Single Hair Shafts Research Articles

Anisotropic swelling due to hydration constrains anisotropic elasticity in biomaterial fibers

Naturally occurring protein fibers often undergo anisotropic swelling when hydrated. Within a tendon, a hydrated collagen fibril’s radius expands by 40% but its length only increases by 5%. The same effect, with a similar relative magnitude, is observed for single hair shafts. Fiber hydration is known to affect elastic properties. Here we show that anisotropic swelling constrains the anisotropic linear elastic properties of fibers. First we show, using data from disparate previously reported studies, that anisotropic swelling can be described as an approximately linear function of water content. Then, under the observation that the elastic energy of swelling can be minimized by the anisotropic shape, we relate swelling anisotropy to elastic anisotropy — assuming radial (transverse) symmetry within a cylindrical geometry. We find an upper bound for the commonly measured axial Poisson ratio νzx<1/2. This is significantly below recently estimated values for collagen fibrils extracted from tissue-level measurements, but is consistent with both single hair shaft and single collagen fibril mechanical and hydration studies. Using νzx, we can then constrain the product γ≡(1−νxy)Ez/Ex — where νxy is the seldom measured transverse Poisson ratio and Ez/Ex is the ratio of axial to radial Young’s moduli.

Acquired curved hair is caused by fusion of multiple hair matrix cells

Background“Curved hair” caused by acquired factors is considered to have adverse cosmetic effects, but the detailed mechanism behind curved hair remains obscure. ObjectiveWe attempted to clarify the causes of curved hair that appeared to have occurred via acquired factors. MethodsOuter root sheath cells (ORSC) isolated from plucked human hair follicles were used to evaluate the expression of type IV collagen. Straight and curved hairs with hair follicle tissue attached were also collected from the same individuals and subjected to morphological, immunohistochemical, and gene expression analyses. ResultsThe amount of type IV collagen increased upon inducing endoplasmic reticulum stress in ORSC. Meanwhile, in curved hair follicle tissue, the gene expression of type IV collagen decreased. In addition, the curved hair follicle tissue obtained from participants in their 30 s to 50 s had distorted shapes compared with that of straight hair from the same individuals. It was also observed that hair matrix cells based on multiple hair germs fused to eventually form a single hair follicle and hair shaft. In curved hair follicle tissue, KRT71 protein, a marker of inner root sheath differentiation, was unevenly distributed and there was elevated expression of Dickkopf-1 (DKK1) protein, an inhibitor of the Wnt signaling pathway. ConclusionOur study revealed the fusion of hair matrix cells during hair follicle regeneration as a cause of acquired curved hair. We consider that such fusion causes hair follicle tissue to abnormally differentiate, resulting in asymmetric hair follicle shapes and curved hair.

Trichothiodystrophy hair shafts display distinct ultrastructural features.

Hair shafts from three trichothiodystrophy (TTD) patients with mutations in the ERCC2 (XPD) gene were examined by transmission electron microscopy. TTD is a rare, recessive disorder with mutations in several genes in the DNA repair/transcription pathway, including ERCC2. Unlike previous studies, the hair shafts were examined after relaxation of their structure by partial disulphide bond reduction in the presence of sodium dodecyl sulphate, permitting improved visualization. Compared with hair shafts of normal phenotype, TTD cuticle cells displayed aberrant marginal bands and exocuticle layers. Clusters of cells stained differently (light versus dark) in the cortex of aberrant shafts, and the keratin macrofibrils appeared much shorter in the cytoplasm. Considerable heterogeneity in these properties was evident among samples and even along the length of single hair shafts. The results are consistent with not only a paucity of high sulphur components, such as keratin-associated proteins, but also a profound imbalance in protein content and organization.

Detection of deletion/insertion polymorphism profiles from single human hair shafts.

