Abstract
Traumatic spinal cord injury (SCI) is a debilitating condition characterized by the impairment of neural circuits, leading to the loss of motor and sensory functions and accompanied by severe complications. Substantial research has reported the therapeutic potential of Omega-3 fatty acids for the central nervous system, particularly after traumatic SCI. Omega-3 fatty acids may contribute to improving SCI recovery through their anti-inflammatory, anti-oxidative, neurotrophic, and membrane integrity-preserving properties. These functions of Omega-3 fatty acids are primarily mediated via the activation of G protein-coupled receptor 120 (GPR120), commonly known as the fish oil-specific receptor. Advancements in understanding of the molecular mechanisms of GPR120’s recognition of Omega-3 fatty acids and its downstream signaling mechanisms has significantly promoted research on the pharmacological potential of Omega-3 fatty acids and the development of highly selective and high-affinity alternatives. This review aims to provide in-depth analysis of the comprehensive therapeutic potential of Omega-3 fatty acids for SCI and its accompanying complications, and the prospects for developing novel drugs based on the recognition of Omega-3 fatty acids by GPR120.
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Introduction
Traumatic spinal cord injury (SCI) is a debilitating neurological condition characterized by the disruption of neural communication between the brain and effector organs, as well as the interruption of autonomic nerve circuits.1,2,3 This condition is often accompanied by severe complications such as neuropathic pain, osteoporosis, and obesity.2,4 Traumatic SCI has a significant prevalence and is associated with a high disability rate, significantly impacting the quality of patients’ lives and imposing substantial economic burdens on individuals and society.1,5,6 Therefore, there is a critical importance to identify potential clinical intervention strategies for SCI. Current promising clinical and preclinical treatments for SCI include surgical decompression, pharmacotherapy, cell and biological agents, biological carrier transplantation, epidural electrical stimulation, and brain-spinal cord-computer interfaces.1,7,8,9,10,11,12,13 Pharmacotherapy represents a pivotal approach to effectively address the challenges associated with SCI, due to its convenient industrialized production, wide dissemination, minimal requirement for medical guidance, and affordability. However, the limited effectiveness and adverse effects of current pharmacotherapies hinder their widespread clinical application, leading to a lack of suitable pharmacological interventions for the clinical management of SCI. In detail, pharmacological strategies can be categorized into two major classes: microenvironmental regulators, which target the inflammatory and inhibitory microenvironment; and neuroregenerative activators, which target the neurotrophic microenvironment and directly promote the reconstruction of neural circuits.1 Among the pharmacological agents that have entered clinical trials, each possesses its own limitations. Corticosteroids were among the earliest agents to be applied in clinical settings; however, their therapeutic efficacy has been limited due to a narrow treatment window (being effective only when administered within 3–8 h post-injury) and the potential adverse effects associated with high-dose administration.14,15,16 Minocycline and ganglioside have shown promising therapeutic effects in both animal studies and early-phase clinical trials (Phase I/II); however, they failed to demonstrate efficacy in Phase III clinical trials.17,18 Riluzole and neurotrophins, on the other hand, are associated with unexpected side effects, including locomotor ataxia and lethargy, as well as nociceptive sprouting accompanied by neuropathic pain, respectively.19,20 Consequently, there is an urgent need to develop affordable medicines that leverage novel therapeutic targets to enhance treatment outcomes for SCI.
G protein-coupled receptors (GPCRs) constitute the largest family of membrane-protein, widely distributed throughout the human body.21 GPCRs act as pivotal hubs for signal transmission and respond to a variety of signals, including hormones, neurotransmitters, ions, photons, odorants, and other stimuli.21 GPCRs mediate various signaling pathways, contributing to numerous physiological and pathological functions.21 They are thus recognized as significant drug targets, as recent studies indicate that ~34%–36% of drugs approved by the United States Food and Drug Administration specifically target 108 distinct GPCR types, with an additional 66 potential GPCR targets in development.22,23 GPCR-targeting medicines were initially designed for the treatment of various diseases, and their application has expanded to the treatment of central nervous system (CNS) disorders, including Alzheimer’s disease and multiple sclerosis.23 These advancements have spurred interest in exploring GPCRs and their small molecule ligands in the pathological processes and treatment of SCI, offering prospects for comprehensive and targeted drug therapies.
Omega-3 fatty acids, essential nutrients that cannot be synthesized endogenously, are primarily derived from cold-water fish oil.24 Omega-3 fatty acids possess multiple beneficial effects on the human body, including the regulation of glucose and lipid metabolism, and anti-inflammatory and anti-oxidative properties, neurotrophic effects, and membrane integrity preservation.25,26,27 The specific binding receptor for Omega-3 fatty acids, G protein-coupled receptor 120 (GPR120), is integral to these molecular pathways and is pivotal for their therapeutic potential.28,29,30 Over the past 50 years, interest in Omega-3 fatty acids for treating CNS disorders and traumatic injuries has significantly increased.31,32 Consumption of fish oil supplements prior to illness onset has shown preventive effects, particularly when administered as a nutritional intervention to alleviate systemic inflammation after trauma.32,33,34,35,36,37
A primary challenge in Omega-3 fatty acids therapy is low efficacy, even at high doses.38 Recent clinical trials exploring allosteric modulators and biased agonists offer promising avenues for more effective GPCR targeting and activation.23,28,38 A recent study provides promising evidence regarding the capability of GPR120 to discern distinct double bond positions in fatty acids, subsequently triggering downstream effectors.39 This discovery provides a theoretical basis for developing potent pharmaceutical agents specifically targeting GPR120.
This review provides a thorough description of the wide-ranging and specific effects of Omega-3 fatty acids relating to SCI and associated complications, alongside details of the recent advancements in the recognition of Omega-3 fatty acids double bonds by GPR120. The findings propose a novel direction—developing highly selective and high-affinity Omega-3 fatty acids substitutes that target distinct downstream effectors of GPR120; These substitutes hold substantial potential to enhance drug efficacy and reduce adverse effects, ultimately improving conprehensive and targeted clinical treatments for SCI.
Omega-3 fatty acids
Fatty acids
Fatty acids are organic compounds that serve as important components of lipids.40 Based on their length, fatty acids can be categorized as short-chain (fewer than six carbon atoms), medium-chain (six to twelve carbons), and long-chain (twelve or more carbons).41 According to their degree of saturation, fatty acids can be classified as saturated, monounsaturated, or polyunsaturated. Saturated fatty acids have no double bonds between their carbon atoms, while monounsaturated fatty acids have one double bond, and polyunsaturated fatty acids have two or more double bonds.42 The classification and properties of fatty acids have been extensively studied due to their significant implications for human health, particularly Omega-3 fatty acids, which can not only exhibit antioxidant and anti-inflammatory effects but also regulate platelet homeostasis and lower the risk of thrombosis.43
Polyunsaturated fatty acids
Polyunsaturated fatty acids can be further categorized into Omega-3 and Omega-6 fatty acids based on the position of the first double bond from the methyl end of the fatty acids. Omega-3 fatty acids have a double bond at the third carbon atom from the end of the carbon chain, whereas Omega-6 fatty acids have a double bond at the sixth carbon atom.42 Omega-3 fatty acids, known as essential fatty acids, include eicosapentaenoic acid (EPA), docosahexaenoic acid (DHA), alpha-linolenic acid (ALA), and docosapentaenoic acid (DPA).44 EPA and DHA are primarily found in cold-water fish.45 DPA is also widely found in marine foods, but generally at lower levels compared to EPA and DHA.46 ALA is predominantly found in plant-based foods, including flaxseed, echium seeds, and walnuts.47 Arachidonic acid (AA), a form of Omega-6 fatty acid, is mainly found in low-plant species like mosses and lichens.48 The structural dissimilarities of these acids lead to functional differences in terms of their effects on inflammation and metabolism.49 Omega-3 fatty acids play significant roles in preventing and treating of inflammatory diseases and metabolic disorders by inhibiting the activation of NOD-like receptor thermal protein domain associated protein 3 (NLRP3) and reducing the secretion of inflammatory factors.29,50 In contrast, Omega-6 fatty acids exhibit pro-inflammatory properties by increasing the production of inflammatory leukotrienes (LT), prostaglandins (PG), and cytokines.51 Therefore, a well-balanced Omega-3/Omega-6 ratio is crucial for preventing inflammatory and metabolic diseases52 (Table 1).
Overview of GPR120
Omega-3 fatty acids are recognized by GPR120, a receptor that plays a crucial role in regulating metabolic and immune functions.53 Studies have demonstrated an increase in the expression of GPR120 after SCI, with the most significant increase observed in astrocytes.54 Further studies revealed that GPR120 can regulate astrocyte proliferation by influencing the cell cycle,54 suggesting that GPR120 is a potential therapeutic target for the treatment of SCI. Current investigations on GPR120 primarily focuses on its regulatory roles in both physiological and pathological contexts.55,56,57 Further research is needed on GPR120’s intricate signal transduction mechanisms in order to develop safe and effective GPR120-targeted drugs for clinical use.
Basic and clinical studies on the effects of Omega-3 fatty acids on spinal cord injury
Following SCI, various microenvironmental alterations, including pro-inflammatory microglial responses, excessive reactive oxygen species (ROS) that drive oxidative stress, and astrocyte proliferation resulting in fibrotic scar—collectively hinder neurological recovery and complicate SCI rehabilitation. Omega-3 fatty acids, a class of polyunsaturated fatty acids chiefly consisting of eicosapentaenoic acid (EPA), docosahexaenoic acid (DHA), and alpha-linolenic acid (ALA), serve multifaceted roles in enhancing microenvironment, partly by targeting a series of molecules such as GPR120. These roles include anti-inflammatory, antioxidant, neurotrophic, and cell membrane integrity-preserving functions. Thus, Omega-3 fatty acids hold promising potential in modulating central nervous system inflammation, particularly in the treatment of acute neurological damage caused by traumatic events. Overall, Omega-3 fatty acids demonstrate broad therapeutic potential in the field of spinal cord injury treatment. However, further research is required to fully elucidate their mechanisms of action and applicability to determine the optimal therapeutic strategies.
Anti-inflammation
Inflammation is a pathophysiological mechanism initiated by microglia and peripherally derived myeloid cells following SCI and plays a dual role in the repair process of the injured spinal cord.58,59 Microglia and macrophages not only mitigate the inhibitory microenvironment post-SCI by clearing apoptotic cellular debris,60,61 but also can facilitate wound sealing to limit injury expansion and debris removal, thereby potentially contributing to the restoration of motor function.60,62,63,64 Meanwhile, limiting the harmful pro-inflammatory effects of microglia and macrophages is pivotal for SCI treatment. During the acute phase of SCI, initial mechanical tissue damage triggers damage-associated molecular patterns (DAMPs).65,66 These DAMPs activate microglia—resident CNS surveillance cells—resulting in robust inflammation and oxidative stress.65,67 A variety of chemokines—released by astrocytes, resident microglia, and endothelial cells—are subsequently up-regulated in spinal cord. These chemokines, in turn, recruit neutrophils and monocytes derived from peripheral blood and the hematopoietic system to traverse the damaged blood-spinal cord barrier. Some of these exogenous myeloid cells and activated microglia release pro-inflammatory factors, proteases, and other cytotoxic factors.1 The inflammatory microenvironment formed by these compounds substantially contributes to the secondary injury, resulting in neuron and oligodendrocyte death and promoting glial scar formation.68,69 Thus, reducing inflammation from activated microglia, macrophages, and neutrophils while improving the inflammatory microenvironment are effective strategies to alleviate neurological dysfunction after SCI.
The anti-inflammatory properties of Omega-3 fatty acids first identified in cardiovascular diseases.70 Given their efficacy, researchers have advocated for their use in other conditions characterized by acute and chronic inflammation.31,71,72,73,74 The role of Omega-3 fatty acids in regulating neuroinflammation has been extensively investigated in recent decades.75,76 Chronic inflammation of the brain is primarily characterized by overactivation of microglia and the release of inflammatory factors, which are viable targets for Omega-3 fatty acids.77 Knockout of Acsl6(Acyl-CoA Synthetase Long-Chain Family Member 6), a gene associated with Omega-3 fatty acids synthesis in neurons, influences age-related inflammation, thereby affecting motor function and memory.78 Pretreatment with DHA reverses TNFα-induced neuroinflammation in hypothalamic neurons via GPR120, while decreased endogenous GPR120 expression impairs Omega-3 fatty acids efficacy.79 In vitro studies indicate that DHA can reduce inflammatory biomarkers in microglia and hippocampal neurons, underpinning its potential for treating cognitive decline and depressive symptoms.77,80,81 Notably, a large-scale multi-center study has revealed that Omega-3 fatty acids supplementation alleviates primary injury effects, secondary intracellular metabolic disorders, and persistent inflammation associated with traumatic brain injury.82 Furthermore, such supplementation has demonstrated the ability to improve neurological recovery post-cerebral ischemia by modulating microglia polarization.83 These findings highlight the significant prospective role of Omega-3 fatty acids in regulating CNS inflammation, particularly in the treatment of acute nerve injury resulting from traumatic events.
