Prediction of autosomal STR typing success in ancient and Second World War bone samples

Human-specific quantitative PCR (qPCR) has been developed for forensic use in the last 10 years and is the preferred DNA quantification technique since it is very accurate, sensitive, objective, time-effective and automatable. The amount of information that can be gleaned from a single quantification reaction using commercially available quantification kits has increased from the quantity of nuclear DNA to the amount of male DNA, presence of inhibitors and, most recently, to the degree of DNA degradation. In skeletal remains samples from disaster victims, missing persons and war conflict victims, the DNA is usually degraded. Therefore the new commercial qPCR kits able to assess the degree of degradation are potentially able to predict the success of downstream short tandem repeat (STR) typing. The goal of this study was to verify the quantification step using the PowerQuant kit with regard to its suitability as a screening method for autosomal STR typing success on ancient and Second World War (WWII) skeletal remains. We analysed 60 skeletons excavated from five archaeological sites and four WWII mass graves from Slovenia. The bones were cleaned, surface contamination was removed and the bones ground to a powder. Genomic DNA was obtained from 0.5 g of bone powder after total demineralization. The DNA was purified using a Biorobot EZ1 device. Following PowerQuant quantification, DNA samples were subjected to autosomal STR amplification using the NGM kit. Up to 2.51 ng DNA/g of powder were extracted. No inhibition was detected in any of bones analysed. 82% of the WWII bones gave full profiles while 73% of the ancient bones gave profiles not suitable for interpretation. Four bone extracts yielded no detectable amplification or zero quantification results and no profiles were obtained from any of them. Full or useful partial profiles were produced only from bone extracts where short autosomal (Auto) and long degradation (Deg) PowerQuant targets were detected. It is concluded that STR typing of old bones after quantification with the PowerQuant should be performed only when both Auto and Deg targets are detected simultaneously with no respect to [Auto]/[Deg] ratio. Prediction of STR typing success could be made according to successful amplification of Deg fragment. The PowerQuant kit is capable of identifying bone DNA samples that will not yield useful STR profiles using the NGM kit, and it can be used as a predictor of autosomal STR typing success of bone extracts obtained from ancient and WWII skeletal remains.     

Mitochondrial DNA analysis of a Viking age mass grave in Sweden

In 1998, a Viking Age mass grave was discovered and excavated at St. Laurence´s churchyard in Sigtuna, Sweden. The excavated bones underwent osteoarchaeological analysis and were assigned to at least 19 individuals. Eleven skeletons showed sharp force trauma from bladed weapons. Mass graves are an unusual finding from this time period, making the burial context extraordinary. To investigate a possible maternal kinship among the individuals, bones and teeth from the skeletal remains were selected for mitochondrial DNA (mtDNA) analysis. Sanger sequencing of short stretches of the hypervariable segments I and II (HVS-I and HVS-II) was performed. A subset of the samples was also analysed by massively parallel sequencing analysis (MPS) of the entire mtDNA genome using the Precision ID mtDNA Whole Genome Panel. A total of 15 unique and three shared mtDNA profiles were obtained. Based on a combination of genetic and archaeological data, we conclude that a minimum of 20 individuals was buried in the mass grave. The majority of the individuals were not maternally related. However, two possible pairs of siblings or mother-child relationships were identified. All individuals were assigned to West Eurasian haplogroups, with a predominance of haplogroup H. Although the remains showed an advanced level of DNA degradation, the combined use of Sanger sequencing and MPS with the Precision ID mtDNA Whole Genome Panel revealed at least partial mtDNA data for all samples.     

Kinship analysis of 5th- to 6th-century skeletons of Romanized indigenous people from the Bled–Pristava archaeological site

