Forensic serology

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is the detection, identification, classification, and study of various bodily fluids such as blood, semen, saliva, and urine, and their relationship to a crime scene. A forensic serologist may also be involved in DNA analysis and bloodstain pattern analysis. [1]  [2]  Serology testing begins with presumptive tests which gives the analyst an indication that a specific bodily fluid may be present, but cannot completely confirm its presence. Following the presumptive tests, confirmatory tests are done on the same sample to confirm what the unknown substance actually is. [3]

Blood detection

Blood is composed of liquid plasma and serum with solid components consisting of red blood cells (erythrocytes), white blood cells (leukocytes), and platelets (thrombocytes). [4] To detect blood at a crime scene or in the laboratory, an array of tests can be used. The most publicized test by crime shows is the Luminol process in which a chemical is sprayed onto a surface where blood is suspected to be. [4] The chemical reacts with traces of blood, producing a chemi-luminescence, or apparent glow, as a result of the chemical reaction that occurs. As with all presumptive tests, this technique can produce false positive results due to metals and strong chemicals, such as bleach, that will also react. Another common presumptive test is the Kastle-Meyer or Phenolphthalein test. This is a catalytic test that detects the heme group in blood that transports oxygen and carbon dioxide. [5] A sterile cotton swab is soaked in distilled water and applied to the area of suspected blood to pick up some of the sample. [5] One drop of alcohol is applied to the swab, followed by the addition of one drop of the phenolphthalein reagent, followed by one drop of hydrogen peroxide. [6] A positive result induces a color change to pink. [4] Similar to the Kastle-Meyer test, a hemastix is also a catalytic test simplified to a specialized strip where the blood sample is extracted by a wet swab and placed directly on the hemastix. [7] A positive result induces a colour change from yellow to dark green. [7]

Contents

For confirmatory tests, the Takayama Crystal Assay or an immunochromatographic test are typically used. The Takayama Crystal Assay, which forms a ferro protoporphyrin ring by a reaction between pyridine and the iron atom of the heme group. [8] The Takayama reagent is added to a slide with a presumptive blood sample. The slide is dried at 115 degrees Celsius following the addition of the Takayama reagent. Then it is placed under a microscope and a positive result is the visualization of dark red, feathery crystals. [3] For the immunochromatographic test, it functions similar to a pregnancy test where antigens present in blood are detected and a positive result is a band at the test site and control site. [9] After performing the various tests an analyst can confirm the presence of human blood and continue to develop a DNA profile with downstream applications such as DNA extraction, Polymerase Chain Reaction (PCR), Capillary Electrophoresis (CE), etc., followed by profile interpretation.

Stained sperm under microscope Sperm stained.JPG
Stained sperm under microscope

Semen detection

Semen is a colorless fluid that is ejaculated from a male's penis due to sexual arousal. In order to initially detect semen, an alternative light source (ALS) is used. [3] Under UV light, semen fluoresces making it visible to investigators to collect samples from a crime scene. A common presumptive test for detecting semen is called the acid phosphatase (AP) test. [3] The AP test detects the enzyme acid phosphatase that is secreted from the prostate gland. [4] However, this test is only presumptive because acid phosphatase is found in other bodily fluids. [4] To perform the test, a drop of the reagent sodium alpha-napthyphosphate is added to the presumptive stain followed by a drop of fast blue B. A positive result of this test is a color change to dark purple. [4] [3]

Confirmatory tests for semen include the christmas tree stain and the p30/PSA RSID kit. For the christmas tree stain, the sample is extracted with sterile water in order to make a wet mount on a microscope slide. The sample is then heat-fixed to the slide and stained with nuclear fast red for 15 minutes, then rinsed with deionized water. [8] Next, a green stain is applied for 10 seconds, then rinsed with ethanol. The slide is placed under a compound light microscope for sperm observation. If sperm are present, the heads will stain red and the mid-piece and tail stain green. [8] However, not all males release sperm in their semen. If a male is aspermic or oligospermic, they either have no sperm or a low sperm count. [10] Vasectomized males will not release sperm either. [4] When sperm cells are not present, a second confirmatory test, the p30/PSA test, is performed. [3]

PSA(p30) is known as a prostate-specific antigen that is produced by the prostatic gland in males. [9] The p30/PSA test is an immunochromatographic test that detects the presence of the antigen p30 in semen samples. This test functions similar to a pregnancy test, where if the antigen p30 is present a band will appear at the test site and a control band will appear to confirm if the test is working properly. [4] If the confirmatory test is positive, then semen is present in the sample. From there an analyst could continue to develop a DNA profile with downstream applications.

