Neuroinflammation and neurodegeneration in diabetic retinopathy

Diabetic retinopathy (DR) is the most common complication of diabetes mellitus (DM) and the leading cause of preventable blindness in developed countries. In the past, DR was regarded as a microangiopathy because its clinically detectable lesions are mainly vascular: even nowadays, its diagnosis and staging are still based on vascular abnormalities observed by fundoscopy. However, the American Diabetes Association has recently defined DR as a highly tissue-specific neurovascular complication of DM involving progressive disruption of the interdependence between multiple cell types in the retina ( Solomon et al., 2017 ). Indeed, the retinal neurovascular unit (NVU) is composed of neurons, glial cells, and the intraretinal vascular network ( Hawkins and Davis, 2005 ; Antonetti et al., 2012 ). Recent evidence suggests that DR is the result of a global dysfunction of the NVU: the activation of glial cells (astrocytes, Müller cells, and microglia) and degeneration of neural elements (ganglion, bipolar, horizontal, and amacrine cells) are distinct pathogenic events (and therefore therapeutic targets) that interplay with microvascular phenomena ( Gardner and Davila, 2017 ; Nian et al., 2021 ), leading to the development of diabetic retinal disease (DRD). Current treatments for DR are available only for its vision-threatening complications, such as diabetic macular edema (DME) and proliferative diabetic retinopathy (PDR). A better understanding of pathologic retinal changes in diabetes is crucial for the identification of novel pharmacological targets in order to prevent the development of late-stage complications, improve functional and anatomical outcomes and maybe slow the progression of irreversible retinal neurodegeneration. In this review, we discuss the state of the art of research on the role of neuroinflammation and neurodegeneration in DR, with a focus on pathophysiological studies on human subjects, in vivo imaging biomarkers, and clinical trials on novel therapeutic options.

Pathophysiology of retinal inflammation in diabetic retinopathy Inflammation is a complex biological response of tissues and cells to pathogens and damaged cells that involves leucocytes, blood vessels, and many molecular mediators. Acute inflammation typically has beneficial effects in the acute setting, while becomes detrimental if persisting chronically. Initial suggestions for possible involvement of inflammation in DR came from reports of a lower incidence of DR in arthritic patients taking salicylates ( Powell and Field, 1964 ). Experimental evidence for the presence of chronic-low grade inflammation from the early moments of DR pathogenesis began accumulating since Schröder et al. (1991) demonstrated in a murine model that leukostasis, a phenomenon that may cause retinal microvasculature dropout by monocytes and granulocytes, is present even in NPDR. Biochemical, molecular, and cellular mechanisms of neuroinflammation in DR significantly contributed to current knowledge of DR pathogenesis, are better studied in animal models, and are extensively reviewed elsewhere ( Tang and Kern, 2011 ; Forrester et al., 2020 ; Pan et al., 2021 ). Before delving into the relationship between neuroinflammation and DR through the analysis of current evidence on clinical research in human subjects, a short overview is provided. Neuroretinal inflammation is mediated by the retinal glia, which senses stress signals in the neural tissue (such as high glucose levels or glycated compounds, oxidative stress, and damaged cells) and secretes pro-inflammatory mediators. Retinal glia is composed of three cytotypes: astrocytes, Müller cells, and microglia. Astrocytes are not strictly of neuroepithelial origin but enter the developing retina from the optic nerve and present several fibrous processes radiating from the cell body that cover blood vessels in the superficial capillary plexus, contributing to inner retinal blood barrier (iBRB) formation ( Stone and Dreher, 1987 ). Microglial cells are not of neuroglial origin, despite their name, but enter the retina with the mesenchymal precursors of retinal blood vessels and are believed to represent innate immune cells of the neural tissue, with a macrophage-like function ( Rathnasamy et al., 2019 ). Müller cells are sustentacular cells that span from the external to the internal limiting membrane, connecting neurons, and vascular cells ( Vecino et al., 2016 ). Müller cells gliosis (activation) is a hallmark of DR, as demonstrated by a significant increase in aqueous biomarkers of glial activation (glial fibrillary acidic protein, aquaporin 1, and aquaporin 4) in aqueous humor ( Vujosevic et al., 2015 ). Chronic hyperglycemia could induce gliosis through the formation of advanced glycation end products (AGEs) ( Sorrentino et al., 2016 ; Xu et al., 2018 ), which are macromolecules that become abnormally glycated after exposure to chronically elevated blood glucose concentrations. The factors associated with AGEs formation include normal aging, degree of hyperglycemia, and glycated protein turnover ( Sharma et al., 2012 ). Accumulated AGEs, both within retinal walls and serum, are capable of inducing pro-inflammatory responses by receptor (RAGE) dependent or independent pathways: AGEs can induce the upregulation of adhesion molecules (such as ICAM-1) on endothelial cells and directly activate leukocytes ( Moore et al., 2003 ), while the activation of RAGE results in glial activation and inflammatory cytokines secretion. The formation of AGEs is also influenced by oxidizing conditions and reactive oxygen species (ROS) formation concentrations, thereby creating a positive feedback loop between retinal neuroinflammation and AGEs accumulation ( Baynes and Thorpe, 2000 ). Gliosis of Müller cells results in the secretion of pro-inflammatory cytokines, chemokines, and vascular endothelial growth factor (VEGF) ( Bringmann and Wiedemann, 2012 ). While elevated VEGF levels directly cause iBRB instability and neovascularization development ( Ozaki et al., 1997 ; Qaum et al., 2001 ), chemokines and cytokines attract and activate leukocytes. The adhesion of leukocytes to the endothelium for subsequent diapedesis is mediated by leukocyte integrins and endothelial cell adhesion molecules. Indeed, an elevated concentration of E-selectin in the plasma of diabetic subjects may play a role in the development of DR ( Kasza et al., 2017 ). At this point, leucocytes recruited in the retinal capillaries appear to activate the Fas (CD95)/Fas-ligand pathway, eventually leading to endothelial cell apoptosis and further iBRB impairment ( Joussen et al., 2003 ; Vincent and Mohr, 2007 ).

