Hair analysis may refer to the chemical analysis of a hair sample, but can also refer to microscopic analysis or comparison. Chemical hair analysis may be considered for retrospective purposes when blood and urine are no longer expected to contain a particular contaminant, typically three months or less.
Microscopic hair analysis has traditionally been used in forensics as well. Analysts examine a number of different characteristics of hairs under a microscope, usually comparing hair taken from a crime scene and hair taken from a suspect. It is still acknowledged as a useful technique for confirming that hairs do not match. But DNA testing of evidence has overturned many convictions that relied on hair analysis. Since 2012, the Department of Justice has conducted a study of cases in which hair analysis testimony was given by its agents, and found that a high proportion of testimony could not be supported by the state of science of hair analysis.[citation needed]
In forensic toxicology
Chemical hair analysis is used for the detection of many therapeutic drugs and recreational drugs, including cocaine, heroin, benzodiazepines and amphetamines.[3][4] Hair analysis is less invasive than a blood test, if not quite as universally applicable. In this context, it has been reliably used to determine compliance with therapeutic drug regimes or to check the accuracy of a witness statement that an illicit drug has not been taken. Hair testing is an increasingly common method of assessment in substance misuse, particularly in legal proceedings, or in any situation where a subject may have decided not to tell the entire truth about his or her substance-using history. Post-mortem hair sample analysis can also be performed, to allow for determination of long-term drug use or poisoning.[5] It is also used by employers, who test their employees.[6]
Hair analysis has the virtue of showing a 'history' of drug use due to hair's slow growth. Urine analysis might detect drugs taken in the past 2–3 days; hair analysis can sometimes detect use as far as 90 days, although certain cosmetic treatments (e.g. dyeing hair) can interfere with this.[7][8]
Notably, basic drugs get incorporated into hair to a greater extent than neutral or acidic drugs, e.g. amphetamines and cocaine
are present in higher concentrations in hair compared with
benzodiazepines and cannabinoids.[9]
Large-scale drug screening (or urine, hair and other samples) is usually done using enzyme-linked immunosorbent assays (ELISA).[10] Positive ELISA findings are followed by confirmatory testing with liquid chromatography–mass spectrometry (LC-MS) or gas chromatography–mass spectrometry (GC-MS).[8] Chromato-mass-spectrometry is less likely to result in false positive findings than ELISA, but the former requires expensive equipment and highly trained personnel.
The judicial admissibility of the test in the United States is guided by the Daubert standard. A notable court case was United States v. Medina, 749 F.Supp. 59 (E.D.N.Y.1990).[11][12]
Microscopic hair analysis in forensics
Microscopic hair analysis consists of the comparison of several strands of hair under a microscope and determining if the physical characteristics of each individual hairs are consistent with each other or not. It was accepted as a forensic science by the 1950s.[13] Researchers often monitored more than a dozen attributes, including pigment distribution and scale patterns. This technique has been used in criminal investigations to try to tie hair found at a crime scene, or other location of note, and confirm if the hair matches that of a suspect. While a simple hair color match might be consistent with a certain suspect having been at the scene – black hair at the scene when the suspect has black hair – microscopic hair analysis began to claim a stronger standard by the 1970s. Rather than merely "narrow the field" of possibilities, hair analysts claimed to be able to match a specific person, such that the hair could be 'proof' of a specific suspect's presence. While the typed reports often hedged the certainty of microscopic hair analysis, witnesses in court would not always be as modest. The manager of the Montana state crime lab testified there was a "1 in 10,000 chance" that hairs found at a crime scene did not come from the suspect in one case, for example.[14]
Microscopic hair analysis has a long tradition of being used in crime fiction as well; it was originally popularized in the Sherlock Holmes series before being widely used by the police.[13] Fictional TV programs involving police procedurals and detectives have continued to use it since, including Columbo, Quincy, ME, Dexter, and CSI.[14]
Skepticism about the stronger claims used by witnesses in the 1970s and 1980s existed at the time. Researchers said in 1974 that the whole process was inherently subjective, and the FBI wrote in 1984 that hair analysis cannot positively match one single person.[13] In the 1990s, DNA profiling was introduced as a key new technique into forensics investigations; it introduced a new level of certainty about matching suspects to evidence. DNA analysis of old cases from the 1970s and 80s, however, contradicted conclusions about a number of earlier matches on the basis of hair analysis.[15]
In 1994, the Justice Department created a task force which would eventually review 6,000 cases by 2004, focusing on the work of one particularly zealous examiner, Michael Malone.[13] These reviews came after reports that sloppy work by examiners at the FBI lab was producing unreliable forensic evidence in court trials. At first, these investigations were largely kept quiet; The Washington Post reported that "Instead of releasing those findings, they made them available only to the prosecutors in the affected cases."[13] A study of FBI Laboratory hair analysis cases between 1996 and 2000 was released in 2002 by Max M. Houck and Bruce Budowle.[16] The study showed that 11% of hair analysis "matches" were contradicted by DNA analysis. As the set of cases analyzed was one which would be expected to favor matches strongly in any case – only hair of individuals the police already believed to be potential suspects was sent in – this error rate was considered to be extremely high.[13]