Saliva detection

A presumptive test to detect saliva is the alpha-amylase test also known as the Phadebas Test. [4] This detection technique is based on the activity of the enzyme alpha-amylase which breaks down starches from food into smaller oligosaccharide molecules, starting digestion in the mouth. [11] Using a petri dish gel, the saliva sample is added and allowed to diffuse through the gel overnight. Visualization is accomplished by adding iodine to the gel which stains the starch in the gel blue. If saliva is present, then the alpha-amylase breaks down the starch, creating a clear coloured circle around where the sample was placed. RSID tests have also been made in order to detect alpha-amylase, but they are not always reliable because there can be a lot of false positives. [3]

For confirmatory tests, there has not been as much research done compared to blood and semen. Since these tests specifically target amylase, confirmatory tests can not be done considering amylase can be found in other bodily fluids. [12]

Urine Detection

The presumptive detection of urine can be done by alternative light sources or a paradimethylaminocinnamaldehyde test (DMAC). [13] The DMAC will react with urea, uric acid or ammonia which can all be found in urine. [13] When a sample with potential urine is found, 0.1% DMAC can be applied. If there is a positive reaction, a pink/magenta colour will be present on the stain. [13] There are only presumptive tests for urine detection because the tests used target material that can be found in other bodily fluids. This can cause a lot of false positives and inaccurate results. [13]

Current research: microRNA

Testing for different body fluids with traditional serological techniques, such as those listed above, is possible, but not without some drawbacks. Firstly, not all body fluids have a reliable confirmatory test, and those that do typically require a larger amount of the suspected stain in order to perform the confirmatory test. This can be limiting if the forensic sample being tested is small to begin with. Also, serology is often done before any downstream analyses like DNA, so if sample is limited in size to begin with performing serological analyses and obtaining a DNA profile successfully may not be possible. Currently, researchers are looking into ways to identify bodily fluids with more success and less sample needed, and an emerging way to do this is with micro RNAs.

Micro RNAs (miRNA) are small, noncoding, single-stranded RNA that are used to regulate gene expression by either regulating translation (protein synthesis) or marking messenger RNA (mRNA) for degradation. [14] Given their regulatory role, the theory is that different miRNAs would be present in different amounts in certain fluid or tissue types because each of those tissue types should have unique proteins and mRNA based on their role in the body. MiRNAs are also an ideal target for forensic analysis because they are small compared to other cellular components, so they tend to resist degradation better than other tissue markers, which is important considering that case work samples are not always going to be in pristine condition. [14] Finally, miRNAs have the potential to be co-extracted and analyzed at the same time as DNA, combining the two processes into one for biological sample analysis, saving time and sample.

miRNA can be extracted using a number of commercially available kits, such as the Solid Phase QIAmp DNA mini kit. [15] Ideally, like the QIAmp kit, the extraction method used is able to extract DNA and miRNA simultaneously, minimizing the amount of reactions and the amount of sample used. miRNAs can be quantified using quantitative Real Time PCR, similar to traditional DNA samples. [16] However, primers and probes would have to be designed for the miRNA targets in order to do so. Unlike routine DNA profiling, miRNA amplification requires an extra step before the PCR process. miRNA requires a reverse transcription step to convert the miRNA fragments into their complementary DNA (cDNA) fragments. [15] Once this conversion has happened, the cDNA and the other DNA in the sample can be amplified using PCR and then separated/visualized using a capillary electrophoresis protocol. cDNA specific primers would have to be designed for your miRNA targets. The final output is an electropherogram that contains not only the STR profile of the sample, but also a peak representing which miRNA is present in that sample. [15]

Current potential miRNA biomarkers: Research is still needed in order to narrow down potential biomarkers, as some tissues and fluids have the same miRNA expressed in different concentrations. To date, blood and semen miRNAs have been the most studied and have found promising candidate biomarkers.

