OBJECTIVE: To investigate the treatment of nitric oxide (NO)-induced methemoglobinemia by methylene blue (MB), riboflavin, and N-acetylcysteine (NAC) in vitro. DESIGN: Prospective, controlled in vitro study. SETTING: Research laboratory in a university hospital. PARTICIPANTS: Five healthy volunteers. INTERVENTIONS: Generation of 16% to 18% of methemoglobin in red blood cells by NO and subsequent addition of MB, riboflavin, or NAC. Simultaneous NO (32 ppm) and MB or riboflavin exposure of red blood cells. Induction of 14% to 18% of methemoglobin in red blood cells by NO, subsequent addition of MB or riboflavin, and further incubation with NO (80 ppm). MEASUREMENTS AND MAIN RESULTS: After discontinuation of NO, mean half-life for methemoglobin was significantly reduced by MB from 356 mins (controls) to 5 mins (10 microM) in a dose-dependent manner (p < .001). NAC did not alter the half-life for methemoglobin, and a reduction from 356 to 168 mins was seen for 120 microM riboflavin (p < .001). Methemoglobin formation after 3 hrs of NO exposure was 4.3%+/-0.7% in controls and 0.3%+/-0.1% with 10 microM MB (p < .001); 1 microM MB attenuated methemoglobin formation to 1.9%+/-0.1% (p < .01). With riboflavin (120 microM), methemoglobin was 2.2%+/-0.5% vs. 3.2%+/-0.6% in controls (p < .001). In the presence of high methemoglobin concentrations, further methemoglobin formation was inhibited by 1 and 10 microM MB (p < .001) and attenuated by 0.1 microM MB (p < .001) but not by riboflavin. CONCLUSIONS: In vitro, NO-induced methemoglobin formation is significantly decreased by medium (1 microM) and high (10 microM) concentrations of MB and partially by high riboflavin concentrations (120 microM). NAC and low concentrations of riboflavin do not alter methemoglobin formation.
OBJECTIVE: To investigate the treatment of nitric oxide (NO)-induced methemoglobinemia by methylene blue (MB), riboflavin, and N-acetylcysteine (NAC) in vitro. DESIGN: Prospective, controlled in vitro study. SETTING: Research laboratory in a university hospital. PARTICIPANTS: Five healthy volunteers. INTERVENTIONS: Generation of 16% to 18% of methemoglobin in red blood cells by NO and subsequent addition of MB, riboflavin, or NAC. Simultaneous NO (32 ppm) and MB or riboflavin exposure of red blood cells. Induction of 14% to 18% of methemoglobin in red blood cells by NO, subsequent addition of MB or riboflavin, and further incubation with NO (80 ppm). MEASUREMENTS AND MAIN RESULTS: After discontinuation of NO, mean half-life for methemoglobin was significantly reduced by MB from 356 mins (controls) to 5 mins (10 microM) in a dose-dependent manner (p < .001). NAC did not alter the half-life for methemoglobin, and a reduction from 356 to 168 mins was seen for 120 microM riboflavin (p < .001). Methemoglobin formation after 3 hrs of NO exposure was 4.3%+/-0.7% in controls and 0.3%+/-0.1% with 10 microM MB (p < .001); 1 microM MB attenuated methemoglobin formation to 1.9%+/-0.1% (p < .01). With riboflavin (120 microM), methemoglobin was 2.2%+/-0.5% vs. 3.2%+/-0.6% in controls (p < .001). In the presence of high methemoglobin concentrations, further methemoglobin formation was inhibited by 1 and 10 microM MB (p < .001) and attenuated by 0.1 microM MB (p < .001) but not by riboflavin. CONCLUSIONS: In vitro, NO-induced methemoglobin formation is significantly decreased by medium (1 microM) and high (10 microM) concentrations of MB and partially by high riboflavin concentrations (120 microM). NAC and low concentrations of riboflavin do not alter methemoglobin formation.
Authors: Ellen M McDonagh; José M Bautista; Ilan Youngster; Russ B Altman; Teri E Klein Journal: Pharmacogenet Genomics Date: 2013-09 Impact factor: 2.089
Authors: Darren M Roberts; Renate Heilmair; Nick A Buckley; Andrew H Dawson; Mohamed Fahim; Michael Eddleston; Peter Eyer Journal: BMC Clin Pharmacol Date: 2009-02-16