Objective To investigate the expression of Th17 cells in peripheral blood of patients with sarcoidosis at different stage. Methods Flow cytometry was used to detect the Th17 cells in peripheral blood of 38 patients with sarcoidosis, including 18 cases of newly diagnosed active patients with obvious symptoms such as cough, fever, fatigue and weight loss, and 20 stable cases who were followed up regularly.15 cases of healthy volunteers were enrolled as control. Serumangiotensin-converting enzyme ( SACE) of the patients with sarcoidosis was detected by ultraviolet spectrophotometry. The cell classification and CD4 + /CD8 + T in the BALF of the newly diagnosed active patients were calculated. Results The expression of Th17 cells in peripheral blood in the patients with active sarcoidosis were higher than that in the sable patients and the controls [ ( 1. 59 ±0. 44) % vs. ( 0. 56 ±0. 32) % and ( 0. 49 ±0. 23) % , all P lt; 0. 05] . Th17 cells in peripheral blood in the patients with stable sarcoidosis and the controls were not different significantly ( P gt;0. 05) . The levels of SACE in the patients with active sarcoidosis were higher than that in the patients with stable sarcoidosis [ ( 56. 6 ±14. 6) IU/L vs. ( 35. 8 ±18. 3) IU/L, P lt; 0. 05) . There was not significant correlation between the Th17 cells in peripheral blood and SACE in the patients with sarcoidosis ( P gt;0. 05) . In the patients with active sarcoidosis, the Th17 cells in peripheral blood were not significantly correlated with lymphocyte percentages in BALF( P gt; 0. 05) , but significantly correlated with CD4 + /CD8 + in BALF ( r=0. 63, P lt;0. 05) .Conclusion In patients with active sarcoidosis, the increased expression of Th17 cells in peripheral blood may correlate with the activity of sarcoidosis.
【Abstract】Objective To investigate the role of VEGF and its soluble VEGF receptor ( sVEGFR-1) in pathogenesis of acute lung injury ( ALI) induced by immersion in seawater after open chest trauma. Methods Sixteen hybridized adult dogs were randomly divided into control group and seawater group. The control group only suffered from open chest trauma, whereas the seawater group were exposed to seawater after open chest trauma. Blood samples were collected at the 0, 2, 4, 6, 8 h after trauma for measurement of white blood cell count, arterial blood gas, plasma osmotic pressure ( POP) , electrolyte concentration, IL-8, vWF, VEGF and sVEGFR-1 levels. The lungs tissue and BALF was collected at 8 h after trauma. Pathological changes of the lung was observed under light microscope by HE staining. Meanwhile VEGF and sVEGFR-1 levels were measured in BALF and lung tissue homogenate. Total protein concentrations in plasma and BALF were measured to calculate the pulmonary penetration index ( PPI) . Results The lung of the seawater group showed interstitial mononuclear cell and neutrophil infiltration, interstitial edema, and vascular congestion. VEGF and sVEGFR-1 were significantly increased in the plasma, while VEGF was significantly reduced in the lung tissues and BALF. The levels of IL-1β, IL-8 and vWF, just as the level of VEGF, were significantly increased in the plasma. Meanwhile, the POP and electrolyte concentration were significantly increased. In the plasma, the responses of VEGFs during the early onset of ALI induced by immersion in seawater after open chest trauma were consistent with the POP and PPI. Conclusions High plasma levels and low BALF/ lung tissue levels of VEGFs is a distinguishing characteristic during the early onset of ALI induced by immersion in seawater after open chest trauma. VEGF may be a novel biomarker which has an important role in the development of ALI.