Oral and Gut Health, (Neuro) Inflammation, and Central Sensitization in Chronic Pain: A Narrative Review of Mechanisms, Treatment Opportunities, and Research Agenda

SCFAs are the most abundant microbial metabolites in the colonic lumen [17,57], mainly composed of acetate, propionate, and butyrate, with an approximate molar ratio of 60:20:20 [17]. They are produced through microbial fermentation of dietary fibers, with most metabolized by colonic epithelial cells and a smaller portion entering systemic circulation to influence host physiology [39]. Acetate is formed via the acetyl-CoA or Wood–Ljungdahl pathways [58,59] (Figure 2), propionate primarily through the succinate, acrylate, and propanediol routes [56,57,59] (Figure 3), and butyrate mainly through two routes, the butyryl CoA/acetate CoA transferase and the butyrate kinase pathways, using acetate as a co-substrate [57,59,60] or amino acids as alternative precursors [56] (Figure 4).

High protein intake promotes the microbial fermentation of undigested dietary proteins in the colon, producing amino acid-derived metabolites such as branched-chain fatty acids (isobutyrate, 2-methylbutyrate, isovalerate), phenylacetic acid, and other compounds, including phenols, indoles, p-cresol, amines, and ammonia, contributing minimally to the total SCFA pool [56,61,64,65]. Bacteroides spp. and certain Firmicutes degrade aromatic amino acids to yield these metabolites [65], which can exert both beneficial and detrimental effects on host metabolism, immunity, and inflammation [14,57]. Microbial tryptophan metabolism by Clostridium sporogenes and Escherichia coli produces indole, further converted by Limosilactobacillus reuteri (formerly Lactobacillus reuteri) and Lactobacillus johnsonii to indole-3-aldehyde [66,67]. Polyamines (putrescine, spermidine, spermine) arise from bacterial decarboxylation of ornithine and arginine via Bifidobacterium and Lactobacillus enzymes [61,68].

Primary bile acids escaping enterohepatic recirculation are deconjugated by bile salt hydrolases and converted via 7α-dehydroxylation by Clostridium (clusters XIVa and XI), Eubacterium, and Bacteroides into secondary bile acids such as deoxycholic and lithocholic acids, encoded in the bai operon [61,67,69,70,71]. In addition, microbial structural components such as LPS from Gram-negative bacteria [72,73] and peptidoglycan from both Gram-positive and Gram-negative taxa [67,74] serve as MAMPs detected by host pattern recognition receptors (PRRs), such as Toll-like receptors (TLRs) and nucleotide-binding oligomerization domain-like receptors (NLRs, including NOD1 and NOD2), potentially promoting low-grade inflammation and systemic immune activation when gut barrier function is impaired [75,76,77].

Oral microbes can translocate to the distal gut via the enteric pathway through daily saliva swallowing, with humans producing approximately 1 to 1.5 L of saliva containing around 1.5 × 10¹² bacteria per day [101]. This pathway allows acid-resistant oral taxa, such as Porphyromonas gingivalis, Helicobacter pylori, Fusobacterium nucleatum, Klebsiella, and Streptococcus spp., to withstand gastric passage and colonize the intestine, contributing to gut dysbiosis [40,102,103]. Such enteric translocation of oral microbiota can alter intestinal microbiota (dysbiosis) and compromise epithelial barrier integrity, initiating systemic inflammation and neuroimmune activation [40,41,42,43,44,45]. Chronic periodontal dysbiosis, particularly driven by Porphyromonas gingivalis, activates the TLR/NF-κB signaling cascade in intestinal and neural tissues, amplifying cytokine release and sustaining inflammatory communication along the oral–gut–brain axis [46]. In rodents, oral Fusobacterium nucleatum exposure exacerbates visceral hypersensitivity alongside gut dysbiosis, supporting a gut-mediated contribution to peripheral nociceptive sensitization [104]. Pro-inflammatory mediators such as IL-1β, IL-6, and TNF-α, together with microglial activation, are well-established facilitators to peripheral and central sensitization [105,106]. Oral Porphyromonas gingivalis exposure, for example, has been shown to disrupt gut barrier integrity through decreased intestinal zonula occludens-1 (ZO-1) expression, increase colonic TNF-α and IL-1β, elevate serum IL-17A and brain IL-17 receptor A, and activate microglia in the substantia nigra [107,108]. Collectively, these findings indicate that oral microbiota–induced alterations along the oral–gut axis can drive gut barrier dysfunction, systemic cytokine signaling, and neuroinflammation, which are mechanistically consistent with processes that facilitate peripheral and central sensitization.

