QIAGEN's Investigator® Quantiplex® Pro Kit.

The QIAGEN Investigator® Quantiplex® Pro Kit is a real-time quantitative PCR assay utilized by forensic DNA laboratories to determine the amount of amplifiable human and male DNA in a sample prior to downstream amplification of specific STR markers for human identity testing. This quantification method includes two internal controls that assist the analyst in a preliminary evaluation of the sample in regard to both inhibition or degradation that may be present in the sample and subsequently affect the more targeted downstream amplification of specific markers for identity testing. The internal controls are analogous to the quality sensors contained in QIAGEN's Investigator® 24plex line of amplification kits, ensuring that the sample's performance in the quantitation step can accurately predict the success of the STR amplification results. This chapter describes the physical plate setup of a quantitative PCR assay utilizing the QIAGEN Investigator® Quantiplex® Pro Kit as well as the steps and software configurations involved in running such a plate on the Applied Biosystems 7500 Real-Time PCR System for Human Identification using HID Real-Time PCR Analysis Software v1.1 or 1.2.

Detecting DNA damage in stored blood samples.

Several commercially available quantitative real-time PCR (qPCR) systems enable highly sensitive detection of human DNA and provide a degradation index (DI) to assess DNA quality. From routine casework in forensic genetics, it was observed that DNA degradation in forensic samples such as blood samples stored under sub-optimal conditions leads to visible effects in multiplex analyses of short tandem repeat markers (STRs) due to decreased amplification efficiencies in longer amplicons. It was further noticed that degradation indices often remain below the value that is considered to be critical. Thus, the aim of this work was to systematically analyze this effect and to compare conventional qPCR assays with a modified qPCR approach using uracil DNA glycosylase (UNG) and DNA quality assessment methods based on electrophoresis. Blood samples were stored at three different storage temperatures for up to 316 days. Significantly increased DNA recovery was observed from samples stored at high temperatures (37 °C) compared samples stored at room temperature and 4 °C. We observed typical effects of degradation in STR analyses but no correlation between DI and storage time in any of the storage conditions. Adding UNG slightly increased the sensitivity of detecting DNA degradation in one of the qPCR kits used in this study. This observation was not confirmed when using a second qPCR system. Electrophoretic systems did also not reveal significant correlations between integrity values and time. Methods for detecting DNA degradation are usually limited to the detection of DNA fragmentation, and we conclude that degradation affecting forensic STR typing is more complex.

Inhibition of Drug-Induced Liver Injury in Mice Using a Positively Charged Peptide That Binds DNA.

Hepatic cell death occurs in response to diverse stimuli such as chemical and physical damage. The exposure of intracellular contents such as DNA during necrosis induces a severe inflammatory response that has yet to be fully explored therapeutically. Here, we sought means to neutralize the ability of extracellular DNA to induce deleterious tissue inflammation when drug-induced liver injury had already ensued. DNA exposure and inflammation were investigated in vivo in drug-induced liver injury using intravital microscopy. The necrotic DNA debris was studied in murine livers in vivo and in DNA debris models in vitro by using a positively charged chemokine-derived peptide (MIG30; CXCL9[74-103]). Acetaminophen-induced liver necrosis was associated with massive DNA accumulation, production of CXC chemokines, and neutrophil activation inside the injured tissue. The MIG30 peptide bound the healthy liver vasculature and, to a much greater extent, to DNA-rich necrotic tissue. Moreover, MIG30 bound extracellular DNA directly in vivo in a charge-dependent manner and independently of glycosaminoglycans and chemokines. Post-treatment of mice with MIG30 reduced mortality, liver damage, and inflammation significantly. These effects were not observed with a control peptide that does not bind DNA. Mechanistically, MIG30 inhibited the interaction between DNA and histones, and promoted the dissociation of histones from necrotic debris. MIG30 also inhibited the pro-inflammatory effect of CpG DNA, as measured by a reduction in CXCL8 production, indicating that MIG30 disturbs the ability of DNA to induce hepatic inflammation. Conclusion: The use of DNA-binding peptides reduces necrotic liver injury and inflammation, even at late timepoints.