The familial relationship between skeletons buried together in a shared grave is important for understanding the burial practices of past human populations. Four skeletons were excavated from the Late Antiquity part of the Bled–Pristava burial site in Slovenia, dated to the 5th to 6th century. They were anthropologically characterized as two adults (a middle-aged man and a young woman) and two non-adults (of unknown sex). Based on stratigraphy, the skeletons were considered to be buried simultaneously in one grave. Our aim was to determine whether the skeletons were related. Petrous bones and teeth were used for genetic analysis. Specific precautions were followed to prevent contamination of ancient DNA with contemporary DNA, and an elimination database was established. Bone powder was obtained using a MillMix tissue homogenizer. Prior to extracting the DNA using Biorobot EZ1, 0.5 g of powder was decalcified. The PowerQuant System was used for quantification, various autosomal kits for autosomal short tandem repeat (STR) typing, and the PowerPlex Y23 kit for Y-STR typing. All analyses were performed in duplicate. Up to 28 ng DNA/g of powder was extracted from the samples analyzed. Almost full autosomal STR profiles obtained from all four skeletons and almost full Y-STR haplotypes obtained from two male skeletons were compared, and the possibility of a familial relationship was evaluated. No amplification was obtained in the negative controls, and no match was found in the elimination database. Autosomal STR statistical calculations confirmed that the adult male was the father of two non-adult individuals and one young adult individual from the grave. The relationship between the males (father and son) was additionally confirmed by an identical Y-STR haplotype that belonged to the E1b1b haplogroup, and a combined likelihood ratio for autosomal and Y-STRs was calculated. Kinship analysis confirmed with high confidence (kinship probability greater than 99.9% was calculated for all three children) that all four skeletons belonged to the same family (a father, two daughters, and a son). Through genetic analysis, the burial of members of the same family in a shared grave was confirmed as a burial practice of the population living in the Bled area in Late Antiquity.     

Reliable genetic identification of burnt human remains

The identification of severely burnt human remains by genetic fingerprinting is a common task in forensic routine work. In cases of extreme fire impact, only hard tissues (bones, teeth) may be left for DNA analysis. DNA extracted from burnt bone fragments may be highly degraded, making an amplification of genetic markers difficult or even impossible. Furthermore, heavily burnt bones are very prone to contamination with external DNA.We investigated whether authentic DNA profiles can be generated from human bones showing different stages of fire induced destruction (well preserved, semi-burnt, black burnt, blue–grey burnt, blue–grey–white burnt). DNA was extracted from 71 bone fragments derived from 13 individuals. Obtained genetic patterns (STRs and mtDNA sequences) were compared to the genetic pattern of the respective bodies.Our results show that the identification via DNA analysis is reliably and reproducibly possible from well preserved and semi-burnt bones. In black burnt bones the DNA was highly degraded and in some cases no nuclear DNA was left, leaving mitochondrial DNA analysis as an option. Blue–grey burnt bones lead only sporadically to authentic profiles. The investigation of blue–grey–white burnt bones barely led to reliable results.     

Bedeutung der mtDNA-Analyse für forensische Fragestellungen

The analysis of mitochondrial DNA (mtDNA) represents a technological niche in forensic cases where samples have to be identified that contain only nuclear DNA of limited quality and quantity. The high copy number, the increased stability against degradation and the strict maternal inheritance are the main characteristics of the mitochondrial genome which makes it particularly suitable for palaeogenetic inferences and the reconstruction of human evolution. In forensic analyses mtDNA profiling is an established technological resource for cases where conventional nuclear DNA markers fail to give satisfactory results (e.g. analyses of hair shafts, remains of bones and teeth). Substantial collections of validated mtDNA sequences are essential for a meaningful biostatistical evaluation of mtDNA profiles in a given case as the relative frequencies of the haplotypes can only be determined from adequate mtDNA databases. As mtDNA is inherited along a phylogeny, evolutionary features are also important for the interpretation of the data in individual case examples.     

Y-STR DNA analysis of 154 female child sexual assault cases in the Philippines

The laboratory evaluated 154 sexual assault cases from four Child Protection Units in the Philippines involving female child victims aged from 2?years to 18?years old. All child victims sought medical attention within 72?h after sexual contact. In 130 cases, the child victim knew the alleged offender and identified them during the interview with the social worker. Penile ejaculation was reported by 68 child victims with varying reports of washing after contact. Overall, 84 child victims admitted having wiped their genitalia prior to the collection of biological samples for DNA testing. Laboratory personnel examined vaginal smears in only 109 cases using a light microscope and reported 23 samples to be positive for sperm cells. Using the PowerPlex? short tandem repeat of the Y chromosome (Y-STR) DNA multiplex system, male DNA was detected in vaginal swab samples from 63 child victims. In 39 cases, positive amplification at 11 Y-STR DNA markers consistent with a single male DNA profile was observed. Twenty-eight of these full single Y-STR DNA profiles were found to be unique when searched in worldwide Y-STR DNA population databases (~40,000 haplotypes), eight haplotypes matching Filipinos and/or Asian haplotypes and one Y-STR DNA profile only matching European, Caucasian, and Latin American haplotypes. Y-STR DNA profiles generated will be compared with reference DNA profiles of alleged offenders once reference samples are submitted to the laboratory.     

