The Autoimmune Rheumatic Disease Related Dry Eye and Its Association with Retinopathy

Dry eye disease is a chronic disease of the ocular surface characterized by abnormal tear film composition, tear film instability, and ocular surface inflammation, affecting 5% to 50% of the population worldwide. Autoimmune rheumatic diseases (ARDs) are systemic disorders with multi-organ involvement, including the eye, and play a significant role in dry eye. To date, most studies have focused on Sjögren’s syndrome (one of the ARDs) since it manifests as two of the most common symptoms–dry eyes and a dry mouth-and attracts physicians to explore the relationship between dry eye and ARDs. Many patients complained of dry eye related symptoms before they were diagnosed with ARDs, and ocular surface malaise is a sensitive indicator of the severity of ARDs. In addition, ARD related dry eye is also associated with some retinal diseases directly or indirectly, which are described in this review. This review also summarizes the incidence, epidemiological characteristics, pathogenesis, and accompanying ocular lesions of ARD’s related dry eye, emphasizing the potential role of dry eye in recognition and monitoring among ARDs patients.


Introduction
Dry eye is a multifactorial disease of the ocular surface characterized by a loss of homeostasis of the tear film and accompanied by ocular symptoms, in which tear film instability and hyperosmolarity, ocular surface inflammation and damage, and neurosensory abnormalities play etiological roles [1]. It can be manifested as decreased vision and eye discomfort, accompanied by eye inflammation and ocular nerve damage. The vision-related quality of life and work efficiency of patients are significantly reduced by those malaises [2]. Epidemiological surveys reported that the prevalence of dry eye differed greatly among regions, ranging from 5% to 50% worldwide [3]. The incidence of dry eye has increased significantly in recent years due to the prolonged use of digital screens [4], air pollution [5], and population aging. Predisposing factors of dry eye include the environment, increased use of electronic products, systemic diseases, ocular surface diseases, eye surgeries, application of eye drops and ointment, etc. Systemic diseases, especially rheumatic immune diseases are closely related to dry eye [2].
As a systemic disorder with multi-organ involvement, ARDs lead to various clinical manifestations including skin lesions, joint pain, vascular damage, and dry eye. Furthermore, treatments for ARDs, including methotrexate and cyclophosphamide, usually cause or exacerbate symptoms of dry eye. Under normal conditions, the intrinsic immune mechanisms of the eyes could maintain the microenvironment homeostasis. When the eye becomes the target through stress signal transduction pathways [22]. Ocular structures related to dry eye are presented in Figure 1. Figure 1. Ocular structures related to dry eye. The three main components of the tear film are the lipid layer, the aqueous layer, and the mucous layer, which are produced by the meibomian glands, the lacrimal gland, and the conjunctival goblet cells, respectively. Decreased tear production by the lacrimal gland results in less eye surface lubrication. Additionally, decreased oil secretion by meibomian glands leads to excess tear evaporation.
Both innate and adaptive immunity are involved in the pathogenesis of dry eye. Previous studies based on clinical and laboratory research have found that Th1 and Th17 cells could modulate the immune response on the ocular surface [23]. Combined with exposure to autoantigens, these innate inflammatory mediators can lead to an adaptive T cell-mediated response. Additionally, after the activation of the immune response, the dysfunction and death of conjunctival goblet cells is promoted by the Th1 cytokine IFN-γ, which aggravates dry eye [24]. Studies on human and animal models have shown that loss of ocular surface epithelial cells and goblet cells could lead to shorter tear break-up time [25]. Interferon-gamma (IFN-γ), produced by NK cells, is responsible for upregulating Th1 cells to recruit chemokines (CXCL9, CXCL10, and CXCL11) in conjunctival and corneal epithelial cells. Meanwhile, increasing expression of activating NK cell receptor ligands and activation of innate immune pathways can lead to enhancement of T cell infiltration, involving the lysis of epithelial tight junctions. In consequence, the cornea barrier is destroyed and the phenotype of the epithelial cells changes, which destabilizes the tear film, amplifies inflammation and creates a vicious cycle [22].

Pathogenesis of ARD Related Dry Eye
The immune systems in patients with rheumatic immune diseases are impaired, resulting in abnormal immune responses and imbalanced immune regulation. Substantial immune cells and inflammatory factors imperil the lacrimal gland, conjunctival membrane, cornea, and meibomian glands, resulting in tissue destruction and dysfunction [26].

