Serum cystatin C in renal transplant patients

BACKGROUND: Waiting temperature before centrifugation and anticoagulants used, markedly effect total homocysteine concentrations. The aim of this study was to investigate the effect of different anticoagulants and temperature on plasma homocysteine levels. METHODS: We studied total homocysteine concentrations in 23 healthy subjects. Blood was drawn in K(3)EDTA, sodium citrate- or sodium fluoride-containing tubes, and kept at 0 degrees C or 22 degrees C for 3 h. Total homocysteine measurements were performed with fluorescence polarization immunoassay (FPIA) method. We compared all results with baseline EDTA values (samples put on crushed ice and centrifuged immediately) recommended in literature for reference handling. RESULTS: At 22 degrees C, the tubes containing sodium citrate and sodium fluoride showed significantly higher total homocysteine concentrations than their respective baseline values (p=0.000). However, sodium fluoride tubes were not significantly different than baseline EDTA levels. Waiting 3 h at 0 degrees C did not effect sodium citrate and EDTA plasma total homocysteine concentrations when compared to baseline EDTA, but sodium fluoride-containing plasma levels were significantly decreased (p=0.000). CONCLUSIONS: According to our results, the most available and practical temperature and anticoagulant for total homocysteine determination is sodium fluoride at room temperature up to 3 h.     

Effect of anticoagulants and storage temperatures on stability of plasma and serum hormones

OBJECTIVES: To determine the effect of different anticoagulants and storage conditions on the stability of hormones in plasma and serum. DESIGN AND METHODS: Human blood samples were collected from volunteers into EDTA, lithium heparin, sodium fluoride/potassium oxalate, or tubes without anticoagulant, plasma and serum left at -20 degrees C, 4 degrees C or 30 degrees C for 24 and 120 hours then assayed for ACTH, aldosterone, alpha-subunit, AVP, CRH, C-peptide, estradiol, FSH, glucagon, GH, IGF-1, IGFBP-3, insulin, leptin, LH, PPP, PTH, prolactin and VIP, or at room temperature for 0 to 72 hours (BNP, NT-BNP)(n = 6 per condition). RESULTS: The anticoagulant altered the measured concentrations for 9 hormones when compared to EDTA. All hormones except ACTH were stable for > 120 hours in EDTA or fluoride at 4 degrees C, but only 13 hormones were stable in all anticoagulants. At 30 degrees C, 8 hormones were stable for > 120 hours in EDTA, and 3 hormones in all anticoagulants. BNP and NT-BNP were stable for < 24 hours when stored in EDTA or heparin at room temperature. DISCUSSION: Storage of samples in EDTA plasma at 4 degrees C is suitable for most hormones (except ACTH) for up to 120 hours.     

不同标本类型间髓过氧化物酶水平的检测分析

目的探讨不同标本类型间髓过氧化物酶(MPO)检测结果的差异性、抗凝剂的选择及检测结果的比对。方法同时采集165例健康体检人群含乙二胺四乙酸二钾(EDTA-K2)、肝素钠两种抗凝剂的血浆标本及不含抗凝剂的普通生化管的血清标本,分别检测3种标本类型中MPO水平,并对各组检测结果进行统计学分析。结果同一例体检者不同抗凝剂的血浆标本间及与不含抗凝剂的血清标本间MPO检测结果差异有统计学意义(P0.05)。结论不同标本类型对血液标本中MPO水平检测结果差异较大,建议各个实验室检测时根据不同抗凝剂制订相应的参考区间;由于EDTA-K2抗凝血浆不受体外白细胞中MPO释放的影响,推荐采用EDTA-K2抗凝血作为检测MPO水平的首选。     

Influences of blood sample processing on low-molecular-weight proteome identified by surface-enhanced laser desorption/ionization mass spectrometry

