Oxidative stress links periodontal inflammation and renal function.

AIMS: Patients with chronic kidney disease (CKD) are also susceptible to periodontitis. The causal link between periodontitis and CKD may be mediated via systemic inflammation/oxidative stress. Using structural equation modelling (SEM), this cross-sectional study aimed to explore the causal relationship between periodontal inflammation (PI) and renal function. MATERIALS AND METHODS: Baseline data on 770 patients with stage 3-5 (pre-dialysis) CKD from an ongoing cohort study were used. Detailed, bioclinical data on PI and renal function, as well as potential confounders and mediators of the relationship between the two, were collected. SEMs of increasing complexity were created to test the causal assumption that PI affects renal function and vice versa. RESULTS: Structural equation modelling confirmed the assumption that PI and renal function are causally linked, mediated by systemic oxidative stress. The magnitude of this effect was such that a 10% increase in PI resulted in a 3.0% decrease in renal function and a 10% decrease in renal function resulted in a 25% increase in PI. CONCLUSIONS: Periodontal inflammation represents an occult source of oxidative stress in patients with CKD. Further clinical studies are needed to confirm whether periodontal therapy, as a non-pharmacological approach to reducing systemic inflammatory/oxidative stress burden, can improve outcomes in CKD.

LDL-lipids from patients with hypercholesterolaemia and Alzheimer's disease are inflammatory to microvascular endothelial cells: mitigation by statin intervention.

Elevated low-density lipoprotein (LDL) concentration in mid-life increases the risk of developing Alzheimer's disease (AD) in later life. Increased oxidized LDL (oxLDL) modification and nitration is observed during dementia and hypercholesterolaemia. We investigated the hypothesis that statin intervention in mid-life mitigates the inflammatory effects of oxLDL on the microvasculature. Human microvascular endothelial cells (HMVECs) were maintained in transwells to mimic the microvasculature and exposed to patient and control LDL. Blood was obtained from statin-naive, normo- and hyper-lipidaemic subjects, AD with vascular dementia (AD-plus) and AD subjects (n=10/group) at baseline. Only hyperlipidaemic subjects with normal cognitive function received 40 mg of simvastatin intervention/day for 3 months. Blood was re-analysed from normo- and hyper-lipidaemic subjects after 3 months. LDL isolated from statin-naive hyperlipidaemic, AD and AD-plus subjects was more oxidized (agarose gel electrophoretic mobility, protein carbonyl content and 8-isoprostane F2α) compared with control subjects. Statin intervention decreased protein carbonyls (2.5±0.4 compared with 3.95±0.2 nmol/mg; P<0.001) and 8-isoprostane F2α (30.4±4.0 pg/ml compared with 43.5±8.42 pg/ml; P<0.05). HMVEC treatment with LDL-lipids (LDL-L) from hyperlipidaemic, AD and AD-plus subjects impaired endothelial tight junction expression and decreased total glutathione levels (AD; 18.61±1.3, AD-plus; 16.5±0.7 nmol/mg of protein) compared with untreated cells (23.8±1.2 compared with nmol/mg of protein). Basolateral interleukin (IL)-6 secretion was increased by LDL-L from hyperlipidaemic (78.4±1.9 pg/ml), AD (63.2±5.9 pg/ml) and AD-plus (80.8±0.9 pg/ml) groups compared with healthy subject lipids (18.6±3.6 pg/ml). LDL-L isolated after statin intervention did not affect endothelial function. In summary, LDL-L from hypercholesterolaemic, AD and AD-plus patients are inflammatory to HMVECs. In vivo intervention with statins reduces the damaging effects of LDL-L on HMVECs.