Étude multicentrique sur les stratégies de ventilation mécanique employées chez les enfants avec un œdème pulmonaire lésionnel

Santschi, Miriam

08 1900

Des études adultes sur l’œdème pulmonaire lésionnel et le Syndrome de Détresse Respiratoire Aiguë ont mené à l’établissement de recommandations sur les stratégies de ventilation mécanique à employer chez ces patients. Cependant, il n’est pas clair si les recommandations adultes sont également bénéfiques pour l’enfant. Objectif Décrire les stratégies de ventilation mécanique employées chez les enfants atteints d’un œdème pulmonaire lésionnel. Méthodes Étude épidémiologique transversale tenue dans 59 unités de Soins Intensifs Pédiatriques de 12 pays en Amérique du Nord et en Europe. Six jours d’étude ont eu lieu entre juin et novembre 2007. Les enfants atteints d’un œdème pulmonaire lésionnel étaient inclus et des données sur la sévérité de leur maladie, les paramètres de ventilation mécanique et les thérapies adjuvantes employées ont été recueillies. Résultats Des 3823 enfants dépistés, 414 (10.8%) avaient un œdème pulmonaire lésionnel et 165 (40%) ont été inclus dans l’étude (124 étaient sous ventilation mécanique conventionnelle, 27 sous ventilation à haute fréquence par oscillation et 14 sous ventilation non invasive). Dans le groupe sous ventilation conventionnelle, 43.5% étaient ventilés avec un mode contrôlé à pression, le volume courant moyen était de 8.3±3.3 ml/kg et l’utilisation de la PEP et FiO2 était hétérogène. Conclusions Cette étude démontre une hétérogénéité dans les stratégies de ventilation mécanique employées chez les enfants souffrant d’un œdème pulmonaire lésionnel. Celle-ci pourrait être en partie reliée à la robustesse des critères diagnostiques actuellement utilisés pour définir l’ALI/SDRA. Une évaluation rigoureuse de ces stratégies est nécessaire pour guider la standardisation des soins et optimiser l’issue de ces patients. / Acute Lung Injury and Acute Respiratory Distress Syndrome are life-threatening conditions frequently leading to respiratory support with mechanical ventilation. Studies on mechanical ventilation strategies in adult patients have led to lung protective ventilation recommendations. However, there are few pediatric clinical trials on optimal mechanical ventilation management in Acute Lung Injury and it is still unclear if strategies studied in adults are equally beneficial to children. Objective Describe mechanical ventilation strategies in Acute Lung Injury in children. Methods Cross-sectional study for six 24-hour periods from June to November 2007 across 59 Pediatric Intensive Care Units in 12 countries in North America and Europe. We identified children meeting Acute Lung Injury criteria and collected detailed information on illness severity, mechanical ventilation support and use of adjunctive therapies. Results Of 3823 patients screened, 414 (10.8%) were diagnosed with Acute Lung Injury and 165 were included in the study (124 received conventional mechanical ventilation, 27 high frequency oscillatory ventilation, 14 non-invasive mechanical ventilation). In the conventional mechanical ventilation group, 43.5% were ventilated in a pressure control mode, the mean tidal volume was 8.3±3.3 ml/kg and there was no clear relationship between PEEP and FiO2 delivery. Conclusions Our study reveals inconsistent mechanical ventilation practice and use of adjunctive therapies in children with Acute Lung Injury. Rigorous evaluation of ventilator management strategies in children with an Acute Lung Injury are urgently needed to guide standardization of care and optimize clinical outcomes.

Œdème pulmonaire lésionnel

Ventilation mécanique

Enfant

Épidémiologie

Soins Intensifs Pédiatriques

Acute Lung Injury

Respiratory Distress Syndrome

Mechanical Ventilation

Child

Epidemiology

Pediatric Intensive Care

Évaluation, surveillance et soutien de la fonction respiratoire chez des veaux clonés en période néonatale

Brisville, Anne-Claire

08 1900

Une morbidité et une mortalité néonatales élevées limitent l’efficacité du clonage somatique chez les bovins. Des malformations myoarthrosquelettiques, des anomalies ombilicales, des problèmes respiratoires et de la faiblesse ont été fréquemment observés chez les veaux clonés nouveaux-nés. Cette étude rétrospective porte sur 31 veaux clonés. Ses objectifs étaient de décrire les problèmes respiratoires rencontrés, leur évolution au cours du temps, les traitements instaurés pour soutenir la fonction respiratoire et la réponse aux traitements. Vingt-deux veaux ont souffert de problèmes respiratoires. La tachypnée, l’hypoxémie et l’hypercapnie sont les signes cliniques les plus fréquemment observés. L’analyse des gaz sanguins a été un outil essentiel dans le diagnostic et le suivi de la fonction respiratoire. La radiographie a permis une évaluation globale du poumon. L’oxygénothérapie intranasale et la ventilation mécanique ont permis de limiter la mortalité due à une insuffisance respiratoire à 18% (4/22). Cette étude a permis d’émettre des hypothèses quant à l’origine des problèmes respiratoires chez les veaux clonés. Plus d’une maladie semblent affecter les veaux clonés. La déficience en surfactant, l’hypertension pulmonaire persistante et le retard de résorption du fluide pulmonaire figurent parmi les entités pathologiques les plus probables. / High morbidity and mortality decrease the efficiency of somatic cell nuclear transfer. The main abnormalities observed in neonatal cloned calves are skeletal malformations, enlarged umbilical vessels, respiratory problems and weakness. This retrospective study involved 31 cloned calves. The objectives of this study were to describe the respiratory problems suffered by cloned calves during neonatal period, to assess their evolution, and to determine the possible causes. Secondary objectives were to describe the techniques used to assess and support respiratory function and the calves’ response. Respiratory problems affected 22 calves. Tachypnea, hypoxemia and hypercapnia were the most frequently observed signs. Arterial blood gas analyses and chest radiographs were precious to identify and assess respiratory problems. Intranasal oxygen and mechanical ventilation were efficient to limit mortality due to respiratory failure to 18% (4/22). It is plausible that more than one disease affect cloned calves. Delayed resorption of pulmonary fluid, persistent pulmonary hypertension and surfactant deficiency, or a combination of these factors, are among the most probable pathological entities.

veau

clonage

néonatal

problèmes respiratoires

oxygénothérapie

ventilation mécanique

gaz sanguins

calf

cloning

neonatal

respiratory problems

oxygen therapy

mechanical ventilation

blood gas analyses

Interaction entre ventilation mécanique et traumatisme à la moelle épinière : réponses inflammatoires pulmonaires et médullaires

Truflandier, Karine

09 1900

Le traumatisme de la moelle épinière est à l’origine d’une inflammation locale importante caractérisée par l’augmentation massive des cellules inflammatoires et la présence de réactions oxydatives. Cette inflammation locale peut déclencher une réponse inflammatoire systémique par voie hématogène. Au niveau cervical, les lésions médullaires peuvent entraîner des faiblesses ou la paralysie des muscles respiratoires. Le patient, qui ne peut plus respirer de façon autonome, doit avoir recours à un support respiratoire. Bien que la ventilation mécanique soit la thérapie traditionnellement appliquée aux blessés médullaires souffrant d’insuffisance respiratoire, les études ont démontré qu’elle pouvait contribuer à promouvoir une réponse inflammatoire ainsi que des dommages pulmonaires. L’interaction entre le traumatisme médullaire et la ventilation mécanique, indispensable au maintien de l’équilibre des échanges respiratoires, est inconnue à ce jour. En voulant protéger les tissus, cellules et organes, l’organisme met en œuvre toute une panoplie de réponses inflammatoires à différents endroits. Nous pensons que ces réponses peuvent être altérées via l’interaction entre ce traumatisme et cette ventilation mécanique, sous l’influence de la principale source cellulaire de cytokines pour la défense de l’hôte, le macrophage, récemment classé en deux phénotypes principaux: 1) l’activation classique de type M1 et 2) l’activation alternative de type M2. Le phénotype M1 est conduit par le facteur GM-CSF et induit par l’interféron IFN-ɣ ainsi que le lipopolysaccharide. Le phénotype M2 quant à lui, est conduit par le facteur M-CSF et induit par les interleukines IL-4, IL-13 ou IL-21. M1 relâche principalement IL-1β, IL-6, TNF-α et MIP-1α tandis que M2 principalement IL-10 et MCP-1. Toutefois, nous ignorons actuellement par quel type d’activation se manifestera cette réponse immunitaire et si l’application de support respiratoire pourrait entraîner un risque inflammatoire additionnel au site du traumatisme. Nous ignorons également si la ventilation mécanique affecterait, à distance, les tissus de la moelle épinière via une inflammation systémique et amplifierait alors le dommage initial. Il n’existe pas à ce jour, de thérapie qui ait montré d’effet bénéfique réel envers une récupération fonctionnelle des patients blessés médullaires. Il paraît donc essentiel de déterminer si la ventilation mécanique peut moduler l’inflammation post-traumatique à la fois au niveau pulmonaire et au site de la lésion. Ce travail visait à caractériser les liens entre l’inflammation issue du traumatisme médullaire et celle issue de la ventilation, dans le but de fournir une meilleure compréhension des mécanismes inflammatoires activés dans ce contexte. L’étude a été menée sur un modèle animal. Elle consistait à évaluer : 1) si le traumatisme médullaire influençait les réponses inflammatoires pulmonaires induites par la ventilation mécanique, y compris le phénotype des macrophages alvéolaires et 2) si la ventilation pouvait altérer à distance, les tissus de la moelle épinière. L’impact de la blessure médullaire sur l’inflammation pulmonaire et locale, induite par la ventilation fut interprété grâce à l’analyse des cellules inflammatoires dans les lavages broncho-alvéolaires et dans les tissus prélevés à l’endroit de la blessure après 24 heures. Ces analyses ont démontré un profil spécifique des cytokines pulmonaires et médullaires. Elles ont révélé que la ventilation mécanique a engendré un environnement pro-inflammatoire en faveur d’un phénotype M1 chez les animaux ayant bénéficié de la thérapie respiratoire. Inversement, l’atteinte thoracique chez les animaux sans ventilation, a montré qu’une réponse immunitaire avait été activée en faveur d’un environnement anti-inflammatoire de phénotype M2. La lésion cervicale quant à elle a induit un profil de cytokines différent et les réponses au stress oxydatif dans le poumon induites par la ventilation ont été réduites significativement. De plus, une lésion médullaire a augmenté l’expression d’IL-6 et la ventilation a diminué l’IL-1β et augmenté le TNF-α dans les tissus de la moelle. Finalement, ces données ont fourni les premières évidences que la ventilation a induit d’avantage à un phénotype pulmonaire M1 et que le traumatisme médullaire a impacté spécifiquement les réponses inflammatoires et oxydatives dans le poumon. La ventilation a contribué non seulement à distance à une inflammation des tissus médullaires lésés mais aussi des tissus sains. / Spinal cord injury is a major cause of excessive local inflammation characterized by a massive increase in inflammatory cells and oxidative reactions. It can also enhance systemic inflammatory response through the bloodstream. Cervical spinal cord lesions can result in respiratory failure due to weakness or paralysis of respiratory muscles and may lead a patient to require respiratory support. Although mechanical ventilation is the current therapy of choice applied to injured patients for respiratory insufficiency, evidence has shown that it can directly contribute to inflammatory response and lung damage. Currently, interplay between spinal cord injury and mechanical ventilation, essential to maintain the balance of respiratory exchanges, is unknown. To protect tissues, cells and organs, the body implements a wide range of inflammatory responses in various locations. We believe that the immune response can be modulated by this interplay under the influence of the main cellular source of cytokines for host defense; the macrophage. Macrophages have recently been classified into two phenotypes: 1) classical activation (M1) and 2) alternative activation (M2) and, as of today, it is unknown through which activation profile the immune response manifests itself. M1 phenotype is GM-CSF-driven, and also induced or primed by interferon-ɣ and lipopolysaccharide. In contrast, M2 phenotype is M-CSF-driven and induced also by IL-4 and IL-13 or IL-21. M1 release mainly IL-1β, IL-6, TNF-α and MIP-1α whereas M2 produce mainly IL-10 and MCP-1.The application of respiratory support may lead to an additional inflammatory risk to the injury site that may affect distal spinal cord tissues via the systemic inflammatory responses thus amplifying damage to the spine. There is currently no therapy which has shown beneficial effects towards a real functional recovery of spinal cord injury. It seems important to determine if and how mechanical ventilation may affect the post-traumatic inflammation in both lung and at injury site. This work was aimed to better characterize the relationship between inflammation induced by a spinal cord injury and ventilation thus providing a deeper understanding of the activated inflammatory mechanisms in this context. The study was conducted in an animal model and we wanted to evaluate: 1) if spinal cord injury impacts lung inflammatory responses induced by mechanical ventilation including alveolar macrophage phenotype and 2) determine whether mechanical ventilation may alter inflammatory responses of distal spine tissues. Interplay between spinal cord injury and inflammation-induced by mechanical ventilation on lung and local spine was interpreted through analyses of inflammatory cells in broncho-alveolar lavages and spinal cord tissues after 24 hours. These analyses have shown a specific cytokines profiles both in the lung and at local site of injury. It also revealed that the application of mechanical ventilation induced a pro-inflammatory environment favoring the M1 phenotype. Conversely, a thoracic spinal cord injury in non-ventilated animals, showed that an immune response had been activated favoring an anti-inflammatory environment M2 phenotype in the lung. Cervical lesion also induced a different cytokine profile and oxidative stress responses in the lung induced by ventilation have been reduced significantly. In addition, spinal cord injury induced pro-inflammatory cytokines IL-6 expression and mechanical ventilation has been decreased IL-1β and increased TNF-α in spine tissues. In retrospect, this work provide the first evidence that ventilation induced a predominant M1 phenotype and that spinal cord injury modulated specific inflammatory and oxidative stress responses in the lung. In addition, mechanical ventilation not only contributed to local inflammation in distal spinal injured tissues but also in healthy tissues.

Ventilation mécanique

Traumatisme de la moelle épinière

Interaction

Inflammation

Cytokines

Macrophages

Phénotype

Stress oxydatif

mechanical ventilation

Spinal cord injury

Interaction

Inflammation

Cytokines

Macrophages

Phenotype

Oxidative Stress

L'activité tonique diaphragmatique chez les enfants avec et sans support respiratoire

Larouche, Alexandrine

08 1900

Introduction : Les nourrissons, vu la grande compliance de leur cage thoracique, doivent maintenir activement leur volume pulmonaire de fin d’expiration (VPFE). Ceci se fait par interruption précoce de l’expiration, et par le freinage expiratoire au niveau laryngé et par la persistance de la contraction des muscles inspiratoires. Chez les nourrissons ventilés mécaniquement, notre équipe a montré que le diaphragme est activé jusqu’à la fin de l’expiration (activité tonique). Il n’est pas clair si cette activité tonique diaphragmatique compense pour l’absence de freinage laryngé liée à l’intubation endotrachéale. Objectif : Notre objectif est de déterminer si l’activité tonique diaphragmatique persiste après l’extubation chez les nourrissons et si elle peut être observée chez les enfants plus âgés. Méthode : Ceci est une étude observationnelle longitudinale prospective de patients âgés de 1 semaine à 18 ans admis aux soins intensifs pédiatriques (SIP), ventilés mécaniquement pour >24 heures et avec consentement parental. L’activité électrique du diaphragme (AEdi) a été enregistrée à l’aide d’une sonde nasogastrique spécifique à 4 moments durant le séjour aux SIP : en phase aigüe, pré et post-extubation et au congé. L’AEdi a été analysée de façon semi-automatique. L’AEdi tonique a été définie comme l’AEdi durant le dernier quartile de l’expiration. Résultats : 55 patients avec un âge médian de 10 mois (écart interquartile: 1-48) ont été étudiés. Chez les nourrissons (<1an, n=28), l’AEdi tonique en pourcentage de l’activité inspiratoire était de 48% (30-56) en phase aigüe, 38% (25-44) pré-extubation, 28% (17-42) post-extubation et 33% (22-43) au congé des SIP (p<0.05, ANOVA, avec différence significative entre enregistrements 1 et 3-4). Aucun changement significatif n’a été observé pré et post-extubation. L’AEdi tonique chez les patients plus âgés (>1an, n=27) était négligeable en phases de respiration normale (0.6mcv). Par contre, une AEdi tonique significative (>1mcv et >10%) a été observée à au moins un moment durant le séjour de 10 (37%) patients. La bronchiolite est le seul facteur indépendant associé à l’activité tonique diaphragmatique. Conclusion : Chez les nourrissons, l’AEdi tonique persiste après l’extubation et elle peut être réactivée dans certaines situations pathologiques chez les enfants plus âgés. Elle semble être un indicateur de l’effort du patient pour maintenir son VPFE. D’autres études devraient être menées afin de déterminer si la surveillance de l’AEdi tonique pourrait faciliter la détection de situations de ventilation inappropriée. / Background: Infants have to actively maintain their end expiratory lung volume (EELV) due to their high rib cage compliance. Mechanisms such as high respiratory rate, short expiratory time and laryngeal braking are implicated. In mechanically ventilated infants, the diaphragm stays activated until the end of expiration (tonic activity), contributing to EELV maintenance. It is unclear whether tonic activity compensates for the lack of laryngeal braking due to intubation or if it is normally present. Objective: To determine if tonic diaphragm activity remains after extubation in infants, and if it can be observed in older children. Methods: Prospective observational study of pediatric patients 1 week to 18 years-old ventilated for >24 hr with parental consent. Diaphragm electrical activity (EAdi) was recorded using a specific nasogastric catheter during four periods: (i) the acute phase, (ii) pre-extubation, (iii) postextubation, and (iv) at PICU discharge. EADi was analyzed in a semi-automatic manner. Tonic EAdi was defined as the EAdi in the last quartile of expiration. Results: Fifty-five patients, median age 10 months (Interquartile range: 1–48) were studied. In infants (<1 year, n=28), tonic EAdi as a percentage of inspiratory activity was 48% (30-56) in acute phase, 38% (25-44) pre-extubation, 28% (17-42) post-extubation et 33% (22-43) at PICU discharge (p<0.05, ANOVA, with statistically significant difference between recordings 1 and 3-4). No significant change was observed between pre- and post-extubation periods. In older patients (n=27), tonic activity was negligible as a whole (0.6mcv). However, significant tonic EAdi (>1mcv and >10%) was observed in 10 patients (37%). Bronchiolitis was the only independent factor associated with tonic EAdi. Conclusions: In infants, tonic EAdi remains involved in ventilatory control after extubation and restoration of laryngeal braking. Tonic EAdi can be reactivated in older patients. The interest of tonic EAdi as a tool to titrate mechanical ventilation warrants further evaluation.

Ventilation mécanique

Soins Intensifs pédiatriques

Fonction diaphragmatique

Expiration

Volume de fin d'expiration

Pression positive de fin d'expiration

Mechanical ventilation

Pediatric intensive care

Diaphragm function

End expiratory lung volume

Positive end expiratory pressure

Estudo do funcionamento da ventilação assistida proporcional plus em um sistema pulmonar mecânico / Study of the functioning of the proportional assist ventilation plus in a mechanical lung model

Couto, Lara Poletto

13 August 2012

INTRODUÇÃO: Ventilação assistida proporcional plus é um novo conceito de suporte ventilatório assistido que visa atuar de acordo com os níveis de esforço inspiratório, mecânica respiratória e níveis de porcentagem de apoio. A complexa interação entre esses fatores que comandam a sua função é de difícil interpretação na prática clínica. O objetivo deste estudo é provocar alterações na complacência, resistência e esforços inspiratórios, em um sistema pulmonar mecânico, para entender o funcionamento e as respostas desse modo nas suas diferentes porcentagens de apoio. MÉTODOS: No Laboratório de Ventilação Mecânica da Disciplina de Pneumologia da Faculdade de Medicina da Universidade de São Paulo, um ventilador Interplus da marca Intermed foi conectado em um pulmão mecânico da marca Michigan Instruments Inc, com a finalidade de gerar diferentes níveis de esforços inspiratórios e para disparar o ventilador Puritan-Bennett 840 da marca Covidien. Os volumes correntes expirados foram medidos e posteriormente comparados através do método estatístico ANOVA two-way, para 10 níveis de porcentagem de apoio (de 5% a 95%), 3 níveis de complacência (50, 100 e 150 mL/cmH2O), 3 níveis de resistência (5, 20 e 50 cmH2O/L/s) e 4 níveis de esforço inspiratório (-2, -5, -8 e -15 cmH2O). RESULTADOS: Trezentas e sessenta medidas de volume corrente expirado foram obtidas. Os volumes correntes expirados aumentaram significativamente com o incremento dos esforços inspiratórios, durante altos esforços inspiratórios e altas complacências. Diminuíram significativamente durante o incremento das resistências, especialmente quando combinado com baixos esforços inspiratórios e baixas complacências. O fenômeno de sobreassistência (runaway) ocorreu com porcentagem de apoio de 95% combinada com alta resistência e alta complacência. CONCLUSÃO: O modo ventilação assistida proporcional plus respondeu adequadamente às alterações provocadas nas complacências e nos esforços inspiratórios testados. Respondeu à situações de resistência extremamente alta somente quando associado com altos esforços inspiratórios. Não houve fenômeno de sobreassistência em porcentagens de apoio menores que 95%. / BACKGROUND: Proportional assist ventilation plus (PAV+) is a new concept of assist ventilatory support conceived to act according to the levels of inspiratory efforts, respiratory mechanics and percentages levels of assistance. This complex interaction among the factors commanding its function is difficult to detect in clinical setting. This study aimed to provoke changes in compliance, resistance and inspiratory efforts in a lung simulator to understand the responses of PAV+ support. METHODS: In the Mechanical Ventilation Laboratory at University of São Paulo, an Inter Plus ventilator (Intermed ®) connected to lung simulator (Michigan Instruments Inc) acted triggering Puritan-Bennett 840 ventilator (Covidien ®) at different levels of inspiratory efforts. Expiratory tidal volumes were measured and compared (ANOVA-2-way) at 10 levels of PAV+ support (from 5% to 95%), 3 levels of lung simulator compliance (50, 100, 150 mL/cmH20), 3 levels of airway resistance (5, 20, 50 cmH20/L/s) and 4 levels of inspiratory effort ( -2, -5, -8, -15 cmH20). RESULTS: A total of 360 tidal volumes were measured. They increased significantly during increment of inspiratory efforts and during higher inspiratory efforts with higher compliances. They decreased significantly during respiratory resistance increments, especially when combined with low inspiratory efforts and compliances. Runaway occurred during PAV+ support of 95% combined with high respiratory resistance and compliance. CONCLUSIONS: PAV+ responded adequately to provoked changes in the tested respiratory compliances and inspiratory efforts. It responded to very high resistance only when associated with high inspiratory efforts. There was no runaway phenomenon during PAV+ assistance below 95%.

Fenômenos fisiológicos respiratórios

Lung volume measurements

Mecânica respiratória

Mechanical ventilation

Medidas de volume pulmonar

Respiração artificial

Respiration artificial

Respiratory mechanics

Respiratory physiological phenomena

Ventilação mecânica

Ventiladores mecânicos

Ventilators mechanical

Efeitos fisiológicos da ventilação de alta frequência usando ventilador convencional em um modelo experimental de insuficiência respiratória grave / Physiological effects of high frequency ventilation with conventional ventilator in an experimental model of severe respiratory failure

Cordioli, Ricardo Luiz

30 July 2012

Introdução: A Síndrome do Desconforto Respiratório Agudo (SDRA) apresenta alta incidência e mortalidade em pacientes de terapia intensiva. A ventilação mecânica é o principal suporte para os pacientes que apresentam-se com SDRA, entretanto ainda existe muito debate sobre a melhor estratégia ventilatória a ser adotada, pois a ventilação mecânica pode ser lesiva aos pulmões e aumentar a mortalidade se mal ajustada. Um dos principais mecanismos de lesão pulmonar induzida pela ventilação é o uso de volumes correntes altos, havendo evidência na literatura que a utilização de volumes correntes menores fornece uma ventilação dita protetora, a qual aumenta a probabilidade de sobrevivência. Objetivo: Explorar se uma estratégia ventilatória de alta frequência com pressão positiva (HFPPV) realizada através de um ventilador mecânico convencional (Servo-300) é capaz de permitir uma maior redução do volume corrente e estabilização da PaCO2 em um modelo de SDRA severa, inicialmente ventilado com uma estratégia protetora. Métodos: Estudo prospectivo, experimental que utilizou oito porcos que foram submetidos a uma lesão pulmonar através de lavagem pulmonar com soro fisiológico e ventilação mecânica lesiva. Em seguida, os animais foram ventilados com um volume corrente de 6 mL/kg, seguido de uma randomização de sequências diferentes de frequências respiratórias (30, 60, 60 com pausa inspiratória de 10 e 30%, 90, 120, 150, 60 com manobra de recrutamento alveolar mais titulação da PEEP e HFOV com 5 Hertz), até obter estabilização da PaCO2 entre 57 63 mmHg por 30 minutos. O ventilador Servo-300 foi utilizado para HFPPV e o ventilador SensorMedics 3100B utilizado para fornecer a ventilação oscilatória de alta frequência (HFOV). Dados são apresentados como mediana [P25th,P75th]. Principais Resultados: O peso dos animais foi de 34 [29,36] kg. Após a lesão pulmonar, a relação P/F, o shunt pulmonar e a complacência estática dos animais ficaram em 92 [63,118] mmHg, 26 [17,31] % e 11 [8,14] mL/cmH2O respectivamente. O PEEP total usado foi de 14 [10,17] cmH2O durante o experimento. Da frequência respiratória de 35 (e com volume corrente de 6 mL/kg) até a frequência ventilatória de 150 rpm, a PaCO2 foi 81 [78,92] mmHg para 60 [58,63] mmHg (P=0.001), o volume corrente (VT) progressivamente caiu de 6.1 [5.9,6.2] para 3.8 [3.7,4.2] mL/kg (P<0.001), a pressão de platô de 29 [26,30] para 27 [25,29] cmH2O (P=0.306) respectivamente. Não houve nenhum comprometimento hemodinâmico ou da oxigenação, enquanto os animais utilizaram a FiO2 = 1. Conclusões: Utilizando-se de uma ventilação mecânica protetora, a estratégia de HFPPV realizada com um ventilador mecânico convencional em um modelo animal de SDRA severa permitiu maior redução do volume corrente, bem como da pressão de platô. Esta estratégia também permitiu a manutenção de PaCO2 em níveis clinicamente aceitáveis / Introduction: Acute respiratory distress syndrome (ARDS) has a high incidence and mortality between critical ill patients. The mechanical ventilation is the most important support for these patients with ARDS. However, until now there is an important debate about how is the best ventilatory strategy to use, because the mechanical ventilation if not well set can cause lung injury and increase mortality. The use of high tidal volume is one of the most important mechanics of ventilation induced lung injury and there is evidence in the literature that using low tidal volume is a protective ventilation with better survival. Objective: To explore if high frequency positive pressure ventilation (HFPPV) delivered by a conventional ventilator (Servo-300) is able to allow further tidal volume reductions and to stabilize PaCO2 in a severe acute respiratory distress syndrome (ARDS) model initially ventilated with a protective ventilation. Methods: A prospective and experimental laboratory study where eight Agroceres pigs were instrumented and followed by induction of acute lung injury with sequential pulmonary lavages and injurious ventilation. Afterwards, the animals were ventilated with a tidal volume of 6 mL/kg, followed by a randomized sequence of respiratory rates (30, 60, 60 with pauses of 10 and 30% of the inspiratory time, 90, 120, 150, 60 with alveolar recruitment maneuver and PEEP titration and 5 Hertz of HFOV), until PaCO2 stabilization between 57 63 mmHg for 30 minutes. The Servo-300 ventilator was used for HFPPV and the ventilator SensorMedics 3100B was used for HFOV. Data are shown as median (P25th,P75th). Measurements and Main Results: Animals weight was 34 [29,36] kg. After lung injury, the P/F ratio, pulmonary shunt and static compliance of animals were 92 [63,118] mmHg, 26 [17,31] % and 11 [8,14] mL/cmH2O respectively. The total PEEP used was 14 [10,17] cmH2O throughout the experiment. From the respiratory rates of 35 (while ventilating with 6 mL/kg) to 150 breaths/ minute, the PaCO2 was 81 [78,92] mmHg and 60 [58,63] mmHg (P=0.001), the tidal volume progressively felt from 6.1 [5.9,6.2] to 3.8 [3.7,4.2] mL/kg (P<0.001), the plateau pressure was 29 [26,30] and 27[25,29] cmH2O (P=0.306) respectively. There were no detrimental effects in the hemodynamics and blood oxygenation, while the animals were using a FiO2 = 1. Conclusions: During protective mechanical ventilation, HFPPV delivered by a conventional ventilator in a severe ARDS swine model allows further tidal volume reductions. This strategy also allowed the maintenance of PaCO2 in clinically acceptable levels

Acute lung injury

Acute respiratory distress syndrome

Critical care unit

High frequency ventilation

Lesão pulmonar aguda

Mechanical ventilation

Protective ventilation

Respiração artificial

Terapia intensiva

Ventilação de alta frequência

Ventilação protetora

Efeitos fisiológicos da ventilação de alta frequência usando ventilador convencional em um modelo experimental de insuficiência respiratória grave / Physiological effects of high frequency ventilation with conventional ventilator in an experimental model of severe respiratory failure

Ricardo Luiz Cordioli

30 July 2012

Introdução: A Síndrome do Desconforto Respiratório Agudo (SDRA) apresenta alta incidência e mortalidade em pacientes de terapia intensiva. A ventilação mecânica é o principal suporte para os pacientes que apresentam-se com SDRA, entretanto ainda existe muito debate sobre a melhor estratégia ventilatória a ser adotada, pois a ventilação mecânica pode ser lesiva aos pulmões e aumentar a mortalidade se mal ajustada. Um dos principais mecanismos de lesão pulmonar induzida pela ventilação é o uso de volumes correntes altos, havendo evidência na literatura que a utilização de volumes correntes menores fornece uma ventilação dita protetora, a qual aumenta a probabilidade de sobrevivência. Objetivo: Explorar se uma estratégia ventilatória de alta frequência com pressão positiva (HFPPV) realizada através de um ventilador mecânico convencional (Servo-300) é capaz de permitir uma maior redução do volume corrente e estabilização da PaCO2 em um modelo de SDRA severa, inicialmente ventilado com uma estratégia protetora. Métodos: Estudo prospectivo, experimental que utilizou oito porcos que foram submetidos a uma lesão pulmonar através de lavagem pulmonar com soro fisiológico e ventilação mecânica lesiva. Em seguida, os animais foram ventilados com um volume corrente de 6 mL/kg, seguido de uma randomização de sequências diferentes de frequências respiratórias (30, 60, 60 com pausa inspiratória de 10 e 30%, 90, 120, 150, 60 com manobra de recrutamento alveolar mais titulação da PEEP e HFOV com 5 Hertz), até obter estabilização da PaCO2 entre 57 63 mmHg por 30 minutos. O ventilador Servo-300 foi utilizado para HFPPV e o ventilador SensorMedics 3100B utilizado para fornecer a ventilação oscilatória de alta frequência (HFOV). Dados são apresentados como mediana [P25th,P75th]. Principais Resultados: O peso dos animais foi de 34 [29,36] kg. Após a lesão pulmonar, a relação P/F, o shunt pulmonar e a complacência estática dos animais ficaram em 92 [63,118] mmHg, 26 [17,31] % e 11 [8,14] mL/cmH2O respectivamente. O PEEP total usado foi de 14 [10,17] cmH2O durante o experimento. Da frequência respiratória de 35 (e com volume corrente de 6 mL/kg) até a frequência ventilatória de 150 rpm, a PaCO2 foi 81 [78,92] mmHg para 60 [58,63] mmHg (P=0.001), o volume corrente (VT) progressivamente caiu de 6.1 [5.9,6.2] para 3.8 [3.7,4.2] mL/kg (P<0.001), a pressão de platô de 29 [26,30] para 27 [25,29] cmH2O (P=0.306) respectivamente. Não houve nenhum comprometimento hemodinâmico ou da oxigenação, enquanto os animais utilizaram a FiO2 = 1. Conclusões: Utilizando-se de uma ventilação mecânica protetora, a estratégia de HFPPV realizada com um ventilador mecânico convencional em um modelo animal de SDRA severa permitiu maior redução do volume corrente, bem como da pressão de platô. Esta estratégia também permitiu a manutenção de PaCO2 em níveis clinicamente aceitáveis / Introduction: Acute respiratory distress syndrome (ARDS) has a high incidence and mortality between critical ill patients. The mechanical ventilation is the most important support for these patients with ARDS. However, until now there is an important debate about how is the best ventilatory strategy to use, because the mechanical ventilation if not well set can cause lung injury and increase mortality. The use of high tidal volume is one of the most important mechanics of ventilation induced lung injury and there is evidence in the literature that using low tidal volume is a protective ventilation with better survival. Objective: To explore if high frequency positive pressure ventilation (HFPPV) delivered by a conventional ventilator (Servo-300) is able to allow further tidal volume reductions and to stabilize PaCO2 in a severe acute respiratory distress syndrome (ARDS) model initially ventilated with a protective ventilation. Methods: A prospective and experimental laboratory study where eight Agroceres pigs were instrumented and followed by induction of acute lung injury with sequential pulmonary lavages and injurious ventilation. Afterwards, the animals were ventilated with a tidal volume of 6 mL/kg, followed by a randomized sequence of respiratory rates (30, 60, 60 with pauses of 10 and 30% of the inspiratory time, 90, 120, 150, 60 with alveolar recruitment maneuver and PEEP titration and 5 Hertz of HFOV), until PaCO2 stabilization between 57 63 mmHg for 30 minutes. The Servo-300 ventilator was used for HFPPV and the ventilator SensorMedics 3100B was used for HFOV. Data are shown as median (P25th,P75th). Measurements and Main Results: Animals weight was 34 [29,36] kg. After lung injury, the P/F ratio, pulmonary shunt and static compliance of animals were 92 [63,118] mmHg, 26 [17,31] % and 11 [8,14] mL/cmH2O respectively. The total PEEP used was 14 [10,17] cmH2O throughout the experiment. From the respiratory rates of 35 (while ventilating with 6 mL/kg) to 150 breaths/ minute, the PaCO2 was 81 [78,92] mmHg and 60 [58,63] mmHg (P=0.001), the tidal volume progressively felt from 6.1 [5.9,6.2] to 3.8 [3.7,4.2] mL/kg (P<0.001), the plateau pressure was 29 [26,30] and 27[25,29] cmH2O (P=0.306) respectively. There were no detrimental effects in the hemodynamics and blood oxygenation, while the animals were using a FiO2 = 1. Conclusions: During protective mechanical ventilation, HFPPV delivered by a conventional ventilator in a severe ARDS swine model allows further tidal volume reductions. This strategy also allowed the maintenance of PaCO2 in clinically acceptable levels

Lesão pulmonar aguda

Respiração artificial

Terapia intensiva

Ventilação de alta frequência

Ventilação protetora

Acute lung injury

Acute respiratory distress syndrome

Critical care unit

High frequency ventilation

Mechanical ventilation

Protective ventilation

Estudo do funcionamento da ventilação assistida proporcional plus em um sistema pulmonar mecânico / Study of the functioning of the proportional assist ventilation plus in a mechanical lung model

Lara Poletto Couto

13 August 2012

INTRODUÇÃO: Ventilação assistida proporcional plus é um novo conceito de suporte ventilatório assistido que visa atuar de acordo com os níveis de esforço inspiratório, mecânica respiratória e níveis de porcentagem de apoio. A complexa interação entre esses fatores que comandam a sua função é de difícil interpretação na prática clínica. O objetivo deste estudo é provocar alterações na complacência, resistência e esforços inspiratórios, em um sistema pulmonar mecânico, para entender o funcionamento e as respostas desse modo nas suas diferentes porcentagens de apoio. MÉTODOS: No Laboratório de Ventilação Mecânica da Disciplina de Pneumologia da Faculdade de Medicina da Universidade de São Paulo, um ventilador Interplus da marca Intermed foi conectado em um pulmão mecânico da marca Michigan Instruments Inc, com a finalidade de gerar diferentes níveis de esforços inspiratórios e para disparar o ventilador Puritan-Bennett 840 da marca Covidien. Os volumes correntes expirados foram medidos e posteriormente comparados através do método estatístico ANOVA two-way, para 10 níveis de porcentagem de apoio (de 5% a 95%), 3 níveis de complacência (50, 100 e 150 mL/cmH2O), 3 níveis de resistência (5, 20 e 50 cmH2O/L/s) e 4 níveis de esforço inspiratório (-2, -5, -8 e -15 cmH2O). RESULTADOS: Trezentas e sessenta medidas de volume corrente expirado foram obtidas. Os volumes correntes expirados aumentaram significativamente com o incremento dos esforços inspiratórios, durante altos esforços inspiratórios e altas complacências. Diminuíram significativamente durante o incremento das resistências, especialmente quando combinado com baixos esforços inspiratórios e baixas complacências. O fenômeno de sobreassistência (runaway) ocorreu com porcentagem de apoio de 95% combinada com alta resistência e alta complacência. CONCLUSÃO: O modo ventilação assistida proporcional plus respondeu adequadamente às alterações provocadas nas complacências e nos esforços inspiratórios testados. Respondeu à situações de resistência extremamente alta somente quando associado com altos esforços inspiratórios. Não houve fenômeno de sobreassistência em porcentagens de apoio menores que 95%. / BACKGROUND: Proportional assist ventilation plus (PAV+) is a new concept of assist ventilatory support conceived to act according to the levels of inspiratory efforts, respiratory mechanics and percentages levels of assistance. This complex interaction among the factors commanding its function is difficult to detect in clinical setting. This study aimed to provoke changes in compliance, resistance and inspiratory efforts in a lung simulator to understand the responses of PAV+ support. METHODS: In the Mechanical Ventilation Laboratory at University of São Paulo, an Inter Plus ventilator (Intermed ®) connected to lung simulator (Michigan Instruments Inc) acted triggering Puritan-Bennett 840 ventilator (Covidien ®) at different levels of inspiratory efforts. Expiratory tidal volumes were measured and compared (ANOVA-2-way) at 10 levels of PAV+ support (from 5% to 95%), 3 levels of lung simulator compliance (50, 100, 150 mL/cmH20), 3 levels of airway resistance (5, 20, 50 cmH20/L/s) and 4 levels of inspiratory effort ( -2, -5, -8, -15 cmH20). RESULTS: A total of 360 tidal volumes were measured. They increased significantly during increment of inspiratory efforts and during higher inspiratory efforts with higher compliances. They decreased significantly during respiratory resistance increments, especially when combined with low inspiratory efforts and compliances. Runaway occurred during PAV+ support of 95% combined with high respiratory resistance and compliance. CONCLUSIONS: PAV+ responded adequately to provoked changes in the tested respiratory compliances and inspiratory efforts. It responded to very high resistance only when associated with high inspiratory efforts. There was no runaway phenomenon during PAV+ assistance below 95%.

Fenômenos fisiológicos respiratórios

Mecânica respiratória

Medidas de volume pulmonar

Respiração artificial

Ventilação mecânica

Ventiladores mecânicos

Lung volume measurements

Mechanical ventilation

Respiration artificial

Respiratory mechanics

Respiratory physiological phenomena

Ventilators mechanical

Influence of Muscle Strength on Mobility in Critically Ill Adult Patients on Mechanical Ventilation

Roberson, Audrey R

01 January 2018

Patients in the intensive care unit (ICU) setting are prone to develop muscle weakness and the causes are multi-factorial. Muscle strength in adult, critically ill patients on mechanical ventilation decreases with immobility. The influence of muscle strength on different muscle groups and its influence on progressive mobility in the adult, critically ill patient on mechanical ventilation has not been examined. Identifying muscle strength in this patient population can benefit overall muscle health and minimize muscle deconditioning through a progressive mobility plan. The objective of this dissertation was to describe muscle strength in different muscle groups and to describe the influence of muscle strength on mobility in critically ill adult patients on mechanical ventilation (MV). Fifty ICU patients were enrolled in this descriptive, cross sectional study. Abdominal core, bilateral hand grip and extremity strength was measured using three measurement tools. Mobility was measured using the following scale: 0=lying in bed; 1=sitting on edge of bed; 2=sitting on edge of bed to standing; 3=walking to bedside chair and 4=walking >7 feet from the standing position. Predictors of mobility were examined using stepwise regression. Abdominal core, bilateral hand grip and extremity strength demonstrated statistically significant relationships with all variables. Extremity strength accounted for 82% of the variance in mobility and was the sole predictor (β=0.903; F=212.9; p=0.000). Future research addressing the outcomes of implementing a mobility protocol in this patient population and prioritizing when such a protocol should be implemented would be beneficial to ongoing plans to decrease MV, ICU and hospital days. Muscle strength tests implemented at the bedside are crucial to implementing a progressive mobility plan for critically ill adults while they are on MV therapy.

muscle strength

intensive care

mechanical ventilation

muscle weakness

mobility

maximum inspiratory pressure

hand grip

extremity strength

Critical Care

Critical Care Nursing

Kinesiotherapy

Medical Specialties

Physical Therapy

Physiotherapy

Rehabilitation and Therapy

Respiratory Therapy

Analyse et modulation de la réponse inflammatoire au cours de l'agression pulmonaire liée à l'infection bactérienne et à la ventilation mécanique / Analysis and modulation of the inflammatory response through lung agression related to bacterial infection and mechanical ventilation