Figure 1.
Ocular structures related to dry eye. The three main components of the tear film are the lipid layer, the aqueous layer, and the mucous layer, which are produced by the meibomian glands, the lacrimal gland, and the conjunctival goblet cells, respectively. Decreased tear production by the lacrimal gland results in less eye surface lubrication. Additionally, decreased oil secretion by meibomian glands leads to excess tear evaporation.
Both innate and adaptive immunity are involved in the pathogenesis of dry eye. Previous studies based on clinical and laboratory research have found that Th1 and Th17 cells could modulate the immune response on the ocular surface [23]. Combined with exposure to autoantigens, these innate inflammatory mediators can lead to an adaptive T cell-mediated response. Additionally, after the activation of the immune response, the dysfunction and death of conjunctival goblet cells is promoted by the Th1 cytokine IFN-γ, which aggravates dry eye [24]. Studies on human and animal models have shown that loss of ocular surface epithelial cells and goblet cells could lead to shorter tear break-up time [25]. Interferon-gamma (IFN-γ), produced by NK cells, is responsible for upregulating Th1 cells to recruit chemokines (CXCL9, CXCL10, and CXCL11) in conjunctival and corneal epithelial cells. Meanwhile, increasing expression of activating NK cell receptor ligands and activation of innate immune pathways can lead to enhancement of T cell infiltration, involving the lysis of epithelial tight junctions. In consequence, the cornea barrier is destroyed and the phenotype of the epithelial cells changes, which destabilizes the tear film, amplifies inflammation and creates a vicious cycle [22].

Pathogenesis of ARD Related Dry Eye
The immune systems in patients with rheumatic immune diseases are impaired, resulting in abnormal immune responses and imbalanced immune regulation. Substantial immune cells and inflammatory factors imperil the lacrimal gland, conjunctival membrane, cornea, and meibomian glands, resulting in tissue destruction and dysfunction [26]. A large number of immune cells, most of which are T lymphocytes, infiltrate the lacrimal duct and accessory lacrimal gland in patients with rheumatic and immune diseases, causing autophagy and apoptosis of acinar, ductal and myoepithelial cells, disruption of lacrimal gland function and a decrease in tear secretion [25].
Due to the presence of innate immune cells and the secretion of inflammatory response factors, the signal transduction caused by abnormal antibodies leads to chronic fibrosis of the lacrimal gland and further aggravation of dysfunction. The infiltration of T cells in the conjunctival tissue results in squamous metaplasia, decreased goblet cell density, and reduced mucin secretion. The deposition of autoantibodies and antigen-antibody complexes in corneal tissues leads to corneal dystrophy [27]. An increased number of corneal dendritic cells, as well as decreased nerve density and sensitivity are revealed by confocal microscopy through focusing [28]. Villani et.al. found that 35 patients with SS-related dry eye had significantly low corneal nerve counts (3.34 ± 0.76 vs. 5.10 ± 0.79, p < 0.0001) and an increased degree of tortuosity (2.62 ± 0.94 vs. 1.20 ± 0.70, p < 0.0001), compared with the control group [29], which was consistent with the study by Benítez del Castillo et al. [30]. Moreover, Xu et al. [31] reported that the corneal nerve sensitivity of SS-related dry eye patients was significantly reduced (4.5 ± 1.2 cm vs. 5.8 ± 0.4 cm, p < 0.01). Additionally, immune cell infiltration in the meibomian glands and consequent mechanical obstruction of its ducts were very common in patients with rheumatic immune disease related dry eye (57.9%) [32]. Atrophy and occlusion of some meibomian gland ducts can be revealed by meibomian gland imaging. Moreover, recent studies have shown that gut dysbiosis (Firmicutes/Bacteroidetes ratio and genus Faecalibacterium) is closely related to dry eye diseases caused by autoimmune diseases such as SS. However, the key communication routes of the "gut dysbiosis-ocular surface-lacrimal gland axis" still need to be further elucidated [33].
In terms of genetic heredity, RA is a complex disease and is correlated with multiple genetic loci, each of which usually has only one modest association with a specific condition [34]. According to a recent study, 39 variants were identified in immune-related genes across SLE, RA, and SS families. Among this gene set, regulation of T cell activation and T cell receptor signaling pathways were particularly concentrated [35], which might correlate with symptoms and signs of dry eye. Consequently, gene analysis is a powerful tool for understanding the pathogenesis of ARD related dry eye [36].

