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1.
Periodontal Therapy Effects on Nitrite Related to Oral Bacteria: A 6-Month Randomized Clinical Trial.
Cortelli, SC, Costa, FO, Rodrigues, E, Cota, LO, Cortelli, JR
Journal of periodontology. 2015;(8):984-94
Abstract
BACKGROUND Nitrite is a biologic factor relevant to oral and systemic homeostasis. Through an oral bacteria reduction process, it was suggested that periodontal therapy and chlorhexidine (CHX) rinse could affect nitrite levels, leading to negative effects, such as an increase in blood pressure. This 6-month randomized clinical trial evaluated the effects of periodontal therapeutic protocols on salivary nitrite and its relation to subgingival bacteria. METHODS One hundred patients with periodontitis were allocated randomly to debridement procedures in four weekly sections (quadrant scaling [QS]) or within 24 hours (full-mouth scaling [FMS]) in conjunction with a 60-day CHX (QS + CHX and FMS + CHX), placebo (QS + placebo and FMS + placebo), or no mouthrinse (QS + none and FMS + none) use. Real-time polymerase chain reaction determined total bacterial, Aggregatibacter actinomycetemcomitans, Porphyromonas gingivalis, Tannerella forsythia, Treponema denticola, Streptococcus oralis, and Actinomyces naeslundii levels. Salivary nitrite concentration was determined with Griess reagent. Data were analyzed statistically at baseline and 3 and 6 months by analysis of variance, Kruskal-Wallis, Mann-Whitney U, and Spearman correlation tests (P <0.05). RESULTS Nitrite concentrations did not tend to change over time. Regarding CHX use, there was a negative correlation between nitrite and total bacterial load at 6 months (FMS + CHX) and one positive correlation between P. gingivalis and nitrite at baseline (QS + CHX). Independently of rinse type, in the FMS group, nitrite correlated negatively with several microbial parameters and also with a higher percentage of deep periodontal pockets. CONCLUSIONS The relationship between nitrite and bacterial levels appears weak. Short-term scaling exhibited a greater influence on nitrite concentrations then long-term CHX use.
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2.
Experimental evaluation of the nitrite sensitivity coefficient in granular anammox biomass.
Rosenthal, A, Ramalingam, K, Beckmann, K, Deur, A, Fillos, J
Water science and technology : a journal of the International Association on Water Pollution Research. 2013;(9):2103-10
Abstract
Nitrite is widely reported to inhibit anammox activity and growth. One modeling approach for nitrite impairment of anammox growth is the use of a nitrite sensitivity coefficient which increases the endogenous decay coefficient of anammox bacteria proportionally to nitrite concentration. The objective of this study was to measure nitrite concentration profiles within active anammox granules incubated at fixed bulk nitrite concentrations and to compare these with nitrite concentration profiles predicted by a biofilm model that incorporates the nitrite sensitivity coefficient. We developed an apparatus for the repeated measurement of nitrite concentration profiles along the radius of granular anammox biomass over a period of 6 days at fixed bulk nitrite concentrations. Granular anammox biomass was obtained from a two-stage bench-scale partial nitritation/anammox reactor system. There was no apparent effect of nitrite concentration on nitrite utilization kinetics after 6 days at exposures up to 90 mg NO(2)(-)-N/L. These findings suggest that anammox bacteria tolerate extended exposures to elevated nitrite concentrations, and in its present form, the nitrite sensitivity coefficient is not applicable for anammox growth modeling.
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3.
Effect of pH and nitrite concentration on nitrite oxidation rate.
Jiménez, E, Giménez, JB, Ruano, MV, Ferrer, J, Serralta, J
Bioresource technology. 2011;(19):8741-7
Abstract
The effect of pH and nitrite concentration on the activity of the nitrite oxidizing bacteria (NOB) in an activated sludge reactor has been determined by means of laboratory batch experiments based on respirometric techniques. The bacterial activity was measured at different pH and at different total nitrite concentrations (TNO₂). The experimental results showed that the nitrite oxidation rate (NOR) depends on the TNO₂ concentration independently of the free nitrous acid (FNA) concentration, so FNA cannot be considered as the real substrate for NOB. NOB were strongly affected by low pH values (no activity was detected at pH 6.5) but no inhibition was observed at high pH values (activity was nearly the same for the pH range 7.5-9.95). A kinetic expression for nitrite oxidation process including switch functions to model the effect of TNO₂ concentration and pH inhibition is proposed. Substrate half saturation constant and pH inhibition constants have been obtained.