There is a growing scientific interest in the possibility of identifying retinal inflammation in vivo , by means of multimodal imaging, which includes optical coherence tomography (OCT), OCT-angiography (OCTA), fluorescein angiography (FA), indocyanine-green angiography (ICGA), and confocal MultiColor imaging among the others. Retinal hyperreflective foci (HF) are small (<30 μm), punctiform lesions with reflectivity similar to that of NFL, scattered throughout the neuroretina, and visible on OCT B-scans. HF can be distinguished from hard intraretinal exudates and microaneurysms and have been proposed to represent aggregates of microglial cells ( Vujosevic et al., 2017a ; Pilotto et al., 2020 ). In diabetic eyes without clinical retinopathy, HF can be identified in the inner retina, where most microglial cells are present, while DR is associated with their outer retinal migration ( Vujosevic et al., 2013 ). HF number increases with DR and DME severity ( Schreur et al., 2020 ). The inflammatory origin of HF is debated but supported by a histopathologic study that investigated microglial activation in human DR and found an increased number of hypertrophic microglial cells scattered in the inner retinal layers, which were also present in outer retinal layers in later stages of the disease ( Zeng et al., 2008 ). However, it must be noted that immunolabeled microglial cells in retinal sections did not clearly resemble HF and were often located around retinal vasculature, microaneurysms, intraretinal hemorrhages, cotton-wool spots, and neovascularizations, which have not been described for HF, although no OCT-based investigation specifically addressed this area of uncertainty ( Zeng et al., 2008 ). Another research supporting this hypothesis reported an association between aqueous humor concentration of soluble CD14, a molecule involved in the cellular recognition of inflammatory signals (such as lipopolysaccharide), and HF number in diabetics with DME ( Lee et al., 2018 ). Other works specifically investigated the functional, prognostic and predictive role of HF. In DME, HF number shows an inverse correlation with macular sensitivity, possibly linking microglial inflammatory response to functional neuroretinal impairment ( Vujosevic et al., 2016a ), but predicts a higher increase in sensitivity thresholds after intravitreal dexamethasone treatment ( Vujosevic et al., 2017c ). Also, the presence of numerous HF at baseline predicts a worse visual acuity at the end of follow-up in DME treated with observation ( Busch et al., 2020 ). However, a recent systematic review found that it is still unclear whether HF presence in DME can predict treatment outcomes, even though their number decreases after treatment ( Huang et al., 2022 ). Vitreous HF are another potential biomarker of neuroinflammation. The resolution of spectral-domain OCT is in the range of 5–7 μm and, thus, has the potential of imaging leukocytes which can be up to 10–30 μm in size. These leukocytes would appear as vitreous HF, larger and brighter than the usual background speckle and about 20 μm in diameter ( Saito et al., 2013 ). A study by Mizukami et al. (2017) found a correlation between the average number of vitreous HF and the severity of DR. Similarly, macrophage-like cells (MLCs) at the vitreoretinal interface can be seen using en-face OCT. Their signal corresponds to a ramified morphology and a recent study found that MLC density is higher in PDR compared with controls, diabetics without retinopathy, and NPDR ( Ong et al., 2021 ). Interestingly, MLCs are more likely to localize on blood vessels and in perivascular areas than in ischemic areas ( Ong et al., 2021 ). Also, the OCT pattern of DME may become a key feature to guide treatment and predict outcomes. Current treatments for DME include intravitreal therapies that target different aspects of its pathophysiology: anti-VEGF for vasogenic edema and corticosteroids for inflammatory edema ( Romero-Aroca et al., 2016 ; Schmidt-Erfurth et al., 2017 ). DME can present with various patterns on OCT, including subretinal fluid (SRF) accumulation, which is visible on OCT as a hyporeflective area under the neuroretina ( Otani et al., 1999 ). This pattern is associated with higher concentrations of CXCL10, IL-6, IL-8, and PDGF-AA but not VEGF ( Sonoda et al., 2014 ; Kim et al., 2015 ) and by a higher number of HF ( Vujosevic et al., 2017b ), suggesting that inflammation plays a pivotal role in the development of at least some cases of DME. Indeed, dexamethasone treatment of SRF-associated DME is associated with a greater improvement of CMT (central macular thickness), retinal HF, and disorganization of inner retinal layers and cysts area with respect to ranibizumab treatment ( Vujosevic et al., 2020 ). Choroidal OCT biomarkers of inflammation have been proposed to monitor the response of DME to intravitreal corticosteroids: choroidal HF, which again are thought to represent inflammatory aggregates ( L