Hair is a frequently encountered biological evidence in personal identification. The amount of nuclear DNA that can be extracted from a single strand of rootless hair is most limited, making the detection of short tandem repeat (STR) polymorphisms difficult. To overcome these limitations, deletion/insertion polymorphisms (DIP) as a new type of genetic marker have shown their benefits in detecting low-copy-number DNA. The Investigator DIPplex kit contains 30 biallelic autosomal DIP and amelogenin. The analysis of DIPs combines the advantages of both STR and single nucleotide polymorphism analyses. Thus, this study aimed to detect the DIP distribution of individual hair shafts from individuals. DNA was extracted from the shaft of fresh, aged, and shed hair. After DNA was evaluated, the DIP profiles were detected by capillary electrophoresis. The results indicated that the amount of DNA extracted from hair roots was much higher than that from the hair shafts in the same individual for all samples. The degradation index values of DNA from the aged hair shafts were highest. It is classified to be "mildly degraded." Compared with their hair roots, the full DIP profiles were detected for fresh hair, 70% for aged hair, and 92% for shed hair. Contrarily, except for fresh hair shafts, only three STR loci of the aged and shed strands of hair could be genotyped using AmpFlSTR MiniFiler PCR Amplification Kit. These results indicate that the detection of DIP profile is an effective tool for personal identification from hair shafts, including aged hair.

Alternative LC-MS/MS Platforms and Data Acquisition Strategies for Proteomic Genotyping of Human Hair Shafts.

Protein is a major component of all biological evidence. Proteomic genotyping is the use of genetically variant peptides (GVPs) that contain single-amino-acid polymorphisms to infer the genotype of matching nonsynonymous single-nucleotide polymorphisms for the individual from whom the protein sample originated. This can be used to statistically associate an individual to evidence found at a crime scene. The utility of the inferred genotype increases as the detection of GVPs increases, which is the direct result of technology transfer to mass spectrometry platforms typically available. Digests of single (2 cm) human hair shafts from three European and two African subjects were analyzed using data-dependent acquisition on a Q-Exactive Plus Hybrid Quadrupole-Orbitrap system, data-independent acquisition and a variant of parallel reaction monitoring (PRM) on an Orbitrap Fusion Lumos Tribrid system, and multiple reaction monitoring (MRM) on an Agilent 6495 triple quadrupole system. In our hands, average GVP detection from a selected panel of 24 GVPs increased from 6.5 ± 1.1 and 3.1 ± 0.8 using data-dependent and -independent acquisition to 9.5 ± 0.7 and 11.7 ± 1.7 using PRM and MRM (p < 0.05), respectively. PRM resulted in a 1.3-fold increase in detection sensitivity, and MRM resulted in a 1.6-fold increase in detection sensitivity. This increase in biomarker detection has a functional impact on the statistical association of a protein sample and an individual. Increased biomarker sensitivity, using Markov Chain Monte Carlo modeling, produced a median-estimated random match probability of over 1 in 10 trillion from a single hair using targeted proteomics. For PRM and MRM, detected GVPs were validated by the inclusion of stable isotope-labeled peptides in each sample, which served also as a detection trigger. This research accomplishes two aims: the demonstration of utility for alternative analytical platforms in proteomic genotyping and the establishment of validation methods for the evaluation of inferred genotypes.

High Spatial-Resolution Matrix-Assisted Laser Desorption/Ionization-Ion Trap-Time-of-Flight Tandem Mass Spectrometry Imaging for Depicting Longitudinal and Transverse Distribution of Drugs Incorporated into Hair.

This study aims to achieve high spatial-resolution tandem mass spectrometry (MS/MS) imaging for depicting longitudinal and transverse distribution of drugs in hair, which can provide indispensable information for the proper interpretation of hair test results, including the mechanism of drug incorporation into hair. Two types of hair samples were obtained and analyzed: User's Hair, sampled from a volunteer who took an over-the-counter medicine containing methoxyphenamine (MOP), a nonregulated analogue of methamphetamine; and Soaked Hair, prepared by soaking blank hair in MOP solution. Longitudinal and transverse-sectioning of single hair shafts was accomplished by freeze-sectioning using customized microtomes. Vapor deposition of α-cyano-4-hydroxycinnamic acid provided the finest matrix layer (resolution <1 μm, 0.7-μm thickness), although it provided less effective ionization of MOP compared to aerosol spraying or a combination of both. Matrix-assisted laser desorption/ionization (MALDI)-ion trap (IT)-time-of-flight (TOF) MS/MS permitted the imaging of trace-level MOP in hair with a MS/MS window setting of ±0.02 Da and a spatial resolution setting at 5 or 10 μm. For Soaked Hair, localization of MOP in the peripheral part was clearly depicted, but no such biased distribution was observed in the transverse sections of User's Hair. MOP-positive bands generated corresponding to the time periods of MOP intake could be observed on the longitudinal sections of User's Hair. This method can provide forensically crucial information regarding hair analysis for drugs: drug incorporation mechanism into hair, discrimination of undesired surface contamination from endogenous incorporation of ingested drugs, and precise elucidation of drug-use history.

