Elimination profile of low-dose chlortalidone and its detection in hair for doping analysis-Implication for unintentional non-therapeutic exposure.

Chlortalidone (CLT) is a thiazide-type diuretic with high affinity for the erythrocyte carbonic anhydrase. Therapeutically, it is mostly used to treat edema and hypertension due to liver cirrhosis, heart insufficiency, or renal dysfunction. Although diuretics and masking agents are prohibited by the World Anti-Doping Agency (WADA) at all times in sports, substances belonging to this category are constantly detected in athlete samples, according to WADA's annual testing figures. Within this group of structurally diverse compounds, a threshold of 20 ng/mL has been introduced for six substances solely due to their presence as contaminants in other permitted drugs because of pharmaceutical production processes. In a recent presumptive doping case with a low urinary CLT concentration, the question of unintentional doping, for example, by contaminated non-steroidal anti-inflammatory drug intake, arose. To examine this potential scenario, a co-elimination of low-dose CLT and hydrochlorothiazide (HCTA; 20 × 50 µg, 0.2 mg/day each) was conducted on five consecutive days in two volunteers. Urine samples were subjected to liquid chromatography-tandem mass spectrometry (LC-MS/MS). Moreover, we examined the incorporation of CLT in scalp hair. HCTA is rapidly excreted renally in comparatively high concentrations. In contrast, the elimination of CLT is considerably slower (terminal elimination half-life extended by a factor of 12) and, consequently, much less concentrated in corresponding urine samples (45 and 53 ng/mL, respectively). Conversely, a higher hair incorporation of chlorthalidone was observed with simultaneous dosing of both. The results suggest that an unintentional intake of sub-therapeutic CLT doses due to contamination might result in an adverse analytical finding.

An oral load of the early glycation compound lactuloselysine fails to accumulate in the serum of uraemic patients.

BACKGROUND: It has been hypothesized that in renal failure, exogenous glycation compounds from food accumulate and play a major pathogenetic role when renal excretion is impaired. METHODS: To address this, a diet containing a defined amount of the lysine Amadori product (AP) lactuloselysine was used. Plasma concentrations and cumulative urinary excretion of AP were assessed in 16 healthy subjects, 12 renal failure patients and 6 continuous ambulatory peitoneal dialysis (CAPD) patients. Amadori product was measured as furosine using reverse phase high performance liquid chromatography (RP-HPLC) after acid hydrolysis. RESULTS: A diet low in glycation compounds significantly decreased excretion of APs in healthy subjects. In healthy individuals, ingestion of lactuloselysine bound to food proteins caused only a minor acute increase (8.24+/-1.11 mg/day, 2% of the administered dose) of AP excretion in the urine; in patients with renal failure not yet on dialysis, the increase in AP excretion in the urine was significantly less (4.0+/-0.51 mg/day) and the same was true in CAPD patients (0.21+/-0.09 mg/day). The plasma concentration of total APs, i.e. the sum of APs as free amino acids and residues bound to plasma proteins, did not change in any of the three groups, however. CONCLUSION: Dietary APs do not accumulate in the blood even in advanced renal failure. The amount of APs measured as furosine excreted in the urine is significantly less, however, in renal failure and CAPD patients compared with healthy subjects. Although the findings exclude accumulation of lactuloselysine in renal failure, they do not generally exclude accumulation of other food-derived advanced glycation end products (AGEs).

Glucose degradation products in PD fluids: do they disappear from the peritoneal cavity and enter the systemic circulation?

BACKGROUND: Glucose degradation products (GDP) are generated in peritoneal dialysis (PD) fluid during heat sterilization and storage. They are thought to adversely affect the peritoneal membrane. The fate of GDP within the peritoneal cavity has not been well characterized. METHODS: A clinical study was designed to determine (1). whether during the dwell in the peritoneal cavity GDP concentration decreases in the PD fluid as assessed by ex vivo formation of AGE; (2). whether exposure to GDP-containing PD fluids increases plasma fluorescence (as an index of plasma AGE concentration) as well as plasma carboxymethyllysine (CML) concentration; and (3). whether exposure to GDP-containing PD fluids adversely affects glycoprotein CA 125 concentration. A two-group crossover design was adopted comprising two consecutive observation periods of eight weeks each. Stable PD patients were exposed in random order either to conventional PD fluid (heat sterilized at pH 5.5) and subsequently to PD test fluid (or the 2 fluids in reverse order). The PD test fluid was sterilized using a multicompartment bag system separating highly concentrated glucose at pH 3 from the buffer solution. Conventional and test fluids differed with respect to concentrations of GDP, that is, 3-deoxyglucosone (118 vs. 12.3 micromol/L), methylglyoxal (5.3 micromol/L vs. below detection threshold), 3, 4-dideoxyglucosone-3-ene (10 micromol/L vs. below detection threshold) and acetaldehyde (226 vs. <1 micromol/L). RESULTS: The following results were obtained. First, methylglyoxal disappeared completely as early as two hours after intraperitoneal instillation of conventional PD fluid. Second, when spent conventional dialysate was recovered after a two hour and particularly an eight hour dwell and subsequently incubated ex vivo with 40 mg of human serum albumin, there was a continuous decrease of AGE-forming capacity, that is, less generation of fluorescence (AGE) and pyrraline (non-fluorescent Amadori product), and an increase of advanced oxidation protein products (AOPP) in the spent dialysate. Third, plasma fluorescence (exc. 350/em. 430 nm) as an index of circulating AGE compounds as well as plasma CML concentrations were significantly higher in the conventional PD fluid period versus low GDP PD fluid period. Fourth, CA 125 concentrations in spent dialysate were higher during the low GDP PD fluid period compared to the conventional PD fluid period. CONCLUSION: Conventional PD fluid undergoes modifications during intraperitoneal dwell with a loss of AGE forming capacity, suggesting breakdown, precipitation or resorption of GDP in vivo. This is accompanied by an increase in plasma AGE compounds.