Role of molecular techniques in PMI estimation: An update.

The time frames between death and reporting of the cadaver, known as post Mortem interval (PMI), is essential in investigation of homicide deaths, suspicious deaths, or other untimely deaths as well as natural deaths. Such information helps to connect the missing links in homicide or other relevant cases. Over the time several methods are developed which depends upon factors as several methods physiological, biochemical, entomological, and archaeological for the estimation of degradation of body with time. These methods lack precision, require expertise to achieve worthy results or authentic estimate. Although these methods are currently in use but, these evaluations are still unreliable and imprecise. Hence, we still need new methods for better estimation of PMI. Initially, the predictable morphological and chemical changes in cadaver are used as PMI indicators but, as the time since death increases, the above methods become less useful for as they can't pin point the time of death rather give a ballpark idea. With the advent of the field of molecular biology, the estimation of PMI is proposed to be executed by evaluating the degradation pattern of the biological markers (DNA, RNA, and Proteins). It is now proved that the DNA is fairly unwavering over long post-mortem phases, RNA is much more labile in nature, and sensitive to degradation in a tissue-specific manner. Thus, the main purpose (aim, agenda) of this document is to provide review that mainly focuses on potential use of RNA markers in estimation of PMI. For this Critical Review, the systematic evaluation of 47 studies is executed according to the chosen inclusion and exclusion criteria.

Progress in forensic bone DNA analysis: Lessons learned from ancient DNA.

Research on ancient and forensic DNA is related in many ways, and the two fields must deal with similar obstacles. Therefore, communication between these two communities has the potential to improve results in both research fields. Here, we present the insights gained in the ancient DNA community with regard to analyzing DNA from aged skeletal material and the potential use of the developed protocols in forensic work. We discuss the various steps, from choosing samples for DNA extraction to deciding between classical PCR amplification and massively parallel sequencing approaches. Based on the progress made in ancient DNA analyses combined with the requirements of forensic work, we suggest that there is substantial potential for incorporating ancient DNA approaches into forensic protocols, a process that has already begun to a considerable extent. However, taking full advantage of the experiences gained from ancient DNA work will require comparative studies by the forensic DNA community to tailor the methods developed for ancient samples to the specific needs of forensic studies and case work. If successful, in our view, the benefits for both communities would be considerable.

The human intervertebral disc as a source of DNA for molecular identification.

Genetic analyses such as STR-typing are routinely used for identification purposes in forensic casework. Although genotyping techniques only require a minimum amount of DNA to provide a genetic profile, DNA quality differs not only between but also within tissues during ongoing decomposition. Initiated by a recent case where, due to the constitution of the body, preferred tissue was not available or only resulted in a partial and not usable DNA profile, the analysis of intervertebral discs as a source of DNA was considered. As the analysis of this tissue resulted in a high quality DNA profile a further study was performed in which thirty intervertebral discs dissected from bodies in different stages of decay were analyzed. All samples yielded good quality DNA in quantities suitable for STR-based amplification with no or only low degradation indices, resulting in complete genetic profiles. These results demonstrate the robustness of human intervertebral disc tissue as a source of DNA for molecular identification purposes.

Intrinsic and extrinsic factors that may influence DNA preservation in skeletal remains: A review.

