The current LC-MS based desmosine/isodesmosine (DES/IDS) assays may be unsatisfactory for clinical use due to lack of an appropriate internal standard or low throughput. A fast and reliable LC-MS method using a D(5)-DES as an internal standard for measuring urinary total DES/IDS was developed and validated in this study. The reportable range of this assay was 1.0 and 480.0 ng/mL. The intra- and interassay imprecision, accuracy, and recovery for quality control samples were within acceptable range (<25%). Urinary total DES/IDS level was stable at room temperature or 4 degrees C for 20 h, and for three freeze/thaw cycles. The assay was employed to measure urine samples from COPD patients and demographically matched healthy volunteers. The total urinary DES/IDS levels were approximately 3-fold higher in COPD patients compared to healthy volunteers. The suitability of using urinary free DES to estimate elastin degradation was also evaluated in a second cohort. Despite urinary free and total DES/IDS levels being highly correlated, our data suggest that urinary total DES/IDS level is a preferred biomarker for elastin degradation. These results demonstrate that the LC-MS/MS method provides sensitive, reproducible and accurate quantification of urinary total DES/IDS as a biomarker for monitoring elastin degradation in diseases such as COPD.
Quantitation of urinary tetranor PGDM or tetranor PGEM (tPGDM and tPGEM) in the past was performed separately using off-line SPE LC-MS/MS methods. The manual SPE procedure is generally time-consuming and cost-ineffective. In addition, simultaneous quantitation of tPGDM and tPGEM is favorable yet very challenging because of the similar chemical structures and identical MRM transitions. This work describes the development and validation of a high-throughput online SPE-LC-MS/MS method, allowing simultaneous and high-throughput measurement of tPGDM and tPGEM in human urine. The reportable range of the assay was 0.2-40 ng/ml for tPGDM and 0.5-100 ng/ml for tPGEM. Intra- and inter-assay precision and accuracy determined using quality control samples were all within acceptable ranges (% CV and % Bias < 15%). Tetranor PGDM was stable under all tested conditions while tPGEM was stable at 4 °C and after three F/T cycles but not stable at room temperature for 24 h (recovery below 80%). The assay was applied to measure urinary tPGDM and tPGEM among healthy volunteers, smokers and COPD patients. Significantly higher urinary levels of both tPGDM and tPGEM were observed in COPD patients than those of non-smoking healthy volunteers. These results demonstrated that the high-throughput online SPE-LC-MS/MS assay provides sensitive, reproducible and accurate measurement of urinary tPGDM and tPGEM as biomarkers for assessing inflammatory diseases such as COPD.
Several arachidonic acid metabolites and enzyme transcripts involving both lipoxygenase and cyclooxygenase pathways are increased in smokers with asthma and differ from never smokers with asthma. Possibly targeting specific lipoxygenase and cyclooxygenase pathways that are activated by asthma and cigarette smoking may optimize therapeutic responses.
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