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4.
A 12-month evaluation of nitrite oxide metabolism around immediate and conventionally loaded dental implants.
Güncü, GN, Tözüm, TF, Güncü, MB, Yamalik, N, Tümer, C
Implant dentistry. 2009;(1):27-37
Abstract
BACKGROUND During bone remodeling, alignment of bone is affected by loading direction. Considerable amount of data also suggest nitric oxide (NO) to be involved in bone metabolism. This study was conducted to evaluate the potential changes in NO metabolism in relation to the loading style of dental implants by analyzing the nitrite content of peri-implant sulcus fluid. METHODS Dental implants were placed in 12 patients who had first molar loss bilaterally in the mandibular area. One site of the patient determined as immediately loaded and the other side were conventionally loaded. Clinical parameters were recorded and peri-implant sulcus fluid samples were obtained. Peri-implant sulcus fluid nitrite levels were spectrophoto-metrically determined. Clinical measurements and nitrite analysis were repeated at 1, 3, 6, 9, and 12 months. RESULTS In both groups, there was a reduction between baseline and 12 months in all clinical parameters, except probing depth. Although, steady decrease was noticed in total nitrite levels during the whole experimental period in immediately loaded implants, more fluctuations were observed in conventionally loaded ones. CONCLUSIONS The findings of this 12-month follow-up study support the association of NO in the bone metabolism around dental implants and further suggest the impact of different loading regimens on NO metabolism.
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5.
Acute effects of hydrocortisone on plasma nitrate/nitrite activity and forearm vasodilator responsiveness in normal human subjects.
Williamson, PM, Kohlhagen, JL, Mangos, GJ, Whitworth, JA, Kelly, JJ
Clinical and experimental pharmacology & physiology. 2005;(3):162-6
Abstract
1. The aim of the present study was to examine the acute effects of cortisol infusion on plasma nitrate/nitrite (NO) activity and forearm vascular responsiveness to acetylcholine. 2. We performed two randomized, placebo-controlled, cross-over studies. Study A examined the effects of intravenous hydrocortisone (200 mg over a 3 h period) on blood pressure (BP) and plasma NO activity in six healthy male volunteers. Study B examined the effects of intra-arterial hydrocortisone on cholinergic vasodilator responsiveness in six healthy male volunteers. Vasodilator responsiveness was measured by bilateral strain gauge plethysmography. 3. In study A, there was no significant change in BP during the hydrocortisone infusion. Comparing values obtained following 180 min infusion of hydrocortisone and control, there were significant increases in plasma cortisol (3441 +/- 342 vs 209 +/- 29 nmol/L, respectively; P < 0.001) and glucose (5.7 +/- 0.2 vs 4.6 +/- 0.2 mmol/L, respectively; P < 0.05) and a reduction in plasma renin concentration (PRC) (8.1 +/- 1.2 vs 11.0 +/- 1.8 pg/mL, respectively; P < 0.05) following hydrocortisone infusion. However, there were no significant changes in either plasma NO or in the endogenous NO synthase inhibitors asymmetrical and symmetrical dimethylarginine. 4. In study B, there was no significant change in BP or in cholinergic vasodilator responsiveness during the hydrocortisone infusion. 5. Short-term cortisol infusions do not alter biochemical or physiological markers of NO activity. If cortisol-induced hypertension is mediated by suppression of NO activity in humans, it seems likely that these changes take more than 3 h to become detectable.
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6.
Aconiti tuber increases plasma nitrite and nitrate levels in humans.