Oral bacteria can enter the bloodstream during routine activities such as toothbrushing and chewing or following dental procedures, with greater frequency and magnitude in individuals with periodontitis [40]. These episodes of transient bacteremia enable oral pathogens and their byproducts to disseminate systemically, where they can trigger endotoxemia, activate immune cells, and drive cytokine-mediated inflammation [82,109]. For example, Fusobacterium nucleatum-induced apical periodontitis in rats caused bacterial dissemination beyond the oral cavity, with Fusobacterium nucleatum DNA detected in the gut [110]. Histopathological analyses confirmed inflammatory cell infiltration in periapical tissues, while 16S rRNA sequencing revealed altered microbial composition across the gut, heart, liver, and kidney. These findings indicate that oral infection with F. nucleatum can reshape gut microbial communities and promote systemic dysbiosis through hematogenous dissemination [110]. Similarly, translocation of Porphyromonas gingivalis into the bloodstream increases cytokine production and drives mononuclear cell differentiation into highly active osteoclasts, contributing to inflammatory bone loss disorders such as RA [111].

Pathogenic microorganisms influence systemic inflammation through interconnected immune pathways in both the oral cavity and the gut. Certain oral pathogens, such as Porphyromonas gingivalis and Fusobacterium nucleatum, invade and colonize the oral epithelial cells and periodontal tissues, where the bacteria can release virulence factors and toxins that disrupt the integrity of the oral mucosa [112]. This disruption permits the oral microbes to penetrate deeper into gingival tissue. These microbes then interact with local immune cells to trigger activation and recruitment of neutrophils and natural killer cells, subsequently enabling dendritic cells to prime CD4+ and CD8+ T cells, thereby promoting inflammation through cytokine secretion [113]. Orally primed T cells can migrate to the intestinal mucosa, where they aggravate barrier dysfunction and inflammation [40] (Figure 5).

Gut microbiota influence pain through multiple immunoregulatory mechanisms, shaping peripheral and central sensitization through converging systemic and neuroinflammatory processes. The gut microbiome interacts with immune cells to modulate cytokine levels and prostaglandin signaling to influence brain function [17,115]. Experimental evidence indicates that the absence of commensal gut microbiota disrupts neuroimmune homeostasis and alters structural integrity within pain-regulatory circuits, as evidenced by heightened visceral sensitivity, increased spinal TLR and cytokine (IL-6, TNF-α, IL-1α/β, IL-10) expression, glial activation, and morphological alterations in pain-related brain regions (reduced anterior cingulate cortex volume, enlarged periaqueductal gray, and dendritic or spine hypertrophy). Restoration of the microbiota normalized these changes, underscoring its essential role in maintaining balanced neuroimmune and pain-processing mechanisms [116]. Similarly, dysbiosis is associated with increased production of pro-inflammatory cytokines such as IL-1β and TNF-α, which can cross the blood–brain barrier and activate microglia, sustaining neuroinflammatory cascades and facilitating central sensitization [117,118]. Following peripheral nerve injury, dysbiosis exacerbates pain through elevated spinal TNF-α, IL-1β, and glial activation, facilitating central pain sensitization, whereas probiotic administration suppressed these inflammatory and nociceptive changes [119]. Microbiota-derived metabolites, such as SCFAs, bile acids, and tryptophan derivatives, can act on host receptors (e.g., G-protein-coupled receptor (GPR) 43, TLRs, and transient receptor potential (TRP) channels), thereby modifying immune and neuronal signaling in ways that influence nociceptive plasticity (explained in Section 3.4) [14,27]. Translational evidence shows that microbiota from patients with fibromyalgia can transfer mechanical hypersensitivity and immune alterations to germ-free mice, whereas fecal microbiota transplantation from healthy donors alleviates symptoms [120]. Collectively, these data demonstrate that gut microbial communities regulate pain through systemic cytokine induction, microglial priming, and metabolite-mediated immune signaling.

