Flow cytometric detection and microscopic observation of activated eosinophils in peripheral blood.

Eosinophils possess highly electron-dense granules with crystal-like structures and are characterized as high side scatter (SSC) areas by flow cytometry analysis. Eosinophils with low SSC features have been noted in extremely rare cases; however, the underlying cause remains unclear. Eosinophils in the low SSC area were analyzed using microscopy. A transmission electron microscope revealed the loss of crystal-like structures in granules with low electron density and piecemeal degranulation, which was undetectable by May-Grünwald-Giemsa staining. Based on the results of flow cytometry, May-Grünwald-Giemsa staining and transmission electron microscopy, SSC values could help potentially detect crystal-like structures and piecemeal degranulation eosinophils.

Deferasirox, an iron-chelating agent, alleviates acute lung inflammation by inhibiting neutrophil activation and extracellular trap formation.

OBJECTIVE: Reactive oxygen species (ROS) production by neutrophils induces pulmonary endothelial cell damage and results in acute lung injury (ALI). We previously reported that deferasirox (DFS), an iron-chelating agent, inhibits the ROS production and neutrophil extracellular trap (NET) formation induced by phorbol myristate acetate and formylmethionylleucylphenylalanine in vitro. In the present study, we investigated the effects of DFS in vivo using a mouse model of lipopolysaccharide (LPS)-induced ALI. METHODS: After DFS administration for 7 days, ALI was induced in mice by LPS via intratracheal administration. RESULTS: LPS treatment induced neutrophil invasion in the lung tissues, along with NET formation and a significant increase in the quantity of double-stranded DNA in the bronchoalveolar lavage fluid, while pre-administered DFS inhibited these phenomena. However, alteration of neutrophil morphology in the cytoplasm in terms of shape and vacuolization was not inhibited by the pre-administration of DFS, possibly through ROS production. CONCLUSIONS: DFS suppressed neutrophil invasion into lung tissues and reduced the double-stranded DNA content released by the neutrophils. These results suggest that DFS can potentially be used to prevent diseases related to neutrophil activation including ALI, thrombosis, and vascular endothelial dysfunction.

Morphological and optical properties of human immature platelet-enriched population produced in immunodeficient mice.

Ultrastructure analysis of immature platelets is difficult because of the lack of a suitable marker and their relatively low concentration in total platelets. We investigated the morphological and optical properties of human immature platelets produced and enriched in immunodeficient mice via human CD34-positive cell administration. Immunodeficient mice were injected with human CD34-positive cells and administered eltrombopag orally for 14 days (eltro-mice). Some of these mice were maintained for 2-3 months (steady-state-mice). Platelets were double-stained with a human CD41 antibody and a nuclear staining dye (Sysmex hematology analyzer XN series reagent), and then analyzed by flowcytometry FCM to identify human immature platelets. Human CD41-positive cells were isolated from citrated blood by magnetic cell sorting with human CD41 antibody, and examined using electron microscopy. Flow cytometric analysis with the XN reagent demonstrated that peripheral blood from eltro-mice had a higher percentage of immature platelet fraction in human platelets than that from steady-state-mice. The geometric mean of XN reagent fluorescence for human platelets, divided with that for mouse platelets, revealed that the ratios in eltro-mice were significantly higher than those in steady-state-mice, thus indicating that immature platelets were highly enriched in eltro-mice. Scanning and transmission electron microscopy revealed that human citrated platelets isolated from eltro-mice tended to be larger (n = 15, p = 0.276) and contained more mitochondria than those isolated from steady-state-mice (n = 10, p = 0.0002). Therefore, an increased number of mitochondria, rather than platelet size, is a distinctive feature of immature platelets.

Detection of activated neutrophils by reactive oxygen species production using a hematology analyzer.

Neutrophils are recruited to infection sites and kill bacteria by phagocytosis and reactive oxygen species (ROS) production. It has been reported that vacuoles are present in neutrophils that produce ROS and are present in large numbers in blood smears of patients with bacterial infections. The leukocyte differentiation function on the Sysmex automated hematology analyzer classifies leukocytes by flow cytometry. Particularly, side-scattered light is known to reflect the quantity of organelles. This study investigated the possibility of detecting vacuoles or invagination of cell membrane in neutrophils producing ROS using a hematology analyzer. Whole blood and polymorphonuclear (PMN) cell fractions were activated with phorbol myristate acetate (PMA) or formylmethionylleucylphenylalanine (fMLP) and analyzed using the Sysmex XE-2100 automated hematology analyzer. PMN fractions were morphologically analyzed with a confocal laser scanning microscope (CLSM), electron microscope (EM), and general-purpose conventional flow cytometer. In the white blood cell differentiation scattergram obtained in this analysis, a new cluster separate from the original neutrophil cluster appeared in the eosinophil area in an area of higher side-scattering (SSC) intensity. Flow cytometry analysis of the PMN fractions revealed that the cells in this new cluster were CD16b- and APF-positive, indicating that the cells were activated neutrophils that produced ROS. CLSM and EM findings revealed that ROS production occurred in the cytoplasm and that the activated neutrophils contained some vacuole-like structures of vacuoles or invagination of cell membrane. Vacuole-like Sstructures were found within the cytoplasm of neutrophils producing ROS. These neutrophils were detected as an independent cluster in the eosinophil area with higher SSC intensity than that shown by neutrophils in the traditional cluster on the white blood cell differentiation scattergram, likely because the vacuole-like structures increased the SSC intensity.