Currently, a robust amount of research is conducted on developing new pharmacological agents for DR and DME. At the moment the only strategy to prevent or halt the progression of DR is intensive blood glucose control ( Diabetes Control and Complications Trial Research Group, 1995 ) while effective therapies are available to treat only late-stage complications related to ischemia and DME, even though the incidence of persistent DME after 1 or 2 years of anti-VEGF treatment is still very high ( Dugel et al., 2016 ; Bressler et al., 2018 ). Several alternative strategies have been tested in the pre-clinical setting and here we summarize the advancement in research on novel therapeutics targeting inflammation ( Table 2 ) and neurodegeneration ( Table 3 ) in DR and DME, with a focus on those under investigation in clinical trials. TABLE 2 Clinical trials on novel drugs targeting inflammation in diabetic retinopathy. Drug (administration route) Category or mechanism Title Phase Identifier (status) ASP8232 (PO) Vascular adhesion protein-1 inhibitor A study to evaluate ASP8232 in reducing central retinal thickness in subjects with diabetic macular edema (DME) (VIDI) II NCT02302079 (completed) AXT107 (IVT) Integrin receptor antagonist Safety and bioactivity of AXT107 in subjects with diabetic macular edema (CONGO) I-IIa NCT04697758 (active) Dexamethasone (IVT implant) Steroidal anti-inflammatory Three-Year, randomized, sham-controlled trial of dexamethasone intravitreal implant in patients with diabetic macular edema III NCT00168337 , NCT00168389 (completed) EBI-031 (IVT) IL-6 inhibitor Safety study of intravitreal EBI-031 given as a single or repeat injection to subjects with diabetic macular edema I NCT02842541 (withdrawn) Fluocinolone acetonide (IVT implant) Steroidal anti-inflammatory Fluocinolone acetonide implant compared to sham injection in patients with diabetic macular edema (FAME) III NCT00344968 (completed) Infliximab (IV) Anti-TNF-α Treatment of refractory diabetic macular edema with infliximab III NCT00505947 (completed) KVD001 (IVT) Plasma kallikrein inhibitor Study of the intravitreal plasma kallikrein inhibitor, KVD001, in subjects with center-involving diabetic macular edema (ciDME) II NCT03466099 (completed) Nepafenac (T) COX-inhibitor A phase II evaluation of topical non-steroidal anti-inflammatories in eyes with non-central involved diabetic macular edema II NCT01331005 (completed) PF-04634817 (PO) Chemokine receptors antagonist A phase 2, multi-center study to compare the efficacy and safety of a chemokine CCR2/5 receptor antagonist with ranibizumab in adults with diabetic macular edema II NCT01994291 (completed) Risuteganib (IVT) Integrin receptor antagonist Phase 2 randomized clinical trial of luminate as compared to avastin in the treatment of diabetic macular edema IIb NCT02348918 (completed) SF0166 (T) Integrin receptor antagonist Safety and exploratory efficacy study of SF0166 for the treatment of diabetic macular edema (DME) I-II NCT02914613 (completed) THR-149 (IVT) Plasma kallikrein inhibitor A study to evaluate the safety of THR-149 in subjects with diabetic macular edema I NCT03511898 (completed) THR-687 (IVT) Integrin receptor antagonist A phase 1, open-label, multicenter, dose escalation study to evaluate the safety of a single intravitreal injection of THR-687 for the treatment of diabetic macular edema I NCT03666923 (completed) Tocilizumab (IV) IL-6 receptor antagonist Ranibizumab for edema of the macula in diabetes: Protocol 4 with tocilizumab: The READ-4 study (READ-4) II NCT02511067 (withdrawn) Triamcinolone acetonide (IVT) Steroidal anti-inflammatory Intravitreal triamcinolone acetonide vs. laser for diabetic macular edema III NCT00367133 (completed) IV, intravenous; IVT, intravitreal; PO, per os; T, topical. TABLE 3 Clinical trials on novel drugs targeting neurodegeneration in diabetic retinopathy. Drug (administration route) Category or mechanism Title Phase Identifier (status) Brimonidine (topical) α 2 -adrenergic agonist Trial to assess the efficacy of neuroprotective drugs administered topically to prevent or arrest diabetic retinopathy (EUROCONDOR) II-III NCT01726075 (completed) Cibinetide (subcutaneous) Erythropoietin-derived peptide A phase II clinical trial on the use of ARA 290 for the treatment of diabetic macular edema (ARA 290-DMO) II EudraCT 2015-001940-12 (completed) Citicoline and vitamin B 12 (topical) Phosphatidylcholine precursor Long-term retinal changes after topical citicoline administration in patients with mild signs of diabetic retinopathy in type 1 diabetes mellitus Not applicable NCT04009980 (completed) Elamipretide (topical) Mitochondrial cardiolipin stabilizer A study of MTP-131 topical ophthalmic solution in subjects with diabetic macular edema and non-exudative intermediate age-related macular degeneration (SPIOC-101) I-II NCT02842541 (completed) Somatostatin (topical) Endogenous neuroprotective hormone Trial to assess the efficacy of neuroprote