The identification of skeletal human remains, severely compromised by putrefaction, or highly deteriorated, is important for legal and humanitarian reasons. There are different tools that can help in the identification process such as anthropological and genetic studies. The success observed during the last decade in genetic analysis of skeletal remains has been possible especially due to the refinements of DNA extraction and posterior analysis techniques. However, despite these progresses, many challenges keep influencing the results of such analysis, mainly the limited amount and the degradation of the DNA recovered from badly preserved samples. By now, there is still no wide-range knowledge about post-mortem kinetics of DNA degradation. Therefore, taphonomy studies can play a key role in the reconstruction of post-mortem transformations that skeletal remains, and consequently DNA, have undergone. Thus, the goal of the present review focuses on the assessment of the literature regarding the possible effect of intrinsic (characteristics of the bone) and extrinsic (environmental) factors on the state of preservation of skeletal remains recovered in a terrestrial environment and their genetic material. The establishment of useful indicators describing the state of the remains is a key factor in order to determine their suitability for posterior biomolecular analysis.

Bone fragment or bone powder? ATR-FTIR spectroscopy-based comparison of chemical composition and DNA preservation of bones after 10 years in a freezer.

Freezing bone samples to preserve their biomolecular properties for various analyses at a later time is a common practice. Storage temperature and freeze-thaw cycles are well-known factors affecting degradation of molecules in the bone, whereas less is known about the form in which the tissue is most stable. In general, as little intervention as possible is advised before storage. In the case of DNA analyses, homogenization of the bone shortly before DNA extraction is recommended. Because recent research on the DNA yield from frozen bone fragments and frozen bone powder indicates better DNA preservation in the latter, the aim of the study presented here was to investigate and compare the chemical composition of both types of samples (fragments versus powder) using ATR-FTIR spectroscopy. Pairs of bone fragments and bone powder originating from the same femur of 57 individuals from a Second World War mass grave, stored in a freezer at - 20 °C for 10 years, were analyzed. Prior to analysis, the stored fragments were ground into powder, whereas the stored powder was analyzed without any further preparation. Spectroscopic analysis was performed using ATR-FTIR spectroscopy. The spectra obtained were processed and analyzed to determine and compare the chemical composition of both types of samples. The results show that frozen powdered samples have significantly better-preserved organic matter and lower concentrations of B-type carbonates, but higher concentrations of A-type carbonates and stoichiometric apatite. In addition, there are more differences in the samples with a low DNA degradation index and less in the samples with a high DNA degradation index. Because the results are inconsistent with the current understanding of bone preservation, additional research into optimal preparation and long-term storage of bone samples is necessary.

Suitability of specific soft tissue swabs for the forensic identification of highly decomposed bodies.

When decomposition of a recovered body is fairly advanced, identification based on common morphologic features is often impossible. In these cases, short tandem repeat (STR) marker genotyping has established itself as a convenient and reliable alternative. However, at very progressed stages of decomposition, postmortem tissue putrefaction processes can decrease DNA yields considerably. Hence, not all types of tissue are equally suitable for successful STR marker-based postmortem identification. Bone or dental material is often analysed in corpses with advanced decompositional changes. However, processing of these materials is very elaborate and time and resource consuming. We have therefore focused on the suitableness of various types of soft tissue swabs, where DNA extraction is easier and faster. By sampling 28 bodies at various stages of decomposition, we evaluated the suitability of different tissues for genotyping at varying degrees of physical decay. This was achieved by a systematic classification of the sampled bodies by morphological scoring and subsequent analysis of multiple tissue swabs of the aortic wall, urinary bladder wall, brain, liver, oral mucosa and skeletal muscle. In summary, we found variable degrees of suitability of different types of soft tissue swabs for DNA-based identification. Swabs of the aortic wall, the urinary bladder wall and brain tissue yielded the best results - in descending order - even at advanced levels of decay.

Developmental validation of VeriFiler™ Plus PCR Amplification Kit: A 6-dye multiplex assay designed for casework samples.

