Evaluation of the RapidHIT™ 200, an automated human identification system for STR analysis of single source samples

The RapidHIT™ 200 Human Identification System was evaluated to determine its suitability for STR analysis of single source buccal swabs. Overall, the RapidHIT™ 200 performed as well as our traditional capillary electrophoresis based method in producing useable profile information on a first-pass basis. General observations included 100% concordance with known profile information, consistent instrument performance after two weeks of buccal swab storage, and an absence of contamination in negative controls. When data analysis was performed by the instrument software, 95.3% of the 85 samples in the reproducibility study gave full profiles. Including the 81 full profiles, a total of 2682 alleles were correctly called by the instrument software, or 98.6% of 2720 possible alleles tested. Profile information was generated from as little as 10,000 nucleated cells, with swab collection technique being a major contributing factor to profile quality. The average peak-height-ratio for heterozygote profiles (81%) was comparable to conventional STR analysis, and while a high analytical threshold was required when offline profile analysis was performed (800 RFU), it was proportionally consistent with traditional methods. Stochastic sampling effects were evaluated, and a manageable approach to address limits of detection for homozygote profiles is provided. These results support consideration of the RapidHIT™ 200 as an acceptable alternative to conventional, laboratory based STR analysis for the testing of single source buccal samples, with review of profile information as a requirement until an expert software system is incorporated, and when proper developmental and internal validation studies have been completed.     

Internal validation of the RapidHIT® ID system

Traditionally, forensic DNA analysis has required highly skilled forensic geneticists in a dedicated laboratory to generate short tandem repeat (STR) profiles. STR profiles are routinely used either to associate or exclude potential donors of forensic biological evidence. The typing of forensic reference samples has become more demanding, especially with the requirement in some jurisdictions to DNA profile arrestees. The Rapid DNA (RDNA) platform, the RapidHIT^® ID (IntegenX^®, Pleasanton, CA), is a fully automated system capable of processing reference samples in approximately 90 min with minimal human intervention. Thus, the RapidHIT ID instrument can be deployed to non-laboratory environments (e.g., booking stations) and run by trained atypical personnel such as law enforcement. In order to implement the RapidHIT ID platform, validation studies are needed to define the performance and limitations of the system. Internal validation studies were undertaken with four early-production RapidHIT ID units. Reliable and concordant STR profiles were obtained from reference buccal swabs. Throughout the study, no contamination was observed. The overall first-pass success rate with an “expert-like system” was 72%, which is comparable to another current RDNA platform commercially available. The system’s second-pass success rate (involving manual interpretation on first-pass inconclusive results) increased to 90%. Inhibitors (i.e., coffee, smoking tobacco, and chewing tobacco) did not appear to affect typing by the instrument system; however, substrate (i.e., swab type) did impact typing success. Additionally, one desirable feature not available with other Rapid systems is that in the event of a system failed run, a swab can be recovered and subsequently re-analyzed in a new sample cartridge. Therefore, rarely should additional sampling or swab consumption be necessary. The RapidHIT ID system is a robust and reliable tool capable of generating complete STR profiles within the forensic DNA typing laboratory or with proper training in decentralized environments by non-laboratory personnel.     

An evaluation of the RapidHIT® system for reliably genotyping reference samples

Short tandem repeat (STR) typing is used routinely for associating or excluding individuals with biological evidence left at a crime scene. Improvements have been made to reduce the turnaround time and labor involved with profile generation, but there is still some lag time between sample collection and interpretation of results. The RapidHIT^® (IntegenX; Pleasanton, CA, USA) system is an automated instrument that is configured to perform DNA extraction, bead-based DNA normalization, amplification, electrophoresis of PCR amplicons, and data analysis of five reference swabs simultaneously. The RapidHIT system provided reliable STR profiles from reference buccal swabs in approximately 90 min with nominal “hands-on” sample loading time with no evidence of contamination between samples. The overall success rate of typing buccal swabs was comparable to standard typing systems. In the event of a failed run due to instrument failure, the swab can be removed from the cartridge and reanalyzed in the RapidHIT system or with standard STR genotyping workflows.     

