Sage Journals: Discover world-class research

Abstract

Background:

Pre-analytical conditions are key factors in maintaining the high quality of biospecimens. They are necessary for accurate reproducibility of experiments in the field of biomarker discovery as well as achieving optimal specificity of laboratory tests for clinical diagnosis. In research at the National Biobank of Korea, we evaluated the impact of pre-analytical conditions on the stability of biobanked blood samples by measuring biochemical analytes commonly used in clinical laboratory tests.

Methods:

We measured 10 routine laboratory analytes in serum and plasma samples from healthy donors (n=50) with a chemistry autoanalyzer (Hitachi 7600-110). The analyte measurements were made at different time courses based on delay of blood fractionation, freezing delay of fractionated serum and plasma samples, and at different cycles (0, 1, 3, 6, 9) of freeze-thawing. Statistically significant changes from the reference sample mean were determined using the repeated-measures ANOVA and the significant change limit (SCL).

Results:

The serum levels of GGT and LDH were changed significantly depending on both the time interval between blood collection and fractionation and the time interval between fractionation and freezing of serum and plasma samples. The glucose level was most sensitive only to the elapsed time between blood collection and centrifugation for blood fractionation. Based on these findings, a simple formula (glucose decrease by 1.387 mg/dL per hour) was derived to estimate the length of time delay after blood collection. In addition, AST, BUN, GGT, and LDH showed sensitive responses to repeated freeze-thaw cycles of serum and plasma samples.

Conclusion:

These results suggest that GGT and LDH measurements can be used as quality control markers for certain pre-analytical conditions (eg, delayed processing or repeated freeze-thawing) of blood samples which are either directly used in the laboratory tests or stored for future research in the biobank.

Get full access to this article

View all access options for this article.

References

Anderson

, Anderson

. The human plasma proteome: History, character, and diagnostic prospects. Mol Cell Proteomics, 2002; 1:845–867.

Elliott

, Peakman

. The UK Biobank sample handling and storage protocol for the collection, processing and archiving of human blood and urine. Int J Epidemiol, 2008; 37:234–244.

Adkins

, Monroe

, Auberry

et al. A proteomic study of the HUPO Plasma Proteome Project's pilot samples using an accurate mass and time tag strategy. Proteomics, 2005; 5:3454–3466.

Anderson

, Anderson

, Pearson

et al. A human proteome detection and quantitation project. Mol Cell Proteomics, 2009; 8:883–886.

Chaigneau

, Cabioch

, Beaumont

et al. Serum biobank certification and the establishment of quality controls for biological fluids: Examples of serum biomarker stability after temperature variation. Clin Chem Lab Med, 2007; 45:1390–1395.

Thorpe

, Duan

, Forrest

et al. Effects of blood collection conditions on ovarian cancer serum markers. PLoS One, 2007; 2:e1281.

Reyna

, Traynor

, Hines

et al. Repeated freezing and thawing does not generally alter assay results for several commonly studied reproductive hormones. Fertil Steril, 2001; 76:823–825.

Peakman

, Elliott

. The UK Biobank sample handling and storage validation studies. Int J Epidemiol, 2008; 37:i2–6.

Lippi

, Guidi

, Mattiuzzi

et al. Preanalytical variability: The dark side of the moon in laboratory testing. Clin Chem Lab Med, 2006; 44:358–365.

10.

Carraro

, Plebani

. Errors in a stat laboratory: Types and frequencies 10 years later. Clin Chem, 2007; 53:1338–1342.

11.

Romero

, Munoz

, Ramos

et al. Identification of preanalytical mistakes in the stat section of the clinical laboratory. Clin Chem Lab Med, 2005; 43:974–975.

12.

Plebani

, Carraro

. Mistakes in a stat laboratory: Types and frequency. Clin Chem, 1997; 43:1348–1351.

13.

Sweep

, Fritsche

, Gion

et al. Considerations on development, validation, application, and quality control of immuno(metric) biomarker assays in clinical cancer research: An EORTC-NCI working group report. Int J Oncol, 2003; 23:1715–1726.