IL-6 is a key molecule that leads to retinal inflammation in DR and DME since it has been found elevated in vitreous in several studies, as described previously ( Koleva-Georgieva et al., 2011 ; Sonoda et al., 2014 ). Two registered clinical trials investigated the blockage of the IL-6 pathway with monoclonal antibodies in DME: both NCT02842541 for EBI-031 and NCT02511067 for tocilizumab are withdrawn at the present moment. TNF-α is another inflammatory cytokine secreted by activated macrophages and monocytes. Its serum concentrations correlate with the presence and severity of DR ( Koleva-Georgieva et al., 2011 ) and a phase III trial ( NCT00505947 ) demonstrated that intravenous anti-TNF-α monoclonal antibody infliximab significantly improved visual acuity over placebo in patients with DME ( Sfikakis et al., 2010 ). Interestingly, a subsequent retrospective study from Wu et al. (2011) found that intravitreal infliximab (and adalimumab) does not improve visual acuity or CMT in refractory DME. Integrin receptors are transmembrane adhesion proteins that mediate cell-to-cell and cell-to-extracellular matrix attachment and intracellular signal transduction, playing an essential role in leukocytes’ adhesion to the endothelium and extravasation. Most of their ligands are proteins containing arginine-glycine-aspartate (RGD) or leucine-aspartate-valine (LDV) motifs ( van Hove et al., 2021 ). Risuteganib (Luminate) is an intravitreal antagonist of RGD integrin receptors and a phase IIb trial in DME ( NCT02348918 ) showed its non-inferiority to bevacizumab with respect to visual acuity improvement at 24 weeks of follow-up ( Quiroz-Mercado et al., 2018 ). THR-687 is another RGD integrin receptors antagonist that demonstrated an excellent safety profile with no dose-limiting toxicities along with a rapid gain in visual acuity that lasted about 3 months in a phase I trial ( NCT03666923 ) ( Khanani et al., 2021 ). Also OTT-166 (formerly SF0166) is an antagonist that demonstrated biological effects after topical administration in an early clinical trial ( NCT02914613 ) ( Edwards et al., 2018 ), while AXT107 is currently under investigation in a phase I/IIa trial ( NCT04697758 ). Vascular adhesion protein-1 (VAP-1) is an endothelial and soluble enzyme with amine oxidase activity found elevated in the serum of diabetic patients and vitreous of eyes with PDR ( Murata et al., 2012 ; Luo et al., 2013 ) and involved in leukocyte diapedesis and vessel leakage ( Noda et al., 2009 ). Its oral inhibitor ASP8232 had no effect alone or in combination with ranibizumab in a phase II trial on DME ( NCT02302079 ) ( Nguyen et al., 2019 ). Chemokine receptor type 2 and type 5 (CCR2 and CCR5) are expressed by monocytes and play a key role in homing inflammatory cells to retinal tissue ( Rangasamy et al., 2014 ). Since the concentration of CCR2 and CCR5 ligands (monocyte chemoattractant protein-1 and RANTES, respectively) is elevated in the vitreous and aqueous humor of patients with DR and DME ( Funatsu et al., 2009 ; Roh et al., 2009 ) and CCR2 has been implicated in VEGF production and vascular leakage ( Krause et al., 2014 ), a phase II trial on CCR2/5 dual antagonist in DME has been performed ( NCT01994291 ). Treatment with the CCR2/5 inhibitor was associated with a modest improvement in visual acuity, though inferior to intravitreal ranibizumab, despite the high level of CCR2 antagonism observed in the study ( Gale et al., 2018 ).