BACKGROUND: Profiling approaches in proteomics, such as surface-enhanced laser desorption/ionization (SELDI) mass spectrometry, are used in disease marker discovery. The aim of this study was to investigate the potential influence of selected preanalytical factors on the results obtained. METHODS: Plasma samples anticoagulated with EDTA, citrate, or heparin, and serum samples from healthy volunteers were profiled by SELDI on CM10, immobilized metal affinity capture (IMAC) array with copper, and H50 chip surfaces. Using linear mixed-effects models, we examined the influence of elapsed time between venipuncture and sample separation (immediate to 24 h) and the type of serum tube used (Greiner Vacuette activator, gel serum separator, or plain tubes). We analyzed purified platelets, as well as platelet-poor and platelet-rich plasma samples treated with calcium and/or thrombin to determine the platelet contribution, directly or via the clotting process, to the profiles generated. We then used cluster analysis to identify samples with similar peak profiles. RESULTS: Different plasma types and sera could be distinguished on the basis of cluster analyses of their spectral profiles. Elapsed time between venipuncture and separation of plasma and serum from blood samples altered the profiles obtained, particularly for serum samples and particularly on IMAC chips. The type of serum collection tube also affected the profiles because of differences in clotting time. In vitro manipulation of platelets revealed that specific peaks in IMAC profiles of serum appeared to be derived directly from platelets. Several other peaks, including some of those exhibiting time-dependent changes, arose during the clotting process. CONCLUSION: Preanalytical variables, such as sample handling, can markedly influence results.     

Quantitation of genomic DNA in plasma and serum samples: higher concentrations of genomic DNA found in serum than in plasma

BACKGROUND: Plasma and serum samples have been used to detect cell-free genomic DNA in serum or plasma in certain pathologic conditions such as systemic lupus erythematosus, pulmonary embolism, and malignancies, as well as in fetal cell chimerisms in maternal serum and/or plasma. In this study, baseline concentrations of cell-free DNA in serum and plasma samples were evaluated for the study of posttransfusion chimerism. STUDY DESIGN AND METHODS: DNA was extracted from fresh or stored (4 degrees C for 1-6 days) normal donor serum or plasma samples (ACD; EDTA) by using reagents from an HIV assay kit. After incubation and washing of samples, purified DNA was amplified with HLA DQ-alpha primers (GH26 and 27) or human Y-chromosome primers (SA and SD) to quantitate the concentration of genomic DNA. RESULTS: Fresh serum samples had concentrations of cell-free DNA that were about 20-fold higher than the concentrations in fresh plasma samples. The concentration of cell-free genomic DNA in serum samples increased daily, to a level more than 100 times baseline after clotted blood tubes were stored at 4 degrees C for 4 to 5 days. There was a small increase in cell-free plasma DNA in stored ACD whole blood samples. Male WBCs, spiked into fresh nonanticoagulated female blood, were lysed during the process of clotting, with male DNA liberated into the serum samples. CONCLUSION: Most cell-free DNA in serum samples is generated during the process of clotting in the original collection tube. The concentration of cell-free genomic DNA in fresh plasma is probably the same as that in circulation. Consequently, while serum samples should not be used to monitor the concentration of cell-free DNA in a patient's circulation, serum collected from sample tubes containing clots (i.e., without anticoagulant), 3 to 5 days after the date of phlebotomy, could be useful as a source of DNA with which to screen for posttransfusion microchimerism.     

Influence of the sample matrix on the stability of beta-CTX at room temperature for 24 and 48 hours

