Bioluminescent assay of microbial ATP in postmortem tissues for the estimation of postmortem interval

Qian Liu; Qing Sun; Yan Liu; Lan Zhou; Na Zheng; Liang Liu

doi:10.1007/s11596-009-0601-7

Current Medical Science ›› 2009, Vol. 29 ›› Issue (6) : 679 -683. DOI: 10.1007/s11596-009-0601-7

Article

Bioluminescent assay of microbial ATP in postmortem tissues for the estimation of postmortem interval

Author information +

History +

PDF

Abstract

To study the relationship between changes of microbial ATP in four kinds of murine tissues and the postmortem interval (PMI), healthy SD rats were sacrificed and their muscles, livers, spleens and kidneys were sampled at different postmortem intervals. The concentration of microbial ATP was detected using bioluminescent assay and the data was statistically analyzed. The concentration of microbial ATP in muscle increased with PMI time. The peak appeared at the 7th day after death, and at the 10th day, microbial ATP in muscle tissue increased again. In internal organs, the peaks of microbial ATP were observed at the 8th day after death and the level decreased during 8–10 d. The differences in microbial ATP concentration in liver, spleen and kidney were not statistically significant. During day 0 to day 9 after death, the correlation was best between PMI and microbial ATP in muscle. With PMI as the independent variable, the cubic polynomial regression equation was Y=0.02X³-0.166X²-0.666X+13.412 (R²=0.989, P<0.01). In internal organs, the best correlation was found between PMI and microbial ATP during day 0 to day 10. With PMI as the independent variable, the cubic polynomial regression equation was Y=0.016X³-0.127X²-0.809X+13.324 (R²=0.986, P<0.01). There existed high correlations between PMI and microbial ATP concentration in rat tissues. Since only a small amount of tissue was needed for the detection and the sample was not affected by self-decomposition, the method may extend the time range of PMI estimation.

Keywords

forensic medicine / postmortem interval / microbial ATP / bioluminescent assay

Cite this article

Download citation ▾

Qian Liu, Qing Sun, Yan Liu, Lan Zhou, Na Zheng, Liang Liu. Bioluminescent assay of microbial ATP in postmortem tissues for the estimation of postmortem interval. Current Medical Science, 2009, 29(6): 679-683 DOI:10.1007/s11596-009-0601-7

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	StanleyP.E.. A review of bioluminescent ATP techniques in rapid microbiology. J Biolumin Chemilumin, 1989, 4(1): 375-380

[2]	GorusF., SchramE.. Appications of Bio- and chemiluminescence in the clinical laboratory. Clin Chem, 1979, 25(4): 512-519

[3]	MecozziM., AcquistucciR.. Computer assisted determination of ATP in environmental and food samples by bioluminescent assay: comparison of algorithms. Comput Methods Programs Biomed, 2000, 62(1): 35-43

[4]	SunW., KhosraviF., AlbrechtsenH., et al.. Comparison of ATP and in vivo bioluminescence for assessing the efficiency of immunomagnetic sorbents for live Escherichia coli O157:H7 cells. J Appl Microbiol, 2002, 92(6): 1021-1027

[5]	FuZ., RogeljS., KieftT.L.. Rapid detection of Escherichia coli O157:H7 by immunomagnetic separation and real-time PCR. Int J Food Microbiol, 2005, 99(1): 47-57

[6]	SatohT., KatoJ., TakiguchiN., et al.. ATP amplification for ultrasensitive bioluminescence assay: detection of a single bacterial cell. Biosci Biotechnol Biochem, 2004, 68(6): 1216-1220

[7]	UkukuD.O., SapersG.M., FettW.F.. ATP bioluminescence assay for estimation of microbial populations of fresh-cut melon. J Food Prot, 2005, 68(11): 2427-2432

[8]	BellC., StallardP.A., BrownS.E., et al.. ATP-bioluminescent techniques for assessing hygienic condition of milk transport tankers. Int Dairy J, 1994, 4(7): 629-640

[9]	CorbittA.J., BennionN., ForsytheS.J.. Adenylate kinase amplification of ATP bioluminescence for hygiene monitoring in the food and beverage industry. Lett Appl Microbiol, 2000, 30(6): 443-447

[10]	WhiteheadK.A., SmithL.A., VerranJ.. The detection of food soils and cells on stainless steel using industrial methods: UV illumination and ATP bioluminescence. Int J Food Microbiol, 2008, 127(1–2): 121-128

[11]	FrundzhyanV., UgarovaN.. Bioluminescent assay of total bacterial contamination of drinking water. Luminescence, 2007, 22(3): 241-244

[12]	MecozziM., AmiciM., ViscoG.. Correction of the interference by mixing the reagents in the bioluminescent determination of ATP in environmental samples by an interfaced PC photometer and a robust regression procedure. Fresenius J Anal Chem, 1997, 357(6): 747-751

[13]	BulleiaN.C.. An improved method for the extraction of adenosine triphosphate from marine sediments and seawater. Limnol Oceanogr, 1977, 23(1): 174-178

[14]	LarsonE.L., AielloA.E., Gomez-DuarteC., et al.. Bioluminescence ATP monitoring as a surrogate marker for microbial load on hands and surfaces in the home. Food Microbiol, 2003, 20(6): 735-739

[15]	BoyceJ.M., HavillN.L., DumiganD.G., et al.. Monitoring the effectiveness of hospital cleaning practices by use of an adenosine triphosphate bioluminescence assay. Infect Control Hosp Epidemiol, 2009, 30(7): 678-684

[16]	KramerM., Suklje-DebeljakH., KmetecV.. Preservative efficacy screening of pharmaceutical formulations using ATP bioluminescence. Drug Dev Ind Pharm, 2008, 34(5): 547-557

[17]	MorrisH.C.. The benefits of rapid microbiological testing of finished products using ATP bioluminescence. Int J Cosmet Sci, 1998, 20(1): 63-67

[18]	JimenezL.. Adenosine triphosphate bioluminescence analysis for rapid screening of microbial contamination in non-sterile pharmaceutical samples. PDA J Pharm Sci Technol, 2004, 58(3): 159-168

[19]	ConnollyP., BloomfieldS.F., DenyerS.P.. A study of the use of rapid methods for preservative efficacy testing of pharmaceuticals and cosmetics. J Appl Bacteriol, 1993, 75(5): 456-462

[20]	JimenezL.. Molecular diagnosis of microbial contamination in cosmetic and pharmaceutical products: a review. J AOAC Int, 2001, 84(3): 671-675

[21]	ConnR.B., CharacheP., ChapelleE.W.. Limits of applicability of the firefly luminescence ATP assay for the detection of bacteria in clinical specimens. Am J Clin Pathol, 1975, 63(4): 493-501

[22]	MolinO., NilssonL., AnséhnS.. Rapid detection of bacterial growth in blood cultures by bioluminescent assay of bacterial ATP. J Clin Microbiol, 1983, 18(3): 521-525

[23]	ShuB.H., ZhaoZ.Y., XuS.Q., et al.. Study on the rapid bioluminescence assay method for the detection of bacteria. Chin J Luminescence (Chinese), 1999, 20(1): 77-80

[24]	LundinA.. Use of firefly luciferase in ATP-related assays of biomass, enzymes, and metabolites. Methods Enzymol, 2000, 305: 346-370

[25]	HattoriN., SakakibaraT., KajiyamaN., et al.. Enhanced microbial biomass assay using mutant luciferase resistant to benzalkonium chloride. Anal Biochem, 2003, 319(2): 287-295

[26]	KamidateT., YanashitaK., TaniH., et al.. Firefly bioluminescent assay of ATP in the presence of ATP extractant by using liposomes. Anal Chem, 2006, 78(1): 337-342

[27]	LiuQ., CaiX., LiuY., et al.. Spectrophotometric determination of trimethylamine-nitrogen (TMA-N) in cadaver tissues for the estimation of late postmortem interval: a pilot study. J Huazhong Univ Sci Technol [Med Sci], 2008, 28(6): 630-633