Melatonin in Glaucoma: Integrative Mechanisms of Intraocular Pressure Control and Neuroprotection

Glaucoma is a group of optic nerve neuropathies characterized mainly by progressive degeneration of RGC and optic nerve injuries. Elevated IOP plays an important role in the development of glaucoma [1,2]. In 2020, an estimated 76 million people worldwide were affected by glaucoma, of which approximately 74% had primary open-angle glaucoma and the remainder comprised mainly angle-closure and normal-tension subtypes [3]. Glaucoma accounts for roughly 3.6 million cases of bilateral blindness globally, and no current therapy can restore lost vision, underscoring the imperative for early detection and management. With global prevalence projected to rise to 112 million by 2040 due to population aging [4], optimized screening and innovative treatments are urgently needed. As aging populations contribute to a significant increase in glaucoma prevalence in the coming decades [4], improved detection methods and enhanced treatment strategies will be essential to prevent avoidable blindness.

While the cellular mechanisms underlying glaucomatous damage remain inadequately understood, it is widely recognized that the primary injury occurs at the optic nerve head and may involve multiple processes [5], including ischemia [6], axoplasmic transport obstruction [7], biomechanical stress on axons [8], and secondary effects from RGC axon loss [9]. Additionally, optic nerve head glial remodeling in glaucoma involves the activation of resident astrocytes and an extracellular matrix [10]. These glial cells within the optic nerve head and retina respond to mechanical and metabolic stress and strain, playing a critical role in disease progression [9,11,12]. These converging factors underscore glaucoma's multifactorial pathology.

Melatonin, the principal hormone of the pineal gland, has emerged as a promising neuroprotective agent in this context. Studies involving adults with normal vision indicate that the system responsible for detecting brightness provides direct photic input to the suprachiasmatic nuclei (SCN), the primary circadian pacemaker in mammals, through neural pathways independent of standard retinal projections associated with vision [13,14]. Two distinct mechanisms facilitate photic entrainment (Figure 1).The primary mechanism, the retinohypothalamic tract (RHT), channels light-derived signals to the SCN and pineal gland. The RHT transmits light signals from melanopsin-expressing intrinsically photosensitive retinal ganglion cells (ipRGCs) to the SCN through glutamate and pituitary adenylate cyclase-activating polypeptide (PACAP) [15], directly resetting circadian clocks via NMDA/PAC1 receptor activation [16,17]. The secondary pathway, termed the geniculohypothalamic tract (GHT), originating in the thalamic intergeniculate leaflet (IGL), relays non-photic behavioral and metabolic inputs via neuropeptide Y (NPY) and GABA to modulate SCN phase plasticity [18,19].

Downstream, SCN efferents project to the paraventricular nucleus (PVN), which relays signals via the spinal intermediolateral column (IML) and superior cervical ganglion (SCG) to regulate pineal melatonin secretion, suppressing melatonin synthesis in light while allowing nocturnal melatonin release [20].

As retinal ganglion cells with photoreceptive functions play a crucial role in synchronizing the SCN, and ocular disorders can disrupt circadian rhythms, the potential link between melatonin and visual health has become a focal point of research [21,22].

A comprehensive literature search was conducted using the PubMed and Medline databases to identify relevant publications up to 30 March 2025. The search focused on articles published between 2000 and 2025, employing the following keywords and combinations: "melatonin", "glaucoma", "N-acetyl-5-methoxytryptamine", "RGC protection", "intraocular pressure", and "neuroprotection".

Studies not published in English, those irrelevant to the scope of this review, or those lacking complete research data were excluded. Articles identified as errata or corrections were also removed. The literature screening and selection process was independently conducted by two authors. Discrepancies in article inclusion were resolved through open discussion with senior co-authors to ensure consensus.

Interventionary studies involving animals or humans and other studies requiring ethical approval must list the authority that provided approval and the corresponding ethical approval code.

Melatonin (N-acetyl-5-methoxytryptamine), an indolamine hormone derived from tryptophan, is synthesized primarily in pinealocytes and functions as an endocrine modulator of circadian rhythms across multiple organ systems [23]. Common dietary sources of melatonin include walnuts, tart cherries, grapes, tomatoes, rice, and oats; consumption of these foods has been shown to modestly elevate systemic—and by extension ocular—melatonin levels [24]. Melatonin's ocular effects are closely intertwined with other neurotransmitters such as dopamine; in the retina, melatonin and dopamine form an antagonistic circadian feedback loop, with melatonin predominating at night and dopamine during the day. Disruption of this balance in glaucoma may contribute to the circadian rhythm disturbances observed in patients. In addition to the pineal gland, retinal photoreceptors have been identified as local production sites for melatonin [25,26], where it seemingly acts in a paracrine manner due to its minimal systemic release. Further studies have indicated its biosynthesis in the ciliary body epithelium, with subsequent secretion into the aqueous humor [27,28,29].