Given that multiple CNS disorders share common pathological mechanisms, it is plausible to extend the potential therapeutic utility of Omega-3 fatty acids to SCI treatment. At the molecular level in an SCI model, Omega-3 fatty acids have been shown to significantly inhibit the assembly and activation of the NOD-like receptor thermal protein domain associated protein 1 (NLRP1) and NLRP3 inflammasome, reducing IL-1, IL-6, IL-18, and TNFα levels.84,85,86 At the cellular level in an SCI model, Omega-3 fatty acids have been found to reduce the number of, and inhibit activation in, microglia and exogenous monocytes.87,88 Further studies indicate that Omega-3 fatty acids can reduce microglia aggregation89 and inhibit microglia activation.90 Fat-1 transgenic mice, which carry the Fat-1 gene from Caenorhabditis elegans, can insert a double bond into an unsaturated fatty-acid hydrocarbon chain and thus convert Omega-6 to Omega-3 fatty acids.91 These mice therefore serve as an effective model to investigate Omega-3 and Omega-6 fatty acids dynamics. In an SCI model employing Fat-1 mice, investigators observed reduced inflammatory cell activation, lower production of inflammatory factors, and improved motor function recovery.92
Following SCI, significant alterations in membrane remodeling-related metabolites occurred, including the up-regulation of the anti-inflammatory Omega-3 fatty acids DHA and DPA.93 Metabolomic analyses indicate that elevated blood concentrations of DHA and DPA negatively correlate with BBB(Basso-Beattie-Bresnahan) scores. This implies that Omega-3 fatty acids may serve as potential biochemical markers and promoters of locomotor recovery in SCI mice.93,94 This correlation was further supported by López-Vales et al.,95 who found that fenretinide, an anticancer agent that elevates the Omega-3/Omega-6 ratio, exhibits significant inhibitory effects on neuroinflammation by decreasing levels of AA and increasing those of DHA in both serum and spinal cord tissue. Additionally, in patients with chronic SCI, 3 months of dietary Omega-3 fatty acids supplementation reduced chronic inflammation, suppressing cytokines such as IL-1β, IL-6, TNF-α, and interferon-gamma.96 However, another clinical study found that Omega-3 fatty acids mainly inhibited inflammation during the acute phase, with minimal effects on chronic inflammation.97 In summary, numerous pre-clinical and clinical studies support the capacity of Omega-3 fatty acids to inhibit neuroinflammation in acute and, potentially, chronic stages of SCI. Nevertheless, clinical trials involving Omega-3 fatty acids have not yet produced consistent results (Fig. 1).
Overview of Omega-3 fatty acids facilitating the repair of spinal cord injury through anti-inflammatory properties. Omega-3 fatty acids can access the spinal cord injury microenvironment by penetrating the blood-spinal cord barrier. Omega-3 fatty acids suppress monocyte infiltration from the bloodstream and reduce the activation of macrophages and microglia. Regarding the regulation of inflammatory factors, Omega-3 fatty acids inhibit the release of IL-6 and TNF-α from microglia and block the maturation of IL-1β and IL-18 precursors by modulating the pathway of the NLRP1/NLRP3 inflammasome, thus reducing their level in the spinal cord lesion
In summary, Omega-3 fatty acids show substantial potential to enhance SCI outcomes via their anti-inflammatory effects. Nonetheless, the precise mechanisms by which they modulate the inflammatory microenvironment in immune cells post-SCI require further clarification.
Anti-oxidation
Oxidative stress arises from an imbalance in the cellular redox state triggered by excessive reactive oxygen species (ROS).98 Oxidative stress is integral to the secondary injury cascade in SCI, culminating in neuronal apoptosis and autophagy.99 Inflammation and oxidative stress frequently coexist, operating via a reciprocal feedback loop.99,100 Oxidative stress leads to inflammation through nuclear factor kappa-B (NF-κB) and other pathways, in turn, inflammation is associated with the induction of intracellular oxidative stress in mitochondria and endoplasmic reticulum.101,102,103,104 Given the fact that oxidative stress and inflammation can be reactivated via compensatory pathways resulting in treatment failure, some studies have proposed a dual therapeutic anti-oxidant and anti-inflammatory effect of Omega-3 fatty acids on acute SCI.85,95,105 These dual properties also act synergistically.99 For instance, King et al.106 and Huang et al.87 report that intravenous injection of DHA, 30 min post-SCI, effectively suppressed cellular oxidative stress and minimized the extent of the injury area through the reduction of lipid peroxidation, protein oxidation, RNA/DNA oxidation, and cyclooxygenase-2 (COX-2) levels. Additionally, apart from the direct regulation of acute SCI oxidative stress through intravenous administration, a long-term preventive Omega-3 fatty acids-rich diet was shown in the rat to enhance anti-oxidant defense by maintaining metabolic homeostasis after SCI.107 A recent study indicates that Omega-3 fatty acids lessen endoplasmic reticulum stress-induced neuroinflammation after SCI by inhibiting histone deacetylase 3, thus advancing neurological functional recovery.108 Considering the interconnected molecular pathways, the administration of anti-oxidant and anti-inflammatory treatments with the same medication may lead to improved comprehensive efficacy.105 Therefore, Omega-3 fatty acids present significant potential for enhancing SCI outcomes due to these antioxidant and combined effects. Further elucidation of common anti-inflammatory and anti-oxidant pathways such as erythroid 2-Related Factor 2 and NF-κB would be advantageous for exploring the potential of Omega-3 fatty acids.
Regeneration of neural circuits
Activated microglia and macrophages migrate toward the SCI site, leading to glial hyperplasia, extracellular matrix remodeling, and the formation of a fibrous scar within the lesion.109 Reactive astrocytes, oligodendrocyte precursors, and microglia also contribute to the formation of glial scars surrounding the fibrous scar.109 The glial scar border forms to segregate the neural lesion and to isolate spreading inflammation, ROS, and excitotoxicity at the injury epicenter to preserve surrounding healthy tissue.110 While this physiological response preserves viable neural tissue, it is also detrimental to axon sprouting and neural regeneration.109,110 The presence of chondroitin sulfate proteoglycans (CSPGs) and Nogo-A around the glial scar poses a significant challenge to the regeneration of nerve axons and synapses.1 In the spinal cord, the myelin sheath is formed by oligodendrocytes that wrap around nerve axons, aiding in the conduction of nerve impulses.111 After SCI, the apoptosis of oligodendrocytes leads to demyelination of neurons.112 Reducing the damage to myelin, removing damaged myelin debris, and promoting remyelination are potential approaches thereby safeguarding adjacent neurological function.113,114
The direct effect of Omega-3 fatty acids on neural circuits that promote regeneration has been observed in various neurodegenerative and nerve injury models.83 The efficacy of these fatty acids in promoting nerve restoration has also been demonstrated in studies involving corneal nerve injury,115 depression,116 and other conditions, where a high Omega-3 fatty acids diet or local administration has yielded favorable outcomes. Within the complex microenvironment of SCI, Omega-3 fatty acids exhibit the capacity to target glial scars and neurons, thereby facilitating the reconstruction of neural circuits.86,117 The molecular mechanism underlying the reduction of scar formation involves the inhibition of astrocyte hyperplasia118,119; Omega-3 fatty acids can reduce the expression of the astrocyte hyperplasia marker, glial fibrillary acidic protein (GFAP), thereby inhibiting scar formation.86 One of the most widely studied molecular mechanisms underlying the neurotrophic effects of Omega-3 fatty acids is the promotion of brain-derived neurotrophic factor (BDNF) production.120,121 BDNF plays a crucial role in neuroprotection and axonal growth in SCI and it regulates neuron apoptosis through glycogen synthase kinase-3 (GSK-3) and B-cell lymphoma-2 (Bcl-2).122 In a model of chronic spinal cord compression injury, dietary administration of low doses of Omega-3 fatty acids combined with curcumin significantly increased the BDNF content in the injured spinal cord, compared to a Western diet high in saturated fats.123 Omega-3 fatty acids have the potential to enhance neuroplasticity, promote synaptogenesis, and germination of the intact corticospinal tract, particularly 5-hydroxytryptamine fibers, when combined with rehabilitative exercise.117 The underlying mechanisms include the upregulation of miRNA-21 and phosphorylated protein kinase B(AKT) and the downregulation of phosphatase and tensin homolog (PTEN).124 Omega-3 fatty acids have been shown to prevent neuron demyelination by inhibiting oligodendrocyte apoptosis.84 However, it is important to note that phagocytosis of myelin debris by activated macrophages plays a crucial role in improving the SCI microenvironment114 (Fig. 2). These factors must be considered when balancing the effects of Omega-3 fatty acids in inhibiting oligodendrocyte apoptosis and with the potential downside of suppressing macrophage activation, which can ultimately reduce the clearance of harmful myelin debris. To optimize treatment strategies, determining the appropriate dosage is essential while considering both short-term and long-term biological effects.
Overview of Omega-3 fatty acids facilitating the repair of spinal cord injury by the regeneration of neural circuits. In spinal cord injury, the destruction of neural circuits is accompanied by the aggregation of astrocytes, microglia, and macrophages at the site of injury, resulting in glial scar formation. Oligodendrocyte apoptosis leads to demyelination in functional neurons, while neuronal death directly contributes to further neural circuit disruption. Omega-3 fatty acids mitigate the pathological damage through multiple mechanisms: ①Preventing oligodendrocyte apoptosis and neuronal demyelination by inhibiting inflammation; ②Inhibiting the release of chondroitin sulfate proteoglycans (CSPGs) and Nogo-A, thereby improving axon regeneration; ③Reducing GFAP expression and astrocyte hyperplasia to minimize dense glial scar formation; ④Promoting the production of brain-derived neurotrophic factor (BDNF) which regulates apoptosis through GSK-3 and Bcl-2 pathways; ⑤Upregulating miRNA-21 while downregulating PTEN to improve synaptogenesis
Other mechanisms
Polyunsaturated fatty acids predominantly reside within the membrane structure of human cells, playing a vital role in stabilizing the membrane, supporting the repair of damaged plasma membranes, facilitating the healing of damaged plasma membranes and modulating ion channels.125,126 Research has demonstrated that Omega-3 fatty acids help preserve membrane fluidity in the brain, which is essential for normal neuromotor and cognitive function.104,127 At the chronic stage of SCI, a diet high in Omega-3 fatty acids and curcumin led to a significant increase in syntaxin-3 and a reduction in 4-hydroxynonenal levels in the lumbar enlargement, indicating a possible healing effect on the plasma membrane.123 The integration of Omega-3 fatty acids into cell membranes affects signal transduction.128 Omega-3 fatty acids can inhibit neuronal depolarization by blocking voltage-sensitive calcium and sodium channels while activating double-pore potassium channels, thereby reducing in the excitability of hippocampal and spinal cord neurons, and mitigating neurotoxicity caused by the outward flow of glutamic acid.129,130 Ion channel regulation in the nervous system may be a key mechanism by which fatty acids influence SCI, suggesting that an electrophysiological perspective as a viable approach for addressing SCI.
Omega-3 fatty acids have been shown to disrupt lipid raft domains, which are cholesterol- and phospholipid-rich microenvironments in cell membranes, thereby altering the function and distribution of proteins residing in these domains.131,132 Toll-like receptor 4 (TLR4) is important in receiving various pro-inflammatory signals, such as DAMPs and pathogen-associated molecular patterns (PAMPs), following CNS injury.133 DHA inhibits the translocation of TLR4 to the cell membrane, thereby mitigating the inflammatory response of microglia.134
Resolvins D1 and D2 have been demonstrated to inhibit the activation of the Transient Receptor Potential Vanilloid 1 (TRPV1) and Ankyrin 1 (TRPA1) ion channels by perturbing the integrity of lipid rafts in the plasma membranes of sensory neurons. This disruption leads to a modulation of the receptors’ electrical potential, which in turn facilitates peripheral analgesia.135
The therapeutic efficacy of Omega-3 fatty acids in SCI extends beyond the fatty acids themselves to include beneficial effects mediated by their metabolites and synthetic derivatives.136 Specifically, supplementation with synaptic amide, a molecule derived from DHA, has been shown to enhance axonal growth and synaptogenesis, while reducing a reduction in inflammatory responses.137,138 These effects are mediated by GPR110, a receptor distinct from GPR120, which is targeted by Omega-3 fatty acids.139 Resolvin is an endogenous lipid mediator generated from Omega-3 fatty acids and its metabolite.140 In addition to their potent anti-inflammatory effects, resolvins also modulate leukocyte trafficking and enhance the non-inflammatory phagocytosis of apoptotic neutrophils by macrophages, thereby reconciling the dichotomy between anti-inflammatory and pro-phagocytic mechanisms in mice.141,142,143 A recent study confirmed that Resolvin D3 can promote angiogenesis after SCI.136 Investigating into the metabolites or synthetic derivatives of Omega-3 fatty acids and their molecular pathways has yielded novel perspectives on potential pharmacological interventions.
Thus far, several molecules have been identified as key mediators of Omega-3 fatty acids transport and cellular uptake. Up-regulation of fatty acid-binding protein 5 (FABP5) following SCI is associated with alterations in long-chain polyunsaturated fatty acids metabolism.94 Administration of small interfering RNA targeting FABP5 hinders the Omega-3 fatty acids-mediated improvement in locomotor function.94 FABP5-/- mice have been shown to exhibit reduced uptake of exogenous DHA by brain endothelial cells and cerebral capillaries, leading to decreased endogenous DHA levels in the brain parenchyma and subsequent cognitive deficits.144 CD36 facilitates esterification, enhancing fatty acids uptake without directly catalyzing transmembrane translocation of fatty acids.145 Fatty Acid Transport Protein 1, located in the cerebral microvascular basement membrane, catalyzes the translocation of DHA into the brain, increased membrane translocation thereby expediting the cerebral DHA replenishment146 (Table 2).
Therapeutic effects of omega-3 fatty acids on complications of spinal cord injury
For an extended period following spinal cord injury (SCI), patients are susceptible to various health complications, including neuropathic pain, osteoporosis, and obesity. These complications arise as a result of prolonged bed rest due to paralysis, hyperinflammatory states, and metabolic disorders.4,147,148,149,150 Omega-3 fatty acids are known to exhibit comprehensive effects on systemic diseases.151,152 Thus, it is hypothesized that Omega-3 fatty acids may play a role in alleviating complications in the chronic phase of SCI.
