OBJECTIVE: The purpose of this work is to build a well-plate holder for in vitro gamma knife irradiation to cell lines and to verify its validity. METHODS: A well-plate holder for gamma ray irradiation to cell lines using gamma knife was made of acrylonitrile. Inside the holder, a hexahedral space was excavated to hold well plates. The actual radiation dose to cell lines was obtained by comparing the relative dose of the holder with the gamma knife quality assurance standard phantom. All parameters necessary for cell line irradiation were calculated using the commercial software, Leksell Gamma Plan(R) v5.32. Dose distribution was drawn to six and ninety-six wells to search for optimal parameters for cell line irradiation. RESULTS: The dose rate at the center of the well-plate holder was 94+/-4% of the standard phantom and resulting absolute dose at the central area was 2.1+/-0.1Gy/min. The dose distributions of our phantom was the same as that of the standard phantom in qualitative comparison using an image analyzing software. Appropriate isodose lines which fit with the practical situation were obtained with the 18mm collimator of the Gamma knife. CONCLUSION: Our results show that a well-plate holder for gamma knife irradiation is confident and accurate. It can be used for the study of in vitro cellular effects by gamma knife irradiation in the future.
Acrylonitrile ; Cell Line* ; Gamma Rays

OBJECTIVETo establish a method for rapid determination of airborne acrylonitrile using a portable gas chromatograph.

METHODSA single standard sample of acrylonitrile was prepared in a laboratory and sampled by the built-in constant flow pump of the portable gas chromatograph. The sample was then preconcentrated by the preconcentrator, thermally desorbed, separated by capillary columns, and detected by a micro argon ionization detector to determine the retention time. Retention time was then used to perform qualitative analysis. Under the set condition of gas chromatography, the external standard method was used to create a standard curve for quantitative analysis of acrylonitrile.

RESULTSThe linear range of acrylonitrile on the portable gas chromatograph was 0.25 to 3.00 mg/m(3). The regression equation was y = 10(-5) x-0.0275, r = 0.9977. The limit of detection was 0.005 mg/m(3), and the lower limit of quantification was 0.25 mg/m(3). The relative standard deviation was lower than 7.09%, and the degree of accuracy was 91.09-105.54%.

CONCLUSIONPortable gas chromatography is a simple, repeatable, and accurate method for rapid determination of airborne acrylonitrile.

Acrylonitrile ; analysis ; Air Pollutants, Occupational ; analysis ; Chromatography, Gas ; instrumentation ; Workplace

Acrylonitrile ; poisoning ; Adult ; Female ; Humans ; Male ; Middle Aged ; Young Adult

Acrylonitrile ; toxicity ; Carcinogens ; toxicity ; Humans ; Mutagens ; toxicity ; Occupational Exposure

The hydration reaction by microbial method is the crisis of the procedure of acrylamide production from acrylonitrile. This research studied the enzyme catalytic kinetics and de-active kinetics of nitrile hydratase in the type of free cell. Firstly, the effects of the concentration of cells, the temperature, pH value, the concentration of acrylonitrile and the concentration of acrylamide on the activity of nitrile hydratase was investigated. The result is that the temperature and the concentration of acrylamide are the most important among these factors. The activity of the nitrile hydratase was 5659 u/mL (broth) at 28 degrees C; the counterpart was only 663 u/mL (broth) at 5 degrees C. And the activity of NHase in solution of 45% acrylamide was just about half of that in solution of 5% acrylamide. After study on the relation of temperature and the reaction speed, It was found that the activation energy of the hydration of NHase was 65.57 kJ.mol-1. This paper studied the effects of concentration of cells, temperature, pH value, concentrations of acrylonitrile and acrylamide on the deactivation of Nhase, as well as the related enzyme de-active kinetics. The result also showed that the temperature and the concentration of acrylamide are the most important among these factors. In solution of 35% acrylamide, the residual activity was about 0% of the original value after 55 h; but in solution of 10% acrylamide, after the same period of time, the residual activity was 50% of the original one. It was also found that the concentration of acrylonitrile had little effect on the stability of NHase. The coefficient of deactivation at 28 degrees C was 21.77 times of the one at 5 degrees C. Correlating the temperature and the coefficient of deactivation, the activation energy of the de-active reaction was found to be 92.28 kJ.mol-1.
Acrylamide ; metabolism ; Acrylonitrile ; metabolism ; Catalysis ; Hydro-Lyases ; metabolism ; Hydrogen-Ion Concentration ; Kinetics ; Rhodococcus ; enzymology ; Temperature

Acrylonitrile ; poisoning ; Acute Disease ; Adult ; Humans ; Male ; Parkinsonian Disorders ; chemically induced

Acrylonitrile ; toxicity ; Animals ; Male ; Mice ; Mice, Inbred Strains ; Testis ; drug effects ; pathology

Acrylonitrile ; poisoning ; Adult ; Female ; Humans ; Male ; Middle Aged ; Occupational Diseases ; therapy

OBJECTIVETo study the potential aging effect on workers exposed to acrylonitrile (ACN).

METHODSThe deletion rates of mitochondrial DNA (mtDNA) in peripheral blood nucleate cells of 47 exposed workers and 47 non-exposed workers (as control), as well as 12 old people and 12 young people were measured with polymerase chain reaction (PCR).

RESULTSThe positive rates of mtDNA deletion in peripheral blood nucleate cells were 17.02% in the workers exposed to ACN and 25.00% in group of old people. However, the mtDNA deletion was not detected in the control group and young people.

CONCLUSIONSACN could induce mtDNA deletion in peripheral blood nucleate cells of the exposed workers. There may be a potential molecular effect of occupational ACN exposure on workers' aging.

Acrylonitrile ; toxicity ; Adolescent ; Aged ; Aged, 80 and over ; Aging ; drug effects ; Blood Cells ; drug effects ; ultrastructure ; DNA Damage ; DNA, Mitochondrial ; drug effects ; Humans ; Occupational Exposure

Acrylonitrile is most commonly used aliphatic nitrile compounds characterized by the structural formula R-C=N and used mossy to make acrylic fibers, plastics, synthetic rubber, and wall coverings. In recent, because of its extensive usage and the rapid expansion of the chemical industry, many poisonings have been reported and many studies on its health effects have been performed. Acute toxicity resembles cyanide poisoning and results mainly in effects on the nervous system. High exposure also can cause temporary damage to red blood cells and the liver and can cause lead to death. Because long-term occupational exposure to the acrylonitrile has been with cancer in humans, the U.S EPA classifies acrylonitrile as probable carcinogen. For this reason, The federal government has developed regulations and advisories to protect individuals firm the potential health effects of acylonitrile in the environment, but there are few studies, case reports and regulations of the government in our country. We experienced acute poisoning caused by acrylonitrile inhalation that occurred in an industrial accident. So, we report this case with literature reveiw.
Accidents, Occupational ; Acrylonitrile* ; Chemical Industry ; Elastomers ; Erythrocytes ; Federal Government ; Humans ; Inhalation* ; Liver ; Nervous System ; Occupational Exposure ; Plastics ; Poisoning* ; Social Control, Formal