Proteomic genotyping: Using mass spectrometry to infer SNP genotypes in a forensic context

Proteins are an intrinsic part of biological evidence. In the last two decades mass spectrometry has revolutionized the analysis of proteins, allowing for thousands of peptides to be detected in a single analysis, including peptides containing single amino acid polymorphisms. Identification of these genetically variant peptides (GVP) allows for inference of the underlying non-synonymous SNP genotype. We have focused on hair proteins as a source of genetic information, discovering and validating 240 GVPs. Using optimized processing, a single hair shaft can obtain random match probabilities (RMPs) of up to 1 in 100 million. We show that GVP-inferred genotypes are not affected by the anatomical origin of the hair shaft or pigmentation. Harsh oxidation with peroxide does not affect RMPs. Importantly, GVP-inferred SNP genotypes are statistically compatible with STR-typing and Alu retroelements, with 90% of GVP-inferred SNPs being located greater than 10 million and 75 million bp from the nearest STR or Alu element respectively. We have shown separation of DNA and peptide workflows from the same samples. Recent work has shifted to the use of a targeted peptide assay. When data acquisition of GVPs was dynamically triggered by the detection of a standard peptide, this approach resulted in a 2.5 fold increase in sensitivity and increased confidence in peptide detection. Based on Monte Carlo modeling, we predict this increase in sensitivity will result in RMPs in excess of 1 in 1 trillion from a single hair shaft. Proteomic genotyping can also be applied to any protein matrix, including fingermarks and bone. Proteomic genotyping therefore has potential to complement partial PCR-based DNA typing and to provide other options for investigators.

Assessing protein sequencing in human single hair shafts of decreasing lengths

Hair evidence is commonly found at crime scenes and is first analyzed using microscopy techniques. Hair can be processed for DNA analysis, but nuclear DNA analysis may result in a partial or no profile, and mitochondrial DNA analysis is less discriminatory. Single amino acid polymorphisms (SAPs) in hair shaft keratin proteins that result from non-synonymous single nucleotide polymorphisms (nsSNPs) in the genome are being studied as a method of supplementing microscopic comparison of questioned and known hair evidence. Most studies, however, use large amounts of hair (on the order of hundreds of centimeters of hair shaft length), not representative of operational practice in typical forensic casework analyses. Using a recently developed method of hair shaft protein extraction, this study determines how decreasing hair shaft sample length (i.e., 2 cm to 0.12 cm) affects the identification of hair proteins. For example, in 2 cm hair shaft samples, 16 hair shaft keratin proteins, KRT31-40 and KRT80-86, were high-abundant proteins identified with ˜65% average sequence coverage and 44 peptides on average per protein. When the hair shaft samples were decreased to 0.12 cm, this method still identified 15 hair shaft keratin proteins (i.e., except for KRT40) with ˜47% average sequence coverage and 26 peptides on average per protein. This study demonstrates that even with samples as small as 0.12 cm, hair shaft keratin proteins can still be reliably identified and potentially used forensically. Additionally, using the protein extraction technique described in this study, the adequate hair shaft length required for analysis should be in the range of 0.5 cm to 2 cm. Thus, peptide sequencing for SAP identification can be compatible with forensic casework sample sizes.