Neuropathic pain
Neuropathic pain (NP) is a persistent and challenging complication of SCI that significantly impacts the patient’s quality of life.148 While traditional pain management strategies are often ineffective in managing NP,153 various studies in recent years have shown that Omega-3 fatty acids show potential in alleviating these symptoms. Figueroa et al.154 found that feeding rats an Omega-3 fatty acids-enriched diet for 8 weeks before SCI significantly reduced NP sensitivity. Functional neurometabolomic analysis revealed a significant dysregulation in the metabolism of endocannabinoids and related N-acyl ethanolamines (NAEs) at 8 weeks post-SCI. NAEs and endocannabinoids are bioactive lipids mediators that play crucial roles in the regulation of pain signaling pathways.155 They exert their effects primarily through cannabinoid receptors, which are involved in modulating neuropathic pain following spinal cord injury.156 Consumption of Omega-3 fatty acids led to a substantial accumulation of new NAE precursors and reduction in inositols, which are known biomarkers of chronic neuropathic pain. Omics analysis provided new evidence that Omega-3 fatty acids improve the anti-hyperalgesic phenotype at the metabolic level. This analgesic effect can also be attributed to decreased sprouting of calcitonin gene-related peptide (CGRP) nociceptive fibers and the downregulation of p38 MAPK in the dorsal horn.154 Additionally, the intrathecal administration of Resolvin for a period of 3 weeks after SCI in mice was found to prevent mechanical allodynia and heat hyperalgesia by inhibiting microgliosis and TNF-α release.157 At the same time, preclinical and clinical investigations have demonstrated that Omega-3 fatty acids can alleviate NP resulting from chronic sciatic nerve compression injury and diabetic peripheral neuropathy by activating the opioid system.158,159,160,161 In addition, some research suggests that Omega-3 fatty acids may have potential as analgesics. Omega-3 fatty acids and their derivatives can regulate pain-related Transient Receptor Potential (TRP) channels, such as TRPV1, TRPV3, TRPA1, and TRPM8.162,163 These channels play a role in pain treatment by modulating ion channel signaling. However, clinical data on the analgesic effects of Omega-3 fatty acids are still limited.164
Osteoporosis
Osteoporosis is a systemic bone disease characterized by decreased bone mass and impaired bone microstructure, leading to bone fragility and increased fracture risk.165 Osteoporosis is one of the main complications among patients with SCI.166 Although the impact of SCI on bone vary depending on the skeletal site, sex, and age,167 most individuals with complete motor SCI develop significant bone loss or osteoporosis below the level of injury.168 Studies indicate that about 40% of patients with chronic SCI develop osteoporosis and fractures, facing twice the risk of those without SCI.169 The most common sites for fractures due to SCI-related osteoporosis are the proximal tibia, followed by the distal femur.170 Individuals with SCI typically exhibit rapid and severe bone density loss, significantly increasing their risk of developing osteoporosis.171,172 This bone loss occurs in two distinct phases. During the acute phase of SCI, both osteoblastic and osteoclastic activity initially increase, followed by a shift characterized by elevated osteoclastic activity and suppressed osteoblastic activity.173,174 This suppression of osteoblastic activity persists for several months post-injury before returning to pre-injury levels. In the chronic phase, the body exhibits sustained elevated osteoclastic activity and bone resorption.175,176
Neuron impairment in patients may lead to upregulation of receptor activator of NF-κB ligand (RANKL) and dysregulation of Wnt signaling in bones, thereby promoting bone resorption and inhibiting osteogenesis.177 In addition, the inflammation associated with SCI is one of the major pathological mechanisms leading to this complication.177,178 IL-1, IL-6, TNF-α, and prostaglandin E2 (PGE2) have been identified as stimulators of bone resorption.179
Over two decades ago, researchers confirmed that Omega-3 fatty acids, among various dietary fatty acids, can regulate osteogenic and osteoclastic functions while enhancing bone density in animal models.180,181 In vitro and in vivo studies prove that EPA can regulate inflammation-related factors, including PGE2, IL-6, and TNF-α, by reducing AA levels on cell membranes.180 Additionally, EPA can upregulate insulin-like growth factors 1 (IGF-1), regulate inflammation, inhibit bone resorption, and promote bone formation.180,182 Resolvins also have a significant protective effect on bone loss caused by inflammation.183
One of the primary physiological functions of Omega-3 fatty acids is maintaining cell membrane homeostasis, prompting researchers to investigate their impact on the plasma membrane.184 This investigation revealed that DHA-induced lipid profiles create more stable membrane microdomains and increase protein kinase B activity, thus promoting mesenchymal stem cell differentiation into osteoblasts.184 From the perspective of nutrition, Omega-3 fatty acids can enhance calcium absorption by activating ATPase activity in the duodenum, thus improving bone density.185 Omega-3 fatty acids may exert significant therapeutic effects on osteoporosis primarily through GPR120. Activation of GPR120 was shown to stimulate osteoblast differentiation and mineralization while inhibiting osteoclast differentiation and activity in a mice model of osteoporosis.186,187 The GPR120 signaling pathway can also inhibit osteoclast formation and bone resorption by inhibiting ROS production188 (Fig. 3).
Effects of Omega-3 fatty acids on spinal cord injury complications. Post spinal cord injury, Omega-3 fatty acids attenuate pathological neuropathic pain by inhibiting pathological CGRP sensory neuron neogenesis, microgliosis, TNF-α release and p38-MAPK expression in the dorsal horn neuron of the spinal cord. Omega-3 fatty acids reduce bone resorption by inhibiting the secretion of pro-inflammatory relative molecules such as PGE2, TNFα, and IL-6 in bone. Omega-3 fatty acids promote intestinal uptake of calcium ions through activate ATPase and secretion of IGF-1 in bone, thus enhancing bone formation. Omega-3 fatty acids reduce macrophage infiltration by inhibiting the secretion of MCP-1 in adipose tissue and inhibiting the secretion of IL-6 and IL-10 thereby reducing the formation of adipose tissue. Also, GPR120 coupling with Gs can promote adipogenesis, while the lipid content within each adipocyte remains low, ultimately improving overall metabolic health. Omega-3 fatty acids activate GPR120 on intestinal epithelial cells, which enhances the uptake of CCK, and thus suppresses appetite
Nevertheless, it should not be ignored that two randomized controlled trials on osteoporosis in SCI patients and healthy susceptible people did not produce evidence supporting the increase of bone density through dietary Omega-3 fatty acids supplementation.189,190 Further research is therefore required to elucidate the potential effects of Omega-3 fatty acids in preventing or mitigating osteoporosis in healthy individuals, as well as treating osteoporosis in patients with SCI, and determining the optimal dosage necessary to achieve the desired outcome.
Obesity
Obesity—identified by body fat percentages exceeding 22% in males and 35% in females—is frequently observed among patients with SCI, with a prevalence rate of 85%.191 Obesity is a metabolic disorder characterized by an imbalance between energy intake and expenditure, leading to excessive fat accumulation.192 In individuals with SCI, this disorder is further exacerbated by inevitable muscle atrophy, impaired anabolic metabolism, and sympathetic dysfunction. These pathophysiological changes contribute to a marked reduction in overall metabolic rate through the spinal cord–adipose tissue axis and spinal cord-liver axis.192,193,194,195 Additionally, individuals with SCI often spend prolonged periods sitting and have notably reduced physical activity.196 These factors collectively disrupt energy balance, leading to alterations in body composition and resulting in neurogenic obesity. This neurogenic obesity places individuals at heightened risk for systemic inflammation, hyperglycemia, dyslipidemia, and hypertension.197,198 Previous studies have established that SCI patients have 8.5% to 13% more body fat per unit of body weight compared to able-bodied controls.199,200,201,202 Furthermore, one study found that myopenic obesity was prevalent in 41.9% of the sample population. Notably, appendicular lean mass index (ALMI) was lower in participants with complete motor injuries compared to those with incomplete motor injuries.203 Overall, these data suggest a remarkably high frequency of myopenic obesity in chronic SCI individuals.
Obesity further aggravates complications of SCI, including NP and type 2 diabetes.204,205 Therefore, prioritizing the management of obesity is essential for the management of other complications. A systematic review has evaluated different strategies for addressing obesity in patients with SCI, such as physical exercise, neuromuscular electric stimulation (NMES) or functional electric stimulation (FES), pharmacotherapy, surgery, and diet therapy.206 However, these approaches either produce additional adverse effects in individuals with SCI or yield minimal clinical benefits. Therefore, patients with SCI urgently need better treatment strategies with fewer side effects to control obesity.
Obesity is recognized as a chronic low-grade inflammatory condition.207 There is substantial evidence that Omega-3 fatty acids supplementation can help prevent obesity or further weight gain. Anti-inflammation is the most commonly mentioned mechanism.204,208 On the one hand, supplementation with DHA and EPA effectively attenuates adipose inflammation by reducing the production of pro-inflammatory cytokines, including monocyte chemotactic protein-1 (MCP-1), IL-6, and resistin, while simultaneously increasing the release of anti-inflammatory cytokines, such as adiponectin and IL-10 in mice adipose tissue.209,210 Additionally, in obese individuals, Omega-3 fatty acids reduce M1 macrophage infiltration, curb the generation of Omega-6-derived pro-inflammatory lipid mediators, and provide substrates for pro-resolutive lipid mediators.211,212
Meanwhile, GPR120 promotes adipogenesis through TULP3-dependent ciliary localization: under Omega-3 fatty acids stimulation, GPR120 enhances cAMP secretion, subsequently, activating EPAC signaling, CTCF-dependent chromatin remodeling, and transcriptional activation of PPARγ and CEBPα to initiate adipogenesis.30 Although GPR120 coupling with Gs can promote adipogenesis, particularly by increasing the number of adipocytes, the lipid content within each adipocyte remains low. This mechanism fosters hyperplastic expansion of white adipose tissue rather than ectopic fat deposition in other tissues, ultimately improving overall metabolic health. This finding provides a new explanation for the role of Omega-3 fatty acids in the treatment of obesity and their anti-diabetic effects.30
In addition to playing a role at the metabolic level, Omega-3 fatty acids can also help with weight loss by suppressing hunger42,213 and promoting postprandial satiety,214,215 thus reducing food intake (Fig. 3; Table 3).
Gpr120 as a novel GPCR target for spinal cord injury treatment
GPCRs in spinal cord injury mechanisms and therapeutic potential
GPCRs constitute the largest family of membrane-bound receptors in the human genomes, playing pivotal roles in regulating various physiological and pathological processes.216 GPCRs exert significant influence on SCI, critically modulating secondary injury and repair processes. Studies have shown that many GPCRs are vital for regulating neuroinflammation, a hallmark of secondary injury after SCI, driven by cytokine, chemokine, and immune cell activation.217 CX3CR1, a microglia-enriched chemokine receptor activated by CX3CL1, plays a critical role in the regulation of neuroinflammation after SCI by regulating the interactions between neurons, microglia, and immune cells.218,219 In addition, protease activated receptor 1 (PAR1) and protease activated receptor 2 (PAR2) also play important roles in the inflammatory response after SCI.220,221 PAR1 knockout could improve motor recovery, decrease the proliferation of inflammatory cells, and reduce the levels of pro-inflammatory cytokines such as IL-1β and IL-6 in mice.220 Similarly, knockdown of the PAR2 gene also resulted in a significant improvement of motor recovery in SCI mice, as well as a reduction in the secretion of pro-inflammatory cytokines including IL-6, TNF-α and IL-1β.221 This suggests that PAR1 and PAR2 serve as novel drug targets to suppress neuroinflammation. The GPCR family further includes GPR34 and GPR55 as key inflammatory modulators.222,223 GPR34 knockout resulted in reduced levels of pro-inflammatory cytokine and inhibited the pro-inflammatory response of microglia in mice.224 GPR55 also acts as a key target in the regulation of neuroinflammation, and its agonist CID16020046 has a favorable anti-inflammatory effect by activating GPR55 and thereby mediating the JAK2/STAT3 pathway to alleviate neuroinflammation in rats.225 Adhesion GPCRs play diverse roles in neurogenesis and metabolic homeostasis.226 A defining feature of adhesion GPCRs is their large extracellular N-terminal fragment, which serves as an ideal target site for the development of therapeutic antibodies or allosteric modulators.227 This characteristic offers significant potential for designing highly effective anti-inflammatory treatments for SCI.228
Except inflammation, GPCRs are increasingly recognized as having therapeutic potential in NP.229 Studies show that GPR160 expression increases in the rodent dorsal horn of the spinal cord after SCI, and inhibiting GPR160 prevents and reverses NP in rodents without changing normal pain responses. Also, inhibition of GPR160 in the spinal cord attenuated sensory processing in the thalamus, a key relay station in the pain sensory discrimination pathway. These results identify GPR160 as a key factor and potential therapeutic target for NP.230 Sphingosine-1-phosphate receptor (S1PR) is also a therapeutic target for NP, and its agonist fingolimod (FTY720) attenuates nociception in preclinical pain models through either activation (agonism) or inhibition (functional antagonism) of S1PR.231,232 Other GPCRs that play important roles in NP such as GalR2, GPRC5B and GPR151, are also crucial for the development of drugs related to the treatment of NP.233,234,235 Intriguingly, Omega-3 fatty acids also exhibit dual therapeutic potential in modulating neuroinflammation and alleviating neuropathic pain, but the receptor on which they exert their effects remain unclear.
Recognition pattern of Omega-3 fatty acids double bonds by GPR120
With seven transmembrane helices, GPR120 can activate multiple downstream effectors, including G proteins (such as Gs, Gi/o, Gq/11) and arrestins (such as β-arrestin1, β-arrestin2).236
In a recent study, Mao et al. elucidated the signal transduction mechanism of GPR120 in detail: the study utilized single-particle cryo-electron microscopy to achieve a high-resolution structure of the GPR120-G protein complex with different ligands, including EPA, 9-hydroxystearic acid (9-HSA), oleic acid (OA), linoleic acid (LA), and synthetic compound ligand TUG891. They identified a series of aromatic residues that were able to individually recognize specific double C-C bonds present in unsaturated fatty acids. In particular, each of these aromatic residue arrays, such as Phenylalanine (F27N-term, F28N-term, F882.53, F1153.29, F2115.42, and F3037.35) and Tyrosine (W198ECL2, W2075.38, W277 6.48), recognizes one to three double bonds at specific positions of these unsaturated fatty acids. Further experimental verification revealed that these aromatic residues recognize double bonds through π:π interactions and maintain defined angles and distances, which in turn affect different downstream signal transduction.39
This discovery fills the gap in long-chain fatty acids recognition by G protein-coupled receptors. It revealed that the GPR120 has at least nine aromatic residues that selectively recognize the arrangement of double bonds at different positions in unsaturated fatty acids, converting them into distinct signal outputs to create a piano key-like encoding system. Consequently, the study proposes a “piano keyboard” model for the recognition of aromatic residues in GPR120 and double C-C bonds in unsaturated fatty acids. The “keyboard” is made up of a series of double bonds in the unsaturated fatty acids, while specific aromatic residues of GPR120 act as the “fingers”. When in contact with the “keyboard” of unsaturated fatty acids, these “fingers” produce distinct “tunes” to guide biological functions. Based on these findings, unsaturated fatty acids can be modeled as “keyboard models” with different double bond modifications at specific locations that selectively connect to preference signal transduction pathways. By understanding the structural features of unsaturated fatty acids recognized by GPR120, it may be possible to develop more high-selective and effective therapies for a range of diseases (Fig. 4).
