Noninvasive determination of human cortisol and dehydroepiandrosterone sulfate using liquid chromatography-tandem mass spectrometry

Liquid chromatography-tandem mass spectrometry (LC-MS/MS) for measurements of steroids in human saliva has garnered increased interest in the area of clinical psychoneuroendocrinological research. However, performance characteristics of LC-MS/MS methods for the analysis of steroids in saliva are limited. Human saliva samples were collected via passive drool. Cortisol and dehydroepiandrosterone sulfate (DHEA-S) in the samples were extracted together, resolved on a C18-A column, and analyzed using tandem mass spectrometry. The LC-MS/MS method had limits of quantitation of 0.03 and 0.06 ng/mL for DHEA-S and cortisol, respectively. Method evaluations showed coefficient variation (%CV) of inter-assay ranging 4.6–17.9% for DHEA-S and cortisol, recoveries of 102.4–109.5% for DHEA-S and 94.6–98.3% for cortisol, and assay linearity with R² = 0.9964 for DHEA-S (1.0–25.0 ng/mL) and R² = 0.997 (1.0–25.0 ng/mL) for cortisol. No cross contamination among samples was observed. Human saliva showed 20% and 18% ion enhancement effect for DHEA-S and cortisol assay, respectively. No interference by ten common steroids was detected. Regression analysis of method comparisons with laboratory-developed test (LDT) method revealed R² = 0.9688 (LC-MS/MS = 0.9665 LDT-LC-MS/MS − 0.7355) for cortisol, and R² = 0.9039 (LC-MS/MS = 1.0173 LDT-LC-MS/MS + 3.6797) for DHEA-S. Reference ranges for young adults were determined to be 0.3–5.9 ng/mL for females and 0.1–5.6 ng/mL for males for salivary cortisol, and 0.6–7.4 ng/mL for females and 0.6–10.1 ng/mL for males for salivary DHEA-S. An LC-MS/MS method for quantifying cortisol and DHEA-S in human saliva was developed and validated for clinical and psychoneuroendocrinological research that require noninvasive means of measuring these hormones.

     

Temperature-gradient gel electrophoresis for the detection of polymorphic DNA and for quantitative polymerase chain reaction.

In order to detect mutations in a gene, either known mutations from human diseases or artificial ones in transgenic animals, or to screen for not yet identified mutations in patients, a method is required which guarantees detection of mutations which might occur in every single position of the whole open reading frame (ORF). It will be shown that a combination of polymerase chain reaction (PCR) and temperature gradient gel electrophoresis (TOGE) fulfills these requirements. By thermodynamic calculations the shift in the gel electrophoresis due to a mutation can be calculated in dependence on the position of the mutation. The theoretical results were tested with the mutations known so far. The quantitative determination of the copy number of a specific DNA or RNA sequence in a biological specimen (quantitative PCR) can be performed precisely and easily by combining PCR and TGGE. The system uses a quantification strategy of a new type of internal standardization. TGGE is applied to separate homo- and heteroduplexes which correspond respectively to standard and template sequences. The accuracy of this quantification strategy is very high, with a variability of < 15%. In addition to quantification, PCR/TGGE detects PCR artifacts and template mutants.     

Ueber die Bestimmung der Salpeters?ure bei Gegenwart von organischen Substanzen

Ohne Zusammenfassung     

Detection of point mutations by capillary electrophoresis with temporal temperature gradients.

By combining the advantages of capillary electrophoresis and temperature gradient gel electrophoresis, a method was developed to detect point mutations in polymerase chain reaction (PCR) fragments. Increasing and decreasing temporal temperature gradients were established by means of a computer-controlled Peltier module. Native and denaturing conditions were achieved by cooling to 25 degrees C and heating to 70 degrees C, respectively, a thermostating liquid surrounding the capillary. To separate nucleic acid fragments, a sieving media, containing 4% linear polyacrylamide, 1 x Tris borate EDTA buffer (TBE) and 6 M urea, was found appropriate. Renewal of the sieving matrix before each run significantly improved the reproducibility of fragment separation. The ability of this capillary electrophoresis system to detect point mutations is demonstrated with the human prion-protein gene.