Impact of storage temperature and time before analysis on electrolytes (Na+, K+, Ca2+), lactate, glucose, blood gases (pH, pO2, pCO2), tHb, O2Hb, COHb and MetHb results.

OBJECTIVES: The objective of our study is to evaluate the effect of storage temperature and time to analysis on arterial blood gas parameters in order to extend the CLSI recommendations. METHODS: Stability of 12 parameters (pH, pCO2, pO2, Na+, K+, Ca2+, glucose, lactate, hemoglobin, oxyhemoglobin, carboxyhemoglobin, methemoglobin) measured by GEM PREMIER™ 5000 blood gas analyzer was studied at room temperature and at +4 °C (52 patients). The storage times were 30, 45, 60, 90 and 120 min. Stability was evaluated on the difference from baseline, the difference from the analyte-specific measurement uncertainty applied to the baseline value, and the impact of the variation on the clinical interpretation. RESULTS: At room temperature, all parameters except the lactate remained stable for at least 60 min. A statistically significant difference was observed for pH at T45 and T60 and for pCO2 at T60 without modification of clinical interpretation. For lactate, clinical interpretation was modified from T45 and values were outside the range of acceptability defined by the measurement uncertainty. All parameters except pO2 remained stable for at least 120 min at +4 °C. CONCLUSIONS: A one-hour transport at room temperature is compatible with the performance of all the analyses studied except lactate. If the delay exceeds 30 min, the sample should be placed at +4 °C for lactate measurement. If the samples are stored in ice, it is important to note that the pO2 cannot be interpreted.

Ionized Magnesium: Interpretation and Interest in Atrial Fibrillation.

BACKGROUND: Magnesium (Mg) is often used to manage de novo atrial fibrillation (AF) in the emergency department (ED) and intensive care unit (ICU). Point of care measurement of ionized magnesium (iMg) allows a rapid identification of patients with impaired magnesium status, however, unlike ionized calcium, the interpretation of iMg is not entirely understood. Thus, we evaluated iMg reference values, correlation between iMg and plasmatic magnesium (pMg), and the impact of pH and albumin variations on iMg levels. Secondary objectives were to assess the incidence of hypomagnesemia in de novo AF. METHODS: A total of 236 emergency department and intensive care unit patients with de novo AF, and 198 control patients were included. Reference values were determined in the control population. Correlation and concordance between iMg and pMg were studied using calcium (ionized and plasmatic) as a control in the whole study population. The impact of albumin and pH was assessed in the discordant iMg and pMg values. Lastly, we assessed the incidence of ionized hypomagnesemia (hypoMg) among de novo AF. RESULTS: The reference range values established in our study for iMg were: 0.48-0.65 mmol/L (the manufacturers were: 0.45-0.60 mmol/L). A strong correlation was observed between pMg and iMg (r = 0.85), but, unlike for calcium values, there was no significant impact of pH and albumin in iMg/pMg interpretation. The incidence of hypoMg among de novo AF patients was 8.5% (12.7% using our ranges). When using our ranges, we found a significant link (p = 0.01) between hyopMg and hypokalemia. CONCLUSION: We highlight the need for more accurate reference range values of iMg. Furthermore, our results suggest that blood Mg content is not identical to that of calcium. The incidence of ionized hypomagnesemia among de novo AF patients in our study is 8.5%.

Blood Biomarkers for Return to Play after Concussion in Professional Rugby Players.