Overview of recognition mechanism and functions of Omega-3 fatty acids and GPR120. The free fatty acid receptor GPR120 specifically recognizes the C–C double bonds present in Omega-3 fatty acids, through π:π interactions between aromatic residues (Phenylalanine and Tyrosine) and double bonds. The interaction patterns of different C–C double bonds among various Omega-3 fatty acids within the ligand pocket of GPR120 are translated into different signaling outcomes via distinct propagating paths. The Gq pathway(red) of GPR120 stimulates GLP-1 secretion from intestinal L cells, while Gi-mediated signaling(orange) is necessary for GPR120 to suppress Ghrelin secretion in stomach cells. GPR120’s Gs(green) function is crucial for maintaining ciliary fat homeostasis. Additionally, GPR120’s anti-inflammatory effects are facilitated through its interaction with the β-arrestin2 pathway(purple). Blue arrow and notes suggest a possible role for β-arrestin1, whose function remains less defined. Blue sphere and letters on the left side of GPR120 represent the Phenylalanine. purple sphere and letters on the right side represent purple sphere and letters on the right side represent the Tyrosine
In this study, the authors discovered that compared to the saturated fatty acids 9-HSA, EPA forms multiple additional π-π interactions via double bonds on its carbon chain with F27N-term, F1155.39, W1985.38, W2075.38, F2115.42 and F3037.35. Molecular biological experiments revealed that mutations F882.53 A, F2115.42 L and F3037.35 A exerted significantly greater impacts on the Gs signaling pathway mediated by GPR120 than on the Gi signaling pathway, indicating that these three residues recognizing double bonds iii, vi, and xii determine the Gs-biased signaling properties. These findings suggest that distinct π-π interactions between aromatic amino acids on the receptor and the double bonds of the Omega-3 fatty acids EPA drive GPR120-mediated activation of different downstream signaling pathways.39 Clarifying the structural basis of ligand-receptor interactions is critical for new drug development.237,238,239 This study will facilitate the development of high-selective GPR120 agonists and selectively exert their beneficial effects. In addition, by optimizing the specific action sites of ligands, the development of highly selective and high-affinity ligands will effectively reduce the dose of drugs, thereby reducing the occurrence of side reactions and improving the safety of drugs. The piano keyboard model elucidates the recognition pattern of Omega-3 fatty acids and GPR120 under molecular level, which will help us to further explore the function of GPR120 after SCI and develop high-selective and high-affinity drugs for SCI treatment.
Molecular pathway and effects of Omega-3 fatty acids mediated by GPR120
Activation of GPR120 is known to engage various downstream effectors, including G proteins and arrestins, to exert diverse biological functions.236 For example, GPR120 facilitates the recruitment of Gq to the plasma membrane. These proteins then interact with phospholipase C-beta, initiating the hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2) to produce inositol 1,4,5-trisphosphate (IP3) and diacylglycerol (DAG). The increased IP3 then triggers the release of Ca2+, which plays important roles in mediating hormone secretion and glucose uptake.240,241 Activation of the Gq pathway promotes glucagon-like peptide-1 (GLP-1) secretion from pancreatic islet cells and enhances insulin release, thereby reducing blood glucose levels.242,243
Another downstream effector of GPR120 is Gi, which inhibits adenylate cyclase activation, resulting in decreased cyclic adenosine monophosphate (cAMP) levels. Moreover, activation of the Gi can lead to the stimulation of other signaling pathways, including the mitogen-activated protein kinase (MAPK) pathway, which can lead to the phosphorylation of a variety of downstream targets, including transcription factors and other signaling proteins.236,241,244 Some researchers found that activation of the Gi pathway can reduce the secretion of ghrelin by enteroendocrine cells.245 Other studies have indicated that GPR120 couples with Gi proteins in delta cells, resulting in reduced somatostatin secretion under glucose stimulation conditions.246
GPR120 couples with Gs to stimulate adenylate cyclase activity and elevate intracellular cAMP levels. This activation triggers protein kinase A (PKA), leading to the phosphorylation of several downstream targets such as transcription factors, ion channels, and other signaling proteins.28,241,247
GPR120 can also couple with β-arrestin2: following G protein activation, GPCR kinases phosphorylate the GPCR cytoplasmic domain, creating phosphorylation motifs that recruit β-arrestin2, facilitating complex internalization or initiating separate signaling cascades that mediate distinct biological effects.241 The GPR120 pathway mediated by β-arrestin2 is crucial for the anti-inflammatory effects of Omega-3 fatty acids: activated β-arrestin2 can prevent inflammation-driven diseases by inhibiting NLRP3 inflammasome assembly.29 Moreover, the anti-inflammatory effects of β-arrestin2 are significantly beneficial for maintaining pancreatic stability and improving glucose metabolism.248 In addition, β-arrestin2 can interact with transforming growth factor-β-activated kinase 1 (TAK1) and transforming growth factor-β-activated binding protein 1 (TAB1), disrupting pro-inflammatory gene expression mediated by TAK1-TAB1, thus improving inflammatory neuropathy in microglia.249,250
Due to its extensive interactions with various downstream effectors, GPR120 has potential therapeutic implications for multiple diseases, including type 2 diabetes, obesity, and inflammation-driven diseases.55,251 Dysfunction of GPR120 may lead to obesity in mice and humans.252 Furthermore, a class of endogenous mammalian lipids (palmitic acid esters of hydroxy stearic acids), which have anti-diabetic and anti-inflammatory effects, was recently discovered, and they can enhance insulin-stimulated glucose uptake through GPR120.253 Moreover, GPR120 agonists can improve glucose tolerance, reduce hyperinsulinemia, increase insulin sensitivity, and improve islet inflammation in high-fat diet mice.248 Another research indicates that GPR120 is associated with the pathogenesis of both NAFLD and ALD.254,255 Activation of GPR120 has been shown to improve hepatic lipid metabolism and attenuate liver inflammation.256 These effects may contribute to the modulation of spinal cord injury pathology through the spinal cord–liver axis (Fig. 5).
Molecular pathway and effects of Omega-3 fatty acid mediated by GPR120. GPR120 couples with multiple G proteins (Gq, Gi, Gs) and β-arrestin2(βARR2) to regulate diverse physiological processes: (1)Gq activation recruits phospholipase C-beta (PLC-β), hydrolyzing phosphatidylinositol 4,5-bisphosphate (PIP2) into inositol 1,4,5-trisphosphate (IP3) and diacylglycerol (DAG). IP3 triggers calcium ion (Ca²⁺) release from the endoplasmic reticulum, stimulating the secretion of glucagon-like peptide-1 (GLP-1). (2)Gi activation inhibits adenylate cyclase activity, leading to decreased cyclic adenosine monophosphate (cAMP) levels and inhibition of ghrelin secretion. (3)Gs activation enhances adenylate cyclase activity, increasing cAMP and activating PKA to maintain fat homeostasis. (4)βARR2 exerts anti-inflammatory effects by blocking pro-inflammatory gene expression mediated by the TAK1-TAB1 complex (such as TLR4/TNFR1 pathways) and suppressing NLRP3 inflammasome assembly
Apart from its critical role as a drug target in glucose and lipid metabolism disorders, GPR120 functional imbalances can also contribute to the development of various other diseases. GPR120 has been implicated in the regulation of bone metabolism and the development of osteoporosis: activation of GPR120 has been shown to stimulate osteoblast differentiation and mineralization while inhibiting osteoclast differentiation and activity in animal models of osteoporosis.186,187 Furthermore, the GPR120 signaling pathway can inhibit osteoclast formation and resorption by suppressing reactive oxygen species (ROS) production.188
In summary, GPR120 significantly influences various metabolic diseases primarily through its anti-inflammatory functions. Research into the molecular structure and signal transduction mechanism of GPR120 can provide fresh insights into the prevention and treatment of various metabolic diseases. GPR120 is expressed in spinal cord tissue, and its expression levels are increased after SCI.54 However, the precise role of GPR120 in the onset and progression of SCI remains poorly understood. Therefore, a full understanding of the downstream molecular pathway of GPR120 will help us to clarify the function of GPR120 in the occurrence and development of SCI. Targeting relevant molecular pathways through activation or inhibition of GPR120 signaling may represent a novel therapeutic approach for SCI treatment (Table 4).
Future perspectives for the clinical application of Omega-3 fatty acids
In contemporary medical practice, a comprehensive therapeutic approach has emerged, integrating diverse drug targets and surgical interventions, as well as strategies to enhance the body’s microenvironment and organ function. Ideally, these effects can be achieved by administering a single class of drugs capable of targeting multiple receptors.257,258,259,260,261 Omega-3 fatty acids—owing to their multifaceted properties which include anti-inflammatory, anti-oxidative, cell membrane protective, anti-apoptotic, and neurotrophic effects—demonstrate significant potential for modifying the microenvironment of SCI alongside the treatment and prevention of complications85,86,129,262 (Figs. 1, 2).
The administration route of Omega-3 fatty acids has been extensively investigated in numerous studies.263,264,265 Currently, Omega-3 fatty acids can be administered during the acute and chronic phases of SCI through oral supplementation and intravenous injection, respectively.84,88 Because of the necessity of prolonged oral intake to achieve Omega-3 fatty acids enrichment in cells and subsequent protective effects, one to three months of advance administration would be required.266 Moreover, given the practical difficulties of achieving the necessary high concentration by dietary intake alone, this approach is unlikely to be feasible in clinical settings.267 For acute administration, DHA and EPA are typically delivered intravenously 30 min after SCI.86,88,117,268,269 This acute intervention can rapidly target mechanisms active in the early stages of SCI, while dietary Omega-3 fatty acids may support the repair process.266 Accordingly, a combined strategy of intravenous Omega-3 fatty acid injection and oral supplementation should be considered in future clinical trial designs to provide ongoing protection following SCI.266 This perspective has been substantiated: a diet enriched with Omega-3 fatty acids, designed to mimic daily consumption, yielded therapeutic effects comparable to those of intravenous injection,88 while concurrent oral and intravenous administration resulted in a more pronounced therapeutic impact on SCI.269 Although several studies in animal models have reported the therapeutic effects of Omega-3 fatty acids on SCI, the optimal dose required to achieve maximum benefit remains uncertain.128,267
Dose optimization remains a critical challenge in studies investigating Omega-3 fatty acids administration. Unlike routine dietary consumption for disease prevention, SCI treatment necessitates higher doses that are not yet standardized for clinical use.72,270,271 High-dose administration is required to sufficiently activate GPR120 and achieve the desired therapeutic outcomes.38,39 Therefore, developing cost-effective and readily available alternatives to high-affinity fish oil represents an important step toward clinical application. Moreover, the development of GPR120 agonists and modulators of its downstream effectors has driven the search for effective Omega-3 fatty acid substitutes that could serve as future drug candidates for SCI treatment.272
Conclusion
Over the past two decades, numerous studies have documented the therapeutic potential of Omega-3 fatty acids for SCI treatment. Omega-3 fatty acids significantly enhance the inflammatory, inhibitory, and nutritional microenvironment after SCI, thereby facilitating the repair of compromised neural circuits. Their cell membrane modification function also suggests avenues for identification and development of novel therapeutic targets for SCI. In addition to their neuroprotective effects, Omega-3 fatty acids are instrumental in preventing and treating various complications following SCI, including obesity, neuropathic pain, and osteoporosis. This multifaceted action broadens the scope of Omega-3 fatty acids’ comprehensive therapeutic effects on SCI.
Furthermore, the recently elucidated signal transduction mechanism underpinning the interaction between GPR120 and Omega-3 fatty acids offers a strong theoretical basis for designing highly selective, high-affinity drugs that target this receptor. Future drug development for SCI should explore activating different downstream effectors of GPR120 to enhance efficacy, reduce dosage, and mitigate side effects. Based on the interaction between Omega-3 fatty acids and GPR120, the development of fish oil substitutes with improved clinical significance may pave the way for more comprehensive and targeted SCI treatment.
References
Fan, B., Wei, Z. & Feng, S. Progression in translational research on spinal cord injury based on microenvironment imbalance. Bone Res. 10, 35 (2022).
Anderson, M. A. et al. Natural and targeted circuit reorganization after spinal cord injury. Nat. Neurosci. 25, 1584–1596 (2022).
Fan, B. et al. Microenvironment imbalance of spinal cord injury. Cell Transplant. 27, 853–866 (2018).
Ahuja, C. S. et al. Traumatic spinal cord injury. Nat. Rev. Dis. Prim. 3, 17018 (2017).
Freund, P. et al. MRI in traumatic spinal cord injury: from clinical assessment to neuroimaging biomarkers. Lancet Neurol. 18, 1123–1135 (2019).
Global, regional, and national burden of neurological disorders, 1990-2016: a systematic analysis for the Global Burden of Disease Study 2016. Lancet. Neurol. 18, 459–480 (2019).
Kathe, C. et al. The neurons that restore walking after paralysis. Nature 611, 540–547 (2022).
Guan, C. et al. Stability of motor representations after paralysis. eLife 11, e74478 (2022).
Zheng, R. et al. A critical appraisal of clinical practice guidelines on surgical treatments for spinal cord injury. Spine J. 23, 1739–1749 (2023).
Guan, B. et al. A critical appraisal of clinical practice guidelines on pharmacological treatments for spinal cord injury. Spine J. 23, 392–402 (2023).
Zhou, H. et al. Epidemiological and clinical features, treatment status, and economic burden of traumatic spinal cord injury in China: a hospital-based retrospective study. Neural Regen. Res. 19, 1126–1133 (2024).
Huang, H. et al. Advances and prospects of cell therapy for spinal cord injury patients. J. Neurorestoratol. 10, 13–30 (2022).
Ma, C., Zhang, P. & Shen, Y. Progress in research into spinal cord injury repair: Tissue engineering scaffolds and cell transdifferentiation. J. Neurorestoratol. 7, 196–206 (2019).
