Post-mortem interval

This article is about forensic science. For Rosicrucian death practices, see Rosicrucianism § Preservation period after death.

Stages of death
1. Pallor mortis 2. Algor mortis 3. Rigor mortis 4. Livor mortis 5. Putrefaction 6. Decomposition 7. Skeletonization

Post-mortem interval (PMI) is the time that has elapsed since a person has died. If the time in question is not known, a number of medical/scientific techniques are used to determine it. This also can refer to the stage of decomposition of the body.

Types of change after death

Many types of changes to a body occur after death. Some of those that can be used to determine the post mortem interval are:^[1]^[2]

Algor mortis - body cooling;^[1]^:16
Livor mortis - settling of blood in the lowest-placed parts of the body;^[1]^:15–16
Rigor mortis - stiffening of limbs;^[1]^:115
Forensic entomology - insect (especially blowfly)^[2]^:2 activity on the corpse;^[1]^:17
Vitreous humour changes - eye chemistry;^[3] ^[4]
State of decomposition - autolysis (process of self digestion) and putrefaction (process caused by bacteria found within the body).^[1]^:16

Traditional decomposition stages

A person who judges the time of death by the means of decomposition can refer to a simple five-stage process:

Stage 1: Initial Decay - Bacteria located mainly in the lower intestine begin decomposition, giving a greenish color to the lower abdomen.^[1]^:17
Stage 2: Putrefaction - Bacteria grow throughout the body, releasing gases, including cadaverine, which in turn bloat the body and cause unpleasant odor.
Stage 3: Black Putrefaction - This stage brings further discoloration to the body. The gases from bacterial decay begin to escape, causing strong odor.
Stage 4: Butyric Fermentation - The internal organs liquefy and the body begins to dry out.
Stage 5: Mummification - This is the slowest of the five stages. In a hot, dry climate the body may dehydrate, inhibiting bacterial decay; the skin dries to a dark leathery appearance.^[1]^:17

More advanced methods

More advanced methods include DNA quantification,^[5] infrared spectroscopy.^[6] and for buried individuals changes in soils such as the levels of methane,^[7] phosphates and nitrates,^[8] ninhydrin-reactive nitrogen,^[9] volatile organic compounds^[10] and water conductivity.^[11]

References

1 2 3 4 5 6 7 8 Survey of Biological Factors Affecting the Determination of the Postmortem Interval. Bautista, Richard. Spring 2012.
1 2 Blood, guts, gore and soil: decomposition processes in graves and forensic taphonomic applications. Tibbett, Mark. 2010 19th World Congress of Soil Science, Soil Solutions for a Changing World.
↑ Zilg, B.; Bernard, S.; Alkass, K.; Berg, S.; Druid, H. (17 July 2015). "A new model for the estimation of time of death from vitreous potassium levels corrected for age and temperature". 254: 158–166. doi:10.1016/j.forsciint.2015.07.020.
↑ Kokavec, Jan; Min, San H.; Tan, Mei H.; Gilhotra, Jagjit S.; Newland, Henry S.; Durkin, Shane R.; Casson, Robert J. (19 March 2016). "Antemortem vitreous potassium may strengthen postmortem interval estimates". 263. doi:10.1016/j.forsciint.2016.03.027.
↑ Lin, X; Yin, YS; Ji, Q (2011). "Progress on DNA quantification in estimation of postmortem interval". Fa yi xue za zhi. 27 (1): 47–9, 53. PMID 21542228.
↑ Huang, P; Tuo, Y; Wang, ZY (2010). "Review on estimation of postmortem interval using FTIR spectroscopy". Fa yi xue za zhi. 26 (3): 198–201. PMID 20707280.
↑ Davla, M; Moore, TR; Kalacska, M; LeBlanc, G; Costopoulos, A (2015). "Nitrous oxide, methane and carbon dioxide dynamics from experimental pig graves". Forensic Science International. 247: 41–47. doi:10.1016/j.forsciint.2014.12.002.
↑ Senos Matias, MJ (2004). "An investigation into the use of geophysical methods in the study of aquifer contamination by graveyards". Near Surface Geophysics. 2 (3): 131–136. doi:10.3997/1873-0604.2004010.
↑ Van Belle, LE; Carter, DO; Forbes, SL (2009). "Measurement of ninhydrin reactive nitrogen influx into gravesoil during aboveground and below ground carcass (Sus domesticus) decomposition". Forensic Science International. 193: 37–41. doi:10.1016/j.forsciint.2009.08.016.
↑ Vass, A (2012). "Odor mortis". Forensic Science International. 222: 234–241. doi:10.1016/j.forsciint.2012.06.006.
↑ Pringle, JK; Cassella, JP; Jervis, JR; Williams, A; Cross, P; Cassidy, NJ (2015). "Soilwater Conductivity Analysis to Date and Locate Clandestine Graves of Homicide Victims". Journal of forensic sciences. 60 (4): 1052–1061. doi:10.1111/1556-4029.12802.

In medicine

Liquefactive necrosis

Temporal lobe necrosis

Programmed cell death

Immunogenic cell death

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