Kirk L. Odom was convicted of rape in Washington, DC in 1982 by no physical evidence except microscopic hair analysis performed by the FBI Crime Laboratory.[13] Combined with a witness's identification in a line-up (another technique which modern research has shown to be much less reliable than previously thought), Odom was sentenced to twenty or more years in jail. DNA analysis, however, proved that Odom was entirely innocent.[14] While Odom had been released from prison in 2003, he was officially exonerated in 2012 and was paid a large settlement by the city.[17]
In a similar case, Santae Tribble was convicted in 1979 at the age of 17 in Washington, DC of murder due to FBI testimony in a hair analysis match of hair found at the scene. But he had three witnesses who gave him an alibi for the time when the crime was committed. The prosecutor overstated the reliability of hair analysis in identifying a single person, saying in his closing statement that "There is one chance, perhaps for all we know, in 10 million that it could [be] someone else's hair."[13] DNA testing in January 2012, however, showed that the prosecution's key piece of evidence, the hair, did not in fact match the defendant. Tribble was fully exonerated in December 2012, having served 28 years in prison that resulted in severe health problems.[18]
The outcry from defense attorneys about the unreliability of hair analysis and overstatement by FBI experts has resulted in the FBI conducting a review of disputed hair analysis matches since 2012. Due to what it found, in July 2013 the Justice department began an "unprecedented" review of older cases involving hair analysis, examining more than 21,000 cases referred to the FBI Lab's hair unit from 1982 through 1999.
By 2015, these cases included as many as 32 death penalty convictions, in which FBI experts may have exaggerated the reliability of hair analysis in their testimony and affected the verdict. Of these, 14 persons have been executed or died in prison.[19][20] In 2015, DOJ released findings on 268 trials examined so far in which hair analysis was used (the review was still in progress). The review concluded that in 257 of these 268 trials (95 percent), the analysts gave flawed testimony in court that overstated the accuracy of the findings in favor of the prosecution. About 1200 cases remain to be examined. The department emphasized its commitment to following up on these cases to correct any wrongs, saying that they "are committed to ensuring that affected defendants are notified of past errors and that justice is done in every instance. The department and the FBI are also committed to ensuring the accuracy of future hair analysis, as well as the application of all disciplines of forensic science."[19]
In 2017, new Attorney General Jeff Sessions, appointed by President Donald Trump, announced that this investigation would be suspended, at the same time that he announced the end of a forensic science commission that had been working to establish standards on several tests and to improve accuracy; it was a "partnership with independent scientists to raise forensic science standards".[21] Independent scientists, prosecutors, defense counsel and judges criticized ending the commission, saying that the criminal justice system needed to rely on the best science.
As of late 2019, 75 people who were convicted of a crime based on microscopic hair comparison were subsequently exonerated.[22] Another notable case that received media attention since was Anthony Broadwater, who had been convicted of raping Alice Sebold in 1982, and was formally exonerated in 2021 after finishing his time in 1998. The only physical evidence the prosecution offered in 1982 was a hair analysis that was "consistent" with Broadwater. More alarmingly, the only reason the case was re-examined was the unusual fact that Sebold had written an extensive memoir of her experiences (Lucky), which allowed later investigators to uncover major problems with the case.[23]
In environmental toxicology
Analysis of hair samples has many advantages as a preliminary screening method for the presence of toxic substances deleterious to health after exposures in air, dust, sediment, soil and water, food and toxins in the environment. The advantages of hair analysis include the non-invasiveness, low cost, and the ability to measure a large number of, potentially interacting, toxic and biologically essential elements. Hence, head hair analysis is increasingly being used as a preliminary test to see whether individuals have absorbed poisons linked to behavioral or health problems.[1]
In a 1999 study on hair concentrations of calcium, iron, and zinc in pregnant women and effects of supplementation, it was concluded that "From the analyses, it was clear that hair concentrations of Ca, Fe, and Zn could reflect the effects of supplementation... Finally, it could be concluded that mineral element deficiencies might be convalesced by adequate compensations of mineral element nutrients."[24]
Occupational, environmental and alternative medicine
Hair analysis has been used in occupational,[25]environmental and some branches of alternative medicine as a method of investigation to assist screening and/or diagnosis. The hair is sampled, processed and analyzed, studying the levels of mineral and metals in the hair sample. Using the results, as part of a proper examination or test protocol,[26] practitioners screen for toxic exposure and heavy metal poisoning. Some advocates claim that they can also diagnose mineraldeficiencies and that people with autism have unusual hair mineral contents.[27] These uses are often controversial, and the American Medical Association states, "The AMA opposes chemical analysis of the hair as a determinant of the need for medical therapy and supports informing the American public and appropriate governmental agencies of this unproven practice and its potential for health care fraud."[28]
A recent review of scientific literature by Dr Kempson highlighted analysis of metals/minerals in hair can be applied in large population studies for researching epidemiology and groups of chronically exposed populations, however any attempt to provide a diagnosis based on hair for an individual is not possible.[29] An exception to this can be in advanced analyses for acute poisoning.[30]
Literature
Pragst F., Balikova M.A.: State of the art in hair analysis for detection of drugs and alcohol abuse; Clinica Chimic Acta 370 2006 17–49.