The autonomic nervous system forms an essential link between the gut and the brain, with the vagus nerve and the enteric nervous system playing central roles. Microbial metabolites and commensal signals influence brain and pain pathways through vagal afferents projecting from the gut to brainstem nuclei, where serotonergic, opioid, and cholinergic anti-inflammatory circuits modulate nociception, stress responses, and systemic inflammation [17,27,121,122,123,124,125]. By regulating motility and secretion, the vagus nerve supports gut barrier integrity and microbial balance, controlling systemic inflammation and maintaining immune homeostasis [27].

Experimental evidence demonstrates that specific microbial taxa directly modulate autonomic and sensory activity. In rats, oral administration of Lactobacillus reuteri inhibited the cardio-autonomic reflex and prevented the increase in colonic dorsal root ganglion excitability during colorectal distension, indicating that microbial signals can attenuate visceral pain through local enteric–autonomic mechanisms [126,127]. Similarly, Lactobacillus rhamnosus increased vagal afferent firing and responsiveness to gut distension and suppressed visceral pain responses to colorectal distension, demonstrating that specific microbes can modulate both acute vagal signaling and longer-term visceral nociception through integrated enteric and autonomic pathways [128]. The gut microbiota also modulate vagal afferent activity through metabolites such as bile acids, short-chain fatty acids, and 3-indoxyl sulfate, which act via G protein-coupled bile acid receptor 1 (GPBAR1), GPR43, and TRP ankyrin 1 (TRPA1) receptors. These findings show that microbial metabolites serve as chemical mediators of gut–brain communication, linking gut signals to autonomic and brain function [129]. In the absence of commensal microbiota, enteric sensory neurons display reduced excitability and altered membrane properties, which normalize following microbial colonization, underscoring the essential role of gut microbes in maintaining enteric neuronal and sensory function [130].

Microbiota–vagus nerve interactions are further supported by evidence from microbial transfer studies. Transplantation of stress-altered gut microbiota to healthy mice activated vagal pathways and disrupted serotonin–dopamine signaling, inducing hippocampal neuroinflammation and reduced neurogenesis; these effects were abolished by vagotomy, confirming that vagal integrity is essential for microbiota-driven modulation of brain and behavioral responses [131].

The hypothalamic–pituitary–adrenal (HPA) axis regulates stress responses and modulates the gut–brain axis through corticotropin-releasing hormone (CRH)- and adrenocorticotropic hormone (ACTH)-driven cortisol release [132,133,134]. In people with chronic pain, the HPA axis is often dysfunctional, implying alteration of corticosteroid expression, which can imply two opposite phenomena, namely hyper- and hypo-cortisolism [135]. Hypercortisolism is characterized by basal hypercortisolism and/or hyperreactivity, with basal hypercortisolism defined as a permanently increased cortisol level and decreased HPA axis negative feedback system, whereas hyperreactivity refers to normal cortisol levels with exaggerated behavioral and cortisol responses to stressful events [136]. Hypercortisolism has been found in several chronic pain conditions, including myofascial pain and burning mouth syndrome [137,138], and hypocortisolism in patients with myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS), irritable bowel syndrome, fibromyalgia and chronic pelvic pain [139,140,141,142]. While acute cortisol effects imply strong anti-inflammatory properties, chronic elevation of cortisol alters microbiota [27], increases gut permeability [143], and promotes neuroinflammation [144]. Chronic high cortisol is also linked to hippocampal atrophy, impaired stress regulation, and heightened nociceptive sensitivity [27,145]. In addition, gut microbes modulate neurotransmitters such as gamma-aminobutyric acid (GABA), serotonin, and melatonin, which influence nociceptive signaling, mood, and sleep [27,121].

Together, the immune, autonomic, and neuroendocrine pathways provide the major routes by which microbial activity in the gut influences nociceptive processing [14,118]. Their actions on peripheral and central sensitization are discussed in the following sections.