Bracken, M. B. et al. Administration of methylprednisolone for 24 or 48 h or tirilazad mesylate for 48 h in the treatment of acute spinal cord injury. Results of the Third National Acute Spinal Cord Injury Randomized Controlled Trial. National Acute Spinal Cord Injury Study. JAMA 277, 1597–1604 (1997).
Roquilly, A. et al. French recommendations for the management of patients with spinal cord injury or at risk of spinal cord injury. Anaesth. Crit. Care Pain. Med. 39, 279–289 (2020).
Liu, L. J. W., Rosner, J. & Cragg, J. J. Journal Club: High-dose methylprednisolone for acute traumatic spinal cord injury: a meta-analysis. Neurology 95, 272–274 (2020).
Lee, J. H. et al. Lack of neuroprotective effects of simvastatin and minocycline in a model of cervical spinal cord injury. Exp. Neurol. 225, 219–230 (2010).
Geisler, F. H., Coleman, W. P., Grieco, G. & Poonian, D. The Sygen multicenter acute spinal cord injury study. Spine (Philos. Pa 1976) 26, S87–S98 (2001).
Kitzman, P. H. Effectiveness of riluzole in suppressing spasticity in the spinal cord injured rat. Neurosci. Lett. 455, 150–153 (2009).
Tuszynski, M. H. et al. Nerve growth factor delivery by gene transfer induces differential outgrowth of sensory, motor, and noradrenergic neurites after adult spinal cord injury. Exp. Neurol. 137, 157–173 (1996).
Marti-Solano, M. et al. Combinatorial expression of GPCR isoforms affects signalling and drug responses. Nature 587, 650–656 (2020).
Santos, R. et al. A comprehensive map of molecular drug targets. Nat. Rev. Drug Discov. 16, 19–34 (2017).
Hauser, A. S., Attwood, M. M., Rask-Andersen, M., Schiöth, H. B. & Gloriam, D. E. Trends in GPCR drug discovery: new agents, targets and indications. Nat. Rev. Drug Discov. 16, 829–842 (2017).
Fish oil supplements. Jama 312, 839-840 (2014).
Khan, I. et al. Omega-3 long-chain polyunsaturated fatty acids: Metabolism and health implications. Prog. lipid Res. 92, 101255(2023).
Kołodziej, Ł et al. How fish consumption prevents the development of Major Depressive Disorder? A comprehensive review of the interplay between n-3 PUFAs, LTP and BDNF. Prog. lipid Res. 92, 101254 (2023).
Jiang, J. H. et al. Identification of novel acinetobacter baumannii host fatty acid stress adaptation strategies. mBio 10, e02056–18 (2019).
Oh, D. et al. GPR120 is an omega-3 fatty acid receptor mediating potent anti-inflammatory and insulin-sensitizing effects. Cell 142, 687–698 (2010).
Yan, Y. et al. Omega-3 fatty acids prevent inflammation and metabolic disorder through inhibition of NLRP3 inflammasome activation. Immunity 38, 1154–1163 (2013).
Hilgendorf, K. I. et al. Omega-3 fatty acids activate ciliary FFAR4 to control adipogenesis. Cell 179, 1289–1305.e1221 (2019).
Okereke, O. et al. Effect of long-term supplementation with marine omega-3 fatty acids vs placebo on risk of depression or clinically relevant depressive symptoms and on change in mood scores: a randomized clinical trial. JAMA 326, 2385–2394 (2021).
Kagan, I. et al. Preemptive enteral nutrition enriched with eicosapentaenoic acid, gamma-linolenic acid and antioxidants in severe multiple trauma: a prospective, randomized, double-blind study. Intensive Care Med. 41, 460–469 (2015).
Billman, G., Kang, J. & Leaf, A. Prevention of sudden cardiac death by dietary pure omega-3 polyunsaturated fatty acids in dogs. Circulation 99, 2452–2457 (1999).
Hu, F. & Willett, W. Optimal diets for prevention of coronary heart disease. JAMA 288, 2569–2578 (2002).
Rist, P., Buring, J., Cook, N., Manson, J. & Rexrode, K. Effect of vitamin D and/or omega-3 fatty acid supplementation on stroke outcomes: a randomized trial. Eur. J. Neurol. 28, 809–815 (2021).
Vinding, R. et al. Effect of fish oil supplementation in pregnancy on bone, lean, and fat mass at six years: randomised clinical trial. BMJ (Clin. Res. ed.) 362, k3312 (2018).
Mayor, S. High dose fish oil supplements in late pregnancy reduce asthma in offspring, finds study. BMJ (Clin. Res. ed.) 356, i6861 (2016).
Oh, D. et al. A Gpr120-selective agonist improves insulin resistance and chronic inflammation in obese mice. Nat. Med. 20, 942–947 (2014).
Mao, C. et al. Unsaturated bond recognition leads to biased signal in a fatty acid receptor. Science 380, eadd6220 (2023).
de Carvalho, C. & Caramujo, M. J. The various roles of fatty acids. Molecules 23, 2583 (2018).
Kimura, I., Ichimura, A., Ohue-Kitano, R. & Igarashi, M. Free fatty acid receptors in health and disease. Physiol. Rev. 100, 171–210 (2020).
D’Angelo, S., Motti, M. L. & Meccariello, R. ω-3 and ω-6 Polyunsaturated fatty acids, obesity and cancer. Nutrients 12, 2751 (2020).
Djuricic, I. & Calder, P. C. Beneficial outcomes of omega-6 and omega-3 polyunsaturated fatty acids on human health: an update for 2021. Nutrients 13, https://doi.org/10.3390/nu13072421 (2021).
Nguyen, Q. V., Malau-Aduli, B. S., Cavalieri, J., Malau-Aduli, A. E. O. & Nichols, P. D. Enhancing omega-3 long-chain polyunsaturated fatty acid content of dairy-derived foods for human consumption. Nutrients 11, 743 (2019).
Horrocks, L. A. & Yeo, Y. K. Health benefits of docosahexaenoic acid (DHA). Pharmacol. Res. 40, 211–225 (1999).
Li, K., Sinclair, A. J., Zhao, F. & Li, D. Uncommon fatty acids and cardiometabolic health. Nutrients 10, 1559 (2018).
Lane, K., Derbyshire, E., Li, W. & Brennan, C. Bioavailability and potential uses of vegetarian sources of omega-3 fatty acids: a review of the literature. Crit. Rev. Food Sci. Nutr. 54, 572–579 (2014).
Shanab, S. M. M., Hafez, R. M. & Fouad, A. S. A review on algae and plants as potential source of arachidonic acid. J. Adv. Res. 11, 3–13 (2018).
Siriwardhana, N. et al. Modulation of adipose tissue inflammation by bioactive food compounds. J. Nutritional Biochem. 24, 613–623 (2013).
Poggioli, R., Hirani, K., Jogani, V. G. & Ricordi, C. Modulation of inflammation and immunity by omega-3 fatty acids: a possible role for prevention and to halt disease progression in autoimmune, viral, and age-related disorders. Eur. Rev. Med. Pharmacol. Sci. 27, 7380–7400 (2023).
Balić, A., Vlašić, D., Žužul, K., Marinović, B. & Bukvić Mokos, Z. Omega-3 versus Omega-6 polyunsaturated fatty acids in the prevention and treatment of inflammatory skin diseases. Int. J. Mol. Sci. 21, 741 (2020).
Saika, A., Nagatake, T. & Kunisawa, J. Host- and microbe-dependent dietary lipid metabolism in the control of allergy, inflammation, and immunity. Front. Nutr. 6, 36 (2019).
Kimura, I., Ichimura, A., Ohue-Kitano, R. & Igarashi, M. J. A. P. S. B., MD. Free fatty acid receptors in health and disease. Physiol. Rev. 100, 171–210 (2020).
Liu, J., Lv, Z. & Li, H. Upregulation of G-protein coupled receptor 120 in rats following spinal cord injury. Neurochem. Res 47, 921–932 (2022).
Milligan, G., Alvarez-Curto, E., Hudson, B. D., Prihandoko, R. & Tobin, A. B. FFA4/GPR120: pharmacology and therapeutic opportunities. Trends Pharmacol. Sci. 38, 809–821 (2017).
Wang, Y., Liu, H. & Zhang, Z. Recent advance in regulatory effect of GRP120 on bone metabolism. Aging Dis. 14, 1714–1727(2023).
Zhang, X. & Macielag, M. J. GPR120 agonists for the treatment of diabetes: a patent review (2014 present). Expert Opin. Ther. Pat. 30, 729–742 (2020).
Gensel, J. C. & Zhang, B. Macrophage activation and its role in repair and pathology after spinal cord injury. Brain Res. 1619, 1–11 (2015).
Lee, C. Y., Chooi, W. H., Ng, S. Y. & Chew, S. Y. Modulating neuroinflammation through molecular, cellular and biomaterial-based approaches to treat spinal cord injury. Bioeng. Transl. Med. 8, e10389 (2023).
Zhou, X. et al. Microglia and macrophages promote corralling, wound compaction and recovery after spinal cord injury via Plexin-B2. Nat. Neurosci. 23, 337–350 (2020).
Van Broeckhoven, J., Sommer, D., Dooley, D., Hendrix, S. & Franssen, A. Macrophage phagocytosis after spinal cord injury: when friends become foes. Brain J. Neurol. 144, 2933–2945 (2021).
David, S. & Kroner, A. Repertoire of microglial and macrophage responses after spinal cord injury. Nat. Rev. Neurosci. 12, 388–399 (2011).
Yong, V. & Rivest, S. Taking advantage of the systemic immune system to cure brain diseases. Neuron 64, 55–60 (2009).
Shechter, R. et al. Infiltrating blood-derived macrophages are vital cells playing an anti-inflammatory role in recovery from spinal cord injury in mice. PLoS Med. 6, e1000113 (2009).
Gadani, S. P., Walsh, J. T., Lukens, J. R. & Kipnis, J. Dealing with danger in the CNS: the response of the immune system to injury. Neuron 87, 47–62 (2015).
Gong, T., Liu, L., Jiang, W. & Zhou, R. DAMP-sensing receptors in sterile inflammation and inflammatory diseases. Nat. Rev. Immunol. 20, 95–112 (2020).
Hu, X. et al. Spinal cord injury: molecular mechanisms and therapeutic interventions. Signal Transduct. Target. Ther. 8, 245 (2023).
Hellenbrand, D. J. et al. Inflammation after spinal cord injury: a review of the critical timeline of signaling cues and cellular infiltration. J. Neuroinflammation 18, 284 (2021).
Norden, D. M. et al. Bone marrow-derived monocytes drive the inflammatory microenvironment in local and remote regions after thoracic spinal cord injury. J. Neurotrauma 36, 937–949 (2019).
Dietary supplementation with n-3 polyunsaturated fatty acids and vitamin E after myocardial infarction: results of the GISSI-Prevenzione trial Gruppo Italiano per lo Studio della Sopravvivenza nell’Infarto miocardico. Lancet 354, 447–455 (1999).
Manson, J. E. et al. Marine n-3 fatty acids and prevention of cardiovascular disease and cancer. N. Engl. J. Med. 380, 23–32 (2019).
Wei, B. Z., Li, L., Dong, C. W., Tan, C. C. & Xu, W. The Relationship of omega-3 fatty acids with dementia and cognitive decline: evidence from prospective cohort studies of supplementation, dietary intake, and blood markers. Am. J. Clin. Nutr. 117, 1096–1109 (2023).
Hill, C. L. et al. Fish oil in knee osteoarthritis: a randomised clinical trial of low dose versus high dose. Ann. Rheum. Dis. 75, 23–29 (2016).
Jobin, M. L. et al. Impact of membrane lipid polyunsaturation on dopamine D2 receptor ligand binding and signaling. Mol. Psychiatry 28, 1960–1969 (2023).
Wood, A. H. R., Chappell, H. F. & Zulyniak, M. A. Dietary and supplemental long-chain omega-3 fatty acids as moderators of cognitive impairment and Alzheimer’s disease. Eur. J. Nutr. 61, 589–604 (2022).
Custers, Emma, E. M., Kiliaan & Amanda, J. Dietary lipids from body to brain. Prog. lipid Res. 85, 101144 (2022).
Layé, S., Nadjar, A., Joffre, C. & Bazinet, R. Anti-inflammatory effects of omega-3 fatty acids in the brain: physiological mechanisms and relevance to pharmacology. Pharmacol. Rev. 70, 12–38 (2018).
Fernandez, R. et al. Acyl-CoA synthetase 6 is required for brain docosahexaenoic acid retention and neuroprotection during aging. JCI Insight 6, e144351 (2021).
Wellhauser, L. & Belsham, D. Activation of the omega-3 fatty acid receptor GPR120 mediates anti-inflammatory actions in immortalized hypothalamic neurons. J. Neuroinflammation 11, 60 (2014).
Chang, P., Khatchadourian, A., McKinney, R. & Maysinger, D. Docosahexaenoic acid (DHA): a modulator of microglia activity and dendritic spine morphology. J. Neuroinflammation 12, 34 (2015).
Mori, M. et al. Neuroprotective effect of omega-3 polyunsaturated fatty acids in the 6-OHDA model of Parkinson’s disease is mediated by a reduction of inducible nitric oxide synthase. Nutritional Neurosci. 21, 341–351 (2018).
Bailes, J. E. et al. Omega-3 fatty acid supplementation in severe brain trauma: case for a large multicenter trial. J. Neurosurg. 133, 598–602 (2020).
Jiang, X. et al. A post-stroke therapeutic regimen with omega-3 polyunsaturated fatty acids that promotes white matter integrity and beneficial microglial responses after cerebral ischemia. Transl. stroke Res. 7, 548–561 (2016).
Baazm, M., Behrens, V., Beyer, C., Nikoubashman, O. & Zendedel, A. Regulation of inflammasomes by application of omega-3 polyunsaturated fatty acids in a spinal cord injury model. Cells 10, 3147 (2021).
Bi, J. et al. Neuroprotective effect of omega-3 fatty acids on spinal cord injury induced rats. Brain Behav. 9, e01339 (2019).
Paterniti, I. et al. Docosahexaenoic acid attenuates the early inflammatory response following spinal cord injury in mice: in-vivo and in-vitro studies. J. Neuroinflammation 11, 6 (2014).