Pilot study for forensic evaluations of the Precision ID GlobalFiler™ NGS STR Panel v2 with the Ion S5™ system

With the continuous development of massively parallel sequencing (MPS), increasing numbers of laboratories have utilized this method for forensic genomic analyses. When sequencing common short tandem repeats (STRs), MPS does have many advantages over the length-based genotyping method that uses traditional capillary electrophoresis (CE) technology. The Precision ID GlobalFiler™ NGS STR Panel v2 was recently released to simultaneously target 31 autosomal STRs (20 expanded Combined DNA Index System (CODIS) core loci and 11 non-CODIS loci) and 4 gender determination loci (Amelogenin, DYS391, SRY and Y-indel (rs2032678)) with the Ion S5™ System. In the current study, we performed a preliminary validation for this novel MPS-STR panel that included the following analyses: repeatability, concordance, stutter and balance, sensitivity, case-type sample testing, stability, mixture and a population investigation. Complete and reliable profiles were obtained using 125 pg of positive control DNA. The commonly encountered types of case samples and artificial mixtures with ratios of 1:1, 1:3 and 3:1 were also fully genotyped. Additional allele sequence variations were detected in samples from 50 unrelated individuals, and subsequently, an increased power of discrimination and power of exclusion were achieved. However, the average depth of coverage (DoC) of the Penta D locus was detected to be dramatically lower than those of other loci, which caused an interlocus imbalance; this could be one of the reasons for the intralocus imbalance of this locus and the 0.18% inconsistent results in the concordance study. Although certain flaws were observed, the informative metrics, including the DoC, sequence coverage ratios (SCRs) and heterozygote balance (H_b), of the novel MPS multiplex in our study were sufficient for reliable sequencing results that were 99.61% in concordance with the capillary electrophoresis (CE) results. In general, the Precision ID GlobalFiler™ NGS STR Panel v2 was demonstrated to be sensitive, reliable and robust and could be a powerful tool for human identification and kinship analyses. Additionally, we look forward to its updated version.     

Inter-laboratory evaluation of SNP-based forensic identification by massively parallel sequencing using the Ion PGM™

Next generation sequencing (NGS) offers the opportunity to analyse forensic DNA samples and obtain massively parallel coverage of targeted short sequences with the variants they carry. We evaluated the levels of sequence coverage, genotyping precision, sensitivity and mixed DNA patterns of a prototype version of the first commercial forensic NGS kit: the HID-Ion AmpliSeq™ Identity Panel with 169-markers designed for the Ion PGM™ system. Evaluations were made between three laboratories following closely matched Ion PGM™ protocols and a simple validation framework of shared DNA controls. The sequence coverage obtained was extensive for the bulk of SNPs targeted by the HID-Ion AmpliSeq™ Identity Panel. Sensitivity studies showed 90–95% of SNP genotypes could be obtained from 25 to 100 pg of input DNA. Genotyping concordance tests included Coriell cell-line control DNA analyses checked against whole-genome sequencing data from 1000 Genomes and Complete Genomics, indicating a very high concordance rate of 99.8%. Discordant genotypes detected in rs1979255, rs1004357, rs938283, rs2032597 and rs2399332 indicate these loci should be excluded from the panel. Therefore, the HID-Ion AmpliSeq™ Identity Panel and Ion PGM™ system provide a sensitive and accurate forensic SNP genotyping assay. However, low-level DNA produced much more varied sequence coverage and in forensic use the Ion PGM™ system will require careful calibration of the total samples loaded per chip to preserve the genotyping reliability seen in routine forensic DNA. Furthermore, assessments of mixed DNA indicate the user’s control of sequence analysis parameter settings is necessary to ensure mixtures are detected robustly. Given the sensitivity of Ion PGM™, this aspect of forensic genotyping requires further optimisation before massively parallel sequencing is applied to routine casework.     

Developmental validation of the Microreader™ RM-Y ID System: a new rapidly mutating Y-STR 17-plex system for forensic application

International Journal of Legal Medicine - Y-chromosomal short tandem repeats (Y-STRs) are widely applied to evolutionary, genealogical, and kinship analyses of male linages in forensic studies, but...     

