ABSTRACT
Objective To investigate the causes on platelet distribution width (PDW)results not shown in the automatic he-matology analyzer and evaluate the accuracy of the platelet results of these samples with the automatic hematology analyzer. Methods The platelet morphology was observed in microscope for the specimen which PDW were not shown in the auto-matic hematology analyzer.And the platelet results counted in microscope were statistically compared with that in the auto-matic hematology analyzer.Results In the 200 specimens which PDW were not shown in automatic hematology analyzer, there were 104 specimens(52%)in which large platelet was found,36 cases(18%)in which platelet aggregation was visible, 28 cases(14%)in which the microcytes or erythrocyte debris could be seen,32 cases(16%)in which the obvious abnormal was not found.The platelet results counted in microscope for the specimens,in which large platelets,platelet aggregation or microcytes were found,were very different with the results counted with the automatic hematology analyzer(P < 0.05).The PDW of the 200 specimens were rechecked in the automatic hematology analyzer.And 64 cases (32%)PDW results were got,of which 55 cases(85.9%)PDW results were beyond the normal range.Conclusion The main causes for the PDW not shown in automatic hematology analyzer includes large platelets,platelets aggregation and microcytes etc.The platelet re-sults in these specimens by automatic hematology analyzer were different with that counted in microscope.Therefore,the platelet of these specimens should be counted in microscope.
ABSTRACT
Background and purpose:Integrinαvβ3 receptor plays an important role in promoting, sustaining and regulating the angiogenesis. It is overexpressed on neovascular endothelial cells and tumor cells. RGD peptide specifically binds to integrinαvβ3, which could evaluate growth status and invasiveness of tumor. This study aimed to investigate the biodistribution in healthy KM mice and micro PET/CT imaging in U87MG tumor-bearing mice of 18F-E[c(RGDfK)2]. Methods: 18F-E[c(RGDfK)2] was produced using an automated synthesis module via a simple one-step 18F-labeling strategy of the precursor 4-NO2-3-TFMBz-E[c(RGDfK)2]. The percentage activity of injection dose per gram of tissue (%ID/g) was calculated at 0.5, 1, 2, 4 h post injection of the probe. Micro PET/CT images of U87MG tumor-bearing nude mice with or without 18F-E[c(RGDfK)2] blocking were acquired at each time point. Results: The labeling efficiency and radiochemical purity of 18F-E[c(RGDfK)2] were 10% and 98%, respectively. 18F-E[c(RGDfK)2] was excreted via renal route, with a high blood clearance. The other organs had background-level activity accumulation. At 1 h, the%ID/g of kidney, liver, intestine, muscle and blood was (1.02±0.16)%ID/g,(0.24±0.06)%ID/g, (0.35±0.03)%ID/g, (0.13±0.03)%ID/g and (0.11±0.03)%ID/g 18F-E[c(RGDfK)2] had initial high tumor uptake [(5.2±0.56)%ID/g] and good tumor-to-background contrast (5.36) at 1 h post injection. Tumor uptake for blocking group was lower than those without blocking, and T/M reduced to 1.57. Conclusion: 18F-E[c(RGDfK)2] appears a promising PET molecular imaging probe targeting integrin αvβ3, with high tumor uptake. It could be suitable for prognosis evaluation of integrin-positive tumor, selection of vascular targeting therapy and therapy effect monitoring.
ABSTRACT
Background and purpose: One of the main mechanism of chemotherapy is inducing tuomr apoptosis. Molecular imaging can allow noninvasively and dynamically monitor tumor apoptosis in vivo, and help to drug screening and therapeutic evaluation. The purpose of this study was to evaluate the feasibility of 18F-SFB-Annexin B1 in detecting apoptosis at an early phase after chemotheraphy. Methods:Annexin B1 was labeled with 18F using SFB as a chelating agent. Tissue distribution of 18F-SFB-Annexin B1 was studied in healthy mice by the dissection method. W256 tumor-bearing rats were injected with 18F-SFB-Annexin B1 intravenously at 24 h after the treatment of cyclophosphamide (CTX 200 mg/kg) or saline. Then imaging was acquired at 1, 2, 3, and 4 h postinjection on a PET/CT, and the tumor-to-muscle ratio of SUVmax (T/M) and the AI from TUNEL testing were compared. Results: 18F-SFB-Annexin B1 had a radiochemical pruity (RCP)>95%. Biodistribution of this probe showed a predominant uptake in the kidney, then was liver, spleen, and myocardium, rapid clearance from blood and urinary was observed. The radios of T/M were 4.38±0.56, 6.75±1.16, 6.44±1.12, 4.81±0.17, respectively at 1, 2, 3, 4 h post injection of the chemotherapy group, much higher than that of the saline group (2.35±0.14, 2.99±0.55, 3.04±0.41, 2.33±0.47, respectively). The differences between the two groups were significant (F=23.790, 16.913, 14.046, 77.517, respectively, all P<0.05). TUNEL staining revealed that chemotherapy treatment significantly increased the percentage of apoptosis cells with an AI of (21.00±0.04)%in the chemotherapy group, higher than that in the saline group (8.58±0.01)%, the difference was significant (F=21.539, P<0.05). The radios of T/M were significantly correlated with the values of AI (r=0.91, P<0.05). Conclusion: 18F-SFB-Annexin B1 can be used to apoptosis imaging and early therapeutic evaluation in vivo because it can reflect apoptosis at an early stage after chemotheraphy.