Plasma Levels of Mid-Regional Proadrenomedullin Accurately Identify H1N1pdm09 Influenza Virus Patients with Risk of Intensive Care Admission and Mortality in the Emergency Department.

Early identification of severe viral pneumonia in influenza virus A (H1N1pdm09) patients is extremely important for prompt admission to the ICU. The objective is to evaluate the usefulness of MR-proadrenomedullin (MR-proADM) compared to C reactive protein (CRP), procalcitonin (PCT), and ferritin in the prognosis of influenza A pneumonia. This prospective, observational, multicenter study included one hundred thirteen patients with confirmed influenza virus A (H1N1pdm09) admitted to an Emergency Department and ICUs of six hospitals in Spain. Measurements and Main Results: one-hundred thirteen patients with confirmed influenza virus A (H1N1pdm09) were enrolled. Seventy-five subjects (mortality 29.3%) with severe pneumonia caused by influenza A H1N1pdm09 virus (H1N1vIPN) were compared with 38 controls (CG).The median MR-proADM levels at hospital admission were 1.2 nmol/L (IQR (0.8-2.6) vs. 0.5 nmol/L (IQR 0.2-0.9) in the CG (p = 0.01), and PCT levels were 0.43 µg/L (IQR 0.2-1.2) in the H1N1vIPN group and 0.1 µg/L (IQR 0.1-0.2) in the CG (p < 0.01). CRP levels at admission were 15.5 mg/dL(IQR 9.2-24.9) in H1N1vIPN and 8.6 mg/dL(IQR 3-17.3) in the CG (p < 0.01). Ferritin levels at admission were 558.1 ng/mL(IQR 180-1880) in H1N1vIPN and 167.7 ng/mL(IQR 34.8-292.9) in the CG (p < 0.01). A breakpoint for hospital admission of MR-proADM of 1.1 nmol/L showed a sensitivity of 55% and a specificity of 90% (AUC-ROC0.822). Non-survivors showed higher MR-proADM levels: median of 2.5 nmol/L vs. 0.9 nmol/L among survivors (p < 0.01). PCT, CRP, and ferritin levels also showed significant differences in predicting mortality. The MR-proADM AUC-ROC for mortality was 0.853 (p < 0.01). In a Cox proportional hazards model, MR-proADM levels > 1.2 nmol/L at hospital admission were significant predictive factors for ICU and 90-day mortality (HR: 1.3). Conclusions: the initial MR-proADM, ferritin, CRP, and PCT levels effectively determine adverse outcomes and risk of ICU admission and mortality in patients with influenza virus pneumonia. MR-proADM has the highest potency for survival prediction.

Efecto neuroprotector del sevoflurano en anestesia general / Neuroprotective effect of sevoflurane in general anaesthesia

Introducción y objetivo: El objetivo fue evaluar el daño cerebral producido por el sevoflurano inhalado mediante la determinación de la proteína S100B sérica antes y después de una exposición a este fármaco como único agente anestésico. Pacientes y método: Se incluyeron pacientes pediátricos sometidos a resonancia magnética nuclear bajo anestesia general con sevoflurano inhalado a dosis baja. A todos los pacientes se les extrajo una muestra de sangre venosa, antes (muestra basal) y después de la anestesia general (muestra postexposición). Se determinó la concentración de la proteína S100B sérica en la muestra basal (S100Bb) y en la muestra postexposición (S100Bp). Resultados: Se incluyeron 72 pacientes entre 2 y 13 años (mediana = 6), 28 niños y 44 niñas. Los valores de S100Bp (mediana = 66,5 ng/l) fueron significativamente inferiores (p = 0,0059) a los de S100Bb (mediana = 84,0 ng/l). La mediana de las diferencias entre S100Bp y S100Bb resultó −11,0 ng/l. Conclusiones: El sevoflurano inhalado a dosis bajas produce un descenso de la proteína S100B sérica, por lo que este fármaco podría tener un efecto neuroprotector a nivel del sistema nervioso central (AU)