Analytical validation of an RI sample cartridge with the RapidHIT® ID system

International Journal of Legal Medicine - Evaluating the short tandem repeat (STR) in the field is important for the timely identification of a suspect. Several lines showed that the RapidHIT®...     

Evaluation of the RapidHIT™ 200 and RapidHIT GlobalFiler® Express kit for fully automated STR genotyping

The RapidHIT™ 200 Human Identification System and RapidHIT GlobalFiler^® Express kit were evaluated and validated for use with single-source reference samples. It was of primary interest to evaluate the system for its efficacy as an expert system and to estimate a first pass success rate, as well as to identify the technical variables impacting that result. While results indicated that this instrument/kit combination can be used to accurately type single-source buccal samples, substantial variability in sensitivity and intra-color balance were observed, as were multiple artifacts, requiring extensive manual editing of the profiles. Artifacts included dye “blobs” and spectral overlap (pull-up) peaks that often originated from relatively low intensity allele peaks. Reduced intra-color balance, in combination with low sensitivity, occasionally resulted in instances of allelic dropout. Overall, 50% of the buccal samples analyzed in this study would have been successfully typed to give full GlobalFiler^® profiles without the need for manual review and editing.     

Evaluation of the Precision ID Identity Panel for the Ion Torrent™ PGM™ sequencer

In cases where only a partial or incomplete STR profile is obtained from a sample, information contained in single nucleotide polymorphisms (SNPs) can prove informative for human identification. Thermo Fisher Scientific, which developed the high throughput Ion Torrent^™ PGM^™ sequencer, released the Precision ID Identity Panel, a multiplex SNP panel for human identity. We evaluated the reproducibility and sensitivity of this multiplex, which contains primers for the amplification of 90 autosomal SNPs and 34 Y-clade SNPs. The manufacturer’s protocol was tested using five commercially available pure native DNAs and six forensic type samples at a range of DNA input amounts (0.2–1.0 ng; n, 90). In addition to analyzing the data using the manufacturer’s software, HID SNP Genotyper (v4.3.1), we also used CLC Genomics Workbench (Qiagen). Although library yields and templating of ion sphere particles (ISPs) were low, downstream sequencing was still successful. Across all samples, only 1.5% of all possible quality control (QC) flags were raised by both the plugin QC filter and CLC; 85% of those flags were raised as the SNP had a major allele frequency outside the thresholds specified by the manufacturer. For the remaining SNPs, coverage of >1500 X and >780 X was obtained for autosomal and Y-clade SNPs respectively, and 100% congruence among genotype calls from both analysis programs was observed. Our results demonstrate that it is possible to obtain reliable and reproducible genotypes using the Precision ID Identity Panel, when using low quantities (≥0.2 ng) of either pure native DNA or forensic type DNA samples.     

Validation of a rapid DNA process with the RapidHIT® ID system using GlobalFiler® Express chemistry,a platform optimized for decentralized testing environments

The RapidHIT^® ID is a fully automated sample-to-answer system for short tandem repeat (STR)-based human identification. The RapidHIT ID has been optimized for use in decentralized environments and processes presumed single source DNA samples, generating Combined DNA Index System (CODIS)-compatible DNA profiles in less than 90 min. The system is easy to use, requiring less than one minute of hands-on time. Profiles are reviewed using centralized linking software, RapidLINK™ (IntegenX, Pleasanton, CA), a software tool designed to collate DNA profiles from single or multiple RapidHIT ID systems at different geographic locations. The RapidHIT ID has been designed to employ GlobalFiler^® Express and AmpFLSTR^® NGMSElect™, Thermo Fisher Scientific (Waltham, MA) STR chemistries. The Developmental Validation studies were performed using GlobalFiler^® Express with single source reference samples according to Scientific Working Group for DNA Analysis Methods guidelines. These results show that multiple RapidHIT ID systems networked with RapidLINK software form a highly reliable system for wide-scale deployment in locations such as police booking stations and border crossings enabling real-time testing of arrestees, potential human trafficking victims, and other instances where rapid turnaround is essential.     

