Bowen Wang, Samuel J Stephen, Erika L Cyphert, Chongshan Liu, Christopher J Hernandez, Deepak Vashishth
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引用次数: 0
Abstract
Disruptions of the composition of the gut microbiome are linked to impaired bone tissue strength. Fecal microbiota transplantation (FMT) is an established clinical therapy that can restore a healthy gut microbiome and reduce systemic inflammation. However, whether FMT from a healthy donor could rescue bone fragility is unknown. As induced inflammation causes mineralization defects, we hypothesize that manipulations of the gut microbiota alter bone fracture resilience through changes in mineral quality. Here, we altered the compositions of the gut microbiome in mice via antibiotics (ampicillin and neomycin) and FMT. Mice were allocated to 5 groups (M/F, N = 13-18/group): Unaltered, Continuous (dosed 4-24 wk), Initial (dosed 4-16 wk), Reconstituted (dosed 4-16 wk with subsequent FMT from age- and sex-matched mice with unaltered gut microbiota), and Delayed (dosed 16-24 wk). Fracture toughness testing and Raman spectroscopy were conducted on the femora. The maximum toughness was greater in the Reconstituted group (for females, p < .05 compared to Continuous, Unaltered, and Delayed groups; for males, p < .05 compared to groups with antibiotic dosing). The Reconstituted group showed lower type-B carbonate substitution in the bone mineral (all p < .01 for both sexes), and lower mineral-to-matrix ratio (all p < .01 for males, for females, p < .01 compared to Unaltered, Initial, and Delayed groups). In females, mineral crystallinity was higher in the Reconstituted group than those dosed with antibiotics (all p < .05). Serum inflammation marker TNF-α was positively correlated with type-B carbonate substitutions (ρ = 0.66), mineral-to-matrix ratio (ρ = 0.71), and carboxymethyl-lysine (CML) in bone matrix (ρ = 0.43). Enhanced bone maximum fracture toughness was associated with reduced type-B carbonate substitution (r = -0.45), decreased mineral-to-matrix ratio (r = -0.40), increased mineral crystallinity (r = 0.33), and lower levels of bone CML (r = -0.49, all p < .01). These results suggest that the introduction of more beneficial gut microbiota can increase fracture resistance by modifying mineral composition and quality, likely through the reduction of systemic inflammation.
肠道微生物群组成的破坏与骨组织强度受损有关。粪便微生物群移植(FMT)是一种成熟的临床治疗方法,可以恢复健康的肠道微生物群,减少全身炎症。然而,来自健康供体的FMT是否能够挽救骨骼脆弱尚不清楚。由于诱导炎症导致矿化缺陷,我们假设肠道微生物群的操纵通过改变矿物质质量来改变骨折的恢复能力。在这里,我们通过抗生素(氨苄西林和新霉素)和FMT改变了小鼠肠道微生物组的组成。小鼠被分为5组(M/F, N = 13-18/组):未改变组、连续组(给药4-24周)、初始组(给药4-16周)、重组组(给药4-16周,随后从年龄和性别匹配的小鼠中获得FMT,肠道微生物群未改变)和延迟组(给药16-24周)。对股骨进行断裂韧性测试和拉曼光谱分析。重组组的最大韧性更大(女性,p p p p p p p r = -0.45),矿物质与基质比降低(r = -0.40),矿物质结晶度增加(r = 0.33),骨CML水平降低(r = -0.49,均p
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