IMH etiology or stage of development is generally considered to be unrelated to ocular inflammation; thus, affected patients are often included as a control group in analyses of inflammation-related ocular diseases [9]. However, after onset of IMHs, tissue damage and reparation often lead to local inflammatory reactions, which affect cytokine levels in the aqueous humor. The degree of ocular inflammatory response and changes in cytokine levels in the aqueous humor provide useful information for the treatment, prognosis, and diagnosis of IMH.
In the normal retina, Müller cells penetrate the neurosensory layer; the fibers of these cells extend from the outer membrane to the inner limiting membrane, thereby providing retinal support and nutrient metabolism. After IMH formation, the retina undergoes a process called reactive gliosis [10]. This event is triggered by penetration damage involving activated astrocytes. The activation of intermediate filament proteins (i.e., glial fibrillary acidic protein and vimentin) is critical for the formation of glial scars [11, 12].
In the retina, Müller cells are the major glial cell type involved in reactive scar formation following disease-induced retinal degeneration [13]. To restore nutrients, Müller cells and other glial cells in the retina may migrate to the outer surface of the inner limiting membrane in response to various inflammatory factors. Some researchers have proposed that proliferation and contraction of these cells in the inner limiting membrane results in IMH progression. After IMH formation, lymphocytes can destroy the blood–retina barrier and migrate into the vitreous cavity; here, lymphocytes make contact with transitional pigment cells and glial cells, secrete cytokines, promote an inflammatory response, and enhance macrophage-mediated phagocytosis [14]. In addition, lymphocytes in the vitreous cavity can promote the transformation of glial cells into fibroblasts and accelerate the repair of tissue hyperplasia [15].
Immune system-mediated inflammatory responses are known to play important roles in injury-induced neurological damage and tissue repair. The inflammatory response during trauma is mainly mediated by innate immune cells including microglia and astrocytes, which play important roles. However, the recruitment of these innate immune cells leads to some recruitment of T cells and other immune cells and subsequently induces apoptosis and damage repair [16].
The results of this study showed significant upregulation of GM-CSF, which is an important component of microglial products. Microglia represent a type of macrophage; thus, they can phagocytose damaged cell debris and release various cytokines. In IMHs, the microglia in the damaged macular area are rapidly activated, thereby causing microglia morphology to transform into an “ameboid-like” state and migrate to the site of injury. This is followed by the release of various cytokines including NGF, IL-4 (a protective cytokine), IL-10 (an immunosuppressive cytokine), as well as NO and ROS; pro-inflammatory cytokines are also produced (e.g., IL-1, IL-6, and IFN-γ) [17]. These cytokines might accumulate in the aqueous humor, as shown in our study. The upregulation of GM-CSF, IL-1, IL-4, and IFN-γ indicates that microglia play an important role in the immune response during IMH formation and progression.
Previous studies of cytokine levels in the vitreous of patients with ERM and patients with IMHs revealed no significant difference in GM-CSF levels between the two groups. Conversely, we found that the GM-CSF level was significantly upregulated in patients with IMHs, which implies that the use of patients with IMHs as the control group may lead to inaccurate results [18].
The significant downregulation of MIF level in the aqueous extract of patients with IMHs suggests that monocytes play important roles in the activation and development of Müller cells after the onset of IMH formation. The significant upregulation of IL-3, M-CSF, GM-CSF, and IFN-γ levels supported the notion that monocytes play important roles in IMHs. Notably, the MIF level was negatively correlated with the LIF level; LIF is an important neurogenic factor that could promote the differentiation of glial cells. LIF is mainly secreted by macrophages, which implies that macrophages play an important role in the body’s self-repair process after IMH onset.
Microglia activation and production of IL-1 cause activation of astrocytes and Müller cells. During the adaptive nerve injury in patients with IMHs, Müller cells can produce cytokines (e.g., NGF and HGF) to promote neuron survival. In this study, both NGF and HGF levels were significantly upregulated in comparison with the control group, and the NGF level was associated with the HGF level. Because HGF and NGF both play important roles in the treatment of ocular nerve injury diseases (e.g., corneal damage and glaucoma), we hypothesized that HGF and NGF also play important roles in tissue repair during the prophase and postoperative recovery phase of IMHs [19].
In this study, a multiplex analysis with antibody-coupled magnetic beads was used to detect changes in cytokine levels in aqueous humor samples from patients with IMHs. Compared with the traditional ELISA method, this method can detect a wider variety of cytokines with lower sample volume. Moreover, the method can simultaneously detect 48 cytokines in a single experiment, thus avoiding instability related to batch effects [20].