Second-generation sequencing of forensic STRs using the Ion Torrent™ HID STR 10-plex and the Ion PGM™

Second-generation sequencing (SGS) using Roche/454 and Illumina platforms has proved capable of sequencing the majority of the key forensic genetic STR systems. Given that Roche has announced that the 454 platforms will no longer be supported from 2015, focus should now be shifted to competing SGS platforms, such as the MiSeq (Illumina) and the Ion Personal Genome Machine (Ion PGM™; Thermo Fisher). There are currently several challenges faced with amplicon-based SGS STR typing in forensic genetics, including current lengths of amplicons for CE-typing and lack of uniform data analysis between laboratories.Thermo Fisher has designed a human identification (HID) short tandem repeat (STR) 10-plex panel including amelogenin, CSF1PO, D16S539, D3S1358, D5S818, D7S820, D8S1179, TH01, TPOX and vWA, where the primers have been designed specifically for the purpose of SGS and the data analysis is supported by Ion Torrent™ software. Hence, the combination of the STR 10-plex and the Ion PGM™ represents the first fully integrated SGS STR typing solution from PCR to data analysis.In this study, four experiments were performed to evaluate the alpha-version of the STR 10-plex: (1) typing of control samples; (2) analysis of sensitivity; (3) typing of mixtures; and (4) typing of biological crime case samples. Full profiles and concordant results between replicate SGS runs and CE-typing were observed for all control samples. Full profiles were seen with DNA input down to 50 pg, with the exception of a single locus drop-out in one of the 100 pg dilutions. Mixtures were easily deconvoluted down to 20:1, although alleles from the minor contributor had to be identified manually as some signals were not called by the Ion Torrent™ software. Interestingly, full profiles were obtained for all biological samples from real crime and identification cases, in which only partial profiles were obtained with PCR-CE assays. In conclusion, the Ion Torrent™ HID STR 10-plex panel offers an all-in-one solution from amplification of STRs and amelogenin, and sequencing to data analysis.     

A comparison of ABAcard® p30 and RSID™-Semen test kits for forensic semen identification

The screening and confirmatory tests available to a forensic laboratory allow evidence to be examined for the presence of bodily fluids. With the majority of evidence being submitted involving sexual assaults, it is important to have confirmatory tests for the identification of semen that are straightforward, quick, and reliable. The purpose of this study was to compare two commonly used semen identification kits utilized by forensic laboratories: ABAcard^® p30 and Rapid Stain Identification of Human Semen (RSID?-Semen). These kits were assessed with aged semen stains, fresh and frozen post-vasectomy semen, post-coital samples collected on different substrates, post-vasectomy semen mixed with blood, saliva, and urine, a series of swabs collected at increasing time intervals after sexual intercourse, and multiple non-semen samples. The test kits were compared on the basis of sensitivity, specificity, and the cost and time effectiveness of each protocol. Overall, both semen identification tests performed well in the studies. Both kits proved specificity for identifying semen, however the ABAcard^® p30 test surpassed the RSID?-Semen test in sensitivity, cost per test, and simplified test protocol.     

SPERM HY-LITER™ for the identification of spermatozoa from sexual assault evidence

Accurate microscopic identification of human spermatozoa is important in sexual assault cases. We have compared the results of examinations with (1) a fluorescent microscopy method, SPERM HY-LITER™, and (2) Baecchi's method for identification of human spermatozoa. In 35 artificial, forensic type samples, spermatozoa were identified in 45.7% with SPERM HY-LITER™ in Copenhagen, in 54.3% in the laboratory of the manufacturer of SPERM HY-LITER™, and 40.0% of the samples with Baecchi's staining method. When differences occurred between the two methods, it was significantly more often that SPERM HY-LITER™ detected spermatozoa when Baecchi's method did not (t_s = 6.567, df = 1, P = 0.048). This trend was also seen in selected compromised or degraded samples and in selected adjudicative samples. The reactions with spermatozoa from dog, horse, pig and bull were negative with SPERM HY-LITER™, whereas Baecchi's method was non-selective. Data from forensic casework samples in Copenhagen from two years (2008 and 2009) are presented. The samples from 2008 were investigated using Baecchi's method, while those from 2009 were investigated using SPERM HY-LITER™. The frequencies of positive results were similar between the two methods for the two years (27.9% and 32.1% respectively). Analysis of acid phosphatase (ACP) activity for the positive results obtained for these two years does not support the use of a negative ACP result as a prescreen for microscopic analysis for spermatozoa.     