The VeriFiler™ Plus PCR Amplification Kit is a 6-dye multiplex assay that simultaneously amplifies a set of 23 autosomal markers (D3S1358, vWA, D16S539, CSF1PO, D6S1043, D8S1179, D21S11, D18S51, D5S818, D2S441, D19S433, FGA, D10S1248, D22S1045, D1S1656, D13S317, D7S820, Penta E, Penta D, TH01, D12S391, D2S1338, and TPOX), a quality indicator system, and two sex-identification markers. Combined, the markers satisfy the requirements of the Chinese National autosomal DNA database as well as expanded CODIS (Combined DNA Index System). The VeriFiler Plus kit was developed with an improved Master Mix which incorporates the brighter TED™ dye, and accommodates a higher sample loading volume thus allowing for increased sensitivity and enabling maximum information recovery from challenging casework samples including touch, degraded, and inhibited samples. Here, we report the results of the developmental validation study which followed the SWGDAM (Scientific Working Group on DNA Analysis Methods) guidelines and includes data for PCR-based studies, sensitivity, species specificity, stability, precision, reproducibility and repeatability, concordance, stutter, DNA mixtures, and performance on mock casework samples. The results validate the multiplex design as well as demonstrate the kit's robustness, reliability, and suitability as an assay for human identification with casework DNA samples.

Comparison of DNA typing success in compromised blood and touch samples based on sampling swab composition.

Sample collection at the crime scene can introduce variations in DNA recovery based upon the substrate from which a sample is collected, the material of the collection device used, or the storage conditions after collection. There are many factors during this process that can degrade the sample during drying and storage, and before DNA extraction can be performed. The purpose of this study was to evaluate and compare the performance of standard cotton swab collection with the Bode BioSafe® swab, which includes both a desiccant at the swab head and proprietary compounds to prevent degradation of the sample during sample collection and preservation. Blood and touch DNA samples were collected from porous and nonporous substrates and stored at elevated temperatures to simulate accelerated time. DNA quantification and STR profile data were used to assess the performance of the swabs. BioSafe® swab collection resulted in similar DNA yields from blood samples and significantly higher DNA yields from touch samples when compared to collection with cotton swabs. BioSafe® swabs also resulted in higher DNA integrity during long-term storage, increased STR profile success and improved retention of low-level contributor alleles.

Comparative analysis of DNA extraction processes for DNA-based identification from putrefied bodies in forensic routine work.

Identification of putrefied bodies is an important and common task in forensic routine. Usually, the identification of deceased is done by visual recognition, fingerprints, physical distinguishing marks (e.g. tattoos, scars and surgical implants) and/or dental examination. However, if morphologic characteristics are not recognizable, due to advanced putrefaction of the corpse, or recent medical records are not available, the DNA-based identification is favored. Thus, in order to find another reliable procedure for DNA extraction of putrefied samples regarding tissue selection, costs and time, two commercial forensic kits were compared: DNeasy® Blood & Tissue kit and SwabSolution™ kit. Both kits were used for DNA extraction from five soft tissues (brain, aorta, liver, kidney and psoas major muscle) and nails (finger- and toenail) obtained during the medicolegal autopsy of 20 putrefied corpses. DNeasy® Blood & Tissue kit was by quantitative comparison mostly superior to SwabSolution™ kit: it yielded more DNA of better quality (i.e. less degraded and inhibited). However, the qualitative results (DNA profiles) of both extraction procedures were similar. Among the analyzed tissue types, nails were proved as the most suitable for DNA-based identification of putrefied bodies.

Whole human blood DNA degradation associated with artificial ultraviolet and solar radiations as a function of exposure time.

