An efficient removal approach for degradation of metformin from aqueous solutions with sulfate radicals.

Metformin consumption for diabetes treatment is increasing, leading to its presence in wastewater treatment plants where conventional methods cannot remove it. Therefore, this work aims to analyze the performance of advanced oxidation processes using sulfate radicals in the degradation of metformin from water. Experiments were performed in a photoreactor provided with a low-pressure Hg lamp, using K2S2O8 as oxidant and varying the initial metformin concentration (CA0), oxidant concentration (Cox), temperature (T), and pH in a response surface experimental design. The degradation percentages ranged from 26.1 to 87.3%, while the mineralization percentages varied between 15.1 and 64%. Analysis of variance (ANOVA) showed that the output variables were more significantly affected by CA0, Cox, and T. Besides, a reduction of CA0 and an increase of Cox up to 5000 µM maximizes the metformin degradation since the generation of radicals and their interaction with metformin molecules are favored. For the greatest degradation percentage, the first order apparent rate constant achieved was 0.084 min-1. Furthermore, while in acidic pH, temperature benefits metformin degradation, an opposite behavior is obtained in a basic medium because of recombination and inhibition reactions. Moreover, three degradation pathways were suggested based on the six products detected by HPLC-MS: N-cyanoguanidine m/z = 85; N,N-dimethylurea m/z = 89; N,N-dimethyl-cyanamide m/z = 71 N,N-dimethyl-formamide m/z = 74; glicolonitrilo m/z = 58; and guanidine m/z = 60. Finally, it was shown that in general the toxicity of the degradation byproducts was lower than the toxicity of metformin toward Chlamydomonas reinhardtii.

[Usefulness of oral calcium test in renal lithiasis]. / Utilidad de la carga bucal con calcio en la litiasis renal.

We report the results of an oral tolerance test performed in 317 patients with kidney stones. In order to avoid PTH or AMPc measurements, and therefore to reduce costs and time to get the results, we measured the tubular maxima of phosphate per glomerular filtration rate (TmP04/GFR, the phosphate threshold). Urine collections from 7 to 9 h and from 9 to 13 h were obtained. The samples were analyzed for calcium, creatinine and phosphorus content. All patients ingested 1 g of calcium mixed in a meal at 9 o'clock. Venous blood samples were obtained for calcium, creatinine and phosphorus measurements, previous to the calcium ingestion. Urinary calcium to creatinine ratio, before and after the calcium-load, as well as TmP04/GFR were calculated. In 97 subjects (30.8%) there were no calcium metabolism abnormalities. Idiopathic hypercalciuria was present in 183 (57%) and primary hyperparathyroidism in 37 (11.7%). Idiopathic hypercalciuria was classified in four subgroups: absorptive hypercalciuria with normal serum phosphorus, absorptive hypercalciuria with low serum phosphorus (renal phosphate leak), renal hypercalciuria with normal phosphorus and renal hypercalciuria with low serum phosphorus.