We prospectively evaluated a panel of seven blood biomarkers (S100 calcium-binding protein B [S100B], neuron specific enolase [NSE], spectrin breakdown products [SBDP], ubiquitin C-terminal hydrolase L1 [UCHL1], glial fibrillary acidic protein [GFAP], neurofilament light chain [NFL], and tubulin-associated unit [Tau]) for sport-related concussion (SRC) in a large multi-centric cohort of 496 professional rugby players from 14 French elite teams. Players were sampled twice during the season (beginning and end) away from any sport practice. From these two baseline samples, we evaluated the intra-individual variability to establish the effect of rugby on blood biomarkers over a season. Only S100B and GFAP remained stable over the course of a season. During the period of the study, a total of 45 SRC cases was reported for 42 players. In 45 SRCs, the head injury assessment (HIA) process was performed and blood collection was realized 36 h after the concussion (HIA-3 stage). For each biomarker, raw concentrations measured 36 h after SRC were not significantly different between players with a non-resolutive SRC (n = 28) and those with a resolutive SRC (n = 17; p between 0.06 and 0.92). In a second step, blood concentrations measured 36 h after SRC were expressed according to the basal concentrations as an individual percentage change (PCH36[%]), calculated as follows: PCH36 = 100 × (([Biomarker]36h - [Biomarker]basal)/[Biomarker]basal). S100B and NFL concentrations expressed as PCH36[%] were significantly different between non-resolutive and resolutive SRCs (p = 0.006 and 0.01 respectively), with a positive delta found in non-resolutive SRCs. Among the two biomarkers, it is important to note that only the S100B protein was stable during the season. In the context of our study, during HIA-3 assessment, S100B seems to perform better than NSE, SBDP, UCHL1, GFAP, NFL, and Tau as biomarker for SRC. From a clinical standpoint, the S100B modification over baseline may be valuable, at 36 h after concussion to distinguish non-resolutive SRC from resolutive SRC.

Association between proteinuria trajectories and outcomes in critically ill patients with sepsis or shock.

BACKGROUND: Proteinuria results from kidney damage and can be a predictor of illness severity and mortality in the intensive care unit (ICU). However, the optimal timing of proteinuria measurements and the reference values remain undetermined. Our objective was to identify the patterns of proteinuria change associated with mortality in ICU patients with sepsis or shock. METHODS: This monocentric retrospective cohort study performed from April 2010 to April 2018 involved all ICU patients with sepsis or shock and at least two measurements of proteinuria from a 24h-urine collection during the first 10 days of ICU stay, the first of which was made within 48h after ICU admission. We identified proteinuria trajectories by a semi-parametric mixture model and analysed the association between the trajectories and the mortality at day 28 by Cox proportional-hazards model. RESULTS: A total of 3,344 measurements of proteinuria from 659 patients were analysed. Four proteinuria trajectories were identified. Trajectories 1, 2, 3 and 4 comprised 127, 421, 60 and 51 patients, and were characterized by a first proteinuria of 1.14 [0.66-1.55], 0.52 [0.26-0.91], 2.92 [2.38-3.84] and 2.58 [1.75-3.32] g/24h (p<0.001) and a mortality of 24.4%, 38%, 20% and 43% (p = 0.002), respectively. Trajectories 3 and 4 had a high first proteinuria (>2g/24h). Only, the proteinuria of trajectory 4 increased within 3 days following the first measurement and was associated with increased mortality at day 28 (hazard ratio: 2.36 95%CI [1.07-5.19], p = 0.03), regardless of acute renal failure. The factors associated with trajectory 4 were cancer (relative risk: 8.91 95%CI [2.09-38.02], p = 0.003) and use of inotropic drugs (relative risk: 0.17 95%CI [0.04-0.69], p = 0.01). CONCLUSION: This exploratory study of ICU patients with sepsis or shock identified four proteinuria trajectories with distinct patterns of proteinuria change over time and mortality rates. These results provide novel insights into renal pathophysiology and may be helpful to investigate subphenotypes of kidney injury among ICU patients in future studies.

[Pre-analytical phase impact in the differences in natremia obtained by direct and indirect ion selective electrodes methods]. / Impact de la phase pré-analytique dans les différences de natrémies obtenues par techniques potentiométriques directe et indirecte.

Natremia is an important biological parameter providing information on the hydration state of patient's intracellular sector. Its measurement can be carried out either by multiparametric laboratory analyser (indirect potentiometry) or delocalized biology analyser (direct potentiometry). The main problem is that for a same patient, these two analysers can give quite different results, hence inducing interpretation problems for clinician. Two one-week study periods comparing the variations in blood sodium levels produced by these automatic analysers were carried out in two intensive care units of Clermont-Ferrand University Hospital. During the second study period, a protocol for collecting blood samples was applied in order to improve the pre-analytical conditions. Between the two weeks of studies, the median of the differences in natremia was significantly reduced, going from 4 mmol/L to 2 mmol/L (p < 0.001), as was the proportion of patients with large differences in sodium levels (strictly higher than 3 mmol/L) going from 51% to 24.8% (p < 0.001). The patients still presenting large variations in sodium had a median of proteins significantly lower than patients with deviations less than or equal to 3 mmol/L: 58.1 g/L against 62.25 g/L respectively (p < 0.001) leading to pseudo-hypernatremia (indirect potentiometry). Despite a significant reduction in differences linked to the application of good preanalytical practices, some patients nonetheless presented a major difference in natremia due to the difference of technique (variations in the lipidoprotein phase of the plasma of intensive care patients) and to the measurement uncertainties.