Huang, W. L. et al. A combination of intravenous and dietary docosahexaenoic acid significantly improves outcome after spinal cord injury. Brain J. Neurol. 130, 3004–3019 (2007).
Lim, S. N., Huang, W., Hall, J. C., Michael-Titus, A. T. & Priestley, J. V. Improved outcome after spinal cord compression injury in mice treated with docosahexaenoic acid. Exp. Neurol. 239, 13–27 (2013).
Trépanier, M. O., Hopperton, K. E., Orr, S. K. & Bazinet, R. P. N-3 polyunsaturated fatty acids in animal models with neuroinflammation: an update. Eur. J. Pharmacol. 785, 187–206 (2016).
Madore, C. et al. Nutritional n-3 PUFAs deficiency during perinatal periods alters brain innate immune system and neuronal plasticity-associated genes. Brain Behav., Immun. 41, 22–31 (2014).
Kang, J. X., Wang, J., Wu, L. & Kang, Z. B. Transgenic mice: fat-1 mice convert n-6 to n-3 fatty acids. Nature 427, 504 (2004).
Lim, S. N. et al. Transgenic mice with high endogenous omega-3 fatty acids are protected from spinal cord injury. Neurobiol. Dis. 51, 104–112 (2013).
Fujieda, Y. et al. Metabolite profiles correlate closely with neurobehavioral function in experimental spinal cord injury in rats. PLoS one 7, e43152 (2012).
Figueroa, J. D. et al. Fatty acid binding protein 5 modulates docosahexaenoic acid-induced recovery in rats undergoing spinal cord injury. J. Neurotrauma 33, 1436–1449 (2016).
López-Vales, R. et al. Fenretinide promotes functional recovery and tissue protection after spinal cord contusion injury in mice. J. Neurosci. J. Soc. Neurosci. 30, 3220–3226 (2010).
Allison, D. J., Beaudry, K. M., Thomas, A. M., Josse, A. R. & Ditor, D. S. Changes in nutrient intake and inflammation following an anti-inflammatory diet in spinal cord injury. J. Spinal Cord. Med 42, 768–777 (2019).
Norouzi Javidan, A. et al. Does consumption of polyunsaturated fatty acids influence on neurorehabilitation in traumatic spinal cord-injured individuals? A double-blinded clinical trial. Spinal cord. 52, 378–382 (2014).
Ong, G. & Logue, S. E. Unfolding the interactions between endoplasmic reticulum stress and oxidative stress. Antioxidants 12, 981 (2023).
Yu, M. et al. Oxidative stress following spinal cord injury: from molecular mechanisms to therapeutic targets. J. Neurosci. Res. 101, 1538–1554 (2023).
Hollyfield, J. et al. Oxidative damage-induced inflammation initiates age-related macular degeneration. Nat. Med. 14, 194–198 (2008).
Geng, Y. et al. Recent progress in the development of fluorescent probes for imaging pathological oxidative stress. Chem. Soc. Rev. 52, 3873–3926 (2023).
Singh, V. & Ubaid, S. Role of silent information regulator 1 (SIRT1) in regulating oxidative stress and inflammation. Inflammation 43, 1589–1598 (2020).
Muriach, M., Flores-Bellver, M., Romero, F. J. & Barcia, J. M. Diabetes and the brain: oxidative stress, inflammation, and autophagy. Oxid. Med. Cell. Longev. 2014, 102158 (2014).
Shchepinov, M. S. Polyunsaturated fatty acid deuteration against neurodegeneration. Trends Pharmacol. Sci. 41, 236–248 (2020).
Xiong, T. et al. Multifunctional integrated nanozymes facilitate spinal cord regeneration by remodeling the extrinsic neural environment. Adv. Sci. 10, e2205997 (2023).
King, V. R. et al. Omega-3 fatty acids improve recovery, whereas omega-6 fatty acids worsen outcome, after spinal cord injury in the adult rat. J. Neurosci. J. Soc. Neurosci. 26, 4672–4680 (2006).
Figueroa, J. D. & De Leon, M. Neurorestorative targets of dietary long-chain omega-3 fatty acids in neurological injury. Mol. Neurobiol. 50, 197–213 (2014).
He, L., Ye, J., Zhuang, X., Shi, J. & Wu, W. Omega-3 polyunsaturated fatty acids alleviate endoplasmic reticulum stress-induced neuroinflammation by protecting against traumatic spinal cord injury through the histone deacetylase 3/ peroxisome proliferator-activated receptor-γ coactivator pathway. J. Neuropathol. Exp. Neurol. 83, 939–950 (2024).
Tran, A., Warren, P. & Silver, J. The biology of regeneration failure and success after spinal cord injury. Physiol. Rev. 98, 881–917 (2018).
Clifford, T., Finkel, Z., Rodriguez, B., Joseph, A. & Cai, L. Current advancements in spinal cord injury research-glial scar formation and neural regeneration. Cells 12, 853 (2023).
Czepiel, M., Boddeke, E. & Copray, S. Human oligodendrocytes in remyelination research. Glia 63, 513–530 (2015).
Duncan, G. J. et al. The fate and function of oligodendrocyte progenitor cells after traumatic spinal cord injury. Glia 68, 227–245 (2020).
Zheng, B. & Tuszynski, M. H. Regulation of axonal regeneration after mammalian spinal cord injury. Nat. Rev. Mol. Cell Biol. 24, 396–413 (2023).
Zhou, T. et al. Microvascular endothelial cells engulf myelin debris and promote macrophage recruitment and fibrosis after neural injury. Nat. Neurosci. 22, 421–435 (2019).
Britten-Jones, A. C., Craig, J. P. & Downie, L. E. Omega-3 polyunsaturated fatty acids and corneal nerve health: current evidence and future directions. Ocul. Surf. 27, 1–12 (2023).
Song, C. & Wang, H. Cytokines mediated inflammation and decreased neurogenesis in animal models of depression. Prog. Neuro-Psychopharmacol. Biol. Psychiatry 35, 760–768 (2011).
Liu, Z. H., Yip, P. K., Priestley, J. V. & Michael-Titus, A. T. A single dose of docosahexaenoic acid increases the functional recovery promoted by rehabilitation after cervical spinal cord injury in the rat. J. neurotrauma 34, 1766–1777 (2017).
Pekny, M. & Pekna, M. Astrocyte reactivity and reactive astrogliosis: costs and benefits. Physiol. Rev. 94, 1077–1098 (2014).
Adams, K. L. & Gallo, V. The diversity and disparity of the glial scar. Nat. Neurosci. 21, 9–15 (2018).
Blondeau, N. et al. Subchronic alpha-linolenic acid treatment enhances brain plasticity and exerts an antidepressant effect: a versatile potential therapy for stroke. Neuropsychopharmacol. Publ. Am. Coll. Neuropsychopharmacol. 34, 2548–2559 (2009).
Kemse, N., Kale, A., Chavan-Gautam, P. & Joshi, S. Increased intake of vitamin B, folate, and omega-3 fatty acids to improve cognitive performance in offspring born to rats with induced hypertension during pregnancy. Food Funct. 9, 3872–3883 (2018).
Keefe, K. M., Sheikh, I. S. & Smith, G. M. Targeting neurotrophins to specific populations of neurons: NGF, BDNF, and NT-3 and their relevance for treatment of spinal cord injury. Int. J. Mol. Sci. 18, 548 (2017).
Holly, L. T. et al. Dietary therapy to promote neuroprotection in chronic spinal cord injury. J. Neurosurg. Spine 17, 134–140 (2012).
Liu, Z. H. et al. A single bolus of docosahexaenoic acid promotes neuroplastic changes in the innervation of spinal cord interneurons and motor neurons and improves functional recovery after spinal cord injury. J. Neurosci. J. Soc. Neurosci. 35, 12733–12752 (2015).
Billman, G. E. The effects of omega-3 polyunsaturated fatty acids on cardiac rhythm: a critical reassessment. Pharmacol. Therapeutics 140, 53–80 (2013).
Zhao, Z. et al. Docosahexaenoic acid reduces the incidence of early afterdepolarizations caused by oxidative stress in rabbit ventricular myocytes. Front. Physiol. 3, 252 (2012).
Saini, R. K. & Keum, Y. S. Omega-3 and omega-6 polyunsaturated fatty acids: Dietary sources, metabolism, and significance—a review. Life Sci. 203, 255–267 (2018).
Michael-Titus, A. T. & Priestley, J. V. Omega-3 fatty acids and traumatic neurological injury: from neuroprotection to neuroplasticity?. Trends Neurosci. 37, 30–38 (2014).
Vreugdenhil, M. et al. Polyunsaturated fatty acids modulate sodium and calcium currents in CA1 neurons. Proc. Natl. Acad. Sci. USA 93, 12559–12563 (1996).
Heurteaux, C. et al. TREK-1, a K+ channel involved in neuroprotection and general anesthesia. EMBO J. 23, 2684–2695 (2004).
Lingwood, D. & Simons, K. Lipid rafts as a membrane-organizing principle. Science 327, 46–50 (2010).
Kim, W. et al. n-3 polyunsaturated fatty acids suppress the localization and activation of signaling proteins at the immunological synapse in murine CD4+ T cells by affecting lipid raft formation. J. Immunol. 181, 6236–6243 (2008).
Wada, J. & Makino, H. Innate immunity in diabetes and diabetic nephropathy. Nat. Rev. Nephrol. 12, 13–26 (2016).
De Smedt-Peyrusse, V. et al. Docosahexaenoic acid prevents lipopolysaccharide-induced cytokine production in microglial cells by inhibiting lipopolysaccharide receptor presentation but not its membrane subdomain localization. J. Neurochem. 105, 296–307 (2008).
Payrits, M. et al. Resolvin D1 and D2 inhibit transient receptor potential vanilloid 1 and ankyrin 1 ion channel activation on sensory neurons via lipid raft modification. Int. J. Mol. Sci. 21, 5019 (2020).
Kim, J. et al. Resolvin D3 promotes inflammatory resolution, neuroprotection, and functional recovery after spinal cord injury. Mol. Neurobiol. 58, 424–438 (2021).
Raker, V. K., Becker, C. & Steinbrink, K. The cAMP pathway as therapeutic target in autoimmune and inflammatory diseases. Front. Immunol. 7, 123 (2016).
Lee, J. W. et al. Orphan GPR110 (ADGRF1) targeted by N-docosahexaenoylethanolamine in development of neurons and cognitive function. Nat. Commun. 7, 13123 (2016).
Kim, H. Y. & Spector, A. A. N-Docosahexaenoylethanolamine: a neurotrophic and neuroprotective metabolite of docosahexaenoic acid. Mol. Asp. Med. 64, 34–44 (2018).
Bäck, M. Icosapent ethyl in cardiovascular prevention: resolution of inflammation through the eicosapentaenoic acid-resolvin E1-ChemR23 axis. Pharmacol. Ther. 247, 108439 (2023).
Lee, H. N. & Surh, Y. J. Therapeutic potential of resolvins in the prevention and treatment of inflammatory disorders. Biochem. Pharmacol. 84, 1340–1350 (2012).
Liu, G. et al. Neuronal phagocytosis by inflammatory macrophages in ALS spinal cord: inhibition of inflammation by resolvin D1. Am. J. Neurodegener. Dis. 1, 60–74 (2012).
Park, C. K. et al. Resolvin D2 is a potent endogenous inhibitor for transient receptor potential subtype V1/A1, inflammatory pain, and spinal cord synaptic plasticity in mice: distinct roles of resolvin D1, D2, and E1. J. Neurosci. J. Soc. Neurosci. 31, 18433–18438 (2011).
Pan, Y. et al. Fatty acid-binding protein 5 at the blood-brain barrier regulates endogenous brain docosahexaenoic acid levels and cognitive function. J. Neurosci. J. Soc. Neurosci. 36, 11755–11767 (2016).
Xu, S., Jay, A., Brunaldi, K., Huang, N. & Hamilton, J. A. CD36 enhances fatty acid uptake by increasing the rate of intracellular esterification but not transport across the plasma membrane. Biochemistry 52, 7254–7261 (2013).
Ochiai, Y. et al. The blood-brain barrier fatty acid transport protein 1 (FATP1/SLC27A1) supplies docosahexaenoic acid to the brain, and insulin facilitates transport. J. Neurochem. 141, 400–412 (2017).
Lin, T. et al. A comprehensive study of long-term skeletal changes after spinal cord injury in adult rats. Bone Res. 3, 15028 (2015).
Ushida, T. et al. Mirogabalin for central neuropathic pain after spinal cord injury: a randomized, double-blind, placebo-controlled, phase 3 study in Asia. Neurology 100, e1193–e1206 (2023).
Dionyssiotis, Y. et al. Sarcopenic obesity in individuals with neurodisabilities: the SarcObeNDS Study. Front. Endocrinol. 13, 868298 (2022).
Raguindin, P. et al. Body composition according to spinal cord injury level: a systematic review and meta-analysis. J. Clin. Med. 10, 3911 (2021).
Lin, Z. et al. Cardiovascular benefits of fish-oil supplementation against fine particulate air pollution in China. J. Am. Coll. Cardiol. 73, 2076–2085 (2019).
Fu, Y. et al. Associations among Dietary Omega-3 Polyunsaturated Fatty Acids, the Gut Microbiota, and Intestinal Immunity. Mediators Inflamm. 2021, 8879227 (2021).
Jensen, M., Chodroff, M. & Dworkin, R. The impact of neuropathic pain on health-related quality of life: review and implications. Neurology 68, 1178–1182 (2007).
Figueroa, J. D. et al. Metabolomics uncovers dietary omega-3 fatty acid-derived metabolites implicated in anti-nociceptive responses after experimental spinal cord injury. Neuroscience 255, 1–18 (2013).
Hama, A. & Sagen, J. Activation of spinal and supraspinal cannabinoid-1 receptors leads to antinociception in a rat model of neuropathic spinal cord injury pain. Brain Res. 1412, 44–54 (2011).
Finnerup, N. B. & Baastrup, C. Spinal cord injury pain: mechanisms and management. Curr. Pain. Headache Rep. 16, 207–216 (2012).