Bodily FluidPotential Biomarkers for ID [17]
BloodmiR451, miR16
SemenmiR135b, miR10b
SalivamiR658, miR205
Vaginal SecretionsmiR124a miR372
Menstrual BloodmiR412 with miR451

Current research: Loop-mediated isothermal amplification

Like the technique of extracting miRNA, researchers have been able to test one or more samples by extracting DNA and testing it in an instrument that most labs have readily available. This method has proven to produce more DNA than PCR based amplification. Researchers have also added other factors to the loop-mediated isothermal amplification make identification of different body fluids. Using LAMP has reduced the time needed to get results, which is what the ultimate goal was. Although it has proven to decrease total and hands-on time needed to get a result, there are still kinks to work out before this method is used in many or all forensic labs.

See also

Related Research Articles

<span class="mw-page-title-main">Prostate-specific antigen</span> Mammalian protein found in humans

Prostate-specific antigen (PSA), also known as gamma-seminoprotein or kallikrein-3 (KLK3), P-30 antigen, is a glycoprotein enzyme encoded in humans by the KLK3 gene. PSA is a member of the kallikrein-related peptidase family and is secreted by the epithelial cells of the prostate gland in men and the paraurethral glands in women.

<span class="mw-page-title-main">Blood test</span> Laboratory analysis performed on a blood sample

A blood test is a laboratory analysis performed on a blood sample that is usually extracted from a vein in the arm using a hypodermic needle, or via fingerprick. Multiple tests for specific blood components, such as a glucose test or a cholesterol test, are often grouped together into one test panel called a blood panel or blood work. Blood tests are often used in health care to determine physiological and biochemical states, such as disease, mineral content, pharmaceutical drug effectiveness, and organ function. Typical clinical blood panels include a basic metabolic panel or a complete blood count. Blood tests are also used in drug tests to detect drug abuse.

<span class="mw-page-title-main">Diagnosis of HIV/AIDS</span> Immunological test

HIV tests are used to detect the presence of the human immunodeficiency virus (HIV), the virus that causes acquired immunodeficiency syndrome (AIDS), in serum, saliva, or urine. Such tests may detect antibodies, antigens, or RNA.

A drug test is a technical analysis of a biological specimen, for example urine, hair, blood, breath, sweat, or oral fluid/saliva—to determine the presence or absence of specified parent drugs or their metabolites. Major applications of drug testing include detection of the presence of performance enhancing steroids in sport, employers and parole/probation officers screening for drugs prohibited by law and police officers testing for the presence and concentration of alcohol (ethanol) in the blood commonly referred to as BAC. BAC tests are typically administered via a breathalyzer while urinalysis is used for the vast majority of drug testing in sports and the workplace. Numerous other methods with varying degrees of accuracy, sensitivity, and detection periods exist.

<span class="mw-page-title-main">Forensic toxicology</span> Use of toxicology for investigations

Forensic toxicology is a multidisciplinary field that combines the principles of toxicology with expertise in disciplines such as analytical chemistry, pharmacology and clinical chemistry to aid medical or legal investigation of death, poisoning, and drug use. The paramount focus for forensic toxicology is not the legal implications of the toxicological investigation or the methodologies employed, but rather the acquisition and accurate interpretation of results. Toxicological analyses can encompass a wide array of samples. In the course of an investigation, a forensic toxicologist must consider the context of an investigation, in particular any physical symptoms recorded, and any evidence collected at a crime scene that may narrow the search, such as pill bottles, powders, trace residue, and any available chemicals. Armed with this contextual information and samples to examine, the forensic toxicologist is tasked with identifying the specific toxic substances present, quantifying their concentrations, and assessing their likely impact on the individual involved.

Forensic identification is the application of forensic science, or "forensics", and technology to identify specific objects from the trace evidence they leave, often at a crime scene or the scene of an accident. Forensic means "for the courts".

Differential extraction refers to the process by which the DNA from two different types of cells can be extracted without mixing their contents. The most common application of this method is the extraction of DNA from vaginal epithelial cells and sperm cells from sexual assault cases in order to determine the DNA profiles of the victim and the perpetrator. Its success is based on the fact that sperm cells pack their DNA using protamines which are held together by disulfide bonds. The protamines sequester DNA from spermatozoa, making it more resilient to DNA extraction than DNA from epithelial cells.

<span class="mw-page-title-main">Forensic biology</span> Forensic application of the study of biology

Forensic biology is the application of biological principles and techniques in the investigation of criminal and civil cases.

Rapid Stain Identification Series (RSID) is designed for fast, easy and reliable detection of human fluids from a variety of samples encountered by forensic laboratories.

