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Abstract

During shipping, microbial cultures and clinical samples are subjected to irradiation by x-ray baggage inspection systems and most high-containment laboratories use similar equipment to screen materials prior to admittance. Low-to-medium kiloelectron volt (keV) energy baggage x-ray inspection systems are used for this purpose. However, the effect of the x-ray exposure that occurs during the screening session on the viability of microbial agents or the radiation's ability to induce damage to their genomes is unknown. This study was undertaken to determine if the x-ray screening process has any deleterious effects on microbial viability or if it causes mutations to their genome. A total of 11 microorganisms, including bacteria, bacterial spores, yeast, and viruses, were screened with a baggage x-ray inspection system. No evidence of loss of viability was observed. The Ames test was used to determine the extent of radiation-induced mutations resulting from a baggage inspection system exposure. This study concludes that low-to-medium energy x-ray radiation received from the baggage screening x-ray inspection systems used in security operations does not significantly reduce the viability of microorganisms nor cause mutations in the microbial genome.

References

Ames

B. N.

(1971). The detection of chemical mutagens with enteric bacteria. In Hollaender

, (Ed.), Chemical mutagens, principles and methods for their detection (vol. 1) (pp. 267–282). New York: Plenum Press.

Ames

B. N.

(1972). A bacterial system for detecting mutagens and carcinogens. In Sutton

H. E.

& Harris

M. J.

(Eds.), Mutagenic effects of environmental contaminants (pp. 57–66). New York: Academic Press.

Barnes

, Tuley

, & Eisenstadt

(1982). Base-sequence analysis of His + revertants of the hisG46 missense mutation in Salmonella typhimurium. Environmental Mutagenesis, 4, 297.

Bonura

, Youngs

D. A.

, & Smith

K. C.

(1975). R.b.e. of 50 kVp X-rays and 660 keV y-rays (¹³⁷Cs) with respect to the production of DNA damage, repair and cell-killing in Escherichia coli K-12. International Journal of Radiation Biology, 28, 539–548.

Danielson

J. W.

, Zuroski

K. E.

, Twohy

, Thompson

R. D.

, Bell

, & McClure

(2000). Recovery and sporicidal resistance of various B. subtilis spore preparations on porcelain penicylinders compared with results from AOAC test methods. Journal of AOAC International, 83, 145–155.

Driedger

A. A.

, James

A. P.

, & Grayston

M. J.

(1970). Cell survival and x-ray-induced DNA degradation in Micrococcus radiodurans. Radiation Research, 44, 835–845.

Haraldsen

J. D.

, & Sonenshein

A. L.

(2003). Efficient sporulation in Clostridium difficile requires disruption of the sigmaK gene. Molecular Microbiology, 48, 811–821.

Imray

F. P.

, & MacPhee

D. G.

(1981). Mutagenesis by ionizing radiation in strains of Salmonella typhimurium used in the Ames test. International Journal of Radiation Biology and Related Studies in Physics, Chemistry, and Medicine, 40, 111–115.

Isildar

, & Bakale

(1984). Radiation-induced mutagenicity and lethality in Ames tester strains of salmonella. Radiation Research, 100, 396–411.

10.

Isildar

, & Bakale

(1985). Comparative lethal effects of uv and ionizing radiation in Ames tester strains of salmonella. Radiation Research, 103, 461–465.

11.

Isono

, & Yourno

(1974). Chemical carcinogens as frameshift mutagens: Salmonella DNA sequence sensitive to mutagenesis by polycyclic carcinogens. Proceedings of the National Academy of Sciences USA, 71, 1612–1617.

12.

Johansen

, Gulbrandsen

, & Pettersen

(1974). Effectiveness of oxygen in promoting x-ray-induced single-strand breaks in circular phage lambda DNA and killing of radiation-sensitive mutants of Escherichia coli. Radiation Research, 58, 384–397.

13.

MacPhee

D. G.

, & Schoeffel

K. L.

(1981). Frameshift mutagenesis by ultraviolet light effects of broth and caffeine in the post-irradiation plating medium. Mutation Research, 80, 9–14.

14.

Mahmoud

B. S.

(2009). Inactivation effect of x-ray treatments on Cronobacter species (Enterobacter sakazakii) in tryptic soy broth, skim milk, low-fat milk and whole-fat milk. Letters in Applied Microbiology, 49, 562–567.

15.

Mahmoud

B. S.

(2010). Effects of x-ray radiation on Escherichia coli O157:H7, Listeria monocytogeneses, Salmonella enterica and Shigella flexneri inoculated on shredded iceberg lettuce. Food Microbiology, 27, 109–114.

16.

Mahmoud

B. S.

, Bachman

, & Linton

R. H.

(2010). Inactivation of Escherichia coli O157:H7, Listeria monocytogeneses, Salmonella enterica and Shigella flexneri on spinach leaves by x-ray. Food Microbiology, 27, 24–28.

17.

Maron

D. M.

, & Ames

B. N.

(1983). Revised methods for the Salmonella mutagenicity test. Mutation Research, 113, 173–215.

18.

Mortelmans

, & Zeiger

(2000). The Ames Salmonella/microsome mutagenicity assay. Mutation Research, 455, 29–60.

19.

Moga

P. D.

, & Obringer

J. W.

(1996). Assaying the mutagenic potential of ELF radiation through reverse mutagenesis via the Ames test. Colorado Springs, CO: U.S. Air Force Academy.

20.

Roos

, Thomas

W. H.

, & Kellerer

A. M.

(1985). Enhanced response of the Salmonella mutagenicity test to ionizing radiations. Radiation Research, 104, 102–108.

21.

Roos

, Thomas

W. H.

, Fitzek

, & Kellerer

A. M.

(1988). His + reversions caused in Salmonella typhimurium by different types of ionizing radiation. Radiation Research, 116, 292–304.

22.

Sorg

J. A.

, & Sonenshein

A. L.

(2008). Bile salts and glycine as cogerminants for Clostridium difficile spores. Journal of Bacteriology, 190, 2505–2512.

23.

Springthorpe

V. S.

, & Sattar

S. A.

(2005). Carrier tests to assess microbicidal activities of chemical disinfectants for use on medical devices and environmental surfaces. Journal of AOAC International, 88, 182–201.

24.

Youngs

D. A.

, & Smith

K. C.

(1976). The yield and repair of x-ray-induced single-strand breaks in the DNA of Escherichia coli K-12 cells. Radiation Research, 68, 148–154.

Evaluation of the Effects of Radiation from an X-ray Baggage Inspection System on Microbial Agents

Abstract

References