Melatonin biosynthesis proceeds via four distinct enzymatic reactions (Figure 2). The metabolic sequence begins with hydroxylation of tryptophan by tryptophan hydroxylase (TPH), generating 5-hydroxytryptophan. This intermediate is then transformed into serotonin through a decarboxylation step mediated by aromatic amino acid decarboxylase (AADC) [30]. Subsequently, arylalkylamine N-acetyltransferase (AANAT) catalyzes the acetylation of serotonin into N-acetylserotonin [31], which is ultimately methylated by hydroxyindole-O-methyltransferase (HIOMT) to form melatonin [32]. This biosynthetic pathway is subject to circadian control, with both enzymatic activity and gene transcription of TPH and AANAT exhibiting time-of-day dependency, especially nocturnal upregulation [15,33]. A comparable daily rhythm of melatonin synthesis has been identified in the retina, reinforcing its role in local circadian regulation [34,35]. Once synthesized, melatonin interacts with a diverse array of receptor subtypes located across multiple tissues. These interactions mediate its systemic and local functions, including regulation of sleep architecture, endocrine cycles, reproductive timing, immune modulation, and behavioral rhythms.

While elevated IOP remains the primary risk factor for glaucoma, contributing to optic nerve damage through disrupted axonal transport and impaired neuronal signaling, growing evidence indicates that RGC degeneration involves a complex interplay of additional pathological mechanisms. These include vascular dysregulation-induced hypoxia [116], glutamate excitotoxicity [117,118], neuroinflammation [119], oxidative stress [120,121,122], and mitochondrial dysfunction [123,124,125,126,127], all of which may act independently of or synergistically with IOP elevation to accelerate disease progression. Melatonin, a pleiotropic molecule with neuroprotective properties, has shown potential in modulating these processes, offering a multifaceted therapeutic avenue for glaucomatous neurodegeneration [128].

Accumulating evidence supports melatonin's multi-target neuroprotective role in glaucoma, acting through antioxidative, anti-apoptotic, anti-inflammatory, and synaptic regulatory mechanisms. These diverse effects are mediated via mitochondrial preservation, inhibition of regulated cell death pathways, immune modulation, and retinal circuit stabilization as listed in. Table S2 (Supplementary Materials)

In retinal ischemia–reperfusion (RIR) injury models, Zhang et al. [154] demonstrated that melatonin administration in C57BL/6J mice significantly reduced RGC death (37.2% increase in survival), lipid peroxidation (54% decrease in malondialdehyde levels), and iron accumulation (42% reduction in ferritin expression). Mechanistically, melatonin preserved mitochondrial ultrastructure (28% increase in cristae density) by modulating the Slc7a11/Alox12 axis and inhibiting p53-mediated ferroptosis, thereby mitigating oxidative and iron-dependent cell death.

Its anti-apoptotic efficacy was further highlighted in acute ocular hypertension (AOH) models. Ye et al. [155] reported that melatonin inhibited PANoptosis—a hybrid pathway integrating apoptosis, necroptosis, and pyroptosis—by suppressing caspase-3 (62% reduction in TUNEL-positive cells), RIP1/RIP3 phosphorylation (73% decrease in p-RIP1), and NLRP3 inflammasome activation (58% reduction in IL-1β). These effects preserved retinal laminar integrity, with inner nuclear layer thickness retained at 89.7% (p < 0.001 vs. controls). Similarly, Shi et al. [156] identified an SIRT1-dependent mechanism in optic nerve crush models, where melatonin reduced p53 acetylation (65% reduction in Ac-p53), elevated antioxidant capacity (1.8-fold increase in SOD activity), and suppressed senescence (42% reduction in SA-β-gal-positive cells). The reversal of these effects by EX-527, a SIRT1 inhibitor, confirmed pathway specificity.

