User:Jmwood48/sandbox

Article Evaluations
The article I evaluated is the article Crime Scene. All of the information contained in the article is relevant to the topic and there is no distracting information. The article is neutral and very fact based. There is no obvious bias in the article. There are no over or under represented viewpoints but there could be more information included in the sections about documentation and reconstruction. The links in the citations work and the references support the claims in the article. The facts are appropriately referenced in most places. The information comes from the Department of Justice, the California Department of Justice Bureau of Forensic Services, and various articles about crime scenes and evidence collection. The information is not biased, so no indication is needed. The conversation in the talk page is about changing the lead section and adding a timeline section. The article is classified as a stub, and there is no importance rating as of right now. Overall this article is well written, but some more information and examples would improve it.

Ideas for Articles to Improve
Purnell equation- I would add a section discussing the history of the equation, when and where it was created and by who. I would also add sections describing how to measure each variable and what each variable means. Sections on how to improve each variable in the equation would also be added.

Post-mortem chemistry- I would add sections about the tests mentioned in the lead section, and any more that I can find that aren't mentioned. I would discuss the different instrumentation used to perform these tests and what the information gained from these tests is used for.

Annotated Bibliography for Post-mortem Chemistry

 * 1) Arroyo, A., et al. “Cerebrospinal Fluid: Postmortem Biochemical Study.” Journal of Clinical Forensic Medicine, vol. 12, no. 3, 2005, pp. 153–156., doi:10.1016/j.jcfm.2004.11.001.
 * 2) * The authors, who are researchers at Legal Medicine Institute of Catalunya in Barcelona, Spain and the Biochemistry Department of Bellvitge hospital, Hospitalet de Llobregat in Barcelona, Spain, studied cerebrospinal fluid. They were examining the changes in cerebrospinal fluid post-mortem. The results show that it is a useful technique for determining levels of different electrolytes/proteins/ect. in the body post-mortem.
 * 3) “Blood Tests.” National Heart Lung and Blood Institute, U.S. Department of Health and Human Services, www.nhlbi.nih.gov/health-topics/blood-tests.
 * 4) * The Department of Health created a list of different types of blood tests, and the different types of information that can be determined from these tests. Some of these tests are used post-mortem to determine cause of death, or if the person was intoxicated, or if they were taking medications, ect.
 * 5) Jashnani, Kusum D., et al. “Vitreous Humor: Biochemical Constituents in Estimation of Postmortem Interval*,†.” Journal of Forensic Sciences, vol. 55, no. 6, 2010, pp. 1523–1527., doi:10.1111/j.1556-4029.2010.01501.x.
 * 6) * The authors studied the concentrations of different electrolytes in the vitreous humor post-mortem at different times to determine a relationship between concentration and time. They also included some information about what the vitreous humor is.
 * 7) Swain, Rajanikanta, et al. “Estimation of Post-Mortem Interval: A Comparison between Cerebrospinal Fluid and Vitreous Humour Chemistry.” Journal of Forensic and Legal Medicine, vol. 36, Nov. 2015, pp. 144–148., doi:10.1016/j.jflm.2015.09.017.
 * 8) * The authors determined that while both vitreous humor and cerebrospinal fluid methods work, vitrous humor analysis is more accurate than cerebrospinal analysis. Their other results agree with Jashnani (3) and Arroyo (1).
 * 9) Yang, Mingzhen, et al. “A Study on the Estimation of Postmortem Interval Based on Environmental Temperature and Concentrations of Substance in Vitreous Humor.” Journal of Forensic Sciences, vol. 63, no. 3, May 2018, pp. 745–751., doi:10.1111/1556-4029.13615.
 * 10) * The authors results agree with Jashnana (3). They varied the temperature of the vitreous humor, as well as the post-mortem interval.
 * 11) Avedschmidt, Sarah. “Postmortem Chemistry.” Edited by Theodore T. Brown, Pathology Outlines - PathologyOutlines.com, 11 Jan. 2017, www.pathologyoutlines.com/topic/forensicschemistry.html.

Post-mortem Chemistry
lead already written

Post-mortem Interval Measurement
The post-mortem interval is the time that has elapsed since death. There are several different methods that can be used to estimate the post-mortem interval.