Primary Sjogren's Syndrome & Dry Eye
Primary SS is an autoimmune and systemic disorder. Globally, the prevalence of primary SS ranges from 0.1% to 4.8% depending on age [37,38], and 90% of patients are females. Sicca symptoms (dry mouth and dry eyes) are common oral and ocular complaints. Nevertheless, SS is often underdiagnosed, misdiagnosed, or delayed in being diagnosed since the symptoms are usually vague for many years [39] until irreversible organ damage has occurred [40]. As an autoimmune disease that mainly affects exocrine glands (such as the salivary and lacrimal glands), primary SS is most closely related to dry eye among the various types of ARDs. Primary SS is also a possible diagnosis in patients with dry eye symptoms. Staining of the temporal conjunctiva and severe dry mouth symptoms were the major factors in distinguishing primary SS from dry eye disease [41].
SS is a chronic inflammatory autoimmune disease, histopathologically characterized by lymphocytic infiltration of exocrine (mainly salivary and lacrimal) glands with remarkable B-cell hyperactivity and the presence of autoantibodies against the ribonucleoprotein particles SSA/Ro and SSB/La. The glandular function is impaired by the infiltrating cells in several ways, including local production of autoantibodies, destruction of glandular structures by cell-mediated mechanisms, and secretion of cytokines that activate pathways related to interferons (IFNs) [13]. The salivary and lacrimal glands are the principal targets of a proposed T cell-mediated chronic inflammation, followed by glandular atrophy and deficient function. Primary SS is considered to arise from an interplay between environmental factors and genetic susceptibility. Activation of B cells, the presence of anti-Ro-52 antibody and the "triggers" of viral infections result in the activation of the innate and adaptive immune systems, which perpetuate self-reactive activity against healthy tissues [42,43].
Due to the invasive process of lacrimal gland biopsy, most studies of SS related dry eye were carried out on mouse models, such as the Aec and IL-12 transgenic mice [44], TSP-1KO mice [45], CD25KO mice [46], BXSB/MpJ-Yaa mice [47], and lupus-prone female NZB×NZWF1 (B/WF1) mice [48] (secondary SS), and indicated lymphocytic infiltrations as well as loss of secretory functions. Noteworthily, Hayashi et al. [48] reported substantial destruction of the myoepithelial cells and lysis of basement membranes within the inflammatory lymphocytic foci in the lacrimal gland. Hawley et al. found substantial changes in the myoepithelial cell morphology and contractile protein expression in these relatively normal areas (between the lymphocytic foci) of the lacrimal gland, which is likely due to decreased expression of the contractile proteins of smooth muscle actin and calponin, and significant loss of the oxytocin receptor [49]. Hayashi et al. suggested that acini destruction in lacrimal glands may be induced by systemic and local Th1 cell-dominant reactions [50].
In addition, the corneal nerves play a critical role in the pathophysiology of dry eye because they contribute to the reflex control of basal tear production and blinking [51]. Compared to healthy subjects, both the density and function of sensory nerve fiber terminals in the cornea declined in primary SS [52,53], leading to a vicious circle of corneal hypoesthesia. Moreover, primary SS also results in damage to secretomotor innervation and inflammatory destruction of acini and ducts [54]. SS dry eye is generally described as aqueous-deficient dry eye and much attention has been paid to the lack of tear production [55,56]. However, as a result of the meibomian glands being under immune attack, meibomian glands dysfunction (MGD) is captured in primary SS patients [57], with a diffuse abnormality of the meibomian glands, commonly characterized by chronic terminal duct obstructions and qualitative or quantitative changes in the glandular secretion [58]. Lymphocytic infiltration was also found in the conjunctiva of patients with SS related dry eye [59]. By using a Sjogren's syndrome model MRL/MpJ-Fas(lpr) mouse, Diebold et al. found lymphocytic infiltration and goblet cell marker alteration in the conjunctiva [60]. Furthermore, desiccating stress caused by SS promotes the maturation of monocytes to antigen-presenting cells with elevated levels of inflammatory genes in conjunctiva [61]. Keratinization of the conjunctival and corneal epithelia, squamous metaplasia, and goblet cell loss are observed in severe primary SS.
In conclusion, SS dry eye is a multifactorial disease, comprising aqueous, lipid, and mucin components, which is comprised of a series of disorders of the lacrimal gland, conjunctiva, corneal and meibomian glands, causing aqueous-deficient or evaporative dry eye.