Laboratory investigations were conducted to evaluate the effect of ultraviolet radiation components and solar radiation exposure as a function of time on the degradation of whole human blood DNA from the standpoint of forensic analysis. Ten µL of whole human male blood samples were exposed to UV-A, UV-B, UV-C, and solar radiation at 20 min intervals up to 120 min. Allele frequencies of 16 short tandem repeat (STR) markers were monitored by employing current forensic typing DNA techniques. The STR markers were grouped into high, medium, and low molecular weight categories. Results revealed that even 20 min exposure to 4.89 eV UV-C photons (ʎ = 254 nm) with radiation intensity of 1200 µW/cm2 would degrade whole human male blood DNA samples significantly, making them unfit for human identification due to the breakdown of high molecular weight STRs. Exposure of blood samples to 4.11 eV UV-B photons (ʎ = 302 nm) with radiation intensity of 900 µW/cm2 resulted in complete degradation of high molecular weight STRs after 60 min. Partial breakdown of medium and low molecular weight STRs started after 80 min exposure. The degradation index (DI) values appear to show that the degradation of the DNA template molecule was relatively less in the low molecular weight DNA fragments as compared with high molecular weight DNA fragments. This finding indicates that genetic profiles obtained from whole human male blood exposed to this radiation for 60 min will give inconclusive results. Samples exposed up to 120 min to 3.40 eV UV-A photons (ʎ = 365 nm) and 3.10-3.94 eV photons of solar radiation did not appear to produce appreciable degradation in any of three molecular weight STRs in the whole human blood DNA samples.

DIP-microhaplotypes: new markers for detection of unbalanced DNA mixtures.

The identification of a suspect in a degraded and unbalanced DNA mixture has been a challenge for the standard short tandem repeat polymorphisms (STR) typing. Several methods have been introduced to solve this problem, such as DIP-STR, DIP-SNP, and SNP-STR markers. In this study, we proposed DIP-microhaplotype (deletion/insertion linked a chain of SNPs) as a kind of new genetic marker to type the unbalanced and degraded DNA mixture. We established the detection method with ten DIP-microhaplotype markers including 26 SNPs using allele-specific multiplex PCR followed by SNaPshot assay. This novel compound marker allows us to detect the minor DNA with a sensitivity of 1:100 to 1:1000 in a DNA mixture of any gender. Most of the DIP-microhaplotype markers had a relatively high probability of informative alleles with an average informative value (I value) of 0.308. In all, we proposed DIP-microhaplotype as a novel type of DNA marker for the detection of minor contributor from unbalanced DNA mixtures. Due to their inherent shorter length, higher polymorphism, and sensitivity, DIP-microhaplotypes are promising markers for the examination of the degraded and unbalanced mixtures in forensic stains or clinical chimeras.

Discrimination of highly degraded, aged Asian and African elephant ivory using denaturing gradient gel electrophoresis (DGGE).

BACKGROUND: Elephant populations have greatly reduced mainly due to illegal poaching for their ivory. The trade in elephant products is protected by national laws and CITES agreements to prevent them from further decline. For instance, in Thailand, it is illegal to trade ivory from African elephants; however, the law allows possession of ivory from Asian elephants if permission has been obtained from the authorities. As such, means of enforcement of legislation are needed to classify the legal status of seized ivory products. Many DNA-based techniques have been previously reported for this purpose, although all have a limit of detection not suitable for extremely degraded samples. AIM: We report an assay based on nested PCR followed by DGGE to confirm the legal or illegal status of seized ivory samples where it is assumed that the DNA will be highly degraded. METHOD AND RESULTS: The assay was tested on aged ivory from which the assay was tested for reproducibility, specificity, and, importantly, sensitivity. Blind testing showed 100% identification accuracy. Correct assignment in all 304 samples tested was achieved including confirmation of the legal status of 227 highly degraded, aged ivories, thus underlining the high sensitivity of the assay. CONCLUSION AND RECOMMENDATION: The research output will be beneficial to analyze ivory casework samples in wildlife forensic laboratories.

Quantifying visible absorbance changes and DNA degradation in aging bloodstains under extreme temperatures.

