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Centrifugation is a routine process in a clinical chemistry laboratory where blood specimens collected into anticoagulant containers are centrifuged to separate the plasma from the blood cells. This is done at various speeds, times and temperature which most times affect the quality of samples mainly due to haemolysis. World Health Organisation guidelines advocate for a maximum duration of 15 minutes as the centrifugation duration for separation of plasma. Various laboratories in this region adopt various speeds and duration for separation of blood samples without minding any possible effect it may have on the value of certain common analytes. This study was therefore designed to study the effect of different centrifugation speeds and duration (within the scope of the WHO centrifugation time guidelines) on the value of commonly measured analytes like sodium, potassium, chloride and bicarbonate. A cross-sectional study where blood was taken from 30 apparently healthy undergraduate volunteers after dividing the group into A and B of 15 subjects each. From the A group, blood specimens from each subject was separated based on the different centrifugation speeds and from the B group, blood specimens from each subject was separated based on different centrifugation times. The different samples from each subject were analysed for sodium, potassium, chloride and bicarbonate and this was done for all subjects. The mean values of all the analytes were about the same for the 1000 Revolutions per Minutes (RPM), 2000 RPM, 3000 RPM and 4000 RPM and so were the mean values of all the samples labelled 3 minutes, 6 minutes, 9 minutes, 12 minutes and 15 minutes. The differences in the means of the subgroups for group A and group B were statistically not significant. From this study, it can be advocated that plasma can be separated from whole blood samples at a maximum speed of 4000 RPM for 3 minutes duration without affecting the accuracy of most analytes and the introduction of this speed and duration will improve the quality assurance of laboratories in this region.

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References

  1. Mark Frei. Centrifugation Separations. Bio Files ;6 (5): 6–7
     Google Scholar
  2. WHO: Use of anticoagulants in diagnostic laboratory investigations. WHO/DIL/LAB/99.1/Rev 2. 2002
     Google Scholar
  3. A. Marcia Blood Sample Processing: Clinical Perspectives on Recent Developments in Technology and Laboratory Operations. Laboratory Medicine 2012;43(1): 7–10
    DOI  |   Google Scholar
  4. F. L. Kiechle., F. Betson., J. Blackeney, R. R. Calam, I. M. Catalasan, P. S. Raj, et al. Procedures for the handling and processing of blood specimens; approved guideline. Wayne USA fourth Edition: CLSI; 2010, HA18-A4-A3. CLSI Guidelines; 30 (10):0273-30990
     Google Scholar
  5. L. Heireman, P. Van Geel, L. Musger, E. Heylen, W. Uyttenbroeck, B. Mahieu Causes, consequences and management of sample hemolysis in the clinical laboratory. Clin Biochem 2017; 50(18):1317-1322.
    DOI  |   Google Scholar
  6. E. L. Minder, A. Schibli, D. Mahrer, P. Nesic, K. Plüer. Effects of different centrifugation conditions on clinical chemistry and Immunology test results. BMC Clin Pathol 2011( 11) 6 https://doi.org/10.1186/1472-6890-11-6
    DOI  |   Google Scholar
  7. J. Cadamuro, C. Mrazek, A. B. Leichtle. Influence of centrifugation conditions on the results of 77 routine clinical chemistry analytes using standard vacuum blood collection tubes and the new BD-Barricor tubes. Biochem Med (Zagreb). 2018;28(1):010704. doi:10.11613/BM.2018.010704
    DOI  |   Google Scholar
  8. J. H. Howanitz, P. J. Howanitz. Laboratory results. Timeliness as a quality attribute and strategy. Am J Clin Pathol 2001; 116:311–315
    DOI  |   Google Scholar
  9. S. R. Mikkelsen, E. Cortón. Bioanalytical Chemistry, Ch. 13. Centrifugation Methods. John Wiley & Sons 2004; 4 : 247-267
    DOI  |   Google Scholar
  10. S. J. Steindel, P. J. Howanitz. Physician satisfaction and emergency department laboratory test turnaround time. Arch Pathol Lab Med 2001; 125:863–871
    DOI  |   Google Scholar