SCFAs primarily exert anti-inflammatory effects by modulating key signaling hubs like NF-kB, MAPK, and mammalian target of rapamycin (mTOR). These effects occur through GPR binding or histone deacetylase (HDAC) inhibition following cellular entry via transporters (e.g., Na⁺-coupled SMCT1/2 on the apical epithelium and H⁺-coupled MCT1/4 on both apical and basolateral membranes) or passive diffusion [13,39]. However, these actions are context-dependent, with paradoxical pro-inflammatory outcomes in pathological states. For example, acetate can engage GPR43 on neutrophils, potentiating their chemotaxis, oxidative burst, and cytokine production [14]. Their actions depend on carbon chain length, with acetate favoring GPR43, propionate targeting GPR41 and GPR43, and butyrate preferentially binding GPR109A and to some extent GPR41 [39,147]. Activation of GPR109A inhibits TLR4-induced expression and secretion of TNFα, IL-6 and CCl-2 and activation of GPR109A by butyrate exerts anti-inflammatory effects in colonic inflammation [148].

Microbiota-derived SCFAs can also modulate GPR41-mediated primary nociceptor excitability at the trigeminal ganglion, thereby shaping peripheral input to the spinal trigeminal nucleus caudalis (SpVc) [149]. In vivo studies demonstrate that intravenous propionic acid rapidly and reversibly suppresses SpVc wide-dynamic-range neuronal firing in response to mechanical stimuli [149]. In models of inflammatory hyperalgesia, butyrate reduces inflammatory hyperexcitability in nociceptive primary trigeminal ganglion neurons, thereby alleviating inflammatory hyperalgesia [150]. Evidence suggests that activation of satellite glia in sensory ganglia may also play an important role in the development of hyperalgesia and allodynia [151]. GPR43/GPR109A was detected in satellite glial cells of the dorsal root ganglia in the peripheral nervous system [152,153], implying that SCFAs could modulate satellite glial cells and thereby shape the local cytokine/chemokine milieu within ganglia.

Gut microbes metabolize dietary amino acids such as tryptophan and histidine into a range of bioactive compounds that influence pain signaling. Tryptophan metabolites include indoles, serotonin, and kynurenic acid. Indoles can activate TLR4 and TRPA1 channels on dorsal root ganglion neurons, leading to calcium influx, oxidative stress, and neuropeptide release, which in turn increase excitability and promote neurogenic inflammation [14]. Indoles also stimulate the aryl hydrocarbon receptor (AhR), which promotes the release of IL-6 and TNF-a upon activation, enhancing pro-inflammatory IL-17 signaling [163] and amplifying neuroinflammation and nociceptor hyperexcitability. In gut epithelial cells, AhR activation also increases serotonin release, which sensitizes TRPV1 channels on afferent neurons, heightening visceral hypersensitivity. Indoles can also directly activate chloride channels by binding to the extracellular domain of the GABA-A receptor and induce hyperpolarization of the resting membrane potential in dorsal root ganglion neurons, thereby reducing the frequency of action potential firing [14].

Polyamines, including putrescine, spermidine, and spermine, modulate neuronal excitability by influencing N-methyl-D-aspartate (NMDA) receptor activity and microglial activation [164]. Dysregulated polyamine metabolism in dysbiosis promotes neuroinflammation and enhances glutamatergic signaling [146], thereby contributing to central sensitization [165].

Secondary bile acids such as deoxycholic acid and lithocholic acid modulate nociception through both pronociceptive and antinociceptive mechanisms. On the pronociceptive side, activation of TLR4 on dorsal root ganglion neurons upregulates TRPV4 channel expression via NF-κB signaling, sensitizing the channels and promoting calcium influx and neuronal hyperexcitability [14]. In addition, it activates ERK1/2 pathway via TLR4, enhancing adenosine triphosphate (ATP)-induced calcium inward flow and synergistically amplifying neuronal hyperexcitability [166]. Bile acids also disrupt inhibitory control by inducing endocytosis of GABA-A receptors, which reduces chloride currents and promotes depolarization [14]. Conversely, bile acids produce antinociceptive effect by acting on GPBAR1, expressed on sensory neurons and macrophages, where receptor activation triggers TRPA1-dependent calcium influx and itch responses in neurons but promotes analgesia through opioid release in macrophages. Beyond bile acids, the microbiota contributes to the production of kynurenic acid, which signals through GPR35 in dorsal root ganglion neurons to reduce excitability and induce dose-dependent analgesia in vivo [14].