Bringing colour back after 70 years: Predicting eye and hair colour from skeletal remains of World War II victims using the HIrisPlex system

Retrieving information about externally visible characteristics from DNA can provide investigative leads to find unknown perpetrators, and can also help in disaster victim and other missing person identification cases. Aiming for the application to both types of forensic casework, we previously developed and forensically validated the HIrisPlex test system enabling parallel DNA prediction of eye and hair colour. Although a recent proof-of-principle study demonstrated the general suitability of the HIrisPlex system for successfully analysing DNA from bones and teeth of various storage times and conditions, practical case applications to human remains are scarce. In this study, we applied the HIrisPlex system to 49 DNA samples obtained from bones or teeth of World War II victims excavated at six sites, mostly mass graves, in Slovenia. PCR-based DNA quantification ranged from 4 pg/μl to 313 pg/μl and on an average was 41 pg/μl across all samples. All 49 samples generated complete HIrisPlex profiles with the exception of one MC1R DNA marker (N29insA) missing in 83.7% of the samples. In 44 of the 49 samples (89.8%) complete 15-loci autosomal STR (plus amelogenin) profiles were obtained. Of 5 pairs of skeletal remains for which STR profiling suggested an origin in the same individuals, respectively, 4 showed the same HIrisPlex profiles and predicted eye and hair colours, respectively, while discrepancies in one pair (sample 26 and 43) are likely to be explained by DNA quantity and quality issues observed in sample 43. Sample 43 had the lowest DNA concentration of only 4 pg/μl, producing least reliable STR results and could be misleading in concluding that samples 43 and 26 originate from the same individual. The HIrisPlex-predicted eye and hair colours from two skeletal samples, suggested to derive from two brothers via STR profiling together with a living sister, were confirmed by the living sister's report. Overall, we demonstrate that after more than 70 years, HIrisPlex-based eye and hair colour prediction from skeletal remains is feasible with high success rate. Our results further encourage the use of the HIrisPlex system in missing person/disaster victim identification to aid the identification process in cases where ante-mortem samples or putative relatives are not directly available, and DNA predicted eye and hair colour information provides leads for locating them, allowing STRbased individual identification.     

GHEP-ISFG collaborative simulated exercise for DVI/MPI: Lessons learned about large-scale profile database comparisons

The GHEP-ISFG Working Group has recognized the importance of assisting DNA laboratories to gain expertise in handling DVI or missing persons identification (MPI) projects which involve the need for large-scale genetic profile comparisons. Eleven laboratories participated in a DNA matching exercise to identify victims from a hypothetical conflict with 193 missing persons. The post mortem database was comprised of 87 skeletal remain profiles from a secondary mass grave displaying a minimal number of 58 individuals with evidence of commingling. The reference database was represented by 286 family reference profiles with diverse pedigrees. The goal of the exercise was to correctly discover re-associations and family matches. The results of direct matching for commingled remains re-associations were correct and fully concordant among all laboratories. However, the kinship analysis for missing persons identifications showed variable results among the participants. There was a group of laboratories with correct, concordant results but nearly half of the others showed discrepant results exhibiting likelihood ratio differences of several degrees of magnitude in some cases. Three main errors were detected: (a) some laboratories did not use the complete reference family genetic data to report the match with the remains, (b) the identity and/or non-identity hypotheses were sometimes wrongly expressed in the likelihood ratio calculations, and (c) many laboratories did not properly evaluate the prior odds for the event. The results suggest that large-scale profile comparisons for DVI or MPI is a challenge for forensic genetics laboratories and the statistical treatment of DNA matching and the Bayesian framework should be better standardized among laboratories.     

Testing the performance of mtSNP minisequencing in forensic samples

There is a growing interest among forensic geneticists in developing efficient protocols for genotyping coding region mitochondrial DNA (mtDNA) SNPs (mtSNPs). Minisequencing is becoming a popular method for SNP genotyping, but it is still used by few forensic laboratories. In part, this is due to the lack of studies testing its efficiency and reproducibility when applied to real and complex forensic samples. Here we tested a minisequencing design that consists of 71 mtSNPs (in three multiplexes) that are diagnostic of known branches of the R0 phylogeny, in real forensic samples, including degraded bones and teeth, hair shafts, and serial dilutions. The fact that amplicons are short coupled with the natural efficiency of the minisequencing technique allow these assays to perform well with all the samples tested either degraded and/or those containing low DNA amount. We did not observe phylogenetic inconsistencies in the 71 mtSNP haplotypes generated, indicating that the technique is robust against potential artefacts that could arise from unintended contamination and/or spurious amplification of nuclear mtDNA pseudogenes (NUMTs).     