Phylogenetic and forensic studies of the Southeast Florida Hispanic population using the next-generation forensic PowerPlex® Y23 STR marker system

The purpose of this study is to examine the robustness and sensitivity of the newly available Y-STR multiplex kit, the PowerPlex® Y23 System, by comparing our data at the 23-loci level to the routinely used 17 loci provided by the AmpFlSTR® Yfiler® PCR Amplification kit. For the first time, allelic and genotypic frequencies for the 23 Y-STR loci included in the PowerPlex® Y23 System are provided for the Southeast Florida Hispanic (SFH) population. In addition, we have characterized the SFH population in terms of intra-population and inter-population parameters. We also compared these indices of forensic and population genetics interest in the SFH population to comparable data of previously published populations to assess their phylogenetic relationships. Our 23-loci data was shown to provide more discriminatory values as compared to the data when using only 17 loci. Also, the R_ST distance values demonstrate the superior capacity of the PowerPlex® Y23 system to discriminate among populations.     

Allele frequencies and other forensic parameters of the HID-Ion AmpliSeq™ Identity Panel markers in Basques using the Ion Torrent PGM™ platform

The HID-Ion AmpliSeq™ Identity Panel amplifies 90 autosomal SNPs and 34 Y- SNPs with massively parallel sequencing (MPS) using the Ion Torrent PGM™ platform. In the present study, 105 Basques were analyzed to assess this panel. All loci were in Hardy-Weinberg equilibrium and no association between them was detected. Forensic parameters were calculated as 5.74 × 10⁻³⁶ for combined match probability and 99.99998% for combined power of exclusion. In conclusion, the HID Identity panel and the use of this new MPS technology are very promising tools for paternity testing and human identification in routine casework in the forensic field.     

Comparison between MACSprep™ forensic sperm microbead kit and Erase Sperm Isolation kit for the enrichment of sperm fractions recovered from sexual assault samples

International Journal of Legal Medicine - Sexual assault samples often contain mixtures of cells coming from at least two donors. Ideally, one would need to separate the cells into two cellular...     

Is the amelogenin gene reliable for gender identification in forensic casework and prenatal diagnosis?

In humans, the amelogenin gene is present on both the X and the Y chromosomes. However, there are size differences in this gene between these chromosomes, which have been utilised for sexing in forensic casework and prenatal diagnosis. Our study using the AmpFl STR Profiler Plus kit, showed a deletion of Y chromosome-specific amelogenin in five Indian males (1.85%). We propose to call them “deleted-amelogenin males” (DAMs), who but for the detection of the presence of other Y-specific markers (e.g. SRY, STR and 50f2) would have been identified as females. Considering the consequences of the result obtained only using the amelogenin marker, we suggest the use of additional Y chromosome markers for unambiguous gender identification. Received: 17 May 2001 / Accepted: 24 July 2001     

Amplification volume reduction on DNA database samples using FTA™ Classic Cards

The DNA forensic community always strives towards improvements in aspects such as sensitivity, robustness, and efficacy balanced with cost efficiency. Therefore our laboratory decided to study the feasibility of PCR amplification volume reduction using DNA entrapped in FTA? Classic Card and to bring cost savings to the laboratory. There were a few concerns the laboratory needed to address. First, the kinetics of the amplification reaction could be significantly altered. Second, an increase in sensitivity might affect interpretation due to increased stochastic effects even though they were pristine samples. Third, statics might cause FTA punches to jump out of its allocated well into another thus causing sample-to-sample contamination. Fourth, the size of the punches might be too small for visual inspection. Last, there would be a limit to the extent of volume reduction due to evaporation and the possible need of re-injection of samples for capillary electrophoresis. The laboratory had successfully optimized a reduced amplification volume of 10 μL for FTA samples.