Matrix-assisted laser-desorption/ionization mass spectrometric imaging of olanzapine in a single hair using esculetin as a matrix

Matrix-assisted laser desorption/ionization-mass spectrometric imaging (MALDI-MSI) for the analysis of intact hair is a powerful tool for monitoring changes in drug consumption. The embedding of a low drug concentration in the hydrophobic hair matrix makes it difficult to extract and detect, and requires an improved method to increase detection sensitivity. In this study, an MSI method using MALDI-Fourier transform ion cyclotron resonance was developed for direct identification and imaging of olanzapine in hair samples using the positive ion mode. Following decontamination, scalp hair samples from an olanzapine user were scraped from the proximal to the distal end three times, and 5mm hair sections were fixed onto an Indium-Tin-Oxide (ITO)-coated microscopic glass slide. Esculetin (6,7-dihydroxy-2H-chromen-2-one) was used as a new hydrophobic matrix to increase the affinity, extraction and ionization efficiency of olanzapine in the hair samples. The spatial distribution of olanzapine was observed using five single hairs from the same drug user. This matrix improves the affinity of olanzapine in hair for molecular imaging with mass spectrometry. This method may provide a detection power for olanzapine to the nanogram level per 5mm hair. Time course changes in the MSI results were also compared with quantitative HPLC–MS/MS for each 5mm segment of single hair shafts selected from the MALDI target. MALDI imaging intensities in single hairs showed good semi-quantitative correlation with the results from conventional HPLC–MS/MS. MALDI-MSI is suitable for monitoring drug intake with a high time resolution.

Terminal restriction fragment length polymorphism profiling of bacterial flora derived from single human hair shafts can discriminate individuals.

Human hairs are the trace evidence most commonly encountered at many crime scenes. However, they have not been effectively utilized for actual criminal investigations because of the low accuracy of their morphological inspection, low detection rate of short tandem repeat (STR) typing, and the problem of heteroplasmy in mitochondrial DNA analysis. Here, we examined the possibility of individual discrimination by comparing profiles of bacterial flora on hair. We carried out the profiling of terminal restriction fragment length polymorphisms (T-RFLP) of the amplified bacterial 16S ribosomal RNA (rRNA) gene from hair samples. Compared with existing STR typing methods that use hair roots, this method using hair shafts allowed the detection of stable bacterial DNA. We successfully obtained the T-RFLP profile from single hair shafts of all volunteers tested. The profiles were specific to each individual, and multiple profiles obtained from the individual him/herself showed higher similarity than those from different individuals. These individual-specific profiles were stably obtained from samples from most volunteers, when collected again after 6months. Storage of the collected hair samples at -30°C was effective for obtaining reproducible T-RF profiles. When unidentified hair samples collected in the laboratory were compared with a pre-constructed database, 17 of 22 hairs were assigned to a small group of people, including the corresponding individuals. These results show that T-RFLP analysis of bacterial flora on a hair shaft found at a crime scene could provide useful information for narrowing down a suspect.

Time-course mass spectrometry imaging for depicting drug incorporation into hair.

In order to investigate the incorporation of drugs into hair, matrix-assisted laser desorption/ionization-time-of-flight tandem mass spectrometry (MS/MS) imaging was performed on the longitudinal sections of single scalp hair shafts sampled from volunteers after a single oral administration of methoxyphenamine (MOP), a noncontrolled analogue of methamphetamine. Hair specimens were collected by plucking out with the roots intact, and these specimens were prepped by an optimized procedure based on freeze-sectioning to detect the drug inside the hair shaft and hair root. Time-course changes in the imaging results, with confirmatory quantitative liquid chromatography-tandem mass spectrometry (LC-MS/MS) analysis for each 1-mm segment of single hair strands, revealed a substantial concentration of the drug first onto the hair bulbs after ingestion, while only a small portion appeared to be incorporated into the hair matrix, forming a 2-3 mm distinctive drug band with tailing. Comparable amount of the drug also appeared to be incorporated into the keratinized hair shaft in the upper dermis zone, forming another distinct drug band of about 2 mm, which both moved toward the distal side, following the strand's growth rate. These findings provide forensically crucial information: there are two major drug incorporation sites, at least for MOP, which cause overlap of the recordings and deteriorates its chronological resolution down to about 11 days or perhaps longer.