Physicochemical property changes observed in a degrading bloodstain can be used to estimate its time since deposition (TSD) and provide a timestamp to the sample's age. Many of the time-dependent processes that occur as a bloodstain degrades, such as DNA fragmentation and changes in hemoglobin structure, also exhibit temperature-dependent behaviours. Previous studies have demonstrated that pairing high-resolution automated gel electrophoresis and visible absorbance spectroscopy could be used to quantify the rate of degradation of a bloodstain in relation to time and storage substrate. Our study investigates such trends with an added factor, extreme temperatures. Passive drip stains were stored in either microcentrifuge tubes or on FTA cards at either -20°C, 21°C or 40°C and tested over 11 time points spanning 15 days. For both storage substrates, the wavelength at maximum absorbance for the Soret band and the maximum absorbance of the Alpha band showed a negative trend over time suggesting that spectral shifts are informative for TSD estimates. The ratio of the maximum peak height for DNA fragments lengths of 500-1000 base pairs to 1000-5000 base pairs was the most informative DNA variable in relation to time for both substrates. Cross-validation suggested the appropriate fit of the models with the data and reasonable predictive ability. We integrated both DNA concentration and hemoglobin visible absorbance metrics using principal component analysis (PCA) into a single model. Adding the random effect of the donor to the PCA model accounted for a large portion of the variation as did storage method and temperature. Additionally, canonical correspondence showed that temperature corresponded differently to the response variables for FTA card and microcentrifuge tube samples, suggesting a substrate specific effect. This study confirms that pairing DNA concentration and hemoglobin's visible absorbance can provide insight on the effect of different environmental and storage conditions on bloodstain degradation. While the level of uncertainty surrounding TSD estimates still precludes its use in the field, this study provides a valuable framework that improves our understanding of variation surrounding TSD estimates, which will be critical to any eventual application.

Development of a quantitative PCR-based method for studying temporal DNA degradation in waterlogged bone.

While several studies have examined temporal DNA degradation in bones collected from terrestrial environments, studies on temporal DNA degradation in bones collected from aquatic environments are limited and mostly based on case studies. The objective of this study was to assess the impact of long-term submersion, aquatic environment, bone type and DNA extraction method on DNA quality and quantity. Bone samples (scapulae and ribs), collected every ~1000 ADD from a freshwater lake and river, underwent DNA extraction via ChargeSwitch® gDNA Plant Kit and organic phenol-chloroform methods, and DNA quantitation using both TaqMan and SYBR Green-based quantitative PCR (qPCR) methods. Results suggest that in both bone types, quality of recovered DNA (i.e., degradation index) declined significantly with increase in submersion time. Among two bone types, quality of recovered DNA from scapulae declined faster than rib samples. There was no significant difference in recovered DNA quantity between bone types, DNA extraction methods, or locations but various interactions between these variables showed significant difference. Overall, it can be concluded that DNA can be extracted from waterlogged bone in sufficient quantity to generate an STR profile up to 4000 ADD.

Corneocyte lysis and fragmented DNA considerations for the cellular component of forensic touch DNA.

DNA deposited by individuals' hands is a routine part of forensic analysis, yet little is understood about the precise cellular contents left by handling. "Dead" skin cells known as corneocytes make up the majority of the cellular material left in touch deposits by people's hands but are known to lack nuclei, making their DNA content ambiguous. Here we measure DNA released from anucleate corneocytes following various lysis methods to determine how much DNA may be present in these cells and how best to recover it from inside the cornified envelope. We demonstrate that enhanced lysis methods using a reducing agent and longer incubation may be valuable for hand deposit samples. Corneocyte DNA can be characterized as highly degraded based on the quantification, STR profiling and fluorescence microscopy of the cells from freshly washed hands. Purification to target shorter DNA fragments is demonstrated. DNA from the washed corneocyte cells is shown to constitute the majority of recoverable DNA with these methods. We consider the use of new methods adapted to cornified cells and fragmented DNA for future research into this sample type.

Assessment of the Precision ID Identity Panel kit on challenging forensic samples.