The measurement of beta-C-telopeptides of type I collagen (beta-CTX) reflects the rate of bone resorption in a variety of metabolic bone disorders and it is increasingly used to assist diagnosis and follow-up of these pathologies. Since preanalytical biases in the results of this marker can decrease its clinical usefulness, specific stability studies should be developed to prevent that inconsistent results of laboratory testing might affect patient health and waste economical resources. Three blood samples were simultaneously collected without venous stasis into evacuated tubes containing no additives, K2 EDTA or lithium heparin, from 23 out-patients referred to our phlebotomy service for routine laboratory testing. After centrifugation and separation of the specimens, a first aliquot was immediately analyzed, whereas a second and third aliquot was processed after a 24- and 48-hour storage at room temperature (21 degrees C). Beta-CTX was assayed on the automated electrochemiluminescence analyzer E170. A modest and clinically irrelevant underestimation was observed in lithium heparin plasma when compared with either K2 EDTA (-7.1%; 95% C.I. -2.0 to -12.3%; p < 0.001) or serum (-7.8%; 95% C.I. -3.2 to -12.4%; p < 0.001), but not between serum and K2 EDTA (+0.8%, 95% C.I. -5.3 to +6.9%; p = 0.260). Storage at room temperature in K2 EDTA plasma introduced a modest and clinically negligible decay in immunoreactivity (-4.4% and -5.7% at 24 and 48 hours, respectively), whereas storage at room temperature in both serum (-17.6% and -28.6% at 24 and 48 hours, respectively) and lithium heparin plasma (-29.1% and -44.0% at 24 and 48 hours, respectively) was associated with a substantial decay and a larger inter-individual variability in the measurable concentration of the analyte. In conclusion, the results of our investigation demonstrate that EDTA plasma is the most suitable sample matrix for the storage of beta-CTX at room temperature after centrifugation.     

Release of anandamide from blood cells.

BACKGROUND: Endogenous ligands of cannabinoid receptors (endocannabinoids), in particular anandamide (arachidonylethanolamide), have been recognized as being of crucial importance in a variety of physiological functions. Plasma concentrations of anandamide have been measured in a number of investigations; however, discrepant data on "normal" anandamide plasma concentrations were reported. Since this might be caused by pre-analytical variables, we investigated the impact of different sample handling conditions on measured plasma anandamide concentrations. METHODS: Blood samples were taken from healthy volunteers in EDTA- or heparin-containing tubes; whole blood samples were kept at +4 degrees C, room temperature, or 37 degrees C, respectively, for up to 120 min before obtaining plasma by centrifugation. Plasma anandamide concentrations were measured by an isotope-dilution liquid chromatography tandem mass spectrometry (LC-MS/MS) method. RESULTS: A marked time- and temperature-dependent increase in plasma anandamide concentrations ex vivo was observed in both EDTA- and heparin-containing tubes. Mean anandamide concentrations approximately doubled when EDTA samples were kept at 4 degrees C for 60 min before centrifugation [immediately centrifuged, 1.3 microg/L (SD 0.3 microg/L); 2.8 microg/L (SD 0.5 microg/L) after storage for 60 min; n=12). After storage of heparinized whole-blood samples for 120 min at 37 degrees C, a mean plasma anandamide concentration of 11.9 microg/L (SD 1.8 microg/L) was found. In cell-free plasma, no increase in anandamide concentrations was found. CONCLUSION: Anandamide is released from blood cells ex vivo at a very high rate; therefore, strictly standardized pre-analytical protocols have to be applied for plasma anandamide determination.     

Preanalytical variables and off-site blood collection: influences on the results of the prothrombin time/international normalized ratio test and implications for monitoring of oral anticoagulant therapy

BACKGROUND: The quality of oral anticoagulant therapy management with coumarin derivatives requires reliable results for the prothrombin time/International Normalized Ratio (PT/INR). We assessed the effect on PT/INR of preanalytical variables, including ones related to off-site blood collection and transportation to a laboratory. METHODS: Four laboratories with different combinations of blood collection systems, thromboplastin reagents, and coagulation meters participated. The simulated preanalytical variables included time between blood collection and PT/INR determinations on samples stored at room temperature, at 4-6 degrees C, and at 37 degrees C; mechanical agitation at room temperature, at 4-6 degrees C, and at 37 degrees C; time between centrifugation and PT/INR determination; and times and temperatures of centrifugation. For variables that affected results, the effect of the variable was classified as moderate when <25% of samples showed a change >10% or as large if >25% of samples showed such a change. RESULTS: During the first 6 h after blood collection, INR changed by >10% in <25% of samples (moderate effect) when blood samples were stored at room temperature, 4-6 degrees C, or 37 degrees C with or without mechanical agitation and independent of the time of centrifugation after blood collection. With one combination of materials and preanalytical conditions, a 24-h delay at room temperature or 4-6 degrees C had a large effect, i.e., changes >10% in >25% of samples. In all laboratories, a 24-h delay at 37 degrees C or with mechanical agitation had a large effect. We observed no clinically or statistically relevant INR differences among studied centrifugation conditions (centrifugation temperature, 20 degrees C or no temperature control; centrifugation time, 5 or 10 min). CONCLUSIONS: We recommend a maximum of 6 h between blood collection and PT/INR determination. The impact of a 24-h delay should be investigated for each combination of materials and conditions.     