Introduction and objective: The aim of this study was to evaluate the brain damage caused by inhaled sevoflurane, by determining the concentration of serum S100B protein before and after the exposure to this drug as the only anaesthetic agent. Patients and method: Paediatric patients undergoing general anaesthesia for the conduct of a nuclear magnetic resonance were included in the study. A venous blood sample was taken from each patient before (basal sample) and after (post-exposure sample) administering the general anaesthesia. The concentration of serum S100B protein was determined in the basal (S100Bb) and post-exposure sample (S100Bp). Results: A total of 72 patients were included in the study, with a mean patient age of 2 to 13 years (median = 6), 28 males and 44 females. S100Bp values (median = 66.5 ng/L) were significantly lower (P = .0059) than those of S100Bb (median = 84.0 ng/L). The median of the difference between S100Bp and S100Bb was −11.0 ng/L. Conclusions: Inhaled sevoflurane at low doses causes a decrease of serum S100B protein levels, hence, this drug could have a neuroprotective effect in the central nervous system (AU)

Neuroprotective effect of sevoflurane in general anaesthesia. / Efecto neuroprotector del sevoflurano en anestesia general.

INTRODUCTION AND OBJECTIVE: The aim of this study was to evaluate the brain damage caused by inhaled sevoflurane, by determining the concentration of serum S100B protein before and after the exposure to this drug as the only anaesthetic agent. PATIENTS AND METHOD: Paediatric patients undergoing general anaesthesia for the conduct of a nuclear magnetic resonance were included in the study. A venous blood sample was taken from each patient before (basal sample) and after (post-exposure sample) administering the general anaesthesia. The concentration of serum S100B protein was determined in the basal (S100Bb) and post-exposure sample (S100Bp). RESULTS: A total of 72 patients were included in the study, with a mean patient age of 2 to 13 years (median=6), 28 males and 44 females. S100Bp values (median=66.5ng/L) were significantly lower (P=.0059) than those of S100Bb (median=84.0ng/L). The median of the difference between S100Bp and S100Bb was -11.0ng/L. CONCLUSIONS: Inhaled sevoflurane at low doses causes a decrease of serum S100B protein levels, hence, this drug could have a neuroprotective effect in the central nervous system.

New role of biomarkers: mid-regional pro-adrenomedullin, the biomarker of organ failure.

Mid-regional pro-adrenomedullin (MR-proADM) has a good biomarker profile: its half-life is several hours, and its plasma concentrations can be determined in clinical practice, it is essentially irrelevant, but proportionally represents the levels and activity of adrenomedullin (ADM). ADM synthesis is widely distributed in tissues, including bone, adrenal cortex, kidney, lung, blood vessels and heart. Its fundamental biological effects include vasodilator, positive inotropic, diuretic, natriuretic and bronchodilator. It has been described high levels in septic patients, interacting directly with the relaxation of vascular tone, triggering hypotension of these patients. It is also found high levels in other diseases such as hypertension, heart failure, respiratory failure, renal failure, cirrhosis and cancer. MR-proADM has been identified as a prognostic marker, stratifying the mortality risk in patients with sepsis in emergency department (ED) and ICU. Evolutionary MR-proADM levels and clearance marker to the 2nd-5th days of admission help to determine the poor performance and the risk of mortality in patients with severe sepsis admitted to the ICU. The MR-proADM levels are more effective than procalcitonin (PCT) and C-reactive protein (CRP) levels to determine an unfavorable outcome and the risk of mortality in patients with sepsis admitted to the ICU. It has also proved useful in patients diagnosed with organ dysfunction of infectious etiology. MR-proADM levels are independent of the germ conversely it is related to the magnitude of organ failure and therefore severity. We consider advisable incorporating the MR-proADM the panel of biomarkers necessary for the diagnosis and treatment of critically ill patients admitted to the ICU with severe sepsis. The combined PCT and MR-proADM levels could represent a valid tool in the clinical practice to timely identify patients with bacterial infections and guide the diagnosis and treatment of sepsis and septic shock.

