Strategy for effective inhibition of arylsulfatase/β-glucuronidase to prevent deconjugation of sulfate and glucuronide conjugates in wastewater during sample collection and storage

Protein profiling using SELDI-TOF-MS has gained over the past few years an increasing interest in the field of biomarker discovery. The technology presents great potential if some parameters, such as sample handling, SELDI settings, and data analysis, are strictly controlled. Practical considerations to set up a robust and sensitive strategy for biomarker discovery are presented. This paper also reviews biological fluids generally available including a description of their peculiar properties and the preanalytical challenges inherent to sample collection and storage. Finally, some new insights for biomarker identification and validation challenges are provided.

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Gamma-hydroxybutyric acid endogenous production and post-mortem behaviour – The importance of different biological matrices, cut-off reference values, sample collection and storage conditions

Journal of Forensic and Legal Medicine ◽

10.1016/j.jflm.2014.07.008 ◽

2014 ◽

Vol 27 ◽

pp. 17-24 ◽

Cited By ~ 30

Author(s):

André L. Castro ◽

Mário Dias ◽

Flávio Reis ◽

Helena M. Teixeira

Keyword(s):

Reference Values ◽

Storage Conditions ◽

Post Mortem ◽

Hydroxybutyric Acid ◽

Sample Collection ◽

Biological Matrices ◽

Endogenous Production ◽

And Storage

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Microbore high-performance liquid chromatographic method for the measurement of dopamine and its metabolites: recommendations for optimal sample collection and storage

Journal of Chromatography B Biomedical Sciences and Applications ◽

10.1016/0378-4347(94)80056-1 ◽

1994 ◽

Vol 660 (1) ◽

pp. 158-163 ◽

Cited By ~ 10

Author(s):

Adrian J. Carter

Keyword(s):

High Performance ◽

Chromatographic Method ◽

High Performance Liquid Chromatographic ◽

Sample Collection ◽

Optimal Sample ◽

Liquid Chromatographic Method ◽

Liquid Chromatographic ◽

And Storage

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Pre-analytical errors and patient safety / Preanalitičke greške i bezbednost pacijenata

Journal of Medical Biochemistry ◽

10.2478/v10011-012-0014-1 ◽

2012 ◽

Vol 31 (4) ◽

pp. 265-270 ◽

Cited By ~ 5

Author(s):

Mario Plebani

Keyword(s):

Information Technologies ◽

Clinical Laboratory ◽

Healthcare Personnel ◽

Laboratory Diagnostics ◽

Specimen Preparation ◽

Sample Collection ◽

Patient Preparation ◽

Analytical Phase ◽

And Storage ◽

Analytical Errors

Summary Laboratory medicine, as a specialty that had prioritised quality control, has always been at the forefront of error reduction. In the last decades, a dramatic decrease of analytical errors has been experienced, while a relatively high frequency of errors has been documented in the pre-analytical phase. Most pre-analytical errors, which account for up to 70% of all mistakes made in laboratory diagnostics, arise during patient preparation, and sample collection, transportation, preparation for analysis and storage. However, while it has been reported that the pre-analytical phase is error-prone, only recently has it been demonstrated that most of these errors occur in the »pre-pre-analytical phase«, which comprises the initial procedures of the testing process performed outside the laboratory walls by healthcare personnel outside the direct control of the clinical laboratory. Developments in automation and information technologies have played a major role in decreasing some pre-analytical errors and, in particular, the automation of repetitive, errorprone and bio-hazardous pre-analytical processes performed within the laboratory walls has effectively decreased errors in specimen preparation, centrifugation, aliquot preparation, pipetting and sorting. However, more efforts should be made to improve the appropriateness of test request, patient and sample identification procedures and other pre-analytical steps performed outside the laboratory walls.

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Variability in, variability out: best practice recommendations to standardize pre-analytical variables in the detection of circulating and tissue microRNAs

Clinical Chemistry and Laboratory Medicine (CCLM) ◽

10.1515/cclm-2016-0471 ◽

2017 ◽

Vol 55 (5) ◽

Cited By ~ 20

Author(s):

Jenna Khan ◽

Joshua A. Lieberman ◽

Christina M. Lockwood

Keyword(s):

Best Practice ◽

Rna Extraction ◽

Storage Conditions ◽

Sample Collection ◽

Ischemic Time ◽

Cold Ischemic Time ◽

C Storage ◽

Tissue Specimens ◽

And Storage

Abstract:microRNAs (miRNAs) hold promise as biomarkers for a variety of disease processes and for determining cell differentiation. These short RNA species are robust, survive harsh treatment and storage conditions and may be extracted from blood and tissue. Pre-analytical variables are critical confounders in the analysis of miRNAs: we elucidate these and identify best practices for minimizing sample variation in blood and tissue specimens. Pre-analytical variables addressed include patient-intrinsic variation, time and temperature from sample collection to storage or processing, processing methods, contamination by cells and blood components, RNA extraction method, normalization, and storage time/conditions. For circulating miRNAs, hemolysis and blood cell contamination significantly affect profiles; samples should be processed within 2 h of collection; ethylene diamine tetraacetic acid (EDTA) is preferred while heparin should be avoided; samples should be “double spun” or filtered; room temperature or 4 °C storage for up to 24 h is preferred; miRNAs are stable for at least 1 year at –20 °C or –80 °C. For tissue-based analysis, warm ischemic time should be <1 h; cold ischemic time (4 °C) <24 h; common fixative used for all specimens; formalin fix up to 72 h prior to processing; enrich for cells of interest; validate candidate biomarkers with in situ visualization. Most importantly, all specimen types should have standard and common workflows with careful documentation of relevant pre-analytical variables.

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Effect of sample storage temperature and buffer formulation on faecal immunochemical test haemoglobin measurements

Journal of Medical Screening ◽

10.1177/0969141316686808 ◽

2017 ◽

Vol 24 (4) ◽

pp. 176-181 ◽

Cited By ~ 8

Author(s):

Erin L Symonds ◽

Stephen R Cole ◽

Dawn Bastin ◽

Robert JL Fraser ◽

Graeme P Young

Keyword(s):

Room Temperature ◽

Storage Temperature ◽

Test Accuracy ◽

Sample Collection ◽

Storage Duration ◽

Initial Concentration ◽

Faecal Immunochemical Test ◽

Immunochemical Test ◽

New Formulation ◽

And Storage

Objectives Faecal immunochemical test accuracy may be adversely affected when samples are exposed to high temperatures. This study evaluated the effect of two sample collection buffer formulations (OC-Sensor, Eiken) and storage temperatures on faecal haemoglobin readings. Methods Faecal immunochemical test samples returned in a screening programme and with ≥10 µg Hb/g faeces in either the original or new formulation haemoglobin stabilizing buffer were stored in the freezer, refrigerator, or at room temperature (22℃–24℃), and reanalysed after 1–14 days. Samples in the new buffer were also reanalysed after storage at 35℃ and 50℃. Results were expressed as percentage of the initial concentration, and the number of days that levels were maintained to at least 80% was calculated. Results Haemoglobin concentrations were maintained above 80% of their initial concentration with both freezer and refrigerator storage, regardless of buffer formulation or storage duration. Stability at room temperature was significantly better in the new buffer, with haemoglobin remaining above 80% for 20 days compared with six days in the original buffer. Storage at 35℃ or 50℃ in the new buffer maintained haemoglobin above 80% for eight and two days, respectively. Conclusion The new formulation buffer has enhanced haemoglobin stabilizing properties when samples are exposed to temperatures greater than 22℃.

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