Searching for the mother missed since the Second World War

The aim of the study was to perform the genetic identification of a human cranium from a Second World War gravesite in Slovenia and find out if it belonged to the mother of a woman used as a family reference. Both genetic and anthropological examinations were carried out. The genetic examination was performed on 2 molars and petrous bone. Prior to DNA isolation 0.5 g of tooth and bone powder was decalcified. The DNA was purified in a Biorobot EZ1 (Qiagen) device. The nuclear DNA of the samples was quantified and short tandem repeat (STR) typing performed using two different autosomal and Y-STR kits. Up to 22.4 ng DNA/g of powder was obtained from samples analyzed. We managed to obtain nuclear DNA for successful STR typing from the left second molar and from the petrous bone. Full autosomal genetic profile including amelogenin locus revealed the male origin of the cranium that was further confirmed by the analyses of Y-STRs. The same conclusions were adopted after the anthropological analysis which identified the cranium as that of a very young Caucasoid male. The male origin of the cranium rejected the possibility of motherhood for the compared daughter. For traceability in the event of contamination, we created an elimination database including genetic profiles of the nuclear and Y-STRs of all persons that had been in contact with the analyzed cranium and no match was found.     

DNA typing from skeletal remains following an explosion in a military fort--first experience in Ecuador (South-America)

We present individual body identification efforts, to identify skeletal remains and relatives of missing persons of an explosion took place inside one of the munitions recesses of the Armoured Brigade of the Galapagos Armoured Cavalry, in the city of Riobamba, Ecuador, on Wednesday, November 20, 2002. Nineteen samples of bone remains and two tissue samples (a blood stain on a piece of fabric) from the zero zone were analysed. DNA extraction was made by Isoamilic Phenol-Chloroform-Alcohol, and proteinase K. We increased PCR cycles to identify DNA from bones to 35 cycles in some cases. An ABI 310 sequencer was used. Determination of the fragment size and the allelic designation of the different loci was carried out by comparison with the allelic ladders of the PowerPlex 16 kit and Gene Scan Analysis Software programme. Five possible family groups were established and were compared with the profiles found. Classical Bayesian methods were used to calculate the Likelihood Ratio and it was possible to identify five different genetic profiles in our country. This paper is important because is a novel experience for our forensic services, because this was the first time DNA had been used as an identification method in disasters, and it was validated by Ecuadorian justice like a very effective method.     

Identification of victims of the 1998 Taoyuan Airbus crash accident using DNA analysis

In February 1998 a civilian aeroplane carrying 196 individuals crashed in Taiwan and killed another 6 people on the ground. Although there were dental and medical records, fingerprints, photographic evidence and personal effects to identify some of the victims, DNA analysis was required to further identify severely damaged remains. From the 202 people known to have perished in the plane crash, a total of 685 fragments of human remains were subjected to DNA analysis. The analysis was carried out using nine microsatellite loci, plus amelogenin to cluster the 685 fragments into 202 groups, accounting for all the victims. To establish genetic relatedness of the victims to other victims and living relatives, additional DNA loci were used. In this case the paternity index was increased by using HLA DQA1 plus Polymarker. The same 16 DNA loci were used to test blood samples from 201 relatives to establish parent/child and sibling relationships. With the exception of 19 victims identified by non-genetic evidence, 183 victims were successfully identified by DNA typing with relatively high values of paternity index by the direct or indirect comparison of relatives. The 202 victims were from 37 different families, ranging in size from 2 to 13 members and 74 individuals known to be unrelated to any other victim. The DNA from living relatives was used to identify one member of a family group, from which other victims of the family could be identified. ABO blood group information was further used to confirm genetic relatedness within families. A comparison of the DNA profiling results to the ABO blood group of the victims showed no discrepancies with the exception of two mutations in the FGA locus. In cases of severely damaged victims from a plane crash, DNA analysis proved to be the best choice to identify victims. Received: 19 August 1998 / Received in revised form: 4 January 1999 / Accepted: 10 March 1999     

The impact of DNA contamination of bone samples in forensic case analysis and anthropological research