Xu, Z. Z., Berta, T. & Ji, R. R. Resolvin E1 inhibits neuropathic pain and spinal cord microglial activation following peripheral nerve injury. J. Neuroimmune Pharm. 8, 37–41 (2013).
Unda, S. R., Villegas, E. A., Toledo, M. E., Asis Onell, G. & Laino, C. H. Beneficial effects of fish oil enriched in omega-3 fatty acids on the development and maintenance of neuropathic pain. J. Pharm. Pharm. 72, 437–447 (2020).
Durán, A. M. et al. Effects of omega-3 polyunsaturated fatty-acid supplementation on neuropathic pain symptoms and sphingosine levels in Mexican-Americans with type 2 diabetes. Diab Metab. Syndr. Obes. 12, 109–120 (2019).
Yorek, M. A. The potential role of fatty acids in treating diabetic neuropathy. Curr. Diab Rep. 18, 86 (2018).
Redivo, D. D. B., Jesus, C. H. A., Sotomaior, B. B., Gasparin, A. T. & Cunha, J. M. Acute antinociceptive effect of fish oil or its major compounds, eicosapentaenoic and docosahexaenoic acids on diabetic neuropathic pain depends on opioid system activation. Behav. Brain Res. 372, 111992 (2019).
Motter, A. L. & Ahern, G. P. TRPA1 is a polyunsaturated fatty acid sensor in mammals. PLoS One 7, e38439 (2012).
Skerratt, S. E. & West, C. W. Ion channel therapeutics for pain. Channels 9, 344–351 (2015).
Ko, G. D., Nowacki, N. B., Arseneau, L., Eitel, M. & Hum, A. Omega-3 fatty acids for neuropathic pain: case series. Clin. J. Pain. 26, 168–172 (2010).
Ensrud, K. E. & Crandall, C. J. Osteoporosis. Ann. Intern. Med. 167, Itc17–itc32 (2017).
Craven, B., Cirnigliaro, C., Carbone, L., Tsang, P. & Morse, L. The pathophysiology, identification and management of fracture risk, sublesional osteoporosis and fracture among adults with spinal cord injury. J. Personalized Med. 13, 966 (2023).
Garland, D. E., Adkins, R. H. & Stewart, C. A. Five-year longitudinal bone evaluations in individuals with chronic complete spinal cord injury. J. Spinal Cord. Med. 31, 543–550 (2008).
Abdelrahman, S., Ireland, A., Winter, M. E., Purcell, M. & Coupaud, S. Osteoporosis after spinal cord injury: aetiology, effects and therapeutic approaches. J Musculoskelet Neuronal Interact. 21, 26–50 (2021)
Tan, C. O., Battaglino, R. A. & Morse, L. R. Spinal cord injury and osteoporosis: causes, mechanisms, and rehabilitation strategies. Int. J. Phys. Med. Rehabil. 1, 127 (2013).
Morse, L. R. et al. Osteoporotic fractures and hospitalization risk in chronic spinal cord injury. Osteoporos. Int. 20, 385–392 (2009).
Hachem, L. D., Ahuja, C. S. & Fehlings, M. G. Assessment and management of acute spinal cord injury: From point of injury to rehabilitation. J. Spinal Cord. Med. 40, 665–675 (2017).
Haider, I. T., Lobos, S. M., Simonian, N., Schnitzer, T. J. & Edwards, W. B. Bone fragility after spinal cord injury: reductions in stiffness and bone mineral at the distal femur and proximal tibia as a function of time. Osteoporos. Int. 29, 2703–2715 (2018).
Chantraine, A., Nusgens, B. & Lapiere, C. M. Bone remodeling during the development of osteoporosis in paraplegia. Calcif. Tissue Int. 38, 323–327 (1986).
Minaire, P. et al. Quantitative histological data on disuse osteoporosis: comparison with biological data. Calcif. Tissue Res. 17, 57–73 (1974).
Zehnder, Y. et al. Long-term changes in bone metabolism, bone mineral density, quantitative ultrasound parameters, and fracture incidence after spinal cord injury: a cross-sectional observational study in 100 paraplegic men. Osteoporos. Int. 15, 180–189 (2004).
Szollar, S. M., Martin, E. M., Sartoris, D. J., Parthemore, J. G. & Deftos, L. J. Bone mineral density and indexes of bone metabolism in spinal cord injury. Am. J. Phys. Med. Rehabil. 77, 28–35 (1998).
Shams, R. et al. The pathophysiology of osteoporosis after spinal cord injury. Int. J. Mol. Sci. 22, 3057 (2021).
de Groen, P. et al. Esophagitis associated with the use of alendronate. N. Engl. J. Med. 335, 1016–1021 (1996).
Lerner, U. H. Inflammation-induced bone remodeling in periodontal disease and the influence of post-menopausal osteoporosis. J. Dent. Res. 85, 596–607 (2006).
Watkins, B. A., Lippman, H. E., Le Bouteiller, L., Li, Y. & Seifert, M. F. Bioactive fatty acids: role in bone biology and bone cell function. Prog. Lipid Res. 40, 125–148 (2001).
Sun, D. et al. Dietary n-3 fatty acids decrease osteoclastogenesis and loss of bone mass in ovariectomized mice. J. Bone Miner. Res. 18, 1206–1216 (2003).
Watkins, B. A., Shen, C. L., Allen, K. G. & Seifert, M. F. Dietary (n-3) and (n-6) polyunsaturates and acetylsalicylic acid alter ex vivo PGE2 biosynthesis, tissue IGF-I levels, and bone morphometry in chicks. J. Bone Miner. Res. 11, 1321–1332 (1996).
Hasturk, H. et al. RvE1 protects from local inflammation and osteoclast-mediated bone destruction in periodontitis. Faseb J. 20, 401–403 (2006).
Levental, K. R. et al. ω-3 polyunsaturated fatty acids direct differentiation of the membrane phenotype in mesenchymal stem cells to potentiate osteogenesis. Sci. Adv. 3, eaao1193 (2017).
Haag, M., Magada, O. N., Claassen, N., Böhmer, L. H. & Kruger, M. C. Omega-3 fatty acids modulate ATPases involved in duodenal Ca absorption. Prostaglandins Leukotrienes, Essent. Fat. Acids 68, 423–429 (2003).
Kishikawa, A. et al. Docosahexaenoic acid inhibits inflammation-induced osteoclast formation and bone resorption in vivo through GPR120 by inhibiting TNF-α production in macrophages and directly inhibiting osteoclast formation. Front. Endocrinol. 10, 157 (2019).
Ahn, S. H. et al. Free fatty acid receptor 4 (GPR120) stimulates bone formation and suppresses bone resorption in the presence of elevated N-3 fatty acid levels. Endocrinology 157, 2621–2635 (2016).
Sithole, C., Pieterse, C., Howard, K. & Kasonga, A. GPR120 Inhibits RANKL-induced osteoclast formation and resorption by attenuating reactive oxygen species production in RAW264.7 murine macrophages. Int. J. Mol. Sci. 22, 10544 (2021).
Sabour, H. et al. The effects of n-3 fatty acids on inflammatory cytokines in osteoporotic spinal cord injured patients: a randomized clinical trial. J. Res. Med. Sci. 17, 322–327 (2012).
Dodin, S. et al. The effects of flaxseed dietary supplement on lipid profile, bone mineral density, and symptoms in menopausal women: a randomized, double-blind, wheat germ placebo-controlled clinical trial. J. Clin. Endocrinol. Metab. 90, 1390–1397 (2005).
Ishimoto, R. et al. Prevalence of sarcopenic obesity and factors influencing body composition in persons with spinal cord injury in Japan. Nutrients 15, 473 (2023).
Gater, D. R. Jr. Obesity after spinal cord injury. Phys. Med. Rehabil. Clin. North Am. 18, 333–351 (2007). vii.
Gaudet, A. D. et al. Spinal cord injury in rats dysregulates diurnal rhythms of fecal output and liver metabolic indicators. J. Neurotrauma 36, 1923–1934 (2019).
Cruz-Antonio, L., Flores-Murrieta, F. J., García-Löpez, P., Guízar-Sahagún, G. & Castañeda-Hernández, G. Understanding drug disposition alterations induced by acute spinal cord injury: role of injury level and route of administration for agents submitted to extensive liver metabolism. J. Neurotrauma 23, 75–85 (2006).
Liu, X. H. et al. Spinal cord injury reduces serum levels of fibroblast growth factor-21 and impairs its signaling pathways in liver and adipose tissue in mice. Front. Endocrinol. 12, 668984 (2021).
Buchholz, A. C. & Pencharz, P. B. Energy expenditure in chronic spinal cord injury. Curr. Opin. Clin. Nutr. Metab. Care 7, 635–639 (2004).
McMillan, D. W., Bigford, G. E. & Farkas, G. J. The physiology of neurogenic obesity: lessons from spinal cord injury research. Obes. Facts 16, 313–325 (2023).
Gater, D. R. Jr., Farkas, G. J. & Tiozzo, E. Pathophysiology of neurogenic obesity after spinal cord injury. Top. Spinal Cord. Inj. Rehabil. 27, 1–10 (2021).
Spungen, A. M. et al. Factors influencing body composition in persons with spinal cord injury: a cross-sectional study. J. Appl. Physiol. 95, 2398–2407 (2003).
Sorenson, M. R. Body composition of women and men with complete motor paraplegia. J. Spinal Cord. Med. 37, 366–367 (2014).
Jones, L. M., Legge, M. & Goulding, A. Healthy body mass index values often underestimate body fat in men with spinal cord injury. Arch. Phys. Med. Rehabil. 84, 1068–1071 (2003).
Yarar-Fisher, C., Chen, Y., Jackson, A. B. & Hunter, G. R. Body mass index underestimates adiposity in women with spinal cord injury. Obesity 21, 1223–1225 (2013).
Pelletier, C. A., Miyatani, M., Giangregorio, L. & Craven, B. C. Sarcopenic obesity in adults with spinal cord injury: a cross-sectional study. Arch. Phys. Med. Rehabil. 97, 1931–1937 (2016).
Felix, E. R. & Gater, D. R. Jr. Interrelationship of neurogenic obesity and chronic neuropathic pain in persons with spinal cord injury. Top. Spinal Cord. Inj. Rehabil. 27, 75–83 (2021).
Gordon, P. S., Farkas, G. J. & Gater, D. R. Jr. Neurogenic obesity-induced insulin resistance and type 2 diabetes mellitus in chronic spinal cord injury. Top. Spinal Cord. Inj. Rehabil. 27, 36–56 (2021).
Shojaei, M. H., Alavinia, S. M. & Craven, B. C. Management of obesity after spinal cord injury: a systematic review. J. Spinal Cord. Med. 40, 783–794 (2017).
Hotamisligil, G. S. Inflammation and metabolic disorders. Nature 444, 860–867 (2006).
Kalupahana, N., Goonapienuwala, B. & Moustaid-Moussa, N. Omega-3 fatty acids and adipose tissue: inflammation and browning. Annu. Rev. Nutr. 40, 25–49 (2020).
Titos, E. & Clària, J. Omega-3-derived mediators counteract obesity-induced adipose tissue inflammation. Prostaglandins Other Lipid Mediat. 107, 77–84 (2013).
Kalupahana, N. S. et al. Eicosapentaenoic acid prevents and reverses insulin resistance in high-fat diet-induced obese mice via modulation of adipose tissue inflammation. J. Nutr. 140, 1915–1922 (2010).
Martínez-Fernández, L., Laiglesia, L. M., Huerta, A. E., Martínez, J. A. & Moreno-Aliaga, M. J. Omega-3 fatty acids and adipose tissue function in obesity and metabolic syndrome. Prostaglandins Other Lipid Mediat 121, 24–41 (2015).
Gao, H., Geng, T., Huang, T. & Zhao, Q. Fish oil supplementation and insulin sensitivity: a systematic review and meta-analysis. Lipids Health Dis. 16, 131 (2017).
Albracht-Schulte, K. et al. Omega-3 fatty acids in obesity and metabolic syndrome: a mechanistic update. J. Nutr. Biochem. 58, 1–16 (2018).
Parra, D. et al. A diet rich in long chain omega-3 fatty acids modulates satiety in overweight and obese volunteers during weight loss. Appetite 51, 676–680 (2008).
Thorsdottir, I. et al. Randomized trial of weight-loss-diets for young adults varying in fish and fish oil content. Int. J. Obes. 31, 1560–1566 (2007).
Lagerström, M. C. & Schiöth, H. B. Structural diversity of G protein-coupled receptors and significance for drug discovery. Nat. Rev. Drug Discov. 7, 339–357 (2008).
Cohen, J. et al. Recent research trends in neuroinflammatory and neurodegenerative disorders. Cells 13, 511 (2024).
Poniatowski, Ł et al. Analysis of the role of CX3CL1 (Fractalkine) and its receptor CX3CR1 in traumatic brain and spinal cord injury: insight into recent advances in actions of neurochemokine agents. Mol. Neurobiol. 54, 2167–2188 (2017).
Goode-Romero, G. & Dominguez, L. Computational study of the conformational ensemble of CX3C chemokine receptor 1 (CX3CR1) and its interactions with antagonist and agonist ligands. J. Mol. Graph. Model. 117, 108278 (2022).
Radulovic, M., Yoon, H., Wu, J., Mustafa, K. & Scarisbrick, I. A. Targeting the thrombin receptor modulates inflammation and astrogliosis to improve recovery after spinal cord injury. Neurobiol. Dis. 93, 226–242 (2016).
Radulovic, M. et al. Genetic targeting of protease activated receptor 2 reduces inflammatory astrogliosis and improves recovery of function after spinal cord injury. Neurobiol. Dis. 83, 75–89 (2015).
Lin, B. et al. GPR34 senses demyelination to promote neuroinflammation and pathologies. Cell. Mol. Immunol. 21, 1131–1144 (2024).
Apweiler, M. et al. Modulation of neuroinflammation and oxidative stress by targeting GPR55-new approaches in the treatment of psychiatric disorders. Mol. Psychiatry 29, 3779–3788 (2024).
Sayo, A. et al. GPR34 in spinal microglia exacerbates neuropathic pain in mice. J. Neuroinflammation 16, 82 (2019).
Jiang, W., Yu, W. & Tan, Y. Activation of GPR55 alleviates neuropathic pain and chronic inflammation. Biotechnol. Appl. Biochem. 72, 196–206 (2025).