Stability of YKL-40 concentration in blood samples

The stability of YKL-40, a mammalian member of the family of 18 glycosylhydrolases, in blood samples handled under different temperatures and different time intervals before centrifugation was studied in paired serum and plasma samples from 25 healthy premenopausal Danish women. Significant elevations of YKL-40 were found in 8 paired serum samples left on the clot for more than 3 h at room temperature compared to paired serum samples left on the clot for 3 h or less. Significant elevations of YKL-40 were found in 8 paired plasma (EDTA) samples left on the blood cells for more than 8 h at room temperature compared to paired plasma (EDTA) samples left on the blood cells for 8 h or less. No elevations were found in YKL-40 levels in serum samples left on the clot at 4 degrees C for 24 h or in plasma (EDTA) samples left on the blood cells for 72 h before centrifugation. Significantly lower concentrations of YKL-40 were measured in plasma (EDTA) compared with paired serum samples with a serum/plasma ratio of 1.4 in samples left on the clot or on blood cells at 4 degrees C for up to 24 h. Repetitive freezing and thawing had no significant effect on the measured YKL-40 concentrations. In conclusion, we have shown that YKL-40 is very dependent on the handling procedures. All the blood samples must be processed into plasma (EDTA) within 8 h at room temperature or into serum in less than 3 h at room temperature. If this is not possible, the blood samples must be stored at 4 degrees C until processed.     

Assay values for thiamine or thiamine phosphate esters in whole blood do not depend on the anticoagulant used

We compared the whole blood, plasma, and erythrocyte (red blood cell (RBC)) concentrations of thiamine and thiamine phosphate esters in the presence of heparin or EDTA as anticoagulants. Three blood specimens were collected from each of 24 healthy volunteers into evacuated collection tubes containing the following anticoagulants: heparin, Na2EDTA, or K2EDTA. The concentrations of nonphosphorylated free thiamine (T), thiamine monophosphate (TMP), thiamine diphosphate (TDP), and thiamine triphosphate (TTP) were determined by the NH2-column HPLC method. The anticoagulant used had no effect on the concentrations obtained in whole blood and plasma of thiamine or any of the above thiamine compounds (P>0.05). RBCs were isolated by centrifugation and washed with isotonic saline, and the cell counts of the washed cells were adjusted to their whole blood values. In the washed RBCs with any anticoagulant, the concentrations of T, TMP, and TDP expressed either as nmol/L of whole blood or a ratio to hemoglobin were significantly lower (P<0.05) than those in whole blood.     

Preanalytical factors affecting the stability of matrix metalloproteinase-2 concentrations in cerebrospinal fluid

BACKGROUND: Matrix metalloproteinases (MMPs) are crucially involved in central nervous system inflammation. This study assesses preanalytical factors on MMP-2 concentrations in cerebrospinal fluid (CSF). METHODS: The concentrations of MMP-2 in CSF obtained from 13 patients were measured using ELISA. Identical measurements were done from the samples of the CSF from the same collection that were successively stored in glass tubes, stored at room temperature (21 degrees C), or refrigerated (4 degrees C) and frozen and thawed five times. RESULTS: After 48 h of storage at room temperature and refrigeration, there was a significant decrease in the concentrations of MMP. Sample storage in polypropylene or glass tubes led to a comparable decrease in MMP-2 concentrations. The freeze-thaw cycles, which were repeated five times, did not significantly affect MMP-2 concentrations. CONCLUSIONS: The storage of CSF at room temperature or refrigeration significantly decreases MMP-2 concentrations. Subsequent freeze-thaw cycles or glass tube material did not influence MMP-2 concentrations. Samples of CSF should be frozen immediately after collection to ensure accuracy of MMP measurements.     

