Clinical significance of a single cerebrospinal fluid immunoglobulin band: A retrospective study.

BACKGROUND: To demonstrate an inflammatory process in the central nervous system, the presence of at least two immunoglobulin (Ig) bands in the cerebrospinal fluid (CSF) is required. So far, the presence of a single abnormal Ig band is considered as negative. OBJECTIVE: The objective was to assess retrospectively the significance of a single CSF Ig band in clinical practice. METHODS AND RESULTS: Out of 10,286 CSF analyses, we retained 214 results with single Ig. An inflammatory neurological disorder was diagnosed in 41% of patients. CONCLUSION: Despite a modest sensitivity, the presence of a single CSF Ig band may be a biomarker of an inflammatory mechanism and, as such, may prompt the clinician to repeat the analysis when the clinical context remains suggestive.

[Long-term automated Bayesian management of IQC results: The experience of the Lyon Hospitals Board hemostasis laboratory]. / Déploiement d'une gestion automatisée au long cours des résultats de CIQ en approche bayésienne : retours d'expérience du Laboratoire d'hémostase aux Hospices Civils de Lyon.

The Lyon Hospitals Board (HCL) hemostasis laboratory has shifted from a frequentist to a long-term Bayesian approach to IQC results management, using the Hemohub® software of the Werfen corporation, which hosts the requisite Bayesian tools. IQC plans based on supplier specifications proved effective in managing analytic risk in line with the ISO 15189 standard. Long-term Hemohub® control and monitoring has been validated by acceptable feedback from the EQA organization used by the hemostasis community.

How to Obtain a High Quality ctDNA in Lymphoma Patients: Preanalytical Tips and Tricks.

The analysis of circulating tumor DNA (ctDNA) released by tumor cells holds great promise for patients with lymphoma, to refine the diagnostic procedure, clarify the prognosis, monitor the response to treatment, and detect relapses earlier. One of the main challenges of the coming years is to adapt techniques from highly specialized translational teams to routine laboratories as this requires a careful technical and clinical validation, and we have to achieve this as fast as possible to transform a promising biomarker into a routine analysis to have a direct consequence on patient care. Whatever the analytical technology used, the prerequisite is to obtain high yields of ctDNA of optimal quality. In this review, we propose a step-by-step description of the preanalytical process to obtain high-quality ctDNA, emphasizing the technical choices that need to be made and the experimental data that can support these choices.