On the distribution of uranium in hair: Non-destructive analysis using synchrotron radiation induced X-ray fluorescence microprobe techniques

In the present study the distribution of uranium in single human hair shafts has been evaluated using two synchrotron radiation (SR) based micro X-ray fluorescence techniques; SR μ-XRF and confocal SR μ-XRF. The hair shafts originated from persons that have been exposed to elevated uranium concentrations. Two different groups have been studied, i) workers at a nuclear fuel fabrication factory, exposed mainly by inhalation and ii) owners of drilled bedrock wells exposed by ingestion of water. The measurements were carried out on the FLUO beamline at the synchrotron radiation facility ANKA, Karlsruhe. The experiment was optimized to detect U with a beam size of 6.8μm×3μm beam focus allowing detection down to ppb levels of U in 10s (SR μ-XRF setup) and 70s (SR confocal μ-XRF setup) measurements. It was found that the uranium was present in a 10–15μm peripheral layer of the hair shafts for both groups studied. Furthermore, potential external hair contamination was studied by scanning of unwashed hair shafts from the workers. Sites of very high uranium signal were identified as particles containing uranium. Such particles, were also seen in complementary analyses using variable pressure electron microscope coupled with energy dispersive X-ray analyzer (ESEM–EDX). However, the particles were not visible in washed hair shafts.These findings can further increase the understanding of uranium excretion in hair and its potential use as a biomonitor.

Histopathologic features of canine distichiasis

To describe the histologic features of canine distichiasis using excised tarsoconjunctival specimens that included roots of distichiatic cilia. The study group included 21 strips of cilia-bearing tarsoconjunctiva resected from 20 dogs with distichiasis. Eyelid tissue specimens were also collected from 11 euthanized dogs without distichiasis to serve as controls. All flat mount preparations were processed for histologic examination, and serial sections were stained with hematoxylin-eosin (H&E). A total of 157 slides were examined for the study group to describe the follicles and path of the distichiatic hairs and determine their potential connection with the tarsal glands. A total of 82 slides were examined for the control group. In 19 of the 20 dogs with distichiasis, serial sections of the specimens identified anatomic segments of hair follicles located abnormally in the eyelid tarsus and associated with the aberrant cilia. They appeared as hair bulbs adjacent to tarsal glands, middle portions of hair follicles located between sebaceous lobules, and single or multiple hair shafts present within the sebaceous duct. The tarsal glands in the cilia-bearing tarsoconjunctiva were not different from those of the controls, in which no distichiatic hair bulbs or shafts were observed. These results demonstrate that adventitious cilia are not associated with histologic changes of the tarsal glands, and appear to arise from ectopic hair follicles present in the tarsus. Canine distichiasis may result from anomalous regulation of morphogenesis of hair follicles in the mesenchymal tissue of the tarsal plate.

Imaging of methamphetamine incorporated into hair by MALDI-TOF mass spectrometry

Matrix-assisted laser desorption ionization (MALDI)–time-of-flight (TOF) mass spectrometry (MS) was used for visual demonstration of methamphetamine (MA) incorporation into human hair. Longitudinal sections of human scalp hair shafts from chronic MA users were directly subjected to imaging MS. Numerous MA-positive spots with various intensities were observed in the specimens, which probably reflect habitual MA abuse and the different MA blood levels upon each administration. This imaging MS method for drugs in hair seems to give much more accurate chronological information on drug use, and clearer discrimination between deliberate drug use and passive exposure, using only a single hair shaft. This is the first report of imaging MS applied to forensic toxicology. This method is expected open a new field in analyses of drugs in hair.