[Remethylation disorders: about two cases]. / Troubles de la reméthylation : à propos de deux cas.

In order to propose a course of action to be taken in the face of any hyperhomocysteinemia, we have reported for the first time in a French journal the recommendations made within the framework of the European E-HOD project for the diagnosis and treatment of remethylation disorders. The remethylation route ensures homocysteine-methionine conversion. It is linked to the folate cycle and the intracellular metabolism of cobalamins. Remethylation disorders can be classified into three groups: 1) isolated disorders (cblD-HC, cblE, cblG) corresponding to an isolated deficit in the production of methylcobalamin, cofactor of methionine synthase; 2) combined disorders (cblC, cblD-MMA/HC, cblF, cblJ) corresponding to an alteration of the transport and intracellular metabolism of cobalamins, which causes a defect in the synthesis of the two functional forms of cobalamin: methylcobalamin and adenosylcobalamin, a cofactor for methyl malonylCoA mutase; 3) MTHFR deficit, an abnormality of the folate cycle. The biological anomalies observed are hyperhomocysteinemia and hypomethioninaemia associated in the case of disorders combined with increased urinary excretion of methylmalonic acid. The clinical presentation is however heterogeneous according to the remethylation disorder but also for the same pathology according to the age. Given the large number of pathologies grouped together in remethylation disorders, this point is illustrated by only two clinical cases concerning the same deficit (deficit in MTHFR) but with different discovery circumstances: a neonatal form and a late form.

Interest of blood biomarkers to predict lesions in medical imaging in the context of mild traumatic brain injury.

Mild traumatic brain injury (mTBI) is one of the common causes of emergency department visits around the world. Up to 90% of injuries are classified as mTBI. Cranial computed tomography (CCT) is a standard diagnostic tool for adults with mTBI. Alternatively, children can be admitted for inpatient observation with CCT scans performed only on those with clinical deterioration. The use of blood biomarkers is a supplementary tool for identifying patients at risk of intracerebral lesions who may need imaging. This review provides a contemporary clinical and laboratory framework for blood biomarker testing in mTBI management. The S100B protein is used routinely in the management of mTBI in Europe together with clinical guidelines. Due to its excellent negative predictive value, S100B protein is an alternative choice to CCT scanning for mTBI management under considered, consensual and pragmatic use. In this review, we propose points to help clinicians and clinical pathologists use serum S100B protein in the clinical routine. A review of the literature on the different biomarkers (GFAP, UCH-L1, NF [H or L], tau, H-FABP, SNTF, NSE, miRNAs, MBP, ß trace protein) is also conducted. Some of these other blood biomarkers, used alone (GFAP, UCH-L1) or in combination (GFAP + H-FABP ± S100B ± IL10) can improve the specificity of S100B.

[Transient hyperprolactinemia secondary to benzodiazepines: a case report]. / Hyperprolactinémie transitoire secondaire aux benzodiazépines : à propos d'un cas.

Hyperprolactinemia is common and accounts for 20 to 25% of secondary amenorrhea causes. Here, we report a case of moderate hyperprolactinemia observed in a 40-year-old patient consulting for spaniomenorrhea and inguinal pain during a bartholinitis episode. After eliminating all known causes of hyperprolactinemia, alprazolam intake is finally assumed. This hyperprolactinemia is found in a few bibliographic studies and is also noted in the summary of product characteristics. However, benzodiazepines are not known as hyperprolactinemia-inducing drugs by the endocrinologists and do not appear in the list of drugs established by a consensus of experts from the French Society of Endocrinology. This article aims to increase awareness of prescribing physicians and biologists of the possible occurrence of hyperprolactinemia in patients treated by benzodiazepines, especially since the intake of this molecule is particularly common in France, whether it is a medical prescription or self-medication.

Inherited Metabolic Diseases and Cardiac Pathology in Adults: Diagnosis and Prevalence in a CardioMetabo Study.

