Effects of Long Distance Transportation of Specimens on Test Results.
- Author:
Hwan Sub LIM
1
;
You Kyung LEE
;
Won Ki MIN
Author Information
- Publication Type:Original Article
- Keywords: Specimen delivery; Container; Hemolysis
- MeSH: Alanine; Blood Cell Count; Blood Sedimentation; Creatinine; Dietary Sucrose; Electrolytes; Fibrinogen; Glucose; Hematology; Hemolysis; L-Lactate Dehydrogenase; Laboratories, Hospital; Partial Thromboplastin Time; Phosphotransferases; Referral and Consultation; Transferases; Transportation
- From:Laboratory Medicine Online 2011;1(2):72-80
- CountryRepublic of Korea
- Language:Korean
- Abstract: BACKGROUND: Accuracy of laboratory test results is an important issue. New guidelines for specimen delivery systems are needed for appropriate pretreatment of specimens and accuracy of results. METHODS: We evaluated various laboratory profiles, comparing the effects of specimen rack holders and coolants within transport containers. The hematology profiles (complete blood cell count [CBC], erythrocyte sedimentation rate [ESR]), chemistry profiles (aspartate aminotransaminase [AST], alanine aminotransaminase [ALT], gamma-glutamyl transferase [gamma-GT], electrolytes [Na, K, Cl], glucose, lactate dehydrogenase [LD], creatinine kinase [CK]), and coagulation profiles (prothrombin time [PT], activated partial thromboplastin time [aPTT], fibrinogen level). We also investigated the effects of transportation time including the presence or absence of hemolyzation. We received from 9 different university hospital laboratories using conventional transporation methods. RESULTS: Hemolytic features were seen in short drawn specimens. Fewer result variations were observed in specimens transported with coolants. Average specimen transportation time was 11.3 hours, and average temperatures of container was 10.9degrees C with coolant and 25.0degrees C without coolants. Non-centrifuged specimens transported with coolants showed increased serum K levels than centrifuged specimens. Coagulation tests showed less than a 10% differences. Centrifuged specimen prior to transportation showed no hemolyzation and no differences in results. CONCLUSIONS: Appropriate temperatures for each analyte should be defined to ensure the accuracy of results. To reduce hemolyzation, appropriate temperature and rack holder should be used. Temperature of the transport container should be monitored in objectively. Coagulation tests should be added as referral tests, if appropriate specimen transport monitoring system for time and temperature could be adopted.
