Objective To investigate the effects of noninvasive ventilation for the treatment of acute respiratory failure secondary to severe acute respiratory syndrome ( SARS) . Methods 127 patients with complete information were collected from the database of SARS in Guangdong province, who were all consistent with the ALI/ARDS diagnostic criteria. The patients were divided into three groups depending on ventilation status, ie. a no-ventilation group, a noninvasive ventilation group, and a mechanical ventilation group. The outcome of ventilation treatmentwas followed up.Multi-factor regression analysis was conducted to analyze the relations of ventilation treatment with ARDS and mortality, and factors associated with success of noninvasive ventilation. Results As soon as the patients met the diagnostic criteria of ALI/ARDS, the patients in the noninvasive ventilation group were in more serious condition and had a higher proportion of ARDS compared with the no-ventilation group ( P lt;0. 01) . The patients in the mechanical ventilation group had a higher mortality rate ( P lt;0.01) . 6 and 7 patients in the no-ventilation group had noninvasive ventilation and invasive ventilation thereafter, respectively. 15 patients in the noninvasive group switched to invasive ventilation. Compared with the patients without ventilation ( n =45) , the patients receiving noninvasive ventilation ( n = 61) were in more serious condition and at higher risk of developing ARDS ( P lt;0. 01) , but the mortality was not different between them ( P gt; 0. 05) . The patients who continued to receive noninvasive ventilation ( n = 40) were in more serious condition, and at higher risk of developing ARDS compared with the patients without ventilation ( n = 45) ( P lt; 0. 01) . 15 patients in the noninvasive group who switched to invasive ventilation were older than those patients continuing noninvasive ventilation.Conclusions For SARS patients fulfilling the ALI/ARDS criteria, the patients underwent noninvasive ventilation are more severe, run a higher probability of developing ARDS from ALI. But earlier initiation of noninvasive ventilation has no impact on mortality. The patients who tolerate noninvasive ventilation can avoid intubation, especially for young patients. However, the time and indication of shifting from noninvasive ventilation to invasive ventilation should be emphasized.
Objective To formulate an evidence-based position program for a ventilation patient with acute respiratory distress syndrome (ARDS). Methods Based on fully assessing the patient’s conditions, the clinical problems were put forward according to PICO principles. Such database as The Cochrane Library (2005 to January 2011), DARE (March 2011), CCTR (March 2011), MEDLINE (1996 to January 2011) and CNKI (1979 to January 2011) were retrieved to collect high quality clinical evidence, and then the optimum nursing program was designed in line with patient’s conditions and relatives’ willingness. Results Three meta-analyses, three randomized controlled trials, one systematic review and one anterior-posterior self-control study were included. The available clinical evidence displayed that: a) the prone position adopting earlier, especially for patients with bilateral lungs or left lung functional disorder, was propitious to effectively improve the oxygenation condition and reduce the incidence of ventilator induced lung injury (VILI); b) The long-term prone position could increase the risk of pressure sore; c) The prone position could prolong the survival time, but there was no enough evidence to prove that it could obviously decrease the mortality rate of ARDS. So finally a nursing plan was made in combination with literature evidence and patient’s condition: adopting the prone position after onset within 24 to 36 hours, and enhancing the skin nursing to prevent pressure sore at the same time. After 4-week comprehensive therapy and prone position ventilation, the patient got obvious alleviated in oxygenation, with SpO 2 up to 90% to 100%, stable vital signs, and no more VILI and pressure sore. And then the patient was stopped applying ventilator, and transferred to a general ward for further treatment. Conclusion The earlier adoption of prone position ventilation for severe ARDS can improve oxygenation and reduce ventilator associated pneumonia (VAP) and VILI, but whether it can prolong survival time and reduce mortality for mild ARDS or not still has to be proved with more high quality evidence in the future.
Objective To investigate the physiological effects of different oxygen injection site on ventilatory status and oxygenation during noninvasive positive pressure ventilation ( NPPV) with portable noninvasive ventilators. Methods A prospective crossover randomized study was performed. Oxygen injection site was randomized into the outlet of the ventilator, the connection site between mask and circuit, and the mask under the condition of leak port immobilized in the mask. Oxygen flow was retained in the baseline level at the initial 5 to 10 minutes, and adjusted to obtain arterial oxygen saturation measured by pulse oximetry ( SpO2 ) ranging from 90% to 95% after SpO2 remains stable. SpO2 at the initial 5 to 10 minutes, oxygen flow, ventilatory status, oxygenation, hemodynamics and dyspnea indexes at0. 5 hour, 1 hour, and 2 hours of NPPV were compared between different oxygen injection sites. Results 10 patients were recruited into the study. Under the condition of the same oxygen flow, SpO2 with oxygen injection site in the outlet of the ventilator was significantly higher than that with oxygen injection site in the connection site between mask and circuit [ ( 98.9 ±0.9) % vs. ( 96.9 ±1.1) % , P =0. 003] , whereas SpO2 with oxygen injection site in the connection site between mask and circuit was significantly higher than that with oxygen injection site in the mask [ ( 96.9 ±1.1) % vs. ( 94.1 ±1.6) %, P = 0.000] . Oxygen flow with oxygen injection site in the mask was statistically higher than that with oxygen injection site at other sites ( P lt; 0.05) . Arterial oxygen tension/ oxygen flow with oxygen injection site in the outlet of the ventilator was significantly higher than that with oxygen injection site in the connection site between mask and circuit ( 67.9 ±31.1 vs. 37.0 ±15.0, P =0.007) , and than that with oxygen injection site in the mask ( 67.9 ± 31.1 vs. 25.0 ±9.1, P = 0.000) . pH, arterial carbon dioxide tension, hemodynamics and dyspnea indexes were not significantly different between different oxygen injection sites ( P gt; 0.05) .Conclusions When portable noninvasive ventilator was applied during NPPV, oxygen injection site significantly affects improvement of oxygenation, and shows a trend for affecting ventilatory status and work of breathing. When the leak port was immobilized in the mask, the nearer oxygen injection site approaches the outlet of the ventilator, the more easily oxygenation is improved and the lower oxygen flow is demanded.
