Pathological pain can be initiated after inflammation and/or peripheral nerve injury. It is a consequence of the pathological functioning of the nervous system rather than only a symptom. In fact, pain is a significant social, health, and economic burden worldwide. Flavonoids are plant derivative compounds easily found in several fruits and vegetables and consumed in the daily food intake. Flavonoids vary in terms of classes, and while structurally unique, they share a basic structure formed by three rings, known as the flavan nucleus. Structural differences can be found in the pattern of substitution in one of these rings. The hydroxyl group (-OH) position in one of the rings determines the mechanisms of action of the flavonoids and reveals a complex multifunctional activity. Flavonoids have been widely used for their antioxidant, analgesic, and anti-inflammatory effects along with safe preclinical and clinical profiles. In this review, we discuss the preclinical and clinical evidence on the analgesic and anti-inflammatory proprieties of flavonoids. We also focus on how the development of formulations containing flavonoids, along with the understanding of their structure-activity relationship, can be harnessed to identify novel flavonoid-based therapies to treat pathological pain and inflammation.
Unaccustomed exercise involving eccentric contractions, high intensity, or long duration are recognized to induce delayed-onset muscle soreness (DOMS). Myocyte damage and inflammation in affected peripheral tissues contribute to sensitize muscle nociceptors leading to muscle pain. However, despite the essential role of the spinal cord in the regulation of pain, spinal cord neuroinflammatory mechanisms in intense swimming-induced DOMS remain to be investigated. We hypothesized that spinal cord neuroinflammation contributes to DOMS. C57BL/6 mice swam for 2 h to induce DOMS, and nociceptive spinal cord mechanisms were evaluated. DOMS triggered the activation of astrocytes and microglia in the spinal cord 24 h after exercise compared to the sham group. DOMS and DOMS-induced spinal cord nuclear factor κB (NFκB) activation were reduced by intrathecal treatments with glial inhibitors (fluorocitrate, α-aminoadipate, and minocycline) and NFκB inhibitor [pyrrolidine dithiocarbamate (PDTC)]. Moreover, DOMS was also reduced by intrathecal treatments targeting C-X3-C motif chemokine ligand 1 (CX3CL1), tumor necrosis factor (TNF)-α, and interleukin (IL)-1β or with recombinant IL-10. In agreement, DOMS induced the mRNA and protein expressions of CX3CR1, TNF-α, IL-1β, IL-10, c-Fos, and oxidative stress in the spinal cord. All these immune and cellular alterations triggered by DOMS were amenable by intrathecal treatments with glial and NFκB inhibitors. These results support a role for spinal cord glial cells, via NFκB, cytokines/chemokines, and oxidative stress, in DOMS. Thus, unveiling neuroinflammatory mechanisms by which unaccustomed exercise induces central sensitization and consequently DOMS.
Gram-negative bacterial infections
induce inflammation and pain.
Lipopolysaccharide (LPS) is a pathogen-associated molecular pattern
and the major constituent of Gram-negative bacterial cell walls. Diosmin
is a citrus flavonoid with antioxidant and anti-inflammatory activities.
Here we investigated the efficacy of diosmin in a nonsterile model
of inflammatory pain and peritonitis induced by LPS. Diosmin reduced
in a dose-dependent manner LPS-induced inflammatory mechanical hyperalgesia,
thermal hyperalgesia, and neutrophil recruitment to the paw (myeloperoxidase
activity). Diosmin also normalized changes in paw weight distribution
assessed by static weight bearing as a nonreflexive method of pain
measurement. Moreover, treatment with diosmin inhibited LPS-induced
peritonitis as observed by a reduction of leukocyte recruitment and
oxidative stress. Diosmin reduced LPS-induced total ROS production
(DCFDA assay) and superoxide anion production (NBT assay and NBT-positive
cells). We also observed a reduction of LPS-induced oxidative stress
and cytokine production (IL-1β, TNF-α, and IL-6) in the
paw. Furthermore, we demonstrated that diosmin inhibited LPS-induced
NF-κB activation in peritoneal exudate. Thus, we demonstrated,
using a model of nonsterile inflammation induced by LPS, that diosmin
is a promising molecule for the treatment of inflammation and pain.
Background and Purpose
Gouty arthritis is characterized by an intense inflammatory response to monosodium urate crystals (MSU), which induces severe pain. Current therapies are often ineffective in reducing gout‐related pain. Resolvin D1 (RvD1) is a specialized pro‐resolving lipid mediator with anti‐inflammatory and analgesic proprieties. In this study, we evaluated the effects and mechanisms of action of RvD1 in an experimental mouse model of gouty arthritis, an aim that was not pursued previously in the literature.
Experimental Approach
Male mice were treated with RvD1 (intrathecally or intraperitoneally) before or after intraarticular stimulation with MSU. Mechanical hyperalgesia was assessed using an electronic von Frey aesthesiometer. Leukocyte recruitment was determined by knee joint wash cell counting and immunofluorescence. IL‐1β production was measured by ELISA. Phosphorylated NF‐kB and apoptosis‐associated speck‐like protein containing CARD (ASC) were detected by immunofluorescence, and mRNA expression was determined by RT‐qPCR. CGRP release was determined by EIA and immunofluorescence. MSU crystal phagocytosis was evaluated by confocal microscopy.
Key Results
RvD1 inhibited MSU‐induced mechanical hyperalgesia in a dose‐ and time‐dependent manner by reducing leukocyte recruitment and IL‐1β production in the knee joint. Intrathecal RvD1 reduced the activation of peptidergic neurons and macrophages as well as silenced nociceptor to macrophage communication and macrophage function. CGRP stimulated MSU phagocytosis and IL‐1β production by macrophages. RvD1 downmodulated this phenomenon directly by acting on macrophages, and indirectly by inhibiting CGRP release and CGRP‐dependent activation of macrophages.
Conclusions and Implications
This study reveals a hitherto unknown neuro‐immune axis in gouty arthritis that is targeted by RvD1.
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