In hypertensive glaucoma models, Dal Monte et al. [55] showed that topical melatonin/agomelatine application reduced IOP by 28.4% and inhibited Bax-caspase-3-mediated apoptosis (61% reduction in caspase-3 activity). However, in contrast, Marangoz et al. [157] found that systemic melatonin administration in episcleral vein-cauterized rats lowered IOP by 19.2%, but failed to significantly preserve RGC density—unlike brimonidine tartrate, which maintained 78.4% RGC survival. These contrasting results suggest that melatonin's neuroprotective efficacy may be influenced by the delivery route, bioavailability, and disease stage, highlighting the need for pharmacokinetic optimization in clinical applications.

Beyond acute injury models, melatonin also exhibits benefits in chronic, normotensive glaucoma contexts. Hu et al. [158] showed that oral melatonin improved RGC survival (to 82.3% of control levels) in EAAC1−/− mice via the NRF2/p53/SIRT1 axis, with concurrent reductions in oxidative DNA damage (54% decrease in 8-OHdG-positive cells). In addition, González Fleitas et al. [159] reported that melatonin selectively protected melanopsin-expressing RGCs (76% survival increase) and restored mitochondrial membrane potential (2.3-fold increase in JC-1 red/green fluorescence ratio), leading to functional recovery in circadian light reflexes (41% decrease in latency).

Melatonin's neurorestorative effects extend to synaptic function. Zhao et al. [160] demonstrated that MT2 receptor activation enhanced glycine receptor currents by 217% in rat RGCs via a phosphatidylcholine-specific PLC/PKC pathway, independent of cAMP/cGMP signaling. This modulation improved contrast sensitivity under scotopic conditions (peak efficacy at 5 lux), suggesting its relevance in visual function preservation.

The immunomodulatory actions of melatonin were elucidated in NMDA-induced excitotoxicity models. Zou et al. [161] showed that melatonin suppressed microglial activation (63% reduction in Iba1+ area), decreased TNF-α secretion (58%), and inhibited p38 MAPK signaling in RGCs (72% decline in p-p38). These effects were abolished by minocycline, confirming a microglia-dependent mechanism. In complementary work, Belforte et al. [162] found that melatonin restored glutamate-GABA balance (38% reduction in glutamate; 1.5-fold increase in GAD67 expression) and attenuated nitric oxide overproduction (64% reduction in iNOS), thereby limiting neuroinflammatory cascades. These findings highlight the translational need for optimized delivery and receptor-targeted design.

Current clinical studies on melatonin for glaucoma therapy primarily employ oral administration. However, its clinical utility remains limited due to the lack of robust preclinical models and its inherently low oral bioavailability (15%), which is attributed to extensive hepatic first-pass metabolism [163]. Topical ocular delivery, though widely considered, faces significant physiological barriers such as rapid tear turnover, corneal impermeability, nasolacrimal drainage, and enzymatic degradation. These factors contribute to poor drug retention, low targeting efficiency, and limited transcorneal permeation [164]. Alternatively, while intravitreal injections can deliver drugs directly to the posterior segment, they pose risks of retinal toxicity at high doses [165]. Immediate-release formulations further compound these limitations by exhibiting short plasma half-lives and inadequate absorption profiles [166].

To overcome these challenges, nanotechnology-based drug delivery systems have been increasingly explored. Nanocarriers with mucoadhesive and mucopenetrating properties—such as nanocapsules, liposomes, micelles, and polymeric nanoparticles—show promise in enhancing melatonin permeability across ocular barriers, prolonging retention time, and enabling controlled release [55,167,168,169,170,171,172,173]. For instance, Romeo et al. developed melatonin-loaded lipid–polymer hybrid PLGA-PEG nanoparticles coated with a cationic lipid shell, which demonstrated superior neuroprotective and antioxidant activity compared to melatonin in aqueous solution [174]. Similarly, Quinteros et al. reported that combining bioadhesive polymers with liposomal carriers significantly improved the IOP-lowering efficacy of the melatonin derivative 5-MCA-NAT [167].

Nanocarrier systems can be categorized by geometry: (1) Zero-dimensional (0D) nanoparticles—Polymeric nanoparticles, such as poly(lactic-co-glycolic acid)-polyethylene glycol (PLGA-PEG), have been shown to sustain melatonin release for up to 8 h and produce greater IOP reduction than solution-based formulations [172,175]. Cationic nanoparticles, such as those coated with chitosan, enhance mucoadhesion and prolong corneal residence time [169]. (2) One-dimensional (1D) nanofibers—Electrospun nanofibers made from poly(vinyl alcohol) (PVA) and poly(lactic acid) (PLA) exhibit tunable release profiles: PVA achieves rapid, complete drug release within 20 min, while PLA supports sustained delivery over several hours, thus improving ocular bioavailability [173,176]. (3) Two-/three-dimensional (2D/3D) systems—Nanofilms and hydrogels, particularly those based on hyaluronic acid, offer high drug-loading capacity and stimulus-responsive release. However, their application in melatonin delivery remains underexplored [177].