Rheumatoid Arthritis & Dry Eye
RA is a common systemic inflammatory disease, characterized by persistent synovitis, systemic inflammation, and autoantibodies (particularly rheumatoid factor and citrullinated peptide) [62]. The morbidity ranges from 0.5% to 2% in the overall population [63]. RA affects the joints, but the systemic inflammatory process could affect other tissues and organs, for example, the eyes. Most relevant studies showed that dry eye was the most frequent ocular complication in RA patients, while others include scleritis, episcleritis, keratitis, etc. [64][65][66]. Although some patients with RA can develop secondary SS with the prevalence varying from 4% to 50% [67], dry eye is common even in RA patients without secondary SS [10]. No matter what kind of RA (RA-SS or RA-nonSS), dry eye is the most common ocular manifestation. As for gender characteristics of dry eye in RA, it is more common in women, with a female-to-male ratio of 9:1 [68]. The probability of ocular involvement increases with the duration of the disease and it may represent the main clinical manifestation of RA in patients with long-standing disease. In addition, sometimes ocular complaints are the first symptom of RA patients [64]. The severity of eye dryness was verified to be highly correlated with juvenile RA [69]. However, there was no significant correlation between the severity of dry eye and RA activity. Therefore, the deterioration of the systemic condition of RA does not one hundred percent lead to the aggravation of dry eye symptoms, and dry eye cannot be excluded even in patients with mild RA [10].
Mechanisms of RA are the repeated activation of innate immunity, especially at mucosal surfaces. Innate immunity could activate fibroblast-like synoviocytes, dendritic cells, and macrophages during the earliest phases in individuals with underlying immune hyperreactivity. The overproduction of pro-inflammatory cytokines, such as tumor necrosis factor (TNF) and interleukin-6 (IL-6), lead to the proliferation of synovial cells in joints and subsequent pannus formation, cartilage destruction, and bone erosions [62]. Among ARDs other than SS, the association is the closest between dry eye and RA [70]. As mentioned above, increased deterioration of RA seems not to lead to the aggravation of dry eye. Consequently, the etiology of dry eye is different in SS and non-SS patients with RA [10].
The mechanism of dry eye in RA patients is different from SS and might be a result of local pathology affecting the tear fluid, conjunctiva, or cornea. The pathological changes of the ocular surface in RA-SS are dissimilar to RA-nonSS as discovered by Villani et al. after they detected the concentration of human IL-1a, IL-6, IL-8, and TNF-a (substantial in the synovial fluid and tissue of RA patients) in tear samples [66]. After intervention therapy using blockers against TNF-a, IL-1a, and IL-6, there were remarkable therapeutic efficacies in RA. Additionally, the concentration of IL-1a and IL-6 in the tear ducts of RA-SS patients declined significantly, while there were no evident changes of those cytokines in RA-nonSS patients [66]. However, Usuba et al. demonstrated the evaporative component disturbance in RA patients, with the presence of meibomian gland dysfunction (associated with alterations in the lipid layer of tear film) as well as decreased goblet cell numbers (associated with the mucin layer of the tear film), in addition to the traditional aqueous tear deficiency related to dry eye disease. Furthermore, treatment with TNF inhibitors improved conjunctival goblet cell numbers in RA patients with mild dry eye, which is conducive to relieving dry eye by increasing the secretion of mucin [71]. This is consistent with Tong's findings that TNF-inhibitor treatment controlled inflammatory disease activity concomitantly to conjunctival cytology, especially the goblet cell density, implying a common underlying inflammatory mechanism for ocular and articular activity [72]. In addition, in a clinical trial by Schargus et al., tear film hyperosmolarity highly correlates (>316 mOsmol/L) with undiagnosed dry eye in RA patients [73].
Most of the current studies demonstrated that dry eye in RA tends to correlate with local pathogenic mechanisms other than with systemic inflammation [10,73]. In summary, mixing aqueous-deficient dry eye and evaporative dry eye, RA-nonSS dry eye comprises disorders of the conjunctiva and meibomian gland, resulting from a decrease of aqueous, lipid, and mucin components. Findings of note include that the meibomian gland dysfunction is associated with higher disease activity parameters, and that TNF-inhibitor therapy improves ocular surface health by promoting the recovery of goblet cells.