Yamada, K, Suzuki, E, Nakaki, T, Watanabe, S, Kanba, S
Journal of ethnopharmacology. 2005;(1-2):165-9
Abstract
Some herbal medicines, including Aconiti tuber (Aconitum carmichaeli Debeaux, Ranunculaceae), have been recognized as being effective for the treatment of a "peripheral uncomfortable feeling of cold (hie)". We hypothesized that these compounds affect peripheral vascular function via the nitric oxide (NO) system, which leads to recovery from "hie". To answer this question, we investigated Aconiti tuber-induced changes in plasma levels of nitrite (p-NO2-) and nitrate (p-NO3-), final nitric oxide-oxidation products measurable in vivo. After written informed consent was obtained, patients suffering from "hie" were treated with several kinds of kampo (Japanese traditional herbal medicine), selected on the basis of traditional theory. Twenty-four patients took kampo formulas, some included Aconiti tuber (n=11; A-group) and others did not (n=13; C-group), for 4 weeks. p-NO2- and p-NO3- levels were measured before the start and after 4 weeks of treatment. In the A-group, the p-NO2- plus p-NO3- (p-NOx) level was significantly increased at 4 weeks (p=0.04), while that of the C-group was not. There was a statistically significant increase in the p-NOx level of the A-group as compared to the C-group (d.f.=1,22, F=9.38, p=0.006). The results suggest that Aconiti tuber may increase NO production in humans.
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7.
Evidence of nitrosative damage in the brain white matter of patients with multiple sclerosis.
Bizzozero, OA, DeJesus, G, Bixler, HA, Pastuszyn, A
Neurochemical research. 2005;(1):139-49
Abstract
Nitric oxide (NO) has been implicated in the pathophysiology of both experimental autoimmune encephalomyelitis and multiple sclerosis (MS). NO-mediated protein damage in MS appears to be confined to large plaques where 3-nitrotyrosine has been detected. To determine whether nitrosative damage takes place beyond visible MS plaques, the occurrence of various NO-triggered protein modifications in normal-appearing white matter (NAWM) of eight MS brains was assessed and compared to that in white matter (WM) of four control brains. As determined by amino acid analysis and western blotting, no evidence of tyrosine nitration was found in the MS samples studied, suggesting that they did not contain appreciable amounts of plaque-derived material. The amino acid composition of total myelin proteins and proteolipid protein (PLP) was also unaltered in the diseased tissue, as was the fatty acid composition of PLP. In addition, we detected no changes in the number of protein free thiols suggesting that oxidation do not occur to any appreciable extent. However, the levels of nitrite in MS-NAWM were higher than those in control WM, while in the MS-gray matter (GM) the concentration of this ion was unaltered. Furthermore, five of the MS samples analyzed, and the same as those with high levels of glial fibrilary acidic protein, showed increased amounts of protein nitrosothiols as determined by the "biotin switch" method. S-nitrosation of GM proteins was again normal. There was no indication of N-nitrosation of tryptophan and N-terminal amino groups in both control and MS tissue. Overall, the data suggests that WM, but not GM, from MS brains is subjected to considerable nitrosative stress. This is the first report to present direct evidence of increased protein S-nitrosation and nitrite content in the brain parenchyma of MS patients.
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8.
Modeling and simulation of oxygen-limited partial nitritation in a membrane-assisted bioreactor (MBR).
