RESUMEN
Objective: To investigate the application value of combined detection of anti-beta 2-glycoprotein I antibody (anti-ß2-GPI), anti-cardiolipin antibody (ACL), and lupus anticoagulant (LA) in the diagnosis of patients with antiphospholipid syndrome (APS). Methods: 30 APS patients in our hospital between Jan. 2020 and Jan. 2021 were chosen as the experimental group, and 30 healthy persons with normal physical examination during the same period were selected as the control group The anti-ß2-GPI and ACL indexes of both groups were detected by enzyme-linked immunosorbent assay (ELISA), with the LA levels tested by modified dilute Russell's viper venom time (dRVVT) and LA ratio calculated. The diagnostic efficacy of single detection and combined detection was analyzed by plotting the receiver operating characteristic (ROC) curve. Results: The serum indexes in the experimental group were remarkably higher than those in the control group (P < 0.001). ROC curve analysis suggested that in the diagnosis of APS, the area under the ROC curve by detecting anti-ß2-GPI, ACL, LA ratio alone and simultaneously were 0.517, 0.583, 0.683, and 0.817 respectively, and the combined detection of the three had remarkably higher sensitivity and specificity than those of each single detection. Conclusion: The indexes of anti-ß2-GPI, ACL, and LA ratio were highly expressed in APS patients, and the combined detection of the three has high diagnostic value and can effectively screen and assist the diagnosis of APS.
RESUMEN
BACKGROUND: Mechanical insufflation-exsufflation (MI-E) has been proposed as a potential strategy to generate high expiratory flows and simulate cough in the critically ill. However, efficacy and safety of MI-E during invasive mechanical ventilation are still to be fully elucidated. This study in intubated and mechanically ventilated pigs aimed to evaluate the effects of 8 combinations of insufflation-exsufflation pressures during MI-E on mucus displacement, respiratory flows, as well as respiratory mechanics and hemodynamics. METHODS: Six healthy Landrace-Large White female pigs were orotracheally intubated, anesthetized, and invasively ventilated for up to 72 h. Eight combinations of insufflation-exsufflation pressures (+40/-40, +40/-50, +40/-60, +40/-70, +50/-40, +50/-50, +50/-60, +50/-70 cm H2O) were applied in a randomized order. The MI-E device was set to automatic mode, medium inspiratory flow, and an inspiratory-expiratory time 3 and 2 s, respectively, with a 1-s pause between cycles. We performed 4 series of 5 insufflation-exsufflation cycles for each combination of pressures. Velocity and direction of movement of a mucus simulant containing radio-opaque markers were assessed through sequential lateral fluoroscopic images of the trachea. We also evaluated respiratory flows, respiratory mechanics, and hemodynamics before, during, and after each combination of pressures. RESULTS: In 3 of the animals, experiments were conducted twice; and for the remaining 3, they were conducted once. In comparison to baseline mucus movement (2.85 ± 2.06 mm/min), all insufflation-exsufflation pressure combinations significantly increased mucus velocity (P = .01). Particularly, +40/-70 cm H2O was the most effective combination, increasing mucus movement velocity by up to 4.8-fold (P < .001). Insufflation pressure of +50 cm H2O resulted in higher peak inspiratory flows (P = .004) and inspiratory transpulmonary pressure (P < .001) than +40 cm H2O. CONCLUSIONS: MI-E appeared to be an efficient strategy to improve mucus displacement during invasive ventilation, particularly when set at +40/-70 cm H2O. No safety concerns were identified although a transient significant increase of transpulmonary pressure was observed.