Systemic Lupus Erythematosus & Dry Eye
SLE is a multisystem, chronic, autoimmune disease that mostly affects women (female/male ratio ranging from 6:1 to 10:1) who are of child-bearing age [74]. Ocular symptoms can be detected in approximately one-third of SLE patients. The incidence of SS secondary to SLE is about 13.96% [75]. Dry eye complaints are usually ignored in SLE patients without secondary SS. However, dry eye is the most common ocular manifestation of SLE [11], and the same is true of juvenile systemic lupus erythematosus [76]. As a significant "window" into SLE, dry eye is diagnosed with a prevalence of 5% in early-onset SLE patients, 16% in the duration stage, and 33% in late-onset [77].
Elevated levels of anti-double-stranded DNA antibodies (anti-dsDNA) and erythrocyte sedimentation rate [78], as well as the depression in complement levels (C3 and C4) [79,80] are commonly used to predict lupus's flare and assess its activity. Chen et al. found that in SLE patients without secondary SS, the progress of dry eye severity was consistent with anti-dsDNA titers and low C3 levels, but not with the low C4 levels, erythrocyte sedimentation rate, and antinuclear antibodies (ANAs) [81]. SLE alters not only the density and the morphology of the corneal Langerhans cells, but it also interferes with corneal homeostasis and might contribute to the development of dry eye [82].
As significant risk factors for dry eye, poorer meibomian gland function and worse tear film lipid layers were also found in SLE patients without secondary SS, leading to decreased tear volume and faster evaporation [83]. SLE tends to present with multiple factors of induced dry eye, including disorders of the lacrimal gland, cornea, and meibomian glands.

Systemic Sclerosis & Dry Eye
Scleroderma, also called SSc, is an immune-mediated rheumatic disease that is characterized by fibrosis and vasculopathy of the skin and internal organs [84]. The proportion of females with SSc is higher than that of males (female/male = 3:1) [85]. This disease involves different organs, including the eyes and periocular tissues. Dry eye is the most common ocular manifestation of SSc.
SSc related dry eye is likely owing to the fibrosis of the conjunctiva and lacrimal glands [86]. Based on a histological study, the fibrosis of the conjunctiva is associated with degranulating mast cells. Dry eye from primary SS and dry eye from SSc share a similar mechanism since the primary lacrimal gland duct is involved in both. However, the lymphoid infiltration in the gland is sparser in SSc [15], which can be used to differentiate SSc and primary SS related dry eye. The presence of fibrosis suggests SSc, whereas lymphocytic infiltration is a critical sign of primary SS [59]. Because SSc is related to peripheral neuropathy, de A. F. Gomes et al. held the opinion that patients with SSc may have a decreased corneal sensation, which can explain the lack of correlation between signs and symptoms of dry eye [15].
In addition to the impairment of the aqueous layer of the tear film due to lacrimal gland fibrosing [86], blepharitis and MGD are other factors for SSc related dry eye. The lacrimal gland, conjunctiva, cornea, and meibomian glands are all involved in SSc related dry eye. Characteristics of primary SS, RA, SLE, and SSc related dry eye disease are shown in Table 1.

How Dry Eye Disease Affects Retinal Diseases
Dry eye is related to some retinal diseases directly or indirectly. Systemic diseases or exposure to hazardous substances should be considered if the dry eye and retinal diseases are concurrent.
Dry eye and retinal diseases both belong to the catalog of age-related ocular diseases, including age-related macular degeneration, cataracts, and glaucoma. These abovementioned changes may be attributed to similar pathophysiological mechanisms, including dysregulated mitochondrial metabolism, reprogrammed glucose metabolism, and impaired methylation in the aging eye [87]. The overlap of endocrine (hormonal withdrawal) and neuronal dysfunction with aging contribute to age-related ocular diseases [88]. The agerelated ocular diseases can be improved in various parameters of visual function by using L-carnitine and its derivatives [89].
The environment is one of the most significant risks for dry eye. Endocrine disrupting chemicals (EDCs) are a group of chemical compounds that can interfere with endocrine hormone homeostasis, including about 1000 synthesized chemicals. Humans are exposed to EDCs from their diet, thermal receipts, personal care products, antimicrobial soaps, household or agricultural pesticides, and cleaning products, leading to physiological abnormalities in the body, such as ocular surface disorders, including dry eye [90]. The induction of chronic physiological abnormalities caused by EDCs may subsequently result in retina diseases, including age-related macular degeneration, retinitis, retinal detachment, and diabetic retinopathy [91].
In addition, the ocular surface and retina are often involved in diabetes. Diabetes is associated with progressive damage to corneal nerves and epithelial cells, which can increase the risk of dry eye [92]. Up to 54% of type 2 diabetic patients suffer from dry eye syndrome, which is more frequent in diabetic patients with diabetic retinopathy [93].
Alpha-lipoic acid showed similar therapeutic effects in the treatment of both dry eye disease and diabetic retinopathy [94].