Therefore, tailoring melatonin delivery methods—such as optimized dosing schedules, patient-specific formulation selection (e.g., nanocarriers, topical application, or sustained-release systems), and precise receptor targeting—could enhance both safety and effectiveness. These approaches are particularly relevant in overcoming current limitations related to bioavailability and therapeutic consistency.

Despite the promising advances in nanocarrier-based systems, several obstacles remain. These include limitations in penetration efficiency, therapeutic consistency, and ocular targeting. Future research should focus on optimizing delivery vectors, improving tissue-specific transport, and validating efficacy in clinically relevant models. Furthermore, successful clinical translation will require systematic evaluation of safety, therapeutic effectiveness, scalability, commercial viability, and adherence to regulatory standards.

Melatonin represents a promising yet underutilized candidate in the therapeutic landscape of glaucoma. Its dual capacity to modulate intraocular pressure and exert neuroprotective effects offers a pharmacological advantage over agents that solely target pressure reduction. However, despite encouraging preclinical evidence, the clinical application of melatonin remains limited, and the heterogeneity in study design, formulation types, and dosing regimens poses significant barriers to translation. As this review has shown, most investigations are restricted to animal models or small-scale human trials, thereby limiting generalizability.

One major limitation encountered during this review was the restricted number of high-quality, peer-reviewed clinical studies that specifically address melatonin-based interventions for glaucoma. Although melatonin and its analogs have been extensively studied in the context of neurodegeneration, their targeted role in ocular pathophysiology remains comparatively less explored. Despite efforts to broaden the search strategy, the lack of standardized endpoints and inconsistent reporting of outcomes hindered direct comparisons between studies. Additionally, the current literature does not adequately address the long-term safety profile of melatonin, particularly when administered in sustained-release or high-dose formulations tailored for ocular delivery.

Emerging human pluripotent stem cell-derived retinal organoids can recapitulate key features of glaucomatous injury—such as RGC axonal degeneration, gliosis, and neuroinflammation—when subjected to controlled hydrostatic pressure (e.g., 15–30 mmHg). We propose that future work leverage these organoid models to assess the neuroprotective and IOP-modulating effects of melatonin and its analogs. Such studies should measure RGC survival, neurite integrity, synaptic marker expression, and inflammatory cytokine release within perfused organoid culture systems. Comparative evaluation of oral, topical, and nanocarrier-based delivery in organoid perfusion will help define optimal dosing regimens for clinical translation [178].

Given the complexity of glaucomatous neurodegeneration, future research should prioritize well-designed clinical trials to determine optimal delivery strategies, dose safety, and patient-specific responsiveness to melatonin-based therapies. Moreover, elucidating the interplay between melatonin receptors, circadian rhythm disruption, and retinal ganglion cell survival may uncover new therapeutic windows. This review underscores the need for multidisciplinary efforts to validate melatonin's translational potential in glaucoma management.

Glaucoma is a complex neurodegenerative disorder in which retinal ganglion cell loss and optic nerve damage result from not only elevated IOP, but also mitochondrial dysfunction, oxidative stress, neuroinflammation, and excitotoxicity. Melatonin, through its pleiotropic actions—including antioxidant, anti-inflammatory, anti-apoptotic, and mitochondrial protective effects—has shown significant neuroprotective potential in experimental glaucoma models. Its ability to modulate multiple pathogenic pathways positions it as a compelling candidate for disease-modifying therapy.

Melatonin regulates IOP via MT1, MT2, and MT3 receptor pathways and demonstrates additive or synergistic effects when combined with conventional ocular hypotensives. However, its systemic bioavailability remains a major barrier to clinical translation. Recent advances in nanocarrier-based delivery systems—such as polymeric nanoparticles, nanofibers, and hydrogels—offer promising solutions for enhancing ocular retention, permeability, and sustained release.

To fully harness the therapeutic potential of melatonin in glaucoma, future efforts should focus on optimizing delivery vectors, validating receptor-specific mechanisms, and conducting well-designed clinical trials. With continued development, melatonin-based therapeutics may offer a novel, multi-target strategy for preserving visual function in glaucoma patients.