Auwärter V.: Fettsäureethylester als Marker exzessiven Alkoholkonsums – Analytische Bestimmung im Haar und in Hautoberflächenlipiden mittels Headspace-Festphasenmikroextraktion und Gaschromatographie-Massenspektrometrie. Dissertation Humboldt-Universität Berlin 2006.
Pragst F.; Auwärter V.; Kiessling B.; Dyes C. (2004). "Wipe-test and patch-test for alcohol misuse based on the concentration ratio of fatty acid ethyl esters and squalen CFAEE/CSQ in skin surface lipids". Forensic Sci Int. 143 (2–3): 77–86. doi:10.1016/j.forsciint.2004.02.041. PMID15240027.
^Dartmouth Toxic Metals Research Program. A Metals Primer. Archived November 26, 2006, at the Wayback Machine Center for Environmental Health Sciences at Dartmouth. Accessed December 9, 2006.
^Welch M.J.; Sniegoski L.T.; Allgood C.C.; Habram M. (1993). "Hair analysis for drugs of abuse: Evaluation of analytical methods, environmental issues, and development of reference materials". J Anal Toxicol. 17 (7): 389–398. doi:10.1093/jat/17.7.389. PMID8309210.
^Toobin, Jeffery (April 30, 2007). "The CSI Effect". The New Yorker. Retrieved April 6, 2020.
^Houck, Max; Budowle, Bruce (2002). "Correlation of microscopic and mitochondrial DNA hair comparisons". Journal of Forensic Sciences. 47 (5): 964–967. doi:10.1520/JFS15515J. PMID12353582.
^Lathe, Richard, and Michael Le Page. "Toxic metal clue to autism: a study has revealed startling differences in mercury levels in the hair of autistic and normal children. (This Week)." New Scientist 178.2400 (June 21, 2003): 4(2).
^Hair analysis: A potential for medical abuse. Policy number H-175.995,(Sub. Res. 67, I-84; Reaffirmed by CLRPD Rep. 3 – I-94)
^Kempson I.M., Lombi E. (2011). "Hair analysis as a biomonitor for toxicology, disease and health status". Chemical Society Reviews. 40 (7): 3915–3940. doi:10.1039/C1CS15021A. PMID21468435.
^Kempson I.M., Henry D.A. (2010). "Synchrotron Radiation Reveals Arsenic Poisoning and Metabolism in Hair: The case of Phar Lap". Angewandte Chemie International Edition. 49 (25): 4237–4240. doi:10.1002/anie.200906594. PMID20432493.
Henderson, G.L., Harkey, M.R., Jones, R.T., "Analysis of Hair for Cocaine", in (eds. Edward. J. Cone, Ph.D., Michael. J. Welch, Ph.D., and M. Beth Grigson Babecki, M.A.), "Hair Testing for Drugs of Abuse: International Research on Standards and Technology", 1995, pp. 91–120. NIH Publication No. 95-3727.
Kintz P (2007). "Bioanalytical procedures for detection of chemical agents in hair in the case of drug-facilitated crimes". Anal. Bioanal. Chem. 388 (7): 1467–74. doi:10.1007/s00216-007-1209-z. PMID17340077. S2CID28981255.
Romolo F.S.; Rotolo M.C.; Palmi I.; Pacifici R.; Lopez A. (2003). "Optimized conditions for simultaneous determination of opiates, cocaine and benzoylecgonine in hair samples by GC-MS". Forensic Science International. 138 (1–3): 17–26. doi:10.1016/j.forsciint.2003.07.013. PMID14642715.
Sachs H. Kintz (1998). "Testing for drugs in hair. Critical review of chromatographic procedures since 1992". J. Chromatogr. B. 713 (1): 147–161. doi:10.1016/S0378-4347(98)00168-6. PMID9700557.