ABSTRACT
Electrical conductivity (EC) is an important physical and chemical index in electrochemical analysis. In recent years, with the penetration and reference of transformation medicine and interdisciplinary theory and technology in the forensic field, new applications of EC in the field of forensic science have been developed. This paper reviews three aspects of the application of EC, the determination of biological tissue freshness, postmortem interval estimation and the application in forensic taphonomy, in order to provide reference for relevant scientific research and related practices.
Subject(s)
Humans , Autopsy , Electric Conductivity , Forensic Pathology , Forensic Sciences , Postmortem ChangesABSTRACT
Objective To study the mechanism of change of the electrical conductivity (EC) of rat skeletal muscle impregnating solution that occurs with the change of postmortem interval (PMI). Methods Healthy Sprague-Dawley rats were killed and kept at about 25 ℃. Skeletal muscles were extracted at different PMI--immediate (0 d), 1 d, 2 d, 3 d, 4 d, 5 d, 6 d, and 7 d, then mixed with deionized water to make impregnating solution with a mass concentration of 0.1 g/mL. The solution's EC and nine common chemicals in it, such as potassium ion, calcium ion, and chloride ion, were determined. Results EC increased gradually with the extending of PMI (P=0.024) during the 7 days after the rats' death. The content of uric acid (P=0.032), urea nitrogen (P=0.013) and phosphorus (P=0.022) also increased during the extension. However, the content of magnesium ions decreased with extending of PMI (P=0.047). The correlation between potassium ion, sodium ion, chlorine ion, calcium ion, creatinine and PMI were weak (P>0.05). Conclusion The molecular basis of skeletal muscle EC change in rats after their death is the changes of uric acid, urea nitrogen, inorganic phosphorus and other chemical components. Furthermore, combine use of various indicators can improve the accuracy of the EC method to infer PMI.
Subject(s)
Animals , Rats , Electric Conductivity , Forensic Pathology , Muscle, Skeletal , Postmortem Changes , Rats, Sprague-Dawley , Time FactorsABSTRACT
OBJECTIVES@#To determine the electrical conductivity (EC) of the liver, spleen and kidney of rats at different postmortem intervals (PMIs) within 24 hours for investigating the relationship between EC of different organs and early PMI.@*METHODS@#Totally 45 SD rats were sacrificed by cervical dislocation and kept at a constant temperature of 25 ℃. Tissues were taken from the liver, spleen, and kidney of rats at 0, 3, 6, 9, 12, 15, 18, 21 and 24 h. Impregnating solution with a mass concentration 0.1 g/mL was prepared using deionized water. The EC value of impregnating solution with different organs was separately determined. The regression equations of EC and PMI for different organs were established, respectively. The relationship between EC of different organs and early PMI was analysed in deceased rats.@*RESULTS@#The relationship between PMI and EC of the liver and spleen was well fitted with the linear equation. The liver showed the best fitting degree followed by the spleen, while the EC of the kidney showed no significant changes within 24 h. There was a good linear relationship between early PMI and the EC of the liver and spleen.@*CONCLUSIONS@#A good linear relationship between early PMI and the EC of the liver and spleen can be found in rats after death, which can be used for the early PMI estimation.
Subject(s)
Animals , Rats , Electric Conductivity , Forensic Pathology , Liver , Postmortem Changes , Rats, Sprague-Dawley , Spleen , Time FactorsABSTRACT
Objective To detect 715 bp sequence of 28S rRNA in sarcosaphagous flies, and to identify their common species for solving the problem of morphological identification, as well as providing technical support for postmortem interval (PMI) estimation. Methods Twenty-nine common sarcosaphagous flies were collected in Luoyang and classified by morphological characteristics. The DNA was extracted from the fly's legs by Chelex-100 method and then the fragments of 28S rRNA were amplified and sequenced. The results were compared with twenty-eight corresponding fly species of GenBank and EMBL databases. All the sequences were analyzed by MEGA7.0 software, and sequence alignment was performed by the searching in BLAST. The nucleotide composition was analysed, and the intraspecific and interspecific ge-netic distance and phylogenetic tree were established. Results Twenty-nine sarcosaphagous flies were classified into 6 species of 5 genera, 3 families by morphological characteristics. In the obtained 715 bp sequence of 28S rRNA , the comparison result of online BLAST showed that the similarity was 100%. Five species were well clustered by a phylogenetic tree. Between different groups, the interspecific and intraspecific differences ranged from 0.007 to 0.045 and 0 to 0.001, respectively. Conclusion The 28S rRNA target gene sequences shows a good identification capability, which can be a new genetic marker for the identification of sarcosaphagous flies.