血浆同型半胱氨酸及其相关硫醇物在全血中的稳定性研究

目的 观察含EDTA的全血样本放置时间、保存温度以及不同稳定剂对血浆同型半胱氨酸(homocysteine,Hcy)及其相关硫醇物水平的影响.方法 用含EDTA、EDTA-氟化钠(EDTA-NaF)、EDTA-3-Deazaadenosine(EDTA-3DA)的试管收集17名健康成人静脉血,置于碎冰上(0～4 ℃)或室温中(25 ℃)保存,放置0、3、6、24、48 h后分离血浆.用HPLC法测定血浆总同型半胱氨酸(tHcy)、总半胱氨酸(total cysteine,tCys)、总半胱氨酰甘氨酸(total cysteinylglycine,tCysGly)、总谷胱甘肽(total glutathione,tGSH)浓度.设定全血样本0 h分离血浆所测硫醇物浓度为基础值.结果 EDTA管在室温中放置3、6、24、48 h,tHcy分别增加38.5%、64.2%、141.9%、225.4%;tCysGly、tGSH在3 h分别增加20.0%、37.9%,tCys则降低3.5%.EDTA管在碎冰上保存,各硫醇物浓度6 h内增加不超过5%.EDTA-3DA和EDTA-NaF管在室温放置3 h,与各自基础值相比,血浆tHcy、tCys、tCysGly、tGSH浓度差异无统计学意义(EDTA-3DA管:F值分别为0.01、0.94、0.09、0.01,P值均>0.05;EDTA-NaF管:F值分别为0.85、0.04、0.03、0.02,P值均>0.05).结论 EDTA抗凝血浆,所测tHcy及其相关硫醇物浓度呈时间、温度依赖性增加.血浆tHcy等硫醇物测定的分析前处理条件必须标准化.EDTA-3DA和EDTA-NaF管可使血浆tHcy、tCys、tCysGly、tGSH在室温中至少稳定3 h.

Abstract：

Objective To investigate the effects of different stabilizers, time and temperature before centrifugation on the stability of homocysteine (Hcy) and other related thiols levels involving EDTA-containing whole blood.Methods Blood was drawn from 17 healthy adults and collected into tubes containing EDTA, EDTA plus NaF and EDTA plus 3-deazaadenosine(3DA),then stored on crush ice(0-4 ℃) immediately or at room temperature(25 ℃).Plasma was separated at 0, 3, 6, 24 and 48 hours, respectively.The levels of plasma total Hcy (tHcy), total cysteine (tCys), tatal cysteinylglycine (tCysGly) and tatal glutathione (tGSH) were measured by HPLC.The plasma immediately separated was used as baseline sample. Results In EDTA tubes stored at room temperature, tHcy levels increased by 38.5%, 64.2%, 141.9%, 225.4% for 3, 6, 24, and 48 h, respectively.The levels of tCysGly and tGSH increased by 20.0% and 37.9% within 3 h, however, tCys decreased by 3.5%.The levels of the thiols increase by less than 5% up to 6 h in EDTA tubes stored on crush ice.In EDTA-3DA and EDTA-NaF tubes, no statistical differences were observed in the plasma levels of tHcy, tCys,tCysGly and tGSH compared with their respective baseline values at room temperature for 3 h(EDTA-3DA tubes:F=0.01,0.94,0.09,0.01,all P>0.05;EDTA-NaF tubes:F=0.85,0.04,0.03,0.02,all P>0.05).Conclusions The EDTA-plasma levels of tHcy and other related thiols are time and temperature-dependent. There is a strong need for standardization of blood sample collection and processing in tHcy and other thiols assays. The plasma concentrations of tHcy, tCys, tCysGly and tGSH were stable for 3 h at least in the EDTA-3DA and EDTA-NaF tubes kept at room temperature.     

