Excretion analysis

We have completed full excretion analysis of the 5 nm positive, neutral and negative surface CNDs, the 11 nm negatively charged CND, and the 22 nm positively charged CND in healthy mice. ... 

Description of Method. Creatine is an organic acid found in muscle tissue that supplies energy for muscle contractions. One of its metabolic products is creatinine, which is excreted in urine. Because the concentration of creatinine in urine and serum is an important indication of renal function, rapid methods for its analysis are clinically important. In this method the rate of reaction between creatinine and picrate in an alkaline medium is used to determine the concentration of creatinine in urine. Under the conditions of the analysis, the reaction is first-order in picrate, creatinine, and hydroxide. 

Human exposure to environmental contaminants has been investigated through the analysis of adipose tissue, breast milk, blood and the monitoring of faecal and urinary excretion levels. However, while levels of persistent contaminants in human milk, for example, are extensively monitored, very little is known about foetal exposure to xenobiotics because the concentrations of persistent compounds in blood and trans-placental transmission are less well studied. Also, more information is needed in general about the behaviour of endocrine disruptive compounds (and their metabolites) in vivo, for example the way they bind to blood plasma proteins. 

Nitrophenol and 4-nitrophenol glucuronide are excreted in urine. The studies of urinary excretion of methyl parathion metabolites, including those reported in this section, generally hydrolyze the glucuronide prior to analysis and report the resulting total 4-nitrophenol values. 

Methods of detection, metabolism, and pathophysiology of the brevetoxins, PbTx-2 and PbTx-3, are summarized. Infrared spectroscopy and innovative chromatographic techniques were examined as methods for detection and structural analysis. Toxicokinetic and metabolic studies for in vivo and in vitro systems demonstrated hepatic metabolism and biliary excretion. An in vivo model of brevetoxin intoxication was developed in conscious tethered rats. Intravenous administration of toxin resulted in a precipitous decrease in body temperature and respiratory rate, as well as signs suggesting central nervous system involvement. A polyclonal antiserum against the brevetoxin polyether backbone was prepared a radioimmunoassay was developed with a sub-nanogram detection limit. This antiserum, when administered prophylactically, protected rats against the toxic effects of brevetoxin. 

Applicators, mixers, loaders, and others who mix, spray, or apply pesticides to crops face potential dermal and/or inhalation exposure when handling bulk quantities of the formulated active ingredients. Although the exposure periods are short and occur only a few times annually, an estimate of this exposure can be obtained by quantifying the excreted polar urinary metabolites. Atrazine is the most studied triazine for potential human exposure purposes, and, therefore, most of the reported methods address the determination of atrazine or atrazine and its metabolites in urine. To a lesser extent, methods are also reported for the analysis of atrazine in blood plasma and serum. 

Since collection of all urine from volunteers over a 24-h period may not be possible, creatinine analysis of the composite total urine sample is recommended. This will allow for a more scientific analysis and interpretation of the excretion pattern presented by the worker during the course of the monitoring. 

Calculation of ID using biological monitoring techniques requires the knowledge of the pharmacokinetics of the parent pesticide in laboratory animals. This will allow the use of the parent or its urine metabolite(s) to calculate the total amount of the parent that had been absorbed through the skin of the test subject. The amount of the residue in the urine should be corrected for any molecular weight differences between the parent and its urine metabolite(s) and also corrected for daily urine excretion volumes based on creatinine analysis of the urine samples. 

Analysis of the urinary data. The amount of creatinine and 3,5,6-TCP in each urine collection was calculated from the volume of the urine specimen and the concentration of each in that urine specimen. The amount of creatinine excreted per day was compared across days for each volunteer and to standard literature values for creatinine excretion (i.e., mean 1.8 g/24 hr 95% range, 1.1 to 2.5 g/24 hr). The urine collection was considered to be complete if the amount of creatinine was consistent with the amount of creatinine in the other urine specimens provided by that individual and within the literature range for normal creatinine excretion. 

MDCK II cells (Fig. 12.3) [93], Kinetic analysis revealed that the Km value for transcellular transport (24 pM) was similar to the Km for OATP2 (34 pM) [93], Moreover, the efflux across the bile canalicular membrane was not saturated under these experimental conditions. These in vitro observations are consistent with in vivo experimental results in rats which showed that the rate-determining process for the biliary excretion of pravastatin is uptake across the sinusoidal membrane. By normalizing the expression level between the double transfectant and human hepatocytes, it might be possible to predict in vivo hepatobiliary excretion. 

If the unbound drug concentrations in plasma are higher than their K values on the transporters, then transporter function may be significantly affected [106], Following a pharmacokinetic analysis of the effect of probenecid on the hepatobiliary excretion of methotrexate, it has been shown the extent of an in vivo drug-drug interaction can be quantitatively predicted from the kinetic parameters for transport across the sinusoidal and bile canalicular membranes determined in vitro [107]. 

Baker et al. [138] studied the excretion of metabolites in bile following the administration of primaquine in rats. Six metabolites of primaquine were found in the bile of rats. Quantitative high performance liquid chromatography analysis of the metabolites revealed that the sum of the six metabolites excreted in the bile represented quantitative recovery of the dose of primaquine. 

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