Contamination precautions and quality control are great issues when human bones are investigated genetically. This is especially true for historical samples with only minute amounts of usually highly degraded DNA. But also in forensic routine analysis, sometimes DNA has to be isolated from bones in equally bad conditions, e.g. from burned victims. In such cases, there are several eventualities to contaminate the sample with foreign DNA, for example caused by the recovery of the bones, by trace investigation on a crime scene, or - of course - during handling in the lab. We present the investigation of artificially contaminated historical bone samples which contained no original DNA. Three different kind of contamination were studied: (1) touching of the samples, (2) application of saliva, and (3) application of pure DNA. The samples were genetically investigated without and with the employment of a defined cleaning protocol of the bones. The results show that pure DNA can usually not be removed from the bones and that saliva is a similar thread for subsequent DNA analysis. After the cleaning procedure about 70% of saliva contaminated samples still yielded reproducible STR profiles implicating severe problems for the investigation of highly degraded bone fragments. Simple touching of the specimens seems not to be a real problem for genetic investigations since the obtained signals were not reproducible.     

Successful DNA typing of ultrafiltered urines used to detect EPO doping

Endogenous and exogenous erythropoietin (EPO) present in urine can be distinguished according to their isoelectric profiles. This methodology requires urine samples to be concentrated about 200 to 1000 times with manipulations that should remove most of the cells occurring in the original sample. In this study, we tried to obtain DNA profiles from 10 ultrafiltered urines (retentates) in order to evaluate whether a formal genetic identification was technically feasible. No nuclear DNA profiles could be established from retentates, despite 34 PCR-cycles amplifications. Contrastingly, mitochondrial DNA (mtDNA) profiles were obtained for 9 out of the 10 retentates. Apart from some particularities, retentate mtDNA profiles were all distinct and matched mtDNA profiles of corresponding reference samples.     

Mitochondrial DNA variation in Tajiks living in Tajikistan

This study aimed to characterize mtDNA control region (positions 16,024–576) of unrelated Tajiks living in Tajikistan. DNA was isolated from saliva specimens stored on FTA cards. The mtDNA fragments were amplified and directly sequenced in forward and reverse directions. Haplogroups were determined using HaploGrep and the diagnostic polymorphisms in the coding region of mtDNA. The Tajik mtDNA pool was characterized by substantial admixture of western and eastern Eurasian haplogroups, 62.6% and 26.4% sequences, respectively. It also contained 9.9% of South Asian and 1.1% of African haplotypes. The Tajik mtDNA sequences belonged to 90 different haplotypes defined by 148 transitions and 13 transversions in 156 of 1122 nucleotide sites. The Tajik mtDNA pool demonstrated the high genetic variation with genetic diversity of 0.999 ± 0.002, nucleotide diversity of 0.014 ± 0.007, and the mean number of pairwise nucleotide differences of 15.38 ± 6.93. The random match probability and the power of discrimination were 0.0112 and 0.9888, respectively. Ethno-territorial groups of Tajiks demonstrated significant genetic differentiation with 2.67% of the genetic variance explained by differences between subpopulations. This study provides the insight into the mtDNA pool of Tajiks living in Tajikistan. The data should be taken into account in forensic identifications based on mtDNA.     

DNA extraction method from bones using Maxwell® 16

This paper describes the automated purification of DNA extracted from human bones using Maxwell® 16 bench top instrument. Analysis of nuclear short tandem repeats (STR) is invaluable in identification of human remains exhumed from mass graves in Croatia. Up to today 4683 skeletal remains have been recovered and for 897 human remains identity has not been determined. DNA has been extracted from 70% of all unidentified samples. For more than 90% of the samples nuclear STR profiles have been obtained using either organic phenol/chloroform method or silica-column purification for the extraction of DNA from bones or teeth. In order to evaluate a Maxwell® 16 DNA extraction performance 40 bone samples with different stage of decomposition were analyzed. The efficacy of manual silica based extraction and an automated purification was compared. The DNA yield per gram of starting material, removal of inhibitors and the quality of resulting STR profiles of the Maxwell extracts from duplicate amplifications were evaluated. The results show that Maxwell 16 platform can be used instead of manual DNA extraction procedures.     