How ARDs Affect Retinal Diseases
The retina is often involved in ARDs and commonly associated with systemic inflammatory cell infiltration, which may constitute the initial presentation of systemic immune-mediated disorders. Retinal vasculitis may also represent the most common retinal manifestations of the rheumatic disease and it is often accompanied by uveitis, scleritis, or macular edema [95]. It was reported that about 51% of SSc patients had different forms of retinal diseases, including mild retinal pigment epithelial atrophy, drusen, choroidal scar formation, and severe age-related macular degeneration [96]. Retinal involvement, the second most common ocular manifestation among SLE patients, has a prevalence of 7-29% and is one of the most common indicators of a highly-active period of SLE [97].
Since a case of optic neuropathy secondary to SS was first reported in 1990, more and more studies are focusing on the relationship between SS and retinopathy [98]. With the continuous improvement of retinal detecting technology, more details of the mechanisms have been uncovered by recent studies. According to a clinical study of patients with SS, anti-SSB autoantibodies might be a useful marker to predict abnormally reduced peripapillary retinal nerve fiber layers and macular ganglion cell-inner plexiform layer thickness [99]. Furthermore, as reported recently, optical coherence tomography angiography was used to investigate the differences in retinal thickness and superficial vascular density between patients with SS and healthy controls, suggesting the retinal thinning of the macular area can also reflect the severity of dry eye in SS and has clinical value for assisted imaging diagnosis [100]. Similarly, in RA, retinal capillary plexus density in the macula is lower than in normal individuals [101]. In addition, even if no clinical and ophthalmoscopic signs are present, retinal vessel inflammation is present in 18% of RA patients and can represent one of the possible extra-articular manifestations of RA [102].

Clinical Attention-Dry Eye Is the "Window" of ARDs
First, dry eye is a challenge for patients and may be difficult for clinicians to diagnose and manage effectively [103]. Moreover, patients ultimately diagnosed with an autoimmune rheumatic disease are also a diagnostic challenge [6]. We should devote more attention to symptoms of ARD related dry eye. Second, there is a sequence of other ocular disorders that ARDs patients may have, e.g., scleritis, episcleritis, keratitis, etc. However, the symptoms and signs of these ocular diseases are easy to notice, unlike the latent dry eye. Third, the eye could be a surrogate marker for the onset or aggravation of an immune reactivation in ARDs since dry eye complaints can antedate the diagnosis of rheumatic diseases. It is possible to avoid the delay of many long-term sequelae by recognizing dry eye manifestations of ARDs.
Of note, a significant percentage of dry eye diagnoses can be missed because of the number of symptoms just for diagnosis of dry eye as well as isolated inclusion criteria. Severe dry eye is usually common in patients with ARDs. In addition, the decreased corneal sensation is a feature of severe dry eye which might alter the patient's perception of symptoms of ocular irritation. The reduced corneal sensation could provide inadequate feedback through the ophthalmic nerve to the central nervous system, resulting in less efferent stimulation to the lacrimal gland, reduced tear production, and the promotion of a vicious cycle [104]. Overall, examines related to dry eye are significant and should be implemented in patients with ARDs, even if there is no specific ocular complaint.

Conclusions
Dry eye is the most common ocular complication in ARDs. ARD related dry eye, caused by functional disorders of the lacrimal gland, lacrimal duct, conjunctiva, cornea, and meibomian glands, includes the two kinds of aqueous-deficient and evaporative dry eye, simultaneously. Severe symptoms of dry eye are usually presented in patients with ARDs, which might enable the dry eye to be a significant indicator of ARDs. In the future, the research on ARD related dry eye might contribute to the investigation of systemically immunological and molecular mechanisms in ARDs. Significantly, because of the direct or indirect associations of ARD related dry eye with some retinal diseases, a comprehensive understanding of dry eye, ARDs, and relative complications is necessary.