Feedback from the Science Café roundtables at the ninth European Bioanalysis Forum Young Scientist Symposium: optimizing the work-life balance in a bioanalytical laboratory.

As part of the European Bioanalysis Forum's continued commitment to develop young scientists beyond their scientific skills, we also focus on soft skills and a community responsibility during the Young Scientist Symposia, with the Science Café. In previous years, we have focused on topics such as sustainability (green lab) or the impact of the COVID-19 pandemic on career development. At the ninth Young Scientist Symposium, the Science Café roundtables focused on the work-life balance and how caring for it can be beneficial for both the individual and the company. Feedback from a premeeting survey and from the discussions during the roundtables can be an important addition to personal and professional development. If organizations are not already focusing on the importance of a healthy work-life balance, they can be inspired to include some aspects of the outcome of the Science Café discussions when developing their staff toward future (scientific) leadership.

Is the stability of folates in dried blood microsamples sufficient to perform home-sampling studies?

Dried blood microsampling is increasingly used for home-sampling and epidemiological studies because of its multiple advantages, including an often greatly improved analyte stability. However, a critical assessment of the stability under realistic conditions should always be performed as part of the validation, especially for unstable molecules like folates (vitamin B9). Here, the objective was to determine whether folate stability in dried blood microsamples is sufficient to allow the set-up of home-sampling studies for the monitoring of folate status in e.g., women of reproductive age. An extensive set of stability experiments was performed to evaluate the stability of the main folate vitamer 5-methyltetrahydrofolate (5MTHF), its oxidation product MeFOX and the minor non-methyl folate vitamers 10-formylfolic acid (10FoFA), 5,10-methenyltetrahydrofolate (5,10CH+THF) and tetrahydrofolate (THF) in dried blood microsamples using volumetric absorptive microsampling (VAMS) or regular dried blood spots (DBS). The evaluations included (EDTA-anticoagulated blood was collected from a single donor measured in four replicates per condition and time point): (i) the effect of temperature (-20 °C, 4 °C, ambient temperature and 37 °C), (ii) the effect of light (during drying and storage) and humidity, and (iii) the effect of storage under vacuum and pretreatment of the microsamples with stabilizing agents on folate stability. At -20 °C and 4 °C, all folate levels were within 85 to 115% of the baseline value up till two weeks of storage in both VAMS samples and DBS. However, at room temperature the stability of the analyzed folates was only consistently observed up till three days in VAMS samples, and for none of the folates at 37 °C. Humidity had a major impact on 5,10CH+THF stability, but this could be easily improved by using desiccant. Both vacuum treatment and pretreatment of microsamples with 0.1% DL-dithiothreitol and 5% butylated hydroxytoluene improved the stability at room temperature in VAMS samples, but these effects were limited at 37 °C and in DBS. Overall, the stability of the individual folate vitamers proved to be challenging and strongly temperature- and time-dependent. Nonetheless, if controlled transport (temperature and duration) can be assured, the set-up of home-sampling studies to evaluate the folate status using dried blood microsamples can still be beneficial.

Application of non-contact hematocrit prediction technologies to overcome hematocrit effects on immunosuppressant quantification from dried blood spots.

Fully automated dried blood spot (DBS) analysis for therapeutic drug monitoring (TDM) of the immunosuppressants tacrolimus, sirolimus, everolimus and cyclosporin A suffers from a so-called hematocrit (hct) effect. This effect is related to the analysis of a partial DBS punch and extractability differences imposed by blood with different hcts. As this is intrinsic to automated DBS analysis, this poses a serious drawback for accurate immunosuppressant quantification. Knowledge of a sample's hct allows to correct the derived immunosuppressant concentrations for this effect. Unfortunately, when using the DBS approach for sampling at patients' homes, this hct will typically not be available. The aim of this study was to investigate the validity of a correction algorithm during fully automated DBS analysis of immunosuppressants, based on knowledge of the DBS' hct, obtained via two distinct non-contact hematocrit prediction strategies, using either near-infrared (NIR) or ultra-violet/visible (UV/VIS) spectroscopy. For tacrolimus, sirolimus, everolimus, and cyclosporin A, 48, 47, 58 and 48 paired venous whole blood and venous DBS patient samples were collected, respectively, and analyzed using an automated DBS-MS 500 HCT extraction unit coupled to a liquid chromatography tandem mass spectrometry system. Additionally, for all 201 samples the hct of the DBS was predicted based on NIR and UV/VIS spectroscopy. For tacrolimus and cyclosporin A, both hct prediction strategies allowed for adequate correction of the hct effect. Also for sirolimus and everolimus the results greatly improved after hct correction, although a hct bias remained for sirolimus and for everolimus a slightly significant hct effect was observed after NIR- and UV/VIS-based correction. Application of both hct prediction strategies ensured that clinical acceptance limits (i.e. ≥ 80% of the samples within 20% difference compared to whole blood) were met for all analytes. In conclusion, we demonstrated that non-contact hct prediction strategies, applied in tandem with fully automated DBS analysis, can be used to adequately correct immunosuppressant concentrations, yielding a good agreement with whole blood.

In-depth evaluation of automated non-contact reflectance-based hematocrit prediction of dried blood spots.