Microbial cell wall components, including LPS, peptidoglycans, and β-glucans, act as PAMPs of gut origin that are highly relevant to chronic pain [14]. Once released into circulation, they activate TLRs on immune cells and sensory neurons in the dorsal root ganglia, inducing innate immune activation and neuroinflammation that promote peripheral sensitization in models of neuropathic and inflammatory pain [12]. In neuroinflammatory conditions, they promote glial activation and cytokine release, amplifying peripheral nerve hyperexcitability [14,67]. LPS binds TLR4 on peripheral macrophages and dorsal root ganglia neurons, initiating NF-κB signaling that upregulates pro-inflammatory cytokines (e.g., TNF-α, IL-1β), resulting in peripheral sensitization [12,14]. Lipoproteins and peptidoglycans activate TLR2 on peripheral immune cells and sensory neurons, initiating downstream signaling [14]. This activation recruits Toll/IL-1 receptor domain-containing adaptor protein (TIRAP) and MyD88. Together, these adaptor proteins assemble a complex that phosphorylates interleukin-1 receptor-associated kinases (IRAK1 and IRAK4). The activated kinases interact with tumor necrosis factor receptor-associated factor 6 (TRAF6), forming a signaling hub that stimulates transforming growth factor β-activated kinase 1 (TAK1). TAK1 then activates both NF-κB and MAPK pathways. NF-κB activation promotes transcription of pro-inflammatory cytokines such as TNF-α, IL-6, and IL-1β, which promote the activation of macrophages, dendritic cells, and B lymphocytes. These immune cells, once activated, further amplify inflammation through sustained release of TNF-α, IL-12, and interferon gamma (IFN-γ), reinforcing inflammatory signaling via autocrine and paracrine loops [14] (Figure 6).

Diet is a major determinant of gut microbiome composition and function [271], with broad implications for pain and overall health [17,263]. Diets rich in fiber from fruits, vegetables, and whole grains promote the growth of beneficial bacteria that produce SCFAs, which exert anti-inflammatory effects, strengthen the intestinal barrier, and support gastrointestinal, metabolic, and even sleep health [14,17,61,271,272]. In contrast, diets high in processed foods, sugars, and animal fats are associated with dysbiosis, reduced microbial diversity, and impaired intestinal permeability, which may contribute to disease risk [17,271,273]. Excessive intake of saturated fats is associated with unfavorable microbial shifts, whereas omega-3 polyunsaturated and monounsaturated fats (e.g., from fish oil and extra virgin olive oil) enhance microbial diversity, SCFA production, and mucosal integrity, partly via their polyphenol content [17,274]. High added sugar consumption, particularly sucrose and fructose, disrupts the microbiota, reduces SCFA production, and increases pro-inflammatory taxa, a pattern also seen in individuals with sleep disturbances [17]. Excessive consumption of red and processed meat further aggravates dysbiosis, reduces SCFA production, and promotes systemic low-grade inflammation [275]. Alcohol consumption contributes to similar microbial imbalances, weakening barrier function and amplifying permeability [17] (Figure 7). Together, these findings underscore the potential of dietary modification that emphasizes fiber, unsaturated fats, and polyphenol-rich foods while limiting processed foods, sugars, saturated fats, alcohol, and red or processed meat as a microbiome-targeted approach to mitigate chronic pain.