14.

Schrohl

, Wurtz

, Kohn

et al. Banking of biological fluids for studies of disease-associated protein biomarkers. Mol Cell Proteomics, 2008; 7:2061–2066.

15.

Clark

, Youngman

, Chukwurah

et al. Effect of temperature and light on the stability of fat-soluble vitamins in whole blood over several days: Implications for epidemiological studies. Int J Epidemiol, 2004; 33:518–525.

16.

Mejia

, Arroyave

. Determination of vitamin A in blood. Some practical considerations on the time of collection of the specimens and the stability of the vitamin. Am J Clin Nutr, 1983; 37:147–151.

17.

van Eijsden

, van der Wal

, Hornstra

et al.

Can whole-blood samples be stored over 24 hours without compromising stability of C-reactive protein, retinol, ferritin, folic acid, and fatty acids in epidemiologic research?

Clin Chem, 2005; 51:230–232.

18.

Holland

, Smith

, Eskenazi

et al. Biological sample collection and processing for molecular epidemiological studies. Mutat Res, 2003; 543:217–234.

19.

Mitchell

, Yasui

, Li

et al. Impact of freeze-thaw cycles and storage time on plasma samples used in mass spectrometry based biomarker discovery projects. Cancer Inform, 2005; 1:98–104.

20.

Boyanton

Jr. , Blick

. Stability studies of twenty-four analytes in human plasma and serum. Clin Chem, 2002; 48:2242–2247.

21.

Landt

. Glyceraldehyde preserves glucose concentrations in whole blood specimens. Clin Chem, 2000; 46:1144–1149.

22.

Marshall

, Kupchak

, Zhu

et al. Processing of serum proteins underlies the mass spectral fingerprinting of myocardial infarction. J Proteome Res, 2003; 2:361–372.

23.

Eisenberg

, Sherman

, Tiefenbrunn

et al. Sustained fibrinolysis after administration of t-PA despite its short half-life in the circulation. Thromb Haemost, 1987; 57:35–40.

24.

Drammeh

, Schleicher

, Pfeiffer

. Effects of delayed sample processing and freezing on serum concentrations of selected nutritional indicators. Clin Chem, 2008; 54:1883–1891.

25.

Dunn

, Broadhurst

, Ellis

et al. A GC-TOF-MS study of the stability of serum and urine metabolomes during the UK Biobank sample collection and preparation protocols. Int J Epidemiol, 2008; 37:i23–30.

26.

Bhatnagar

, Bogner

, Pikal

. Protein stability during freezing: Separation of stresses and mechanisms of protein stabilization. Pharm Dev Technol, 2007; 12:505–523.

27.

Dong

, Prestrelski

, Allison

et al. Infrared spectroscopic studies of lyophilization- and temperature-induced protein aggregation. J Pharm Sci, 1995; 84:415–424.

28.

Klibanov

, Schefiliti

. On the relationship between conformation and stability in solid pharmaceutical protein formulations. Biotechnol Lett, 2004; 26:1103–1106.

29.

Hsieh

, Zhuang

, Wu

et al. Profiling the proteome dynamics during the cell cycle of human hepatoma cells. Proteomics, 2008; 8:2872–2884.

30.

Reimers

, McCann

, Cowan

et al. Effects of storage, hemolysis, and freezing and thawing on concentrations of thyroxine, cortisol, and insulin in blood samples. Proc Soc Exp Biol Med, 1982; 170:509–516.

31.

DiMagno

, Corle

, O'Brien

et al. Effect of long-term freezer storage, thawing, and refreezing on selected constituents of serum. Mayo Clin Proc, 1989; 64:1226–1234.

32.

Bao

, Zuo

. Effect of repeated freeze-thaw cycles on urinary albumin-to-creatinine ratio. Scand J Clin Lab Invest, 2009; 69:886–888.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.07 MB

0.02 MB

0.03 MB

Identification of Clinical Biomarkers for Pre-Analytical Quality Control of Blood Samples