Objective To evaluate the rescue intubation induced by ketamine and midazolam in patients with acute respiratory failure.Methods 81 patients with acute respiratory failure admitted between June 2010 and June 2012 were recruited in the study. They were randomly divided to a MF group to receive 0. 05 mg/kg of midazolam + 1 to 2 μg/kg of fentanyl ( n =41) , and aMK group to received 0. 05 mg/kg of midazolam + 0. 5 to 1 mg/kg of ketamine ( n =40) for rescue intubation. The APACHEⅡ score on initial24 hours after admission in ICU, length of ICU stay, and 28-day mortality were recorded. The differences in arterial blood pressure, heart rate, respiration rate, and blood oxygen saturation before intubation and 10 minutes after intubation were compared. Incidences of hypotension and other adverse events and difficult intubation were also recorded.Results The midazolamdose in the MK group was significantly less than that in the MF group ( P lt; 0. 01) . The blood pressure in both groups decreased. The systolic blood pressure dropped most significantly in the MF group ( P lt;0. 05) . The incidence of hypotension was 41. 5% in the MF group, significantly higher than that in the MK group ( 20. 0% , P lt;0. 05) . The incidence of hypotension had no correlation with midazolamdosage ( P gt;0. 05) . There was no significant difference in adverse events except for the arrhythmia between two groups. The length of ICU stay and 28-day mortality were similar in both groups ( P gt; 0. 05) . The incidence of difficult tracheal intubation was nearly 50% in both groups.Conclusions In patients with respiratory failure, rescue intubation induced by ketamine can reduce the dose of midazolam and reduce the incidence of hypotension without more complications. The optimal dose of ketamine in induced tracheal intubation requires further study.
ObjectiveTo evaluate the safety and efficacy of non-invasive positive pressure ventilation (NIPPV) combined with fiberoptic bronchoscopy(FB) on acute exacerbation of chronic obstructive puhmonary disease (AECOPD) patients with acute respiratory failure. MethodsA prospective study was conducted on the AECOPD patients with respiratory failure in respiratory intensive care unit of Tangdu Hospital of Fourth Military Medicine University from February 2010 to February 2011.They were randomly divided into a case group and a control group.The case group was administrated FB and lavage after one hour of NIPPV treatment.The control group was administrated NIPPV without FB and lavage.Other treatment regimen was the same in two groups. ResultsThere were 51 subjects recruited in the study, 25 subjects in the case group and 26 subjects in the control group.All variables at baseline were matched (P > 0.05).All variables improved after one hour of NIPPV before FB, without significant difference between two groups (P > 0.05).During the period of FB, heart rate in the case group was faster than that in the control group (P < 0.05), and other variables were not significantly different between two groups (P > 0.05).Both groups received NIPPV for one hour after FB, the variables including heart rate, respiratory rate, pH, PaO2, PaCO2 were statistically significant between two groups(P < 0.05).At the time of 24 hours after FB, the variables including mean arterial pressure, heart rate, respiratory rate, pH, PaO2 and PaCO2 in the case group were nearly recovered, and differences between two groups were significant (P < 0.05).The positive rate of sputum culture was significantly higher in the case group than that in the control group[88.0%(22/25) vs.58.6%(14/26)].Success rate in the case group were obviously superior to that in control group.The cases of failure, death and refusing in the case group were lower than those in the control group.Complications in two groups had no significant difference (P > 0.05).There was not serious complication such as hear arrest, hemoptysis and apnea during the process of NIPPV combined with early FB. Conclusion It deserves to be used in clinic because of the safety, efficacy and feasible for most of AECOPD patients through NIPPV combined with early FB.
Objectives To assess the prognostic value of blood sugar level for acute respiratory failure patients undergoing mechanical ventilation. Methods The study collected 139 acute respiratory failure patients undergoing mechanical ventilation admitted between February 2012 and October 2013. The patients were divided into a hyperglycemic group (n=123, blood sugar ≥143 mg/dl) and a non-hyperglycemic group (n=16, blood sugar <143 mg/dl). The data for basic clinical pathological characteristics and the blood sugar levels were collected, and the correlation between the blood sugar level and the prognosis was assessed using single factor analysis and logistic regression method. Results In the study, 88.49% of patients with acute respiratory failure undergoing mechanical ventilