RESUMO
In some dermal diseases with evident skin dehydration and desquamation, the natural ratio of CER[NP]:CER[AP] is altered in the extracellular matrix of the stratum corneum by increasing the concentration of CER[AP]. The extracellular matrix of the stratum corneum is composed of several stacked lipid bilayers. Molecular dynamics simulations were used to investigate the molecular nanostructure of CER[NP], CER[AP], cholesterol and lignoceric acid models of the extracellular matrix of the stratum corneum with a nativelike CER[NP]:CER[AP] 2:1 ratio and a CER[NP]:CER[AP] ratio of 1:2. Despite the very minor chemical difference between CER[NP] and CER[AP], which is only a single OH group, it was possible to observe differences between the structural influence of the two ceramides. In the models with 1:2 ratio, the higher CER[AP] content leads to a larger inclination of the acyl chains and a smaller overlap in the lamellar midplane, with a small increase of the repeat distance compared to the model with higher CER[NP] concentration. Because CER[AP] forms more H-bonds than CER[NP], the total number of hydrogen bonds in the headgroup region is larger in the models with higher CER[AP] concentration, reducing the mobility of the lipids towards the centre of the bilayer and resulting in less overlap and increased tilt angles.
Assuntos
Epiderme , Simulação de Dinâmica Molecular , Epiderme/química , Pele/química , Bicamadas Lipídicas/química , Ceramidas/químicaRESUMO
BACKGROUND: Analysis of respiratory mechanics during mechanical ventilation (MV) is able to estimate resistive, elastic and inertial components of the working pressure of the respiratory system. Our aim was to discriminate the components of the working pressure of the respiratory system in infants on MV with severe bronchiolitis admitted to two PICU's. METHODS: Infants younger than 1 year old with acute respiratory failure caused by severe bronchiolitis underwent neuromuscular blockade, tracheal intubation and volume controlled MV. Shortly after intubation studies of pulmonary mechanics were performed using inspiratory and expiratory breath hold. The maximum inspiratory and expiratory flow (QI and QE) as well as peak inspiratory (PIP), plateau (PPL) and total expiratory pressures (tPEEP) were measured. Inspiratory and expiratory resistances (RawI and RawE) and Time Constants (KTI and KTE) were calculated. RESULTS: We included 16 patients, of median age 2.5 (1-5.8) months. Bronchiolitis due to respiratory syncytial virus was the main etiology (93.8%) and 31.3% had comorbidities. Measured respiratory pressures were PIP 29 (26-31), PPL 24 (20-26), tPEEP 9 [8-11] cmH2O. Elastic component of the working pressure was significantly higher than resistive and both higher than threshold (tPEEP - PEEP) (P < 0.01). QI was significantly lower than QE [5 (4.27-6.75) v/s 16.5 (12-23.8) L/min. RawI and RawE were 38.8 (32-53) and 40.5 (22-55) cmH2O/L/s; KTI and KTE [0.18 (0.12-0.30) v/s 0.18 (0.13-0.22) s], and KTI:KTE ratio was 1:1.04 (1:0.59-1.42). CONCLUSIONS: Analysis of respiratory mechanics of infants with severe bronchiolitis receiving MV shows that the elastic component of the working pressure of the respiratory system is the most important. The elastic and resistive components in conjunction with flow profile are characteristic of restrictive diseases. A better understanding of lung mechanics in this group of patients may lead to change the traditional ventilatory approach to severe bronchiolitis.
Assuntos
Bronquiolite/terapia , Pulmão/fisiopatologia , Respiração Artificial , Mecânica Respiratória , Feminino , Humanos , Lactente , Masculino , Estudos Prospectivos , Trabalho RespiratórioRESUMO
The Acute Respiratory Distress Syndrome (ARDS) is a life-threatening disease with a high mortality rate. In children it represents a diagnostic and therapeutic challenge. The primary feature in the development of ARDS is the non-cardiogenic pulmonary edema resulting from a disproportionate inflammatory response that increases the blood-gas barrier permeability. There is strong evidence that aninappropriate ventilatory support may induce lung injury, organ dysfunction and increasing mortality.The aim of this article is to review current concepts related to the diagnostic of pediatric ARDS, its pathophysiologic mechanisms, ventilator induced lung injury and a brief description of rescue therapies.
El Síndrome de Distrés Respiratorio Agudo (SDRA) es una entidad grave de elevada mortalidad, siendo en pediatría un desafío diagnóstico y terapéutico. La característica primaria del SDRA es el desarrollo de edema pulmonar no cardiogénico debido a una respuesta inflamatoria excesiva que aumenta la permeabilidad de la barrera sangre-gas. Existe una fuerte evidencia de que una estrategia inadecuada de soporte ventilatorio puede aumentar el daño pulmonar, inducir disfunciones de َrganos a distancia y aumentar la mortalidad.El presente artيculo pretende revisar conceptos actuales relacionados al diagnóstico de SDRA pediátrico, mecanismos fisiopatológicos, daño pulmonar inducido por la ventilación mecánica y una breve revisión de las terapias de rescate.