Endogenous GHB in Segmented Hair Part II: Intra-individual Variation for Exogenous Discrimination.

The endogenous presence of gamma-hydroxybutyric acid (GHB) complicates the interpretation of results in cases where an exogenous dosing is suspected. Due to GHB's rapid metabolism and clearance following exogenous doses, hair has become a preferential matrix for confirmation of GHB exposure in drug-facilitated crimes. However, unlike blood and urine where an agreed-upon cut-off concentration for differentiation between endogenous and exogenous GHB has been made, there has been no consensus on a cut-off concentration for hair. This is due in part to the wide inter- and intra-individual variation that has been observed in endogenous GHB hair studies. A large (>50) population study of 214 donors was conducted to better understand these variations and to evaluate whether a cut-off concentration could be established for endogenous GHB in human hair. As seen in our previous study, the inter-individual variation was large, with concentrations ranging from <0.40 to 5.47 ng/mg. This range made an absolute cut-off concentration recommendation inappropriate, so an alternative approach for GHB discrimination was investigated utilizing the intra-individual variation. Male donors appeared to have greater intra-individual variation than female donors, yet it was noted that segment-to-segment variation along the length of hair had minimal change between individual donor's adjacent segments. Overall, 97.1% of the adjacent segment differences were within ±0.5 ng/mg. Therefore, instead of a recommended cut-off concentration, it appears that using adjacent segment concentration differences could be a strategy to assist in differentiating endogenous from single exogenous GHB exposure. In the absence of controlled dosing data, previously published segmented results from controlled and suspected dosing donors are examined using the adjacent segmental difference approach and the results compared to currently used ratio-based calculations.

Endogenous GHB in Segmented Hair Part I: Inter-individual Variation for Group Comparisons.

While earlier studies have attempted to resolve the challenges encountered when interpreting gamma-hydroxybutyric acid (GHB) concentrations in hair (primarily due to its endogenous presence), few have had large sample sizes. The first objective of this study was to evaluate the inter-individual variation of endogenous GHB concentrations. The second objective, to be detailed in another report, was to assess intra-individual variation and the impact on exogenous GHB discrimination. Over 2,000 hair segments from 141 women and 73 men (all processed hair 3-12 cm long) were analyzed in this study. The raw calculated range of endogenous GHB concentrations was <0.40-5.47 ng/mg with 97.5% of the segmental results calculated less than 2.00 ng/mg. Imputation, assuming a lognormal distribution, was applied to the data to include non-detect (ND) data (

Evaluating Endogenous GHB Variation in Hair with a Synthetic Hair Matrix.

The variation in drug concentrations in human head hair from 22 donors was measured using a synthetic hair matrix (SMx™ hair). This matrix is being reported for the first time as a calibrator for an endogenous substance. In comparison to authentic hair or melanin, the synthetic hair provided a reliable batch-to-batch source of liquid matrix similar in composition to authentic hair, but without detectable concentrations of endogenous gamma-hydroxybutyric acid (GHB). Using the synthetic matrix for calibrator samples, validation of a liquid chromatography-tandem mass spectrometry (LC-MS/MS) quantitative method for GHB in human head hair was completed. Validation included the evaluation of the following parameters: accuracy, precision, calibration model, carryover, interferences, limit of detection (LOD), limit of quantitation (LOQ) and processed sample stability. The method was valid over a range of 0.4-12 ng/mg, and its LOD and LOQ were both experimentally estimated to be 0.4 ng/mg. After validation, the variation in endogenous GHB concentrations across multiple donors and locations in the vertex posterior region of the human head were evaluated. Results for 11 non-GHB users showed minimal variability (average 3.0% RSD) across the vertex posterior for hair samples taken from three different areas. There was also low variability (average 1.8% RSD) in repeat samples taken from the same location for 11 other non-users. Endogenous GHB concentrations from the LOD/LOQ to 5.60 ng/mg were determined for the 22 donors using the synthetic hair as a calibrator. These results demonstrate the successful application of a synthetic hair matrix in the analysis of GHB in human hair.

Development and validation of a solid phase extraction sample cleanup procedure for the recovery of trace levels of nitro-organic explosives in soil.

An improved cleanup method has been developed for the recovery of trace levels of 12 nitro-organic explosives in soil, which is important not only for the forensic community, but also has environmental implications. A wide variety of explosives or explosive-related compounds were evaluated, including nitramines, nitrate esters, nitroaromatics, and a nitroalkane. Fortified soil samples were extracted with acetone, processed via solid phase extraction (SPE), and then analyzed by gas chromatography with electron capture detection. The following three SPE sorbents in cartridge format were compared: Empore™ SDB-XC, Oasis® HLB, and Bond Elut NEXUS cartridges. The NEXUS cartridges provided the best overall recoveries for the 12 explosives in potting soil (average 48%) and the fastest processing times (<30min). It also rejected matrix components from spent motor oil on potting soil. The SPE method was validated by assessing limit of detection (LOD), processed sample stability, and interferences. All 12 compounds were detectable at 0.02µg explosive/gram of soil or lower in the three matrices tested (potting soil, sand, and loam) over three days. Seven explosives were stable up to seven days at 2µg/g and three were stable at 0.2µg/g, both in processed loam, which was the most challenging matrix. In the interference study, five interferences above the determined LOD for soil were detected in matrices collected across the United States and in purchased all-purpose sand, potting soil, and loam. This represented a 3.2% false positive rate for the 13 matrices processed by the screening method for interferences. The reported SPE cleanup method provides a fast and simple extraction process for separating organic explosives from matrix components, facilitating sample throughput and reducing instrument maintenance. In addition, a comparison study of the validated SPE method versus conventional syringe filtration was completed and highlighted the benefits of sample cleanup for removing matrix interferences, while also providing lower supply cost, order of magnitude lower LODs for most explosives, higher percent recoveries for complex matrices, and fewer instrument maintenance issues.