Many inherited metabolic diseases (IMD) have cardiac manifestations. The aim of this study was to estimate the prevalence of IMD in adult patients with hypertrophic cardiomyopathy (HCM) and cardiac rhythm abnormalities that require cardiac implantable electronic devices (CIEDs). The study included a review of the medical files of patients aged 18 to 65 years who were followed in our cardiology department during the period 2010-2017. Metabolic explorations for Fabry disease (FD), mitochondrial cytopathies, and fatty-acid metabolism disorders were carried out in patients with unexplained etiology. The prevalence of IMD in patients with HCM was 5.6% (confidence interval (CI): 2.6-11.6). Six cases of IMD were identified: 1 mitochondrial encephalopathy with lactic acidosis and stroke-like episodes (MELAS) syndrome, 1 Hurler syndrome, 2 Friedreich's ataxia, 1 FD, and 1 short-chain acyl-CoA dehydrogenase deficiency. Three cases of IMD were identified in patients requiring CIEDs: 1 patient with Leber hereditary optic neuropathy, 1 FD, and 1 short chain acyl-CoA dehydrogenase (SCAD) deficiency. IMD prevalence in patients with CIEDs was 3.1% (CI: 1.1-8.8). IMD evaluation should be performed in unexplained HCM and cardiac rhythm abnormalities adult patients, since the prevalence of IMD is relatively important and they could benefit from specific treatment and family diagnosis.

[Analytical validation of 13 biochemistry parameters (CEA, CA 19-9, amylase, lipase, sodium, potassium, chloride, creatinine, glucose, protein, albumin, LDH, triglycerides) in body fluids]. / Validation de méthodes des dosages de 13 paramètres biochimiques (ACE, CA 19-9, amylase, lipase, sodium, potassium, chlorure, créatinine, glucose, protéines, albumine, LDH, triglycérides) dans un panel de liquides biologiques.

The measurement performance of 13 biochemistry parameters (CEA, CA 19-9, amylase, lipase, sodium, potassium, chloride, creatinine, glucose, protein, albumin, LDH, triglycerides) was tested in a panel of biological fluids other than blood and urine (peritoneal, pleural, pancreatic fluids ...). Our protocol, based on a risk analysis, allowed us to justify our choices and compare the performance obtained with those of the serum or plasma matrix already validated. Thus, the coefficients of variation obtained in body fluids are comparable. The assessment of accuracy (spiking and dilution tests) shows the absence of bias, which is consistent with the absence of matrix effect. The linearity studied by dilution tests shows that the upper limits of the measurement interval communicated by the supplier are applicable to body fluids. The absence of contamination and stability have been also confirmed. All analytes are stable for 3 days at room temperature, 7 days between 2 and 8̊C, and 6 months at -20̊C; except LDH and lipase. For most analytes, at least one interference (hemolysis, icterus, lipemia) was found. Finally, a bibliographical study, confronted with the experience of prescribers, led us to define optimal thresholds to help interpret patients' results. In conclusion, this work has allowed us to validate analytical methods for body fluids testing after relying on their comparability to the blood matrix. We have also been able to adapt our practices and finally be accredited according to the standard NF IN ISO 15189.

Measurement of S100B protein: evaluation of a new prototype on a bioMérieux Vidas® 3 analyzer.

Background The addition of S100B protein to guidelines for the management of mild traumatic brain injury (mTBI) decreases the amount of unnecessary computed tomography (CT) scans with a significant decrease in radiation exposure and an increase in cost savings. Both DiaSorin and Roche Diagnostics have developed automated assays for S100B determination. Recently, bioMérieux developed a prototype immunoassay for serum S100B determination. For the first time, we present the evaluation of the S100B measurement using a bioMérieux Vidas® 3 analyzer. Methods We evaluated the matrix effects of serum and plasma, and their stability after storage at 2-8 °C, -20 °C and -80 °C. The new measurement prototype (bioMérieux) was compared with an established one (Roche Diagnostics), and a precision study was also conducted. Lastly, clinical diagnostics performance of the bioMérieux and Roche Diagnostics methods were compared for 80 patients referred to the Emergency Department for mTBI. Results Stability after storage at 2-8 °C, -20 °C, and -80 °C and validation of the serum matrix were demonstrated. The bioMérieux analyzer was compared to the Roche Diagnostics system, and the analytical precision was found to be efficient. Clinical diagnosis performance evaluation confirmed the predictive negative value of S100B in the management of mTBI. Conclusions The study's data are useful for interpreting serum S100B results on a bioMérieux Vidas® 3 analyzer.