Physical activity is increasingly recognized as both a preventive and therapeutic strategy for chronic pain [276], with growing evidence suggesting that gut microbiota may partly mediate these benefits [277]. Regular physical activity has been shown to increase gut microbial diversity, enrich taxa involved in SCFAs metabolism, and reduce both peripheral and central sensitization [278,279]. In contrast, sedentary behavior has been linked to lower salivary microbial diversity and a higher abundance of Streptococcus, a genus associated with late-onset colorectal cancer, suggesting a possible connection between oral and gut microbiota in disease risk [279]. Exercise can also mitigate the harmful impact of high-fat diets by limiting inflammatory cell infiltration and preserving intestinal morphology [277], whereas high-fat diets combined with sedentary behavior induce villus enlargement via plasmacytoid and lymphocytic infiltration [280]. These changes may be counteracted by regular exercise through downregulation of COX-2 expression in both proximal and distal regions of the intestine [277]. The influence of exercise on the microbiome, however, depends on type, frequency, intensity, and duration [263]. Moderate, regular activity promotes a beneficial microbial profile, whereas irregular or excessive training can disrupt gut barrier integrity, promote bacterial translocation, and trigger dysbiosis, leading to impaired immune and gastrointestinal function [263,277]. Furthermore, activation of the HPA axis during intense physical exertion or psychological stress can further aggravate these microbial alterations [277] (Figure 7).

Emerging evidence suggests a bidirectional relationship between sleep and the gut microbiome, mediated by the microbiota–gut–brain axis [17,281]. Sleep disruption alters microbial composition, with reductions in beneficial taxa such as Bifidobacterium and Lactobacillaceae and increases in Firmicutes or Proteobacteria [281]. These changes are accompanied by greater gut permeability and inflammation [281]. Conversely, dysbiosis can impair sleep by disrupting the production of microbial metabolites such as SCFAs and GABA [17]. Sleep restriction to 4–5 h per night for one week impairs glucose tolerance and reduces tissue insulin sensitivity [282]. Extending time in bed by one hour improves insulin sensitivity in chronically sleep-restricted healthy adults [283]. Both sleep disorders and gut dysbiosis can contribute to abnormalities in carbohydrate metabolism [17] (Figure 7). Notably, sleep disturbance is highly prevalent in chronic pain and may perpetuate dysbiosis through stress-related neuroendocrine activation, low-grade inflammation, and pain-related lifestyle changes. Therefore, optimizing sleep through structured sleep hygiene and behavioral interventions (e.g., cognitive behavioral therapy for insomnia) should be considered a key component of multimodal management to help break this vicious cycle and potentially support microbiome recovery. A balanced diet rich in plant-based foods enhances the production of sleep-regulating metabolites, potentially improving quality of sleep and benefiting overall health [17].

Psychological stress may affect the oral and gut microbiomes independently, thereby forming the oral–brain axis and oral–gut axis, respectively [32,284]. The HPA axis regulates stress responses and modulates the gut–brain axis through ACTH-driven cortisol release [132,133,134]. In people with chronic pain, this axis is often dysregulated, leading to hypercortisolism or hypocortisolism. While acute cortisol has anti-inflammatory effects, chronic elevation alters microbiota [27], increases gut permeability [143], and promotes neuroinflammation [144]. Meditation therapy can improve gut microbiota composition and is associated with reduced risk of anxiety, depression and cardiovascular disease and could enhance immune function [285]. A randomized controlled trial showed that cognitive behavioral therapy for irritable bowel syndrome reduced symptom severity, with treatment success associated with baseline gut microbiome composition and concurrent post-treatment changes in both brain networks and microbiota [286].

Poor oral health/oral dysbiosis triggers oral–gut inflammation, resulting in dysbiosis and compromised barrier integrity. This dysbiosis elevates intestinal permeability, allowing microbial metabolites to leak into circulation and drive pro-inflammatory cytokine production, thereby fostering systemic inflammation [40]. Oral microbiota also cross mucosal barriers during routine activities, entering the bloodstream and disseminating to organs, where they induce immune activation and chronic low-grade inflammation [109]. Recent studies suggest that the oral–gut axis may serve as a potential causal link between oral health and systemic disease [46,98,99,100] and chronic pain [37,287]. Improving oral health may downregulate inflammation through host modulation therapies, as prolonged systemic antibiotic use is discouraged owing to resistance concerns as well as devastating effects on the microbiome; instead, probiotics and bioactive metabolites have been extensively explored for modulating inflammation [288].

Multimodal treatments combining nutritional intervention, oral hygiene, physical activity promotion, and sleep and stress management work synergistically with microbial or pharmacological therapies, ensuring that beneficial species can colonize and function in a supportive host environment.