不同抗凝剂对5种特定蛋白检测结果的影响

目的观察常见的4种血样采集管对C3、C4、IgA、IgG、IgM这5项生化项目检测结果的影响,探讨能否用抗凝血浆替代血清用于生化检测。方法对43名体检人员的静脉血管,连续用乙二胺四乙酸二钾(EDTA-K_2)抗凝管、肝素锂抗凝管、普通血清管、枸橼酸钠抗凝管各抽取一管血液,经混匀、离心分离后提取血清或血浆在仪器上同时用C3、C4、IgA、IgG、IgM试剂盒进行测定。结果在相同条件下,5个项目中肝素锂抗凝管与普通血清管比较差异无统计学意义(P0.05),枸橼酸钠抗凝管与用普通血清管的结果比较差异有统计学意义(P0.05),EDTA-K_2抗凝管与用普通血清管的结果比较,IgA、IgM、IgG差异无统计学意义(P0.05),C3、C4差异有统计学意义(P0.05)。结论 IgA、IgM、IgG生化检验项目可用肝素锂抗凝血浆和EDTAK2血浆代替血清,C3和C4生化检验项目可用肝素锂抗凝血浆代替血清,但C4应建立血浆参考区间。     

Effects of temperature on stability of blood homocysteine in collection tubes containing 3-deazaadenosine

BACKGROUND: The accuracy of homocysteine (Hcy) results is currently compromised by the requirement to separate the plasma within 1 h of sample collection. We studied the effect of temperature on the stability of plasma Hcy over a 72-h time course in blood collected into evacuated tubes containing either EDTA alone or both EDTA and 3-deazaadenosine (3DA). METHODS: We recruited 100 volunteers, including both diseased and healthy individuals with a range of baseline plasma Hcy values, from two centers. Blood samples were collected into tubes containing EDTA, and EDTA plus 3DA and stored at ambient temperature (20-25 degrees C) or refrigerated (2-8 degrees C). Aliquots of blood were centrifuged at various times up to 72 h, the plasma was removed, and Hcy was measured by HPLC. RESULTS: Plasma Hcy measurement covering the sample collection and storage conditions during the whole time course was possible on samples from 59 of those recruited. One-way ANOVA for repeated measures within subjects revealed that only samples that were collected into tubes containing EDTA plus 3DA and stored refrigerated were stable over 72 h (P = 0.2761). CONCLUSIONS: A combination of 3DA and storage at 2-8 degrees C will allow collection of samples for plasma Hcy measurement outside of the hospital setting and wider population screening.     

Effects of anticoagulants on the activity of gelatinases

OBJECTIVES: To identify the best procedure for preanalytical blood collection in the determination of matrix metalloproteinase (MMP)-2 and -9 by testing the effects of anticoagulants on their activity. DESIGN AND METHODS: Active forms of both gelatinases were measured by specific activity assay systems in serum, plasma EDTA, plasma-heparin and plasma-citrate obtained from 20 healthy volunteers, as well as in a pooled serum sample before and after anticoagulant treatment. RESULTS:: Active MMP-2 and MMP-9 mean concentrations were similar in serum and in plasma-citrate, higher in plasma EDTA than in serum, in plasma-heparin and in plasma-citrate, and lower in plasma-heparin than in serum and plasma-citrate. A similar trend was observed in untreated and treated pooled serum samples. CONCLUSIONS: Our results indicate that MMP-2 and MMP-9 in their active forms are not released by platelets during blood clotting, whereas the use of calcium chelating anticoagulants can profoundly alter the activity of endogenous gelatinases. This suggests that the determination of active forms of MMP-2 and MMP-9 in serum samples represents a suitable procedure.     

Increased plasma concentrations of soluble CD40 ligand in acute coronary syndrome depend on in vitro platelet activation