Daño cerebral postanestesia general / Brain damage after general anesthesia

Fundamento y objetivo: La proteína S100B es un marcador sérico de daño cerebral. El objetivo fue evaluar el daño cerebral producido por la anestesia general mediante la determinación de la concentración de proteína S100B sérica antes y después de la anestesia general. Pacientes y método: Se incluyeron pacientes con intervención quirúrgica programada de amigdalectomía por hipertrofia amigdalar. En la consulta de preanestesia se extrajo una muestra de sangre venosa (muestra basal). Los pacientes fueron sometidos a anestesia general utilizando los siguientes fármacos anestésicos intravenosos: midazolam, fentanilo y propofol; y sevoflurano inhalado. Al finalizar la intervención quirúrgica y con el paciente aún en quirófano, se extrajo una segunda muestra de sangre venosa (muestra postexposición). Se determinó en suero la concentración de la proteína S100B en la muestra basal (S100Bb) y en la muestra postexposición (S100Bp), mediante inmunoanálisis de electroquimioluminiscencia en el MODULAR E-170 (Roche Diagnostics). Resultados: Se incluyeron 76 pacientes, 46 varones y 30 hembras, con edades entre 3 y 14 años (mediana 5 años). En todos los pacientes, los niveles de proteína S100B sérica aumentaron tras la anestesia general. Los valores obtenidos de S100Bp (mediana 164,0 ng/l) fueron significativamente mayores que los obtenidos de S100Bb (mediana 94,5 ng/l). La mediana de la diferencia entre S100Bp y S100Bb fue de 58,0 ng/l. Mediante el test de Wilcoxon se encontraron diferencias estadísticamente significativas entre S100Bb y S100Bp (p < 0,0001). Conclusiones: La concentración de proteína S100B sérica aumentó significativamente tras la anestesia general. Esto indica que la anestesia general puede producir daño cerebral (AU)

Background and objective: S100B protein is a serum marker of cerebral damage. The objective was to evaluate the brain damage caused by general anaesthesia, by determining the concentration of serum S100B protein before and after of general anaesthesia. Patients and method: Patients with chronic adenotonsillar hypertrophy and indications for tonsillectomy were included. A venous blood sample was taken from the patients before general anaesthesia (basal sample). The patients were anaesthetised using the following intravenous anaesthetic drugs: midazolam, fentanyl and propofol; and inhaled sevoflurane. A second venous blood sample (postoperative sample) was taken from patients after the surgery, in the operating room. The concentration of serum S100B protein was determined in the basal sample (S100Bb) and postoperative sample (S100Bp) by immunoassay electro-chemiluminescence in MODULAR E-170 (Roche Diagnostics). Results: Seventy-six patients were included, 46 males and 30 females, aged between 3 to 14 (median 5 years). In all the patients, serum S100B protein levels increased after general anaesthesia. The values of S100Bp (median 164.0 ng/L) were significantly higher than the values of S100Bb (median 94.5 ng/L). The median of the difference between S100Bp and S100Bb was 58.0 ng/L. There were statistically significant differences between S100Bb and S100Bp using the Wilcoxon test (P < .0001). Conclusions: The concentration of serum S100B protein increased significantly after general anaesthesia. This indicates that general anaesthesia may cause brain damage (AU)

[Brain damage after general anesthesia]. / Daño cerebral postanestesia general.

BACKGROUND AND OBJECTIVE: S100B protein is a serum marker of cerebral damage. The objective was to evaluate the brain damage caused by general anaesthesia, by determining the concentration of serum S100B protein before and after of general anaesthesia. PATIENTS AND METHOD: Patients with chronic adenotonsillar hypertrophy and indications for tonsillectomy were included. A venous blood sample was taken from the patients before general anaesthesia (basal sample). The patients were anaesthetised using the following intravenous anaesthetic drugs: midazolam, fentanyl and propofol; and inhaled sevoflurane. A second venous blood sample (postoperative sample) was taken from patients after the surgery, in the operating room. The concentration of serum S100B protein was determined in the basal sample (S100Bb) and postoperative sample (S100Bp) by immunoassay electro-chemiluminescence in MODULAR E-170 (Roche Diagnostics). RESULTS: Seventy-six patients were included, 46 males and 30 females, aged between 3 to 14 (median 5 years). In all the patients, serum S100B protein levels increased after general anaesthesia. The values of S100Bp (median 164.0 ng/L) were significantly higher than the values of S100Bb (median 94.5 ng/L). The median of the difference between S100Bp and S100Bb was 58.0 ng/L. There were statistically significant differences between S100Bb and S100Bp using the Wilcoxon test (P<.0001). CONCLUSIONS: The concentration of serum S100B protein increased significantly after general anaesthesia. This indicates that general anaesthesia may cause brain damage.