MALDI‐TOF and MALDI‐FTICR imaging mass spectrometry of methamphetamine incorporated into hair

A new approach is described for imaging mass spectrometry (IMS) of methamphetamine (MA) incorporated into human hair using matrix-assisted laser desorption/ionization (MALDI)-time-of-flight (TOF) and MALDI-Fourier transform ion cyclotron resonance (FTICR). A longitudinal section of a lengthwise manually-cut single human hair shaft from a chronic MA user was directly analyzed by MALDI-TOF-IMS after deposited with α-Cyano-4-hydroxycinnamic acid matrix. A barcode-like image, which was most probably generated with repeated intakes of MA, was for the first time obtained by monitoring MA-specific product ion in the selected reaction monitoring mode. Laser beam scan lengthwise-cut hair shafts gave only poor mass spectra of MA, probably due to the loss of MA and/or the thermal denaturation of hair. The identity of MA detected in hair was further confirmed by MALDI-FTICR mass spectrometry. A combination with ultra-high resolution mass spectrometry by FTICR provided indisputable identification of MA. The MALDI-FTICR-IMS of another hair shaft from the same MA user also provided a barcode-like image by monitoring the protonated molecule of MA with ultra-high resolution. The two barcode-like images exhibited a close resemblance. Thus, MALDI-IMS can offer a new perspective: 'imaging hair analyses for drugs'.

Single-Molecule LATE-PCR Analysis of Human Mitochondrial Genomic Sequence Variations

It is thought that changes in mitochondrial DNA are associated with many degenerative diseases, including Alzheimer's and diabetes. Much of the evidence, however, depends on correlating disease states with changing levels of heteroplasmy within populations of mitochondrial genomes, rather than individual mitochondrial genomes. Thus these measurements are likely to either overestimate the extent of heteroplasmy due to technical artifacts, or underestimate the actual level of heteroplasmy because only the most abundant changes are observable. In contrast, Single Molecule (SM) LATE-PCR analysis achieves efficient amplification of single-stranded amplicons from single target molecules. The product molecules, in turn, can be accurately sequenced using a convenient Dilute-‘N’-Go protocol, as shown here. Using these novel technologies we have rigorously analyzed levels of mitochondrial genome heteroplasmy found in single hair shafts of healthy adult individuals. Two of the single molecule sequences (7% of the samples) were found to contain mutations. Most of the mtDNA sequence changes, however, were due to the presence of laboratory contaminants. Amplification and sequencing errors did not result in mis-identification of mutations. We conclude that SM-LATE-PCR in combination with Dilute-‘N’-Go Sequencing are convenient technologies for detecting infrequent mutations in mitochondrial genomes, provided great care is taken to control and document contamination. We plan to use these technologies in the future to look for age, drug, and disease related mitochondrial genome changes in model systems and clinical samples.

Short tandem repeat (STR) genotyping of keratinised hair Part 2. An optimised genomic DNA extraction procedure reveals donor dependence of STR profiles

A feasibility study of short tandem repeat (STR) genotyping of telogen phase hairs in particular, and hair shaft in general, is presented. A number of extraction procedures in common use were investigated and the quantities of nuclear DNA (nuDNA) delivered were quantified via a real-time PCR assay. The extracts were subjected to two variations on AmpFℓSTR ® Profiler Plus™ PCR amplification strategies (extended cycles, two rounds of PCR) and the genotypes compared. Nuclear DNA was found to persist in human hair shafts, albeit at very low levels. Full Profiler Plus™ profiles consistent with the hair donor were obtained from 100 mg hair shaft samples (bleached and unbleached). These were, however, mixed profiles, indicating low copy number (LCN) contamination in the extracts. Single telogen hair clubs and single hair shafts delivered partial profiles with usually only one allele of heterozygous loci. Telogen phase hairs yielded the same amount of nuDNA (and no more) as hair shafts (either anagen or telogen). Whether hair shafts dissolved or not in lysis buffer had no effect on either the quantitated yield of DNA or on the chance of obtaining a correct genotype. These results provide evidence that genomic DNA resides on the exterior of the hair shaft and we use this information to suggest an optimal procedure for nuDNA extraction from keratinised hair samples: soaking hairs in simple digestion buffers containing Tris–HCl, a salt and a chelating agent without prior cleaning of the hair shafts. It is proposed that cleaning removes most of the recoverable DNA. This procedure was applied to obtain genotypes from 3 cm hair shafts which matched reference profiles from the donors at up to 9 out of 10 AmpFℓSTR ® Profiler Plus™ STR loci. When the genotyping success was measured by counting the number of matches between the two dominant alleles at each locus for each extract with the reference DNA profile of the hair donor, the success was found to be highly dependent on the donor. The number of matching alleles varied between not less than 10 for one donor to no more than two for another donor. These results may well be linked to the environmental experience of the hairs from each donor prior to removal.