ABSTRACT
OBJECTIVES@#To explore the relationship between the change rules of volatile organic compounds (VOCs) in rat muscle and postmortem interval (PMI).@*METHODS@#A total of 120 healthy rats were divided randomly into 12 groups (10 for each group). After the rats were sacrificed by cervical dislocation, the bodies were kept at (25±1) ℃. Rat muscle samples were separately obtained at 12 PMI points, including 0, 0.5, 1, 2, 3, 4, 5, 6, 7, 8, 9 and 10 d. The VOCs in rat muscles were collected, detected and analyzed by headspace solid-phase microextraction (HS-SPME) coupled to gas chromatography-mass spectrometer (GC-MS).@*RESULTS@#In total, 15 species of VOCs were identified, including 9 aromatic compounds, 3 sulfur compounds, 2 aliphatic acids and 1 heterocyclic compound. The species of VOCs increased with PMI: no species were detected within 1 day, 3 species were detected on day 2, 9 on day 3, 11 on day 4, 14 from day 5 to 7, and 15 from day 8 to 10. Total peak area of 15 species of VOCs was significantly correlated to PMI (adjusted R²=0.15-0.96): the regression function was y=-17.05 x²+ 164.36 x-246.36 (adjusted R²=0.96) from day 2 to 5, and y=2.24 x+101.13 (adjusted R²=0.97) from day 6 to 10.@*CONCLUSIONS@#The change rules of VOCs in rat muscle are helpful for PMI estimation.
Subject(s)
Animals , Rats , Autopsy , Gas Chromatography-Mass Spectrometry/methods , Muscles/pathology , Solid Phase Microextraction , Volatile Organic Compounds/chemistryABSTRACT
OBJECTIVES@#To analyze the relationship among electrical conductivity (EC), total volatile basic nitrogen (TVB-N), which is an index of decomposition rate for meat production, and postmortem interval (PMI). To explore the feasibility of EC as an index of cadaveric skeletal muscle decomposition rate and lay the foundation for PMI estimation.@*METHODS@#Healthy Sprague-Dawley rats were sacrificed by cervical vertebrae dislocation and kept at 28 ℃. Muscle of rear limbs was removed at different PMI, homogenized in deionized water and then skeletal extraction liquid of mass concentration 0.1 g/mL was prepared. EC and TVB-N of extraction liquid were separately determined. The correlation between EC (x₁) and TVB-N (x₂) was analyzed, and their regression function was established. The relationship between PMI (y) and these two parameters were studied, and their regression functions were separately established.@*RESULTS@#The change trends of EC and TVB-N of skeletal extraction liquid at different PMI were almost the same, and there was a linear positive correlation between them. The regression equation was x₂=0.14x₁-164.91(R²=0.982). EC and TVB-N of skeletal muscle changed significantly with PMI, and the regression functions were y=19.38x₁³-370.68x₁²+2 526.03 x₁-717.06(R²=0.994), and y=2.56x₂³-48.39x₂²+330.60x₂-255.04(R²=0.997), respectively.@*CONCLUSIONS@#EC and TVB-N of rat postmortem skeletal muscle show similar change trends, which can be used as an index for decomposition rate of cadaveric skeletal muscle and provide a method for further study of late PMI estimation.