Vitreous Humor Analysis
The vitreous humor is four to five milliliters of colorless gel in the vitreous body of the eye. Because of its location and the inert nature of the vitreous humor, it is resistant to some of the post-mortem changes that occur in the rest of the body. This is what makes it useful in determining the time since death, along with the fact that it is not affected by age, sex, or cause of death. It is also useful as a source of DNA or for diagnosing diseases. The vitreous humor contains various electrolytes, including but not limited to sodium, potassium, chlorine, calcium, and magnesium. The concentrations of these electrolytes can be measured with analyzers and related to the time since death with various equations. There are various equations because each study has different results, which results in different equations. This is because there are so many factors and differences in experiments that a single equation cannot be determined to be better than the rest. One of these factors is temperature. At higher temperatures, the concentrations are less stable and the degradation of the sample speeds up. The temperature can be controlled once a sample is in the lab, but until then, the body will be the same temperature as the environment it was in. If the same equation is used for a sample that was not kept cold, then the result will not be accurate if the equation is for samples kept cold. Even though different equations have been found, the general trends are in agreement. As the time of death increases, the potassium concentration in the vitreous humor rises, and the sodium and calcium concentrations fall. The ratio of potassium to sodium decreases linearly with time. The reason that the potassium levels rise after death is because of a leak in the cell membrane that allows the concentration to reach equilibrium with the potassium levels in the blood plasma. This method is not exact, but a good estimate for the time since death can be obtained.

Cerebrospinal Fluid Analysis
Cerebrospinal fluid is found in the brain and spinal cord. It is a clear fluid that provides a barrier to absorb shock and prevent injury to the brain. It is useful for diagnosing neuro-degenerative diseases such as Alzheimers. There are various substances in the cerebrospinal fluid that can be measured including urea, glucose, potassium, chloride, sodium, protein, creatinine, calcium, alkaline phosphatase, and cortisol. Different things can be learned about the person or how the died by looking at the concentrations of some of these substances. For example, high levels of urea can indicate kidney damage. High levels of cortisol, the hormone released under stress, could indicate a violent death. Creatinine is stable post-mortem, so the concentration at death is preserved. This is also helpful to determine the kidney function of an individual. Sodium and Potassium can also be measured in the cerebrospinal fluid to predict the time since death, but it is not as accurate as it would be if the vitreous humor was used, since it has a lower correlation.

Toxicological Analysis
Toxicology refers to the science of the chemical and physical properties of toxic substances. Samples from a body are analyzed for drugs or other toxic substances. The concentrations are measured and the substance's contribution to a death can be determined. This is done by comparing concentrations to lethal limits. The most common samples analyzed are blood, urine, kidney, liver, and brain. The samples are usually put through various tests, but the most common instrument used to quantify and determine a substance is gas chromatography-mass spectrometry (GC-MS). These instruments produce chromatograms of the sample, which are then compared to a database of known substances. In blood samples, the substance can usually be found, but in the liver, kidneys, and urine the metabolite may be the only substance that can be found. A metabolite is the broken down version of the original substance after it has gone through digestion and/or other biological processes. Substances can take anywhere from hours to weeks to metabolize and leave the body and have different retention times in different parts of the body. For example, cocaine can be detected in the blood for two to ten days, while it can be detected in urine for two to five days.

Blood Analysis
When blood is used for toxicology testing, drugs of abuse are the usual targets of analysis. Other substances that may be looked for are medications that are known to be prescribed to the individual or poisons if it is suspected.

Tissue Analysis
Tissues can be analyzed to help determine a cause of death. The tissue samples that are most commonly analyzed are the liver, kidney, brain, and lungs.

Hair and Fingernail Analysis
Hair samples can also be analyzed post-mortem to determine if there was a history of drug use or poisoning due to the fact that many substances stay in the hair for a long time. The hair can be separated into sections and a month by month analysis can be performed. Fingernails and hair follicles can also be analyzed for DNA evidence.

Gastric Contents
The stomach contents can also be analyzed. This can help with the post-mortem interval identification by looking at the stage of digestion. The contents can also be analyzed for drugs or poisons to help determine a cause of death if it is unknown.

Post-mortem Diagnosis
Post-mortem diagnosis is the use of post-mortem chemistry analysis tests to diagnose a disease after someone has passed away. Some diseases are unknown until death, or were not correctly diagnosed earlier. One way that diseases can be diagnosed is by examining the concentrations of certain substances in the blood or other sample types. For example, diabetic ketoacidosis can be diagnosed by looking at the concentration glucose levels in the vitreous humor, ketone bodies, glycated hemoglobin, or glucose in the urine. Dehydration can be diagnosed by looking for increased urea nitrogen, sodium, and chloride levels, with normal creatinine levels in the vitreous humor. Endocrine disorders can be diagnosed by looking at hormone concentrations and epinephrine and insulin levels. Liver diseases can be diagnosed by looking at the ratio of albumin and globulin in the sample.