No pharmacologic compound to halt neurodegeneration is approved for clinical use, yet some agents are under investigation. Topical brimonidine and somatostatin The EUROCONDOR phase II–III clinical trial ( NCT01726075 ) investigated the neuroprotective potential of topically administered brimonidine (α 2 -adrenergic agonist) and somatostatin (endogenous neuroprotective hormone) in patients with type 2 diabetes and early stage or no DR ( Simó et al., 2019 ). Indeed, animal studies have demonstrated that topical brimonidine enhances neuronal function and reduces apoptosis ( Saylor et al., 2009 ); similarly, topical somatostatin prevents ERG abnormalities, glial activation, and neuronal apoptosis ( Hernández et al., 2013 ). Results from the trial have shown that somatostatin and brimonidine do not prevent neurodysfunction in diabetics; however, in the subset of patients displaying abnormal mfERG at baseline, these two compounds arrested the progression of neural dysfunction ( Simó et al., 2019 ).

Cardiolipin is a phospholipid of the inner mitochondrial membrane which has an active role in mitochondrial-dependent apoptosis ( Birk et al., 2014 ). Elamipretide (formerly MTP-131) is a soluble tetrapeptide that selectively stabilizes mitochondrial cardiolipin and promotes efficient electron transfer and reversed the visual decline without improving glycemic control or reducing body weight in mouse models of diabetes ( Alam et al., 2015 ). A phase I/II clinical trial has been carried out to determine the effects of topical ocular administration of elamipretide in DME ( NCT02314299 ).

Alpha-lipoic acid is a pro-energetic and antioxidant compound that seems to be a valuable neuroprotective option for Alzheimer’s disease ( Hager et al., 2007 ; Fava et al., 2013 ). Moreover, alpha-lipoic acid treatment reduced VEGF levels and preserved ganglion cells, inner and outer layers in diabetic mouse retinas ( Kan et al., 2017 ). A randomized trial on diabetic subjects receiving 300 mg of ALA orally once daily for 3 months demonstrated that contrast sensitivity remained stable in patients with type 1 DM and improved in those with type 2 while contrast sensitivity declined in diabetics without ALA supplementation; however, visual acuity and eye fundus image was stable in all studied subjects ( Gêbka et al., 2014 ).

DR is characterized by extremely complex pathogenesis, in which microvascular damage holds a pivotal role. However, neuroinflammation and neuronal degeneration are common phenomena occurring in all DR stages, entangled with the effects of vascular exudation and retinal ischemia but at least partially independent, possibly explaining why some patients experience poor outcomes despite optimal treatment. The wide range of molecular targets prompts the development of new drugs, some of which are already under evaluation in clinical trials, in order to provide more bullets in the management of DR while in vivo multimodal imaging biomarkers promise a patient-tailored therapeutic strategy according to the vascular, inflammatory and neurodegenerative DRD phenotype.

FB consultant for: Alcon (Fort Worth, Texas, United States), Alimera Sciences (Alpharetta, Georgia, United States), Allergan Inc. (Irvine, California, United States), Farmila-Thea (Clermont-Ferrand, France), Bayer Shering-Pharma (Berlin, Germany), Bausch And Lomb (Rochester, New York, United States), Genentech (San Francisco, California, United States), Hoffmann-La-Roche (Basel, Switzerland), NovagaliPharma (Évry, France), Novartis (Basel, Switzerland), Sanofi-Aventis (Paris, France), Thrombogenics (Heverlee, Belgium), and Zeiss (Dublin, United States). The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.