Pauchard, Laure-Anne

12 October 2015

Nonobstant d’immenses progrès accomplis depuis des décennies dans la prise en charge des patients soumis à la ventilation mécanique, les pneumonies acquises sous ventilation mécanique continuent de compliquer le séjour en réanimation de près de 28% des patients recevant une assistance respiratoire invasive prolongée. Parmi les malades des unités de soins intensifs, le risque de développer une pneumonie est de 3 à 10 fois supérieur chez les intubés sous ventilation. Elle reste cependant bien souvent le seul moyen de venir en aide aux patients souffrant de graves détresses respiratoires. Il a maintenant été clairement démontré que la ventilation mécanique, en particulier lorsqu’elle est mise en place selon des stratégies dites agressives, active les cellules pulmonaires conduisant alors à une réponse pro-inflammatoire même en l’absence de pathogène. Ce phénomène est connu sous le terme de biotrauma, et serait responsable en partie des lésions induites sur le poumon par la ventilation mécanique. En quelques sortes, la ventilation mécanique prépare les cellules épithéliales pulmonaires à répondre massivement à une seconde agression pro-inflammatoire par la libération de grandes quantités de cytokines (comme l’IL-8 notamment), accentuant alors les lésions du tissu pulmonaire essentiellement par le recrutement de polynucléaires neutrophiles attirés par la sécrétion massive d’IL-8. L’immunité innée joue donc un rôle très important dans le développement du VILI. L’implication des Toll Like Récepteurs a été suggérée par plusieurs études expérimentales. Par ailleurs, la ventilation en décubitus ventral a été décrite pour avoir des effets bénéfiques sur les patients ventilés souffrant de graves lésions pulmonaires particulièrement chez ceux souffrant du syndrome de détresse respiratoire aiguë. Notre équipe s’est particulièrement intéressée au TLR2, qui reconnait les bactéries à Gram-positif, car elle a montré dans des études précédentes in vitro que l’étirement cyclique de cellules pulmonaires humaines augmentait principalement l’expression de TLR2 ainsi que la réactivité de cellules pulmonaires à des composants de la paroi de bactéries à Gram positif. Ces données ont par la suite été confirmées dans un modèle in vivo de lapins ventilés dont la réponse immune innée était stimulée par du Pam3CSK4.Dans un premier projet, nous avons évalué l’impact d’une ventilation mécanique en décubitus ventral chez des lapins avec pneumonie unilatérale à Enterobacter aerogenes soumis à la ventilation mécanique. Nos résultats montrent que le décubitus ventral peut être protecteur si l’hôte est soumis à la ventilation mécanique dans le contexte d’une pneumonie bactérienne unilatérale.Pour vérifier la pertinence de nos hypothèses sur le TLR2 dans notre modèle animal de pneumonie acquise sous ventilation mécanique, nous avons mené des expériences avec des bactéries vivantes reconnues par le TLR2 (une souche de Staphylococcus aureus résistante à la methicilline SARM). Notre étude met en évidence qu’une ventilation mécanique modérément agressive impacte sur la clairance bactérienne pulmonaire en la diminuant, aggrave les lésions sur le tissu pulmonaire et favorise une réponse inflammatoire systémique. La surexpression du TLR2 tant au niveau pulmonaire que systémique pourrait expliquer ces résultats.Le troisième projet s’est attaché à évaluer l’impact d’une thérapie aux statines dans le contexte d’une pneumonie acquise sous ventilation mécanique à SARM, conjointement traitée par le linezolide, dans notre modèle animal de lapins ventilés. Nos résultats suggèrent qu’une pré-­‐exposition aux statines pourrait avoir un effet anti-inflammatoire au niveau pulmonaire et systémique dans ce modèle, qui pourrait passer par une régulation négative de l’expression de TLR2, contre-balançant les effets de l’étirement cyclique. / Despite major advances since decades in the management of ventilated patients, ventilator-associated pneumonia (VAP) continues to complicate the course of approximately 28% of the patients receiving mechanical ventilation (MV). Among patients hospitalized in intensive care units, the risk of pneumonia is 3- to 10- fold increased in MV patients. However, MV is often the only way to care for critically ill patients with respiratory failure. It has now been clearly demonstrated that MV, in particular adverse ventilatory strategies could activate lung cells, thus leading to a proinflammatory response, even in the absence of pathogen. This is the biotrauma paradigm, which accounts, at least in part, for the ventilator induced lung injury (VILI). In one way, MV primes airway cells to respond massively to a second proinflammatory insult, through the subsequent release of large amounts of cytokines (as interleukin (IL)‐ 8), thus leading to additional lung injury, particularly through the recruitment of neutrophils attracted by the massive release of IL-8. Accordingly, innate immunity plays an important role in the developement of VILI. The involvement of Toll-like receptors has been suggested by several experimental studies. Ventilation in the prone position (PP) has been described to have beneficial effects on patients under MV, especially in those with lobar involvement. Our team focused particularly on the TLR2, which interacts with Gram-positive bacteria, and we have previously demonstrated in vitro that cyclic stretch of human pulmonary cells resulted in TLR2 overexpression and enhanced TLR2 reactivity to Gram-positive cell wall components. We confirmed these datas in an in vivo model of ventilated rabbits which immune response had been stimulated with Pam3CSK4. In a first project, we assessed the impact of the PP on unilateral pneumonia to Enterobacter aerogenes in rabbits subjected to MV. Our results shows that the prone position could be protective if the host is subjected to MV and unilateral bacterial pneumonia. To ensure the relevance of our hypothesis on TLR2 in our animal model of VAP, we conducted experiments using live bacteria specifically recognized by TLR2 (Methicilin resist. aureus). We demonstrate that mild-­‐stretch MV impaired lung bacterial clearance, hastened tissue injury and promoted a systemic inflammatory response. Both pulmonary and peripheral blood TLR2 overexpression could account for such an impact. The third project assessed the impact of a statins therapy in the context of MRSA VAP, treated with linezolid, in our model of ventilated rabbits. Our results suggest that statin exposure prior to pneumonia provides an anti-­‐inflammatory effect within the lung and the systemic compartment of rabbits with MRSA VAP. Although LNZ enhances pulmonary bacterial clearance, dampening the host systemic inflammatory response with statin could impede defense against MRSA in this compartment. It could be subsequent to enhanced antibacterial defences and improvements in lung mechanics, thereby blunting overwhelming inflammation. In the last project, in collaboration with the University of Geneva, we assessed whether mitochondrial alarmins are released during VILI and can generate lung inflammation. Our results confirmed the hypothesis made and showed indeed that alarmins are released during during cyclic stretch of human epithelial cells, as well as in BAL fluids from rabbits ventilated with an injurious ventilatory regimen. These alarmins stimulate lung cells to produce bioactive IL-­‐1, and are likely to represent the proximal endogenous mediators of VILI and ARDS, released by injured pulmonary cells.

Ventilation mécanique

Pneumonie

Lésions pulmonaires

Infection

Inflammation

Statines

Décubitus ventral

Alarmines

Mechanical ventilation

Pneumonia

Lung injury

Ventilator-associated pneumonia

Infection

Inflammation

Statins

Prone position

Alarmins

616.2

571.6