Background Coagulation abnormalities in COVID-19 patients have not been addressed in depth. Objective To perform a longitudinal evaluation of coagulation profile of patients admitted to the ICU with COVID-19. Methods Conventional coagulation tests, rotational thromboelastometry (ROTEM), platelet function, fibrinolysis, antithrombin, protein C and S were measured at days 0, 1, 3, 7 and 14. Based on median total maximum SOFA score, patients were divided in two groups: SOFA ≤ 10 and SOFA > 10. Results Thirty patients were studied. Some conventional coagulation tests, as aPTT, PT and INR remained unchanged during the study period, while alterations on others coagulation laboratory tests were detected. Fibrinogen levels were increased in both groups. ROTEM maximum clot firmness increased in both groups from Day 0 to Day 14. Moreover, ROTEM–FIBTEM maximum clot firmness was high in both groups, with a slight decrease from day 0 to day 14 in group SOFA ≤ 10 and a slight increase during the same period in group SOFA > 10. Fibrinolysis was low and decreased over time in all groups, with the most pronounced decrease observed in INTEM maximum lysis in group SOFA > 10. Also, D-dimer plasma levels were higher than normal reference range in both groups and free protein S plasma levels were low in both groups at baseline and increased over time, Finally, patients in group SOFA > 10 had lower plasminogen levels and Protein C than patients with SOFA <10, which may represent less fibrinolysis activity during a state of hypercoagulability. Conclusion COVID-19 patients have a pronounced hypercoagulability state, characterized by impaired endogenous anticoagulation and decreased fibrinolysis. The magnitude of coagulation abnormalities seems to correlate with the severity of organ dysfunction. The hypercoagulability state of COVID-19 patients was not only detected by ROTEM but it much more complex, where changes were observed on the fibrinolytic and endogenous anticoagulation system.
for the BaSICS investigators and the BRICNet members IMPORTANCE Slower intravenous fluid infusion rates could reduce the formation of tissue edema and organ dysfunction in critically ill patients; however, there are no data to support different infusion rates during fluid challenges for important outcomes such as mortality.OBJECTIVE To determine the effect of a slower infusion rate vs control infusion rate on 90-day survival in patients in the intensive care unit (ICU). DESIGN, SETTING, AND PARTICIPANTS Unblinded randomized factorial clinical trial in 75 ICUs in Brazil, involving 11 052 patients requiring at least 1 fluid challenge and with 1 risk factor for worse outcomes were randomized from May 29, 2017, to March 2, 2020. Follow-up was concluded on October 29, 2020. Patients were randomized to 2 different infusion rates (reported in this article) and 2 different fluid types (balanced fluids or saline, reported separately).INTERVENTIONS Patients were randomized to receive fluid challenges at 2 different infusion rates; 5538 to the slower rate (333 mL/h) and 5514 to the control group (999 mL/h). Patients were also randomized to receive balanced solution or 0.9% saline using a factorial design. MAIN OUTCOMES AND MEASURESThe primary end point was 90-day survival.RESULTS Of all randomized patients, 10 520 (95.2%) were analyzed (mean age, 61.1 years [SD, 17.0 years]; 44.2% were women) after excluding duplicates and consent withdrawals. Patients assigned to the slower rate received a mean of 1162 mL on the first day vs 1252 mL for the control group. By day 90, 1406 of 5276 patients (26.6%) in the slower rate group had died vs 1414 of 5244 (27.0%) in the control group (adjusted hazard ratio, 1.03; 95% CI, 0.96-1.11; P = .46). There was no significant interaction between fluid type and infusion rate (P = .98).CONCLUSIONS AND RELEVANCE Among patients in the intensive care unit requiring fluid challenges, infusing at a slower rate compared with a faster rate did not reduce 90-day mortality. These findings do not support the use of a slower infusion rate.
