Objective To evaluate a method of fast detection of the hematopoietic progenitor cell (HPC) in peripheral blood samples and explore for an appropriate cutoff value in prediction of adequate CD34+ cell in apheresis concentrate.Methods Peripheral blood samples and apheresis concentrate samples were collected from 27 auto-PBSCT patients receiving chemotherapy plus G-CSF mobilization (chemo group) and 17 patients receiving G-CSF alone (non-chemo group).CD34+ cell counts were determined by flow cytometry according to ISHAGE guideline and HPC counts were detected using Sysmex XE-2100 automatic hemocyte analyzer.The correlation between HPC and CD34+ cell counts in peripheral blood samples and apheresis concentrates were analyzed.Receiver operating characteristic (ROC) curves was used to determine the cutoff value in prediction of adequate CD34+ cell in apheresis concentrate.Results CD34+ cell counts in peripheral blood samples can be estimated by HPC counts (r =0.711,P =0.000,r =0.656,P =0.004).CD34+ cell counts =-0.829+0.648×HPC counts (in chemo group) or 45.033+0.460×HPC counts (in non-chemo group).HPC counts in the peripheral blood of auto-PBSCT patients were highly correlated with the CD34+ cell yield (r =0.602,P =0.001),CD34+ cell counts =1.106+0.046×HPC counts.When HPC in peripheral blood was ≥85/μl,the prediction of adequate CD34+ cells in the yield of apheresis (≥5×106/kg body weight) would have a sensitivity of 78 ％ and a specifity of 82 ％.Conclusion HPC counts in peripheral blood samples in auto-PBSCT patients can be used to determine the optimal time of apheresis and be used as a good marker to predict the stem cell in the yield.

OBJECTIVETo explore the effects of exogenous carbon monoxide-releasing molecules 2 (CORM-2) on LPS-induced abnormal activation of platelets in peripheral blood of healthy human donors and its possible molecular mechanism.

METHODSVenous blood samples were collected from a healthy volunteer, and platelet-rich plasma (PRP) from the blood were isolated by differential centrifugation. The PRP was subpackaged into siliconized test tubes and then divided into control group, LPS group, inactive CORM-2 (iCORM-2) group, 10 µmol/L CORM-2 group, and 50 µmol/L CORM-2 group according to the random number table, with 3 tubes in each group. The PRP in control group did not receive any treatment. The PRP in LPS group received LPS (20 mL, 10 µg/mL) stimulation, and the PRP in iCORM-2 group, 10 µmol/L CORM-2 group, and 50 µmol/L CORM-2 group underwent the same LPS stimulation and treatment of 50 µmol/L iCORM-2, 10 µmol/L CORM-2, and 50 µmol/L CORM-2, respectively, with the dosage of 20 mL. After being cultured for 30 min, the platelet adhesion rate was determined by glass bottle method, the number of platelet spreading on fibrinogen was determined with immunofluorescent method, and the platelet aggregation rate was measured by turbidimetric method. The platelet poor plasma (PPP) was prepared from PRP, the levels of ATP in PPP and platelets were determined by chemical fluorescein method. The expressions of platelet glycoprotein I bα (GPIbα) and GPVI were analyzed by flow cytometer. The expressions of glycogen synthase kinase 3β (GSK-3β) and phosphorylated GSK-3β were determined by Western blotting and immunoprecipitation, respectively. Measurement of the above indices was repeated for 3 times. Data were processed with one-way analysis of variance and SNK test.

RESULTSCompared with those in control group, the platelet adhesion rates, numbers of platelets spreading on fibrinogen, platelet aggregation rates, expressions of GPIbα and GPVI in PRP, levels of ATP in PPP in LPS and iCORM-2 groups were significantly increased, while levels of ATP in platelets were significantly decreased (with P values below 0.05). Compared with those in LPS group, the former 7 indices in iCORM-2 group showed no significant differences (with P values above 0.05), while the levels of ATP in platelets in the 10 µmol/L CORM-2 and 50 µmol/L CORM-2 groups were significantly increased, and the other 6 indices in 10 µmol/L CORM-2 and 50 µmol/L CORM-2 groups were significantly decreased (with P values below 0.05). The expression levels of GSK-3β of the platelets in PRP in control, LPS, iCORM-2, 10 µmol/L CORM-2, and 50 µmol/L CORM-2 groups were 0.550 ± 0.060, 1.437 ± 0.214, 1.210 ± 0.108, 0.720 ± 0.010, and 0.670 ± 0.010, respectively, and the expression levels of the phosphorylated GSK-3β of the platelets in PRP in the above 5 groups were 0.950 ± 0.070, 1.607 ± 0.121, 1.420 ± 0.040, 1.167 ± 0.015, and 0.513 ± 0.122, respectively. Compared with those in control group, both the expression levels of GSK-3β and phosphorylated GSK-3β of the platelets in PRP in LPS and iCORM-2 groups were significantly increased (with P values below 0.05). The expression levels of GSK-3β and phosphorylated GSK-3β of the platelets in PRP between LPS group and iCORM-2 group were similar (with P values above 0.05). The expression levels of GSK-3β and phosphorylated GSK-3β of the platelets in PRP in 10 µmol/L CORM-2 and 50 µmol/L CORM-2 groups were significantly decreased compared with those in LPS group (with P values below 0.05).

CONCLUSIONSLPS stimulation can abnormally activate the platelets in peripheral blood of healthy human, but the abnormal activation can be inhibited by CORM-2 intervention, and the mechanism of the latter may involve the phosphorylation of GSK-3β mediated by GP.

Blood Platelets ; drug effects ; metabolism ; Carbon Monoxide ; metabolism ; Glycogen Synthase Kinase 3 ; Glycogen Synthase Kinase 3 beta ; Humans ; Lipopolysaccharides ; pharmacology ; Organometallic Compounds ; pharmacology ; Phosphorylation ; drug effects ; Platelet Activation ; drug effects ; Platelet Aggregation ; drug effects ; Platelet-Rich Plasma