Wyffels, S, Van Hulle, SW, Boeckx, P, Volcke, EI, Van Cleemput, O, Vanrolleghem, PA, Verstraete, W
Biotechnology and bioengineering. 2004;(5):531-42
Abstract
Combination of a partial nitritation process and an anaerobic ammonium oxidation process for the treatment of sludge reject water has some general cost-efficient advantages compared to nitrification-denitrification. The integrated process features two-stage autotrophic conversion of ammonium via nitrite to dinitrogen gas with lower demand for oxygen and no external carbon requirement. A nitrifying membrane-assisted bioreactor (MBR) for the treatment of sludge reject water was operated under continuous aeration at low dissolved oxygen (DO) concentrations with the purpose of generating nitrite accumulation. Microfiltration was applied to allow a high sludge retention time (SRT), resulting in a stable partial nitritation process. During start-up of the MBR, oxygen-limited conditions were induced by increasing the ammonium loading rate and decreasing the oxygen transfer. At a loading rate of 0.9 kg N m(-3) d(-1) and an oxygen concentration below 0.1 mg DO L(-1), conversion to nitrite was close to 50% of the incoming ammonium, thereby yielding an optimal effluent within the stoichiometric requirements for subsequent anaerobic ammonium oxidation. A mathematical model for ammonium oxidation to nitrite and nitrite oxidation to nitrate was developed to describe the oxygen-limited partial nitritation process within the MBR. The model was calibrated with in situ determinations of kinetic parameters for microbial growth, reflecting the intrinsic characteristics of the ammonium oxidizing growth system at limited oxygen availability and high sludge age. The oxygen transfer coefficient (K(L)a) and the ammonium-loading rate were shown to be the appropriate operational variables to describe the experimental data accurately. The validated model was used for further steady state simulation under different operational conditions of hydraulic retention time (HRT), K(L)a, temperature and SRT, with the intention to support optimized process design. Simulation results indicated that stable nitrite production from sludge reject water was feasible with this process even at a relatively low temperature of 20 degrees C with HRT down to 0.25 days.
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9.
Serum nitrite and nitrate levels in epileptic children using valproic acid or carbamazepine.
Karabiber, H, Yakinci, C, Durmaz, Y, Temel, I, Mehmet, N
Brain & development. 2004;(1):15-8
Abstract
In experimental epilepsy studies, nitric oxide was found to act as both proconvulsant and anticonvulsant. The objective of this study was to investigate the effects of valproic acid and carbamazepine on serum levels of nitrite and nitrate, which are the metabolites of nitric oxide. To achieve this goal, serum nitrite and nitrate levels were determined in active epileptic 34 children using valproic acid and 23 children using carbamazepine and in non-active epileptic 38 children (control group) not using any antiepileptic drug. In the valproic acid group serum nitrite and nitrate levels were 2.66 +/- 2.11 micromol/l and 69.35 +/- 23.20 micromol/l, 1.89 +/- 1.01 micromol/l and 49.39 +/- 10.61 micromol/l in the carbamazepine group, and 1.22 +/- 0.55 micromol/l, 29.53 +/- 10.05 micromol in the control group, respectively. Nitrite and nitrate levels were significantly high in both valproic acid and carbamazepine groups compared to the control group (P < 0.01). When valproic acid and carbamazepine groups were compared to each other, level of nitrate was found statistically higher in the valproic acid group in relation to the carbamazepine group (P < 0.01), however, there was no statistically significant difference in the levels of nitrite (P > 0.05). No relation could be found between serum drug levels and nitrite and nitrate levels. According to these results, it can be suggested that valproic acid and carbamazepine might have antiepileptic effects through nitric oxide.
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10.
Effects of seawater salinity on nitrite accumulation in short-range nitrification to nitrite as end product.
Yu, DS, Peng, YZ, Zhang, K
Journal of environmental sciences (China). 2004;(2):247-51
Abstract
The effect of seawater salinity on nitrite accumulation in short-range nitrification to nitrite as the end product was studied by using a SBR. Experimental results indicated that the growth of nitrobacteria was inhibited and very high levels of nitrite accumulation at different salinities were achieved under the conditions of 25-28 degrees C, pH 7.5-8.0, and the influent ammonia nitrogen of 40-70 mg/L when seawater flow used to flush toilet was less than 35% (salinity 12393 mg/L, Cl- 6778 mg/L) of total domestic wastewater flow, which is mainly ascribed to much high chlorine concentration of seawater. Results showed that high seawater salinity is available for short-range nitrification to nitrite as the end product. When the seawater flow used to flush toilet accounting for above 70% of the total domestic wastewater flow, the removal efficiency of ammonia was still above 80% despite the removal of organics declined obviously (less than 60%). It was found that the effect of seawater salinity on the removal of organics was negative rather than positive one as shown for ammonia removal.