Sequence polymorphisms of mtDNA HV1, HV2 and HV3 regions in eight population groups living in Taiwan

Analysis of human mitochondrial DNA (mtDNA) polymorphisms in the D-loop region has become a useful tool in forensic casework and matrilineal origin research. In this study, the mtDNA D-loop region including hypervariable region 1 (HV1), hypervariable region 2 (HV2), segment between HV1 and HV2 (7S DNA spanned region), and extended hypervariable region 3 (HV3ex) was sequenced in 539 unrelated individuals from eight population groups living in Taiwan. Combined analyses of the complete D-loop revealed a total of 383 haplotypes with 319 unique haplotypes. The probability of any two individuals sharing the same mtDNA haplotype decreased as the combination of control region segments extended and reached 0.48% with the combination of a complete D-loop region. Sequence variants in HV3ex can further discriminate the haplotypes in some population groups. Phylogenetic haplogroups of these subjects were analyzed. The multidimensional scaling plots of these population groups, constructed based on sequence of the complete D-loop, demonstrated a clear matrilineal genetic substructure in this area. In conclusion, this database of mtDNA complete D-loop sequence including HV3 can serve as a reference for forensic identification. Sequence polymorphisms of the D-loop located outside the HV1 and HV2 may be helpful in further haplogroup characterization.     

Whole mitochondrial genomes assembled from thermally altered forensic bones and teeth

The recovery and analysis of genetic material obtained from thermally altered human bones and teeth are increasingly important to forensic investigations, especially in cases where soft-tissue identification is no longer possible. Although little is known about how these fire-related processes affect DNA degradation over time, next-generation sequencing technology in combination with traditional osteobiographical applications may provide us clues to these questions. In this study, we compare whole mitochondrial genome data generated using two different DNA extraction methods from 27 thermally altered samples obtained from fire victims (Maricopa County, Arizona) . DNA extracts were converted to double-stranded DNA libraries and enriched for whole mitochondrial DNA (mtDNA) using synthetic biotinylated RNA baits, then sequenced on an Illumina MiSeq. We processed the mitochondrial data using an in-house computational pipeline (MitoPipe1.0) composed of ancient DNA and modern genomics applications, then compared the resulting information across the two extraction types and five burn categories. Our analysis shows that DNA fragmentation increases with temperature, but that the acute insult from fire combined with the lack of water is insufficient to produce 5′ and 3′ terminal deamination characteristic of ancient DNA. Our data also suggest an acute and significant point of DNA degradation between 350 °C and 550 °C, and that the likelihood of generating high quality mtDNA haplogroup calls decreases significantly at temperatures > 550 °C. This research is part of a concerted effort to understand how fire affects our ability to generate genetic profiles suitable for forensic identification purposes.     

Investigation of mtDNA control region sequences in an Egyptian population sample

The sequences of mitochondrial DNA (mtDNA) control region were investigated in 101 unrelated individuals living in the northern region of Nile delta (Gharbia, N = 55 and Kafrelsheikh, N = 46). DNA was extracted from blood stained filter papers or buccal swabs. HV1, HV2 and HV3 were PCR amplified and sequenced; the resulted sequences were aligned and compared with revised Cambridge sequence (rCRS). The results revealed presence of total 93 different haplotypes, 86 of them are unique and 7 are shared haplotypes, the most common haplotype, was observed with a frequency, 2.97% of population sample. High mtDNA diversity was observed with genetic diversity and power of discrimination, 0.9982 and 0.9883, respectively. In this dataset the west Eurasian haplogroups predominated over the African haplogroups. The results would be useful for forensic examinations and human genetic studies.     

High efficiency DNA extraction from bone by total demineralization

In historical cases, missing persons’ identification, mass disasters, and ancient DNA investigations, bone and teeth samples are often the only, and almost always the best, biological material available for DNA typing. This is because of the physical and chemical barrier that the protein:mineral matrix of bone poses to environmental deterioration and biological attack. Most bone extraction protocols utilized in the forensic community involve an incubation period of bone powder in extraction buffer for proteinase digestion, followed by the collection of the supernatant, and the disposal of large quantities of undissolved bone powder. Here we present an extremely efficient protocol for recovery of DNA by complete demineralization, resulting in full physical dissolution of the bone sample. This is performed in a manner that retains and concentrates all the reagent volume, for complete DNA recovery.For our study, we selected 14 challenging bone samples. The bones were extracted side-by-side with our new demineralization protocol and the standard extraction protocol in use at AFDIL. A real-time quantification assay based on the amplification of a 143 bp mtDNA fragment showed that this new demineralization protocol significantly enhances the quantity of DNA that can be extracted and amplified from degraded skeletal remains. We have used this technique to successfully recover authentic DNA sequences from extremely challenging samples that failed repeatedly using the standard protocol.