Presumptive tests, in medical and forensic science, analyze a sample and establish one of the following:

  1. The sample is definitely not a certain substance.
  2. The sample probably is the substance.
<span class="mw-page-title-main">Body identification</span> Subfield of forensic science

Body identification is a subfield of forensic science that uses a variety of scientific and non-scientific methods to identify a body. Forensic purposes are served by rigorous scientific forensic identification techniques, but these are generally preceded by formal identification. This involves requesting a family member or friend of the victim to visually identify the body.

Rape investigation is the procedure to gather facts about a suspected rape, including forensic identification of a perpetrator, type of rape and other details.

Phadebas is a synthetic biochemical substrate used for both qualitative and quantitative assessment of the α-amylase enzyme. Its active component is DSM-P, microspheres in which a blue dye has been chemically bound. When the substrate is digested by the amylase enzyme in solution, it releases that blue dye at a rate proportional to the quantity of the enzyme present. It is used in a range of applications from quality control tests for food & beverages to detection of saliva stains in forensic investigations.

<span class="mw-page-title-main">Saliva testing</span>

Saliva testing or Salivaomics is a diagnostic technique that involves laboratory analysis of saliva to identify markers of endocrine, immunologic, inflammatory, infectious, and other types of conditions. Saliva is a useful biological fluid for assaying steroid hormones such as cortisol, genetic material like RNA, proteins such as enzymes and antibodies, and a variety of other substances, including natural metabolites, including saliva nitrite, a biomarker for nitric oxide status. Saliva testing is used to screen for or diagnose numerous conditions and disease states, including Cushing's disease, anovulation, HIV, cancer, parasites, hypogonadism, and allergies. Salivary testing has even been used by the U.S. government to assess circadian rhythm shifts in astronauts before flight and to evaluate hormonal profiles of soldiers undergoing military survival training.

<span class="mw-page-title-main">Cannabis drug testing</span> Drug test methodologies for the use of cannabis

Cannabis drug testing describes various drug test methodologies for the use of cannabis in medicine, sport, and law. Cannabis use is highly detectable and can be detected by urinalysis, hair analysis, as well as saliva tests for days or weeks.

Extracellular RNA (exRNA) describes RNA species present outside of the cells in which they were transcribed. Carried within extracellular vesicles, lipoproteins, and protein complexes, exRNAs are protected from ubiquitous RNA-degrading enzymes. exRNAs may be found in the environment or, in multicellular organisms, within the tissues or biological fluids such as venous blood, saliva, breast milk, urine, semen, menstrual blood, and vaginal fluid. Although their biological function is not fully understood, exRNAs have been proposed to play a role in a variety of biological processes including syntrophy, intercellular communication, and cell regulation. The United States National Institutes of Health (NIH) published in 2012 a set of Requests for Applications (RFAs) for investigating extracellular RNA biology. Funded by the NIH Common Fund, the resulting program was collectively known as the Extracellular RNA Communication Consortium (ERCC). The ERCC was renewed for a second phase in 2019.

<span class="mw-page-title-main">Reverse Transcription Loop-mediated Isothermal Amplification</span>

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Secretor status refers to the presence or absence of water-soluble ABO blood group antigens in a person's bodily fluids, such as saliva, tears, breast milk, urine, and semen. People who secrete these antigens in their bodily fluids are referred to as secretors, while people who do not are termed non-secretors. Secretor status is controlled by the FUT2 gene, and the secretor phenotype is inherited in an autosomal dominant manner, being expressed by individuals who have at least one functioning copy of the gene. The non-secretor phenotype (se) is a recessive trait. Approximately 80% of Caucasian people are secretors, while 20% are non-secretors. Non-secretors have reduced susceptibility to the most common strains of norovirus. Expression of the antigens in the Lewis blood group is also affected by secretor status: non-secretors cannot produce the Le(b) antigen.

Rh factor testing, also known as Rhesus factor testing, is the procedure of determining the Rhesus D status of an individual.

<span class="mw-page-title-main">MicroRNA biosensors</span> Review of microRNA biosensors

MicroRNA (miRNA) biosensors are analytical devices that involve interactions between the target miRNA strands and recognition element on a detection platform to produce signals that can be measured to indicate levels or the presence of the target miRNA. Research into miRNA biosensors shows shorter readout times, increased sensitivity and specificity of miRNA detection and lower fabrication costs than conventional miRNA detection methods.

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