4,4'-Methylenedianiline (MDA) and 4,4'-methylenediphenyl diisocyanate (MDI) are important intermediates in the production of polyurethanes. In order to biomonitor people exposed to low levels of MDA or MDI we have developed sensitive methods to measure hemoglobin (Hb) adducts and urine metabolites. Adducts and metabolites from 33 workers exposed to MDA and 27 workers exposed to MDI were analyzed by gas chromatography-mass spectrometry after hydrolysis, extraction and derivatization with heptafluorobutyric anhydride. Hb adducts of MDA were detected in 31 out of the 33 MDA workers and both MDA and N-acetyl-MDA (AcMDA) were found in 20 of these individuals. The detection limit for MDA was 20 fmol and for AcMDA 100 fmol/sample, which correspond to an absolute detection limit of approximately 1 fmol MDA and 5 fmol AcMDA, respectively. In the urine of workers exposed to MDA both MDA and AcMDA were found in all samples, with the exception of five where only MDA was detected. Acid hydrolysis of the urine samples yielded an approximately 3-fold higher concentration of MDA than the sum of MDA and AcMDA found after base hydrolysis. MDA but not AcMDA found in urine and in Hb correlate well, except for three outliers. In one workers the Hb adduct level of MDA was very low compared to the urine levels. Two workers had very high levels of MDA as Hb adducts but very low levels as urine metabolites. The former case indicates that the workers were recently exposed to higher levels of MDA. The latter case suggests a relatively low recent exposure. The air levels of MDA, monitored using personal air monitors, were below the detection limit. It was possible, however, to determine exposure to MDA for all workers with the methods presented in this publication. Workers exposed exclusively to MDI were studied. Exposure levels, as monitored using personal air samplers, were below the detection limit of 3 micrograms/m3, with the exception of three individuals. In 10 of the MDI workers, hydrolyzable Hb adducts of MDA (57-219 fmol/g Hb) were found. Except for four subjects, the presence of MDA (0.007-0.14 nmol/l) and AcMDA (0.08-3 nmol/l) was detected in all urine samples after base treatment. Following acid hydrolysis of the urine, higher levels of MDA (0.7-10 nmol/l) were found than the sum of free MDA and AcMDA. According to the present data, it was possible to detect exposure to MDI in a greater number of individuals by analyzing urinary metabolites than by measuring Hb adducts or air monitoring.
These data suggest a possible threshold effect of occupational hexavalent chromium exposure on lung cancer.
Control rats and rats with experimental renal hypertension due to unilateral stenosis of one renal artery received a standard diet (0.23% sodium) and a sodium-deficient diet (0.004% sodium), alternately, during which time blood pressure and plasma renin activity were determined. At the end of the experiment, renin content of the kidneys was measured. In normotensive control rats, the sodium-deficient diet did not affect blood pressure, but plasma renin activity and renin content of the kidneys increased. In rats with renal hypertension, restriction of sodium supply was followed by a fall in blood pressure to normotensive levels, provided that an intact contralateral kidney was present. Similarly, sodium-deficient diet prevented the development of hypertension if given immediately after placing the clip on one renal artery. Restriction of sodium supply provoked a marked increase in plasma renin activity, whereas renin content of the ischemic kidney was only slightly, but significantly, higher than in rats with normal sodium intake. Contrary to this, in unilaterally nephrectomized rats with renal hypertension, neither hypertension nor plasma renin activity or renin content of the kidneys was affected by sodium-deficient diet. In control rats with unilateral nephrectomy, plasma renin activity was only half that of intact rats, and restriction of sodium provoked no more than an increase up to normal values of intact rats. Sodium loss by the contralateral kidney may contribute to both the antihypertensive effect of a sodium-deficient diet and the increase in plasma renin activity.
The article contains sections titled: 1. Allyl Chloride 1.1. Physical Properties 1.2. Chemical Properties 1.3. Production 1.3.1. Chlorination of Propene 1.3.2. Other Production Processes 1.4. Handling, Environmental Protection, Storage, and Transportation 1.5. Quality and Analysis 1.6. Uses 1.7. Economic Aspects 2. Allyl Alcohol 2.1. Physical Properties 2.2. Chemical Properties 2.3. Production 2.3.1. Hydrolysis of Allyl Chloride 2.3.2. Isomerization of Propene Oxide 2.3.3. Hydrolysis of Allyl Acetate 2.3.4. Hydrogenation of Acrolein 2.4. Quality and Analysis 2.5. Uses 2.6. Methallyl Alcohol 3. Allyl Esters 3.1. Properties 3.2. Production 3.2.1. Oxidation of Olefins 3.2.2. Esterification 3.2.3. Transesterification 3.2.4. Other Production Methods 3.3. Uses 3.3.1. Polymer Production 3.3.2. Other Uses 4. Allyl Ethers 4.1. Properties and Uses 4.2. Production 5. Allylamines 5.1. Properties and Uses 5.2. Production 6. Toxicology and Occupational Health
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.