Dried blood spot(s) (DBS) microsampling has increasingly attracted interest as a patient-centric alternative to conventional blood withdrawal. Despite the many advantages associated with DBS sampling, its widespread use in clinical practice is still hampered, which is mainly caused by the hematocrit (Hct) effect. One approach to cope with this issue is the Hct prediction of DBS using ultraviolet-visible (UV-Vis) spectroscopy. Recently, a UV-Vis-based Hct prediction module has been incorporated into the automated CAMAG® DBS-MS 500 HCT system. However, although a proof-of-principle yielded promising results, there is no formal in-depth evaluation of the performance of this module. Hence, it remained to be established to what extent automated Hct prediction of DBS via this module can universally be applied and generates acceptable results. Using authentic patient samples, we set up and validated a calibration model and evaluated whether this could serve as a 'generic' calibration model for different, independent Hct prediction modules. A quadratic calibration curve with 1/x2 weighting was established. The bias, intra-day and total precision were below 0.025 L L-1, 2.2% and 2.7%, respectively. Additionally, the influence of storage and the robustness of the method was evaluated. Moreover, a lab-lab comparison of the performance of the Hct module of two independently operated instruments demonstrated that the validated model can be used as a generic calibration model. Finally, application of the method to venous DBS (n = 48) prepared from patient samples in the context of therapeutic drug monitoring of tacrolimus revealed a good concordance between the actual (i.e. Sysmex-based) and UV-Vis-based predicted Hct.

Set-up of a population-based model to verify alcohol abstinence via monitoring of the direct alcohol marker phosphatidylethanol 16:0/18:1.

BACKGROUND AND AIMS: Phosphatidylethanol 16:0/18:1 (PEth) is a biomarker for alcohol intake. It has a half-life of 7.9 days. Chronic alcohol consumption causes high PEth values. It can take weeks before PEth values fall below the decision limit for 'alcohol abstinence'. Our aim was to validate whether alcohol abstinence can be determined based on two consecutive PEth results above the decision limit. DESIGN: Observational study. SETTING: Belgium, February 2019. The study was linked to a social initiative in Belgium, 'Tournée Minérale'. PARTICIPANTS: Adults (aged > 18 years, n = 796) with varying drinking habits who self-reportedly refrained from alcohol consumption during the study. MEASUREMENTS: A validated liquid chromatography-tandem mass spectrometry method was used to quantify PEth in participants' dried blood samples, collected at three time-points via remote fingerprick-based self-sampling. FINDINGS: A population-based algorithm to evaluate abstinence based on 95% prediction limits was developed by fitting a linear mixed-effect model to discern patterns in PEth elimination over time. It took intra- and inter-individual variability into consideration. The algorithm was included in a two-step decision tree, assessing whether (i) PEth values fell within the prediction interval and (ii) the slope between two PEth values was consistent with no alcohol consumption. Data for 74 participants reporting no alcohol intake during the study were used for validation. With a detection limit of 'four units spread over 14 days', the sensitivity and specificity of the decision tree was 89%. CONCLUSIONS: Claims of alcohol abstinence can be verified using a two-step decision tree for phosphatidylethanol 16:0/18:1 values, even when those values are above the limit for 'alcohol abstinence'.

Feedback from the 8th European Bioanalysis Forum Young Scientist Symposium.

After 2 years of COVID-19 restrictions, the 8th Young Scientist Symposium was organized again as a face-to-face meeting covering a broad array of scientific presentations. As in the previous editions, the meeting was organized by young scientists for young scientists under the umbrella of the European Bioanalysis Forum and in collaboration with academia. The traditional Science Café was again included as an interactive round table session. This year, the main focus was on the challenges of communication. New for the 8th edition was a session connecting the young scientists with more seasoned experts in an effort to bridge talent and experience. In this article, we share the feedback of the scientific sessions and the Science Café held at the symposium.

Near-infrared-based hematocrit prediction of dried blood spots: An in-depth evaluation.

BACKGROUND: Dried blood spot (DBS) microsampling has gained interest in different clinical fields, owing to its many advantages compared to conventional blood sampling. However, whilst being applied for decades for screening purposes, some challenges, such as the hematocrit (Hct) effect, hinder further widespread use of DBS for quantitative purposes in clinical practice. Amongst the approaches that were developed to cope with this issue, is the Hct prediction of DBS using near-infrared (NIR) spectroscopy. METHODS: Using left-over EDTA-anticoagulated patient samples, the accuracy and precision, stability, and robustness were assessed. Furthermore, applicability of the method on capillary DBS was evaluated via finger prick samples. RESULTS: A maximal bias, respectively CV, of 0.012 L/L and 4.5% were obtained. The method was robust towards several aspects, including storage (except for storage at 60°C), measurement location, type of filter paper and spotted volume. Furthermore, the potential to predict the Hct of capillary DBS was demonstrated. CONCLUSION: A commercially available NIR set-up was extensively and successfully validated, allowing non-contact Hct prediction of DBS with excellent accuracy and precision. This allows to correct for the Hct-based bias observed in partial-punch DBS analysis and the set-up of blood-plasma conversion factors, increasing the application potential of patient-centric sampling.

Feedback from the Science Café at the 7th European Bioanalysis Forum Young Scientist Symposium.

The 7th Young Scientist Symposium, a meeting again organized as a hybrid online event by young scientists for young scientists under the umbrella of the European Bioanalysis Forum and in collaboration with the Universities of Bologna and Ghent, included a variety of interesting presentations on cutting-edge bioanalytical science and processes. On the morning of day 2, the meeting hosted their traditional Science Café around the theme: 'How has COVID-19 changed our future?' in which the Young Scientist Symposium organizing committee engaged with the delegates on how the COVID-19 pandemic has impacted the careers of young scientists working in a bioanalytical (industry or academic) laboratory, that is, things they lost, for good or for bad - things they gained, wanted or unwanted, things they learned about themselves and their industry. This manuscript provides feedback from those discussions.