BACKGROUND: Soluble CD40 ligand (sCD40L) was suggested as a novel biomarker of cardiovascular risk. We examined the effect of preanalytical variation on the measurement of sCD40L concentration. METHODS: From healthy control individuals (n = 20) and patients with acute coronary syndrome (ACS) (n = 20) or sepsis (n = 20), we obtained blood drawn into 5 tubes containing citrate or a mixture of citrate, theophylline, adenosine, and dipyridamole (CTAD). The tubes were incubated for 30 min at room temperature or 0 degrees C before a single or double centrifugation (15 min, 2500 g) at room temperature or 4 degrees C, respectively. sCD40L, beta-thromboglobulin (betaTG), and platelet factor 4 (PF4) concentrations were measured using immunoassays. RESULTS: Concentrations of sCD40L were very low in all CTAD and citrated samples maintained at 0 degrees C (median < or = 0.076 microg/L). Although increased betaTG and PF4 confirmed disease-related in vivo platelet activation, sCD40L was not higher in patients than in controls. In contrast, if the samples were processed at room temperature, sCD40L was significantly higher in ACS patients than in controls (P <0.02 in CTAD and citrated plasma at room temperature). Moreover, the betaTG:PF4 ratio decreased in patient but not control CTAD samples, suggesting a greater susceptibility of patient platelets to in vitro activation. CONCLUSIONS: Increased sCD40L concentrations resulted from in vitro platelet activation during sample preparation. Disease-related in vivo activation did not contribute to sCD40L concentrations in plasma. Therefore, published studies of sCD40L demand cautious interpretation, because their preanalytical conditions were not standardized.     

The role of ethylenediamine tetraacetic acid (EDTA) as in vitro anticoagulant for diagnostic purposes.

Anticoagulants are used to prevent clot formation both in vitro and in vivo. In the specific field of in vitro diagnostics, anticoagulants are commonly added to collection tubes either to maintain blood in the fluid state for hematological testing or to obtain suitable plasma for coagulation and clinical chemistry analyses. Unfortunately, no universal anticoagulant that could be used for evaluation of several laboratory parameters in a sample from a single test tube is available so far. Ethylenediamine tetraacetic acid (EDTA) is a polyprotic acid containing four carboxylic acid groups and two amine groups with lone-pair electrons that chelate calcium and several other metal ions. Calcium is necessary for a wide range of enzyme reactions of the coagulation cascade and its removal irreversibly prevents blood clotting within the collection tube. Historically, EDTA has been recommended as the anticoagulant of choice for hematological testing because it allows the best preservation of cellular components and morphology of blood cells. The remarkable expansion in laboratory test volume and complexity over recent decades has amplified the potential spectrum of applications for this anticoagulant, which can be used to stabilize blood for a variety of traditional and innovative tests. Specific data on the behavior of EDTA as an anticoagulant in hematology, including possible pitfalls, are presented. The use of EDTA for measuring cytokines, protein and peptides, and cardiac markers is described, with an outline of the protection of labile molecules provided by this anticoagulant. The use of EDTA in proteomics and in general clinical chemistry is also described in comparison with other anticoagulants and with serum samples. Finally, the possible uses of alternative anticoagulants instead of EDTA and the potential use of a universal anticoagulant are illustrated.     

Stability of YKL-40 concentration in blood samples

The stability of YKL-40, a mammalian member of the family of 18 glycosyl-hydrolases, in blood samples handled under different temperatures and different time intervals before centrifugation was studied in paired serum and plasma samples from 25 healthy premenopausal Danish women. Significant elevations of YKL-40 were found in 8 paired serum samples left on the clot for more than 3 h at room temperature compared to paired serum samples left on the clot for 3 h or less. Significant elevations of YKL-40 were found in 8 paired plasma (EDTA) samples left on the blood cells for more than 8 h at room temperature compared to paired plasma (EDTA) samples left on the blood cells for 8 h or less. No elevations were found in YKL-40 levels in serum samples left on the clot at 4°C for 24 h or in plasma (EDTA) samples left on the blood cells for 72 h before centrifugation. Significantly lower concentrations of YKL-40 were measured in plasma (EDTA) compared with paired serum samples with a serum/plasma ratio of 1.4 in samples left on the clot or on blood cells at 4°C for up to 24 h. Repetitive freezing and thawing had no significant effect on the measured YKL-40 concentrations. In conclusion, we have shown that YKL-40 is very dependent on the handling procedures. All the blood samples must be processed into plasma (EDTA) within 8 h at room temperature or into serum in less than 3 h at room temperature. If this is not possible, the blood samples must be stored at 4°C until processed.