Lung histopathological findings in fatal pandemic influenza A (H1N1)
Objective: To describe the lung pathological changes in influenza A (H1N1) viral pneumonia. We studied morphological changes, nitro-oxidative stress and the presence of viral proteins in lung tissue. Methods and patients: Light microscopy was used to examine lung tissue from 6 fatal cases of pandemic influenza A (H1N1) viral pneumonia. Fluorescence for oxidized dihydroethydium, nitrotyrosine, inducible NO synthase (NOS2) and human influenza A nucleoprotein (NP) (for analysis under confocal microscopy) was also studied in lung tissue specimens. Results: Age ranged from 15 to 50 years. Three patients were women, and 5 had preexisting medical conditions. Diffuse alveolar damage (DAD) was present in 5 cases (as evidenced by hyaline membrane formation, alveolo-capillary wall thickening and PMN infiltrates), and interstitial fibrosis in one case. In the fluorescence studies there were signs of oxygen radical generation, increased NOS2 protein and protein nitration in lung tissue samples, regardless of the duration of ICU admission. Viral NP was found in lung tissue samples from three patients. Type I pneumocytes and macrophages harbored viral NP, as evidenced by confocal immunofluorescence microscopy. Resultados histopatológicos pulmonares en la gripe A (H1N1) pandémica letalResumen Objetivo: Describir la histopatología pulmonar de pacientes que fallecieron con neumonía por virus de la influenza A (H1N1), el tipo celular infectado por el virus y la presencia de stress oxidativo y nitrosativo. Métodos: Hemos examinado tejido pulmonar de 6 pacientes fallecidos en la UCI con el diagnós-tico de infección por el virus influenza A (H1N1) (15---50 años de edad) mediante (i) microscopía óptica, (ii) microscopia confocal con tinciones específicas para diferentes tipos celulares (aquoporina 5, factor Von Willebrand, proteína D del surfactante), (iii) inmunofluorescencia (IF) para sonda de dihidroetidio oxidado, óxido nítrico sintasa inducible (NOS2), anti-3-nitrotirosina y nucleoproteína (NP) del virus de la influenza A (H1N1). Resultados: (1) En 5 casos se encontró daño alveolar difuso (DAD), evidenciado mediante la observación de membranas hialinas, engrosamiento de la pared alveolo-capilar e infiltración de PMN, asociado con hemorragia intensa en un paciente. Un caso presentó fibrosis intersticial.(2) Se demostró en todos los casos aumento de la inmuno-reactividad para DHE oxidado, NOS2 y 3-nitrotirosina independientemente de la duración de la estancia en la UCI. (3) Se encontró NP viral en tres pacientes. (4) El virus se localiza en los neumocitos tipo I y en macrófagos alveolares. Conclusiones: El tejido pulmonar de pacientes fallecidos con neumonía por virus de la influenza A (H1N1) evidencia hallazgos histológicos compatibles con DAD. El estrés nitro-oxidativo prolongado está presente a pesar del tratamiento antiviral. Las proteínas virales pueden permanecer en el tejido pulmonar durante períodos prolongados de tiempo, albergándose en los macrófagos y neumocitos tipo I.
Objective: To describe the lung pathological changes in influenza A (H1N1) viral pneumonia. We studied morphological changes, nitro-oxidative stress and the presence of viral proteins in lung tissue. Methods and patients: Light microscopy was used to examine lung tissue from 6 fatal cases of pandemic influenza A (H1N1) viral pneumonia. Fluorescence for oxidized dihydroethydium, nitrotyrosine, inducible NO synthase (NOS2) and human influenza A nucleoprotein (NP) (for analysis under confocal microscopy) was also studied in lung tissue specimens. Results: Age ranged from 15 to 50 years. Three patients were women, and 5 had preexisting medical conditions. Diffuse alveolar damage (DAD) was present in 5 cases (as evidenced by hyaline membrane formation, alveolo-capillary wall thickening and PMN infiltrates), and interstitial fibrosis in one case. In the fluorescence studies there were signs of oxygen radical generation, increased NOS2 protein and protein nitration in lung tissue samples, regardless of the duration of ICU admission. Viral NP was found in lung tissue samples from three patients. Type I pneumocytes and macrophages harbored viral NP, as evidenced by confocal immunofluorescence microscopy. Resultados histopatológicos pulmonares en la gripe A (H1N1) pandémica letalResumen Objetivo: Describir la histopatología pulmonar de pacientes que fallecieron con neumonía por virus de la influenza A (H1N1), el tipo celular infectado por el virus y la presencia de stress oxidativo y nitrosativo. Métodos: Hemos examinado tejido pulmonar de 6 pacientes fallecidos en la UCI con el diagnós-tico de infección por el virus influenza A (H1N1) (15---50 años de edad) mediante (i) microscopía óptica, (ii) microscopia confocal con tinciones específicas para diferentes tipos celulares (aquoporina 5, factor Von Willebrand, proteína D del surfactante), (iii) inmunofluorescencia (IF) para sonda de dihidroetidio oxidado, óxido nítrico sintasa inducible (NOS2), anti-3-nitrotirosina y nucleoproteína (NP) del virus de la influenza A (H1N1). Resultados: (1) En 5 casos se encontró daño alveolar difuso (DAD), evidenciado mediante la observación de membranas hialinas, engrosamiento de la pared alveolo-capilar e infiltración de PMN, asociado con hemorragia intensa en un paciente. Un caso presentó fibrosis intersticial.(2) Se demostró en todos los casos aumento de la inmuno-reactividad para DHE oxidado, NOS2 y 3-nitrotirosina independientemente de la duración de la estancia en la UCI. (3) Se encontró NP viral en tres pacientes. (4) El virus se localiza en los neumocitos tipo I y en macrófagos alveolares. Conclusiones: El tejido pulmonar de pacientes fallecidos con neumonía por virus de la influenza A (H1N1) evidencia hallazgos histológicos compatibles con DAD. El estrés nitro-oxidativo prolongado está presente a pesar del tratamiento antiviral. Las proteínas virales pueden permanecer en el tejido pulmonar durante períodos prolongados de tiempo, albergándose en los macrófagos y neumocitos tipo I.
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