The performance of the Precision ID Identity Panel (Thermo Fisher Scientific) was assessed on a set of 87 forensic samples with different levels of degradation for which a reference sample from the "same donor" or from a "first degree relative" was available. PCR-MPS analysis was performed with DNA input ranging from 1 ng to 12 pg and through 21-26 PCR cycles, in replicate tests, and a total number of 255 libraries were sequenced on the Ion Personal Genome Machine™ (PGM™) System. The evaluation of the molecular data allowed to set a fix threshold for locus call at 50 x which suitably worked even when low amounts of degraded DNA (12 pg) were investigated. In these analytical conditions, in fact, 25 PCR cycles allowed the genotyping of about 50 % and 35 % of the autosomal and the Y-specific markers on average, respectively, for each single amplification with a negligible frequency of drop ins (0.01 %). On the other hand, drop out artefacts reached 18-23 % when low copy number and degraded DNA samples were studied, with surviving alleles showing more than 600 reads in 2.9 % of the cases. Our data pointed out that the Precision ID Identity Panel allowed accurate typing of almost any amount of good quality/moderately degraded DNA samples, in duplicate tests. The analysis of low copy number DNAs evidenced that the same allele of a heterozygous genotype could be lost twice, thus suggesting that a third amplification could be useful for a correct genotype assignment in these peculiar cases. Using the consensus approach, a limited number of genotyping errors were computed and about 37 % of the autosomal markers was finally typed with a corresponding combined random match probability of at least 1.6 × 10-13, which can be considered an excellent result for this kind of challenging samples. In the end, the results presented in this study emphasize the crucial role of the expert opinion in the correct evaluation of artefacts arising from PCR-MPS technology that could potentially lead to genetic mistyping.

Effectiveness of whole genome amplification prior to short tandem repeat analysis for degraded DNA.

Short tandem repeat (STR) analysis is prone to failure as DNA is frequently damaged by various environmental factors; hence, increasing the number of starting templates may constitute a feasible approach to improve STR profiling success. Whole genome amplification (WGA) is often applied to bolster starting template quantity. Moreover, WGA can reportedly be used on degraded DNA samples in forensics. Therefore, we utilized a PCR-based WGA method, termed "modified improved primer extension preamplification" (mIPEP), prior to STR analysis of degraded DNA, as this method is less affected by DNA quantity and quality than most others. Saliva from four volunteers was dried on glass fiber filter papers (paper) and glass slides (glass) and irradiated with UVA light (365 nm). The mIPEP method was initiated using 5, 0.5, and 0.05 ng of DNA following DNA extraction. The DNA degradation index (DI) was calculated based on the ratio of 129 to 41 bp DNA fragments; lower numbers indicate higher degradation. Following mIPEP, STR analysis was performed using the AmpFlSTR Identifiler PCR amplification kit. The number of detectable STR loci, with and without mIPEP, decreased according to reduced DI in a different manner for the various DNA concentrations extracted from paper and glass. Specifically, for the 5 ng DNA sample on paper, at a DI < 0.2, the number of detectable STR loci was greater with mIPEP than without it, owing to fewer locus drop-outs. Similarly, the 0.05 ng DNA sample deposited on paper, at DI ≥ 0.7, exhibited higher numbers of detectable STR loci when prepared using mIPEP owing to fewer allele drop-outs. Moreover, among samples deposited on glass, the 0.05 ng DNA sample at DI ≥ 0.4 afforded a larger number of detectable STR loci when prepared using mIPEP than those without mIPEP, owing to fewer locus drop-outs. These findings suggest that performing mIPEP in accordance with sample DNA condition (e.g., quantity and quality) may lead to increased success of STR analysis. Notably, the conditions identified as most responsive to mIPEP were consistent across both UVA-irradiated and environmentally-damaged sample states. Taken together, our results suggest that applying mIPEP would be beneficial to obtain improved STR profiles under conditions involving severely degraded samples with large quantities of DNA, or with small quantities of DNA albeit with slight degradation.