Raman spectroscopic analyses of preserved historical specimens of human hair attributed to Robert Stephenson and Sir Isaac Newton.

The Raman spectra of two historical specimens of human hair attributed to the engineer Robert Stephenson and scientist Sir Isaac Newton, preserved in private collections are reported. Comparisons are made with the Raman spectra of modern hair specimens and with hair from archaeological excavations. The hair spectra collected with a laser excitation of 785 nm are of a better quality than those collected using 1064 nm. The historical hair specimens are remarkably well-defined spectroscopically in terms of the amide I vibrational mode and the [small nu](SS), ascribed to a predominantly gauche-gauche-gauche CSSC conformation. The contrast with degraded hair specimens recovered from archaeological excavations is striking. The presence of a weak feature near 2590 cm(-1) in the hair samples attributed to a [small nu](SH) vibration could be indicative of a reduction process operative on the CSSC cystine keratotic linkages and a possible origin of this is bacterial biodegradation identified histologically. This study demonstrates the molecular information available from non-destructive Raman spectroscopic analysis from single hair shafts or small bundles of fibres which complements information available from histological and destructive analytical techniques for rare biological specimens subjected to conservation or curation procedures in museums or private collections.

Purification of nuclear DNA from single hair shafts for DNA analysis in forensic sciences

The typing of nuclear DNA from hair shafts has often been unsuccessful to date. We tried to type one of the nuclear DNA loci, HLA-DQA1, from hair shafts, using an efficient cetyl-trimethyl ammonium bromide (CTAB) precipitation for DNA purification and a sensitive semi-nested PCR. After thorough washing with ethanol and water, hair shafts were digested by proteinase K in the presence of dithiothreitol, followed by a purification step including CTAB-DNA precipitation. The specific region of HLA-DQA1 gene was amplified by the semi-nested PCR, and the amplified products were cloned and sequenced. The HLA-DQA1 genotype was determined by comparing the sequence to the known sequence of each allele. All genotypes of HLA-DQA1 were successfully typed with hair shafts from six known heterozygotes, although one of them showed the predominant appearance of one allele. For correct typing, a template DNA equivalent to a hair shaft of 5 or 10 cm in length was necessary. Without the CTAB-DNA precipitation step, DNA extract from such hair shafts inevitably contains enough melanin to inhibit PCR. The present results suggest that hair shafts can be used for the typing of nuclear DNA loci.

Analysis of ofloxacin in hair as a measure of hair growth and as a time marker for hair analysis.

The distribution of ofloxacin (OFLX) along a single hair shaft was analyzed in detail for use as an index of hair growth and as a time marker for drug analysis in hair. A single hair obtained from each of seven subjects, who had taken OFLX for 1-4 days (total of 200-1,200 mg) 2.7-5.3 months before hair sampling, was cut into 1-cm-long portions successively from its scalp end. OFLX in each hair portion was measured by high-performance liquid chromatography with a fluorescence detector, and the distance from the scalp end of the hair portion containing OFLX was determined. Then the other 2-cm long segment of hair, which had the above-determined distance at its middle, was cut successively into 2-mm-long pieces and OFLX was determined in each piece. This procedure was repeated in a total of three to four hair strands collected from one subject. OFLX was observed to distribute only in one to three consecutive 2-mm-long pieces of hair, showing no large diffusion of OFLX along the hair shaft with time. Therefore, OFLX distribution may serve as a time marker for analyzing other drugs in hair. Hair growth rate could be thus estimated and ranged from 0.99 to 1.27 cm/month (1.12 +/- 0.11 cm/month, mean +/- SD) among individuals. The intraindividual variability of hair growth rate was 4.8-18.1% (10.3 +/- 5.1%) as coefficient of variation.