Purcell, R. H. & Hall, R. A. Adhesion G protein-coupled receptors as drug targets. Annu. Rev. Pharm. Toxicol. 58, 429–449 (2018).
Bassilana, F., Nash, M. & Ludwig, M. G. Adhesion G protein-coupled receptors: opportunities for drug discovery. Nat. Rev. Drug Discov. 18, 869–884 (2019).
Zheng, Y. et al. Development of an allosteric adhesion GPCR nanobody with therapeutic potential. Nat. Chem. Biol. 21, 1519–1530 (2025).
Uniyal, A. et al. Targeting sensory neuron GPCRs for peripheral neuropathic pain. Trends Pharmacol. Sci. 44, 1009–1027 (2023).
Yosten, G. L. et al. GPR160 de-orphanization reveals critical roles in neuropathic pain in rodents. J. Clin. Invest. 130, 2587–2592 (2020).
Pondelick, A. M. et al. Dissociation between the anti-allodynic effects of fingolimod (FTY720) and desensitization of S1P(1) receptor-mediated G-protein activation in a mouse model of sciatic nerve injury. Neuropharmacology 261, 110165 (2024).
Birgbauer, E. Lysophospholipid receptors in neurodegeneration and neuroprotection. Exploration Neuroprotective Ther. 4, 349–365 (2024).
Rich, K., Rehman, S., Jerman, J. & Wilkinson, G. Investigating the potential of GalR2 as a drug target for neuropathic pain. Neuropeptides 98, 102311 (2023).
Chung, H. J., Kim, J. D., Kim, K. H. & Jeong, N. Y. G protein-coupled receptor, family C, group 5 (GPRC5B) downregulation in spinal cord neurons is involved in neuropathic pain. Korean J. Anesthesiol. 66, 230–236 (2014).
Holmes, F. E. et al. Targeted disruption of the orphan receptor Gpr151 does not alter pain-related behaviour despite a strong induction in dorsal root ganglion expression in a model of neuropathic pain. Mol. Cell. Neurosci. 78, 35–40 (2017).
Lefkowitz, R. J. & Shenoy, S. K. Transduction of receptor signals by beta-arrestins. Science 308, 512–517 (2005).
Shang, P. et al. Structural and signaling mechanisms of TAAR1 enabled preferential agonist design. Cell 186, 5347–5362.e5324 (2023).
Yang, F. et al. Structure, function and pharmacology of human itch receptor complexes. Nature 600, 164–169 (2021).
Wang, J. L. et al. Functional screening and rational design of compounds targeting GPR132 to treat diabetes. Nat. Metab. 5, 1726–1746 (2023).
Xu, F. et al. Identification and target-pathway deconvolution of FFA4 agonists with anti-diabetic activity from Arnebia euchroma (Royle) Johnst. Pharmacol. Res. 163, 105173 (2021).
Oh, D. Y. & Olefsky, J. M. G protein-coupled receptors as targets for anti-diabetic therapeutics. Nat. Rev. Drug Discov. 15, 161–172 (2016).
Di Petrillo, A., Kumar, A., Onali, S., Favale, A. & Fantini, M. C. GPR120/FFAR4: a potential new therapeutic target for inflammatory bowel disease. Inflamm. bowel Dis. 29, 1981–1989 (2023).
Tanaka, T. et al. Cloning and characterization of the rat free fatty acid receptor GPR120: in vivo effect of the natural ligand on GLP-1 secretion and proliferation of pancreatic beta cells. Naunyn-Schmiedeberg’s. Arch. Pharmacol. 377, 515–522 (2008).
Gagnon, J. & Anini, Y. Glucagon stimulates ghrelin secretion through the activation of MAPK and EPAC and potentiates the effect of norepinephrine. Endocrinology 154, 666–674 (2013).
Engelstoft, M. S. et al. Seven transmembrane G protein-coupled receptor repertoire of gastric ghrelin cells. Mol. Metab. 2, 376–392 (2013).
Stone, V. M. et al. GPR120 (FFAR4) is preferentially expressed in pancreatic delta cells and regulates somatostatin secretion from murine islets of Langerhans. Diabetologia 57, 1182–1191 (2014).
Cho, Y. M. & Kieffer, T. J. K-cells and glucose-dependent insulinotropic polypeptide in health and disease. Vitam. Hormones 84, 111–150 (2010).
Du, Y. Q. et al. Endogenous Lipid-GPR120 Signaling Modulates Pancreatic Islet Homeostasis to Different Extents. Diabetes 71, 1454–1471 (2022).
Feng, X., Wu, C. Y., Burton, F. H., Loh, H. H. & Wei, L. N. β-arrestin protects neurons by mediating endogenous opioid arrest of inflammatory microglia. Cell Death Differ. 21, 397–406 (2014).
Du, R. W., Du, R. H. & Bu, W. G. β-Arrestin 2 mediates the anti-inflammatory effects of fluoxetine in lipopolysaccharide-stimulated microglial cells. J. NeuroImmune Pharmacol. J. Soc. NeuroImmune Pharmacol. 9, 582–590 (2014).
Moniri, N. H. Free-fatty acid receptor-4 (GPR120): Cellular and molecular function and its role in metabolic disorders. Biochem. Pharmacol. 110-111, 1–15 (2016).
Ichimura, A. et al. Dysfunction of lipid sensor GPR120 leads to obesity in both mouse and human. Nature 483, 350–354 (2012).
Yore, M. M. et al. Discovery of a class of endogenous mammalian lipids with anti-diabetic and anti-inflammatory effects. Cell 159, 318–332 (2014).
Elnagdy, M., Barve, S., McClain, C. & Gobejishvili, L. cAMP signaling in pathobiology of alcohol associated liver disease. Biomolecules 10, 1433 (2020).
Secor, J. D., Fligor, S. C., Tsikis, S. T., Yu, L. J. & Puder, M. Free fatty acid receptors as mediators and therapeutic targets in liver disease. Front. Physiol. 12, 656441 (2021).
Wang, M., Ma, L. J., Yang, Y., Xiao, Z. & Wan, J. B. n-3 Polyunsaturated fatty acids for the management of alcoholic liver disease: a critical review. Crit. Rev. Food Sci. Nutr. 59, S116–s129 (2019).
Liu, H. et al. DrugCombDB: a comprehensive database of drug combinations toward the discovery of combinatorial therapy. Nucleic Acids Res. 48, D871–D881 (2020).
Zhang, Y. et al. Versatile metal-phenolic network nanoparticles for multitargeted combination therapy and magnetic resonance tracing in glioblastoma. Biomaterials 278, 121163 (2021).
Kirchhof, P. et al. Early and comprehensive management of atrial fibrillation: executive summary of the proceedings from the 2nd AFNET-EHRA consensus conference ‘research perspectives in AF. Eur. heart J. 30, 2969–2977c (2009).
Oliveros, G. et al. Repurposing ibudilast to mitigate Alzheimer’s disease by targeting inflammation. Brain J. Neurol. 146, 898–911 (2023).
Ma, Y. et al. Medicinal chemistry strategies for discovering antivirals effective against drug-resistant viruses. Chem. Soc. Rev. 50, 4514–4540 (2021).
Figueroa, J. D., Cordero, K., Llán, M. S. & De Leon, M. Dietary omega-3 polyunsaturated fatty acids improve the neurolipidome and restore the DHA status while promoting functional recovery after experimental spinal cord injury. J. Neurotrauma 30, 853–868 (2013).
Cholewski, M., Tomczykowa, M. & Tomczyk, M. A Comprehensive review of chemistry, sources and bioavailability of omega-3 fatty acids. Nutrients 10, 1662 (2018).
Pan, M. et al. Dietary ω-3 polyunsaturated fatty acids are protective for myopia. Proceedings of the National Academy of Sciences of the United States of America 118, e2104689118 (2021).
Tveit, K. S. et al. A randomized, double-blind, placebo-controlled clinical study to investigate the efficacy of herring roe oil for treatment of psoriasis. Acta Derm. Venereologica 100, adv00154 (2020).
Zirpoli, H. et al. Novel approaches for omega-3 fatty acid therapeutics: chronic versus acute administration to protect heart, brain, and spinal cord. Annu Rev. Nutr. 40, 161–187 (2020).
Saravanan, P., Davidson, N. C., Schmidt, E. B. & Calder, P. C. Cardiovascular effects of marine omega-3 fatty acids. Lancet 376, 540–550 (2010).
Hall, J. C., Priestley, J. V., Perry, V. H. & Michael-Titus, A. T. Docosahexaenoic acid, but not eicosapentaenoic acid, reduces the early inflammatory response following compression spinal cord injury in the rat. J. Neurochem. 121, 738–750 (2012).
Ward, R. E., Huang, W., Curran, O. E., Priestley, J. V. & Michael-Titus, A. T. Docosahexaenoic acid prevents white matter damage after spinal cord injury. J. Neurotrauma 27, 1769–1780 (2010).
Jayedi, A., Soltani, S., Emadi, A., Ghods, K. & Shab-Bidar, S. Dietary intake, biomarkers and supplementation of fatty acids and risk of coronary events: a systematic review and dose-response meta-analysis of randomized controlled trials and prospective observational studies. Critical Rev. Food Sci. Nutrition 64, 12363–12382 (2023).
Engelen, M. et al. ω-3 polyunsaturated fatty acid supplementation improves postabsorptive and prandial protein metabolism in patients with chronic obstructive pulmonary disease: a randomized clinical trial. Am. J. Clin. Nutr. 116, 686–698 (2022).
Jiang, H., Galtes, D., Wang, J. & Rockman, H. G protein-coupled receptor signaling: transducers and effectors. Am. J. Physiol. Cell Physiol. 323, C731–C748 (2022).
Ghosh, T., Chouhan, V., Ojha, K., Bala, K. & Bux, F. Effects of antibiotic supplementation vs. nutrient stress on α-linolenic acid and α-tocopherol in Scenedesmus sp. Bioresour. Technol. 418, 131968 (2025).
Alijani, S., Hahn, A., Harris, W. S. & Schuchardt, J. P. Bioavailability of EPA and DHA in humans - a comprehensive review. Prog. Lipid Res. 97, 101318 (2025).
Andriambelo, B., Stiffel, M., Roke, K. & Plourde, M. New perspectives on randomized controlled trials with omega-3 fatty acid supplements and cognition: a scoping review. Ageing Res. Rev. 85, 101835 (2023).
Li, G. et al. Waterborne polyurethane nanoparticles incorporating linoleic acid as a potential strategy for controlling antibiotic resistance spread in the mammalian intestine. Mater. Today Bio 28, 101181 (2024).
Jiang, S. et al. Association of breast milk-derived arachidonic acid-induced infant gut dysbiosis with the onset of atopic dermatitis. Gut 74, 45–57 (2024).
Paredes, A. et al. γ-Linolenic acid in maternal milk drives cardiac metabolic maturation. Nature 618, 365–373 (2023).
Belayev, L. et al. Neuroprotectin D1 upregulates Iduna expression and provides protection in cellular uncompensated oxidative stress and in experimental ischemic stroke. Cell Death Differ. 24, 1091–1099 (2017).
Ramar, M., Yano, N. & Fedulov, A. V. Intra-airway treatment with synthetic lipoxin A4 and resolvin E2 mitigates neonatal asthma triggered by maternal exposure to environmental particles. Int. J. Mol. Sci. 24, 6145 (2023).
Libreros, S., Nshimiyimana, R., Lee, B. & Serhan, C. N. Infectious neutrophil deployment is regulated by resolvin D4. Blood 142, 589–606 (2023).
Spite, M. et al. Resolvin D2 is a potent regulator of leukocytes and controls microbial sepsis. Nature 461, 1287–1291 (2009).
Lee, S. H. et al. Resolvin D3 controls mouse and human TRPV1-positive neurons and preclinical progression of psoriasis. Theranostics 10, 12111–12126 (2020).
Qin, Y. et al. Lipid metabolism of apoptotic vesicles accelerates cutaneous wound healing by modulating macrophage function. J. Nanobiotechnol. 23, 106 (2025).
Silva, R. V. et al. Long-chain omega-3 fatty acids supplementation accelerates nerve regeneration and prevents neuropathic pain behavior in mice. Front. Pharmacol. 8, 723 (2017).
Zhang, E. et al. High omega-3 polyunsaturated fatty acids in fat-1 mice reduce inflammatory pain. J. Med. food 20, 535–541 (2017).
Kato, Y. et al. Vesicular nucleotide transporter is a molecular target of eicosapentaenoic acid for neuropathic and inflammatory pain treatment. Proc. Natl. Acad. Sci. USA 119, e2122158119 (2022).
Huang, C. T. & Tsai, Y. J. Docosahexaenoic acid confers analgesic effects after median nerve injury via inhibition of c-Jun N-terminal kinase activation in microglia. J. Nutr. Biochem. 29, 97–106 (2016).
Acknowledgements
This work was supported by the National Key Research and Development Project ofStem Cell and Transformation Research (2019YFA0112100), Taishan Scholars Programof Shandong Province-Young Taishan Scholars (tsqn201909197), Cutting EdgeDevelopment Fund of Advanced Medical Research Institute (Shandong University),and National Natural Science Foundation of China (82220108005).
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Shiqing Feng, Hengxing Zhou, Zhongze Yuan, Lusen Shi, and Xiao-Na Tao conceptualized the review and designed the outline. Xiangchuang Fan, Han Zheng, Yifan Shang, Xiaoqing Zhao conducted the literature search. Fan Yang, Hui Lin, Peng Xiao, Ning Ran selected relevant articles for inclusion. Zhongze Yuan drafted the manuscript, while Bo Chu, Jichuan Qiu and Shaohui Zong contributed to manuscript revision and editing. Shiqing Feng, Hengxing Zhou, Jin-peng Sun, and Xiaohong Kong supervised the overall process, providing direction and feedback on the content and scope of the review.
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Yuan, Z., Shi, L., Tao, XN. et al. Progress on Omega-3 fatty acids for the comprehensive and targeted treatment of spinal cord injury. Bone Res 14, 3 (2026). https://doi.org/10.1038/s41413-025-00461-w
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DOI: https://doi.org/10.1038/s41413-025-00461-w
