic method for dry AMD treatment. In 2012, researchers first reported the transplantation of human embryonic stem cells (hESC) derived RPE cells into elderly patients with dry AMD. They successfully transplanted the cultured hESC-RPE cells into the patients, and no pathological conditions such as teratoma, abnormal proliferation of hESC-RPE cells were found. Generally speaking, the patients were well tolerated, and the patients' best-corrected visual acuity was also obtained. Researchers designed a biological patch consisting of RPE monolayer derived from hESC. In their clinical trials, the vision of two AMD patients with severe visual impairment was stabilized and improved. Their study demonstrates the feasibility and safety of hESC-RPE patch transplantation as a treatment for dry AMD. One disadvantage of this technique is that local immunosuppression is necessary for hESC-RPE. There is no evidence of adverse proliferation, tumorigenicity or other serious ocular or systemic safety problems associated with transplanted patients. Mandai et al studied the feasibility of transplantation of RPE cells derived from pluripotent stem cells (IPSC) for the treatment of AMD. IPSC was generated by skin fibroblasts of patients (Fig. 6). The patients' best corrected visual acuity did not improve or deteriorate, but their VFQ-25 score improved.

Figure 6

Schematic diagram of cell therapy and gene therapy for AMD. The fertilized ovum was obtained by in vitro fertilization, and the fertilized ovum developed into a morula and then a blastocyst. The inner cell population of the blastula was proliferated in vitro to obtain embryonic stem cells, which were induced to differentiate into RPE cells and transplanted into the patients’ eyes. In addition, skin fibroblasts from the patient were induced to produce pluripotent stem cells, which differentiated into RPE cells and were transplanted into the patients’ eyes. Gene therapy is performed mainly by injecting AAV vector carrying vVEGF-binding protein into the rsubetinal space of patients.

Gene therapy

Gene therapy is also one of the potential therapies for AMD. Because the eye is a small enclosed microenvironment and has a blood-retinal barrier, it can maintain a high concentration for a long time by injecting a small amount of reagent without being affected by the immune system. Gene therapy achieves the goal of treating diseases by introducing genetic material into patients (Fig. 6). In AMD, AAV2 carriers with VEGF binding proteins are used to inhibit angiogenesis. AAV2-sFLT01 and AAV2-sFLT02 are fused into human IgG1 Fc region or its methyl domain and can be used to inhibit CNV., Studies have shown that AAV2 vector-mediated therapy is safe and effective, and can be used as a potential long-term treatment for wet AMD.166, 167, 168, 169, 170 In addition, viral vectors carrying endostatin and angiostatin also inhibited angiogenesis.171, 172, 173 Thumann et al successfully transfected PEDF gene using Sleeping Beauty (SB100X) transposon subsystem and microplasmid without antibiotic resistance marker (pFAR4), and isolated iris pigment epithelium (IPE) cells. Li W et al constructed a target inhibitor CR2-sFlt1, which can significantly reduce the expression of VEGF in RPE cells. The CR2 targeting fragment can locate CR2-sflt1 at the site of complement deposition in CNV region. Their research shows that the targeting inhibitor can inhibit CNV with high selectivity. In addition, cytokines are the basis of targeted combination therapy for wet AMD, among which TNF, PDGF or fibroblast growth factor are potential targets for effective combination therapy.

Outlook

AMD is a complex disease. There are few effective treatments for dry AMD. Healthy lifestyles, such as proper exercise, maintaining a normal weight, control blood pressure, and cholesterol, are important to reduce the risk of AMD. No smoking, a high level of lutein/zeaxanthin diet such as vitamin C, vitamin E, zinc oxide, lutein/zeaxanthin can reduce the risk of AMD. Also, fish and green vegetables can also reduce the risk of AMD. Treatment strategies for AMD should incorporate a variety of risk factors to avoid and improve drug interventions, and also need to take into account personalized genetic information. The activation of complement components further promotes the development of AMD, so the local inhibition of complement is considered to be a choice for the prevention and treatment of early AMD. Besides, CFH, CFB, C2, C3 and CFI in complement pathway, HTRA1, lipids metabolism related genes such as CETP, APOE etc. are closely related to AMD and are expected to become therapeutic targets besides VEGF pathway. Emerging therapies are likely to open up new avenues for AMD treatment. With the development of technology and research progress, the emergence of new and more effective AMD treatment methods will improve patients’ visual acuity, and improve patients' quality of life.

Author contributions

L.H. designed the study. L.H., Y.D., L.Q., M.D., C.Q., J.L. and L.W. performed the literature review and writing. Y. D. and L.H. wrote the manuscript. All authors critically revised, and provided the final approval for this manuscript.

Conflict of interests

The authors declare no competing financial interests related to this paper.