Shunsuke Yoshizawa scite author profile

Significance Periodontal disease (gum disease) is an extremely prevalent inflammatory disease initiated by persistent bacterial insult, leading to the destruction of bone and gingival tissues. Current clinical treatments focus solely on the removal of bacteria. In this study, we put forth a strategy to address the underlying inflammatory imbalance in periodontal disease by harnessing the body’s own sophisticated immunoregulatory mechanisms through the recruitment of regulatory T cells (Tregs). This is accomplished by controllably releasing small quantities (nanogram/kilogram range) of chemokine recognized by Tregs using biodegradable, resorbable polymers with an excellent track record of regulatory approval. Administration of Treg-recruiting treatments to the gingiva of mice and canines reduces clinical scores of disease as well as hard and soft tissue destruction.

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Chemical modification of amino acids by atmospheric-pressure cold plasma in aqueous solution

Takai

Kitamura

Kuwabara

et al. 2014

J. Phys. D: Appl. Phys.

251

175

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In vivo study of magnesium plate and screw degradation and bone fracture healing

et al. 2015

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IL-4/CCL22/CCR4 Axis Controls Regulatory T-Cell Migration That Suppresses Inflammatory Bone Loss in Murine Experimental Periodontitis

Araujo-Pires¹,

Vieira²,

Francisconi³

et al. 2014

104

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Inflammatory bone resorption is a hallmark of periodontitis, and Tregs and Th2 cells are independently associated with disease progression attenuation. In this study, we employed an infection-triggered inflammatory osteolysis model to investigate the mechanisms underlying Treg and Th2 cell migration and the impact on disease outcome. Aggregatibacter actinomycetemcomitans–infected C57Bl/6 (wild-type [WT]) mice develop an intense inflammatory reaction and alveolar bone resorption, and Treg and Th2 cell migration is temporally associated with disease progression attenuation. Tregs extracted from the lesions preferentially express CCR4 and CCR8, whereas Th2 cells express CCR3, CCR4, and CCR8. The absence of CCR5 and CCR8 did not significantly impact the migration of Tregs and Th2 cells or affect the disease outcome. CCR4KO mice presented a minor reduction in Th2 cells in parallel with major impairment of Treg migration, which was associated with increased inflammatory bone loss and higher proinflammatory and osteoclastogenic cytokine levels. The blockade of the CCR4 ligand CCL22 in WT mice resulted in an increased inflammatory bone loss phenotype similar to that in the CCR4KO strain. Adoptive transfer of CCR4+ Tregs to the CCR4KO strain revert the increased disease phenotype to WT mice–like levels; also, the in situ production of CCL22 in the lesions is mandatory for Tregs migration and the consequent bone loss arrest. The local release of exogenous CCL22 provided by poly(lactic-co-glycolic acid) (PLGA) microparticles promotes migration of Tregs and disease arrest in the absence of endogenous CCL22 in the IL-4KO strain, characterized by the lack of endogenous CCL22 production, defective migration of Tregs, and exacerbated bone loss. In summary, our results show that the IL-4/CCL22/CCR4 axis is involved in the migration of Tregs to osteolytic lesion sites, and attenuates development of lesions by inhibiting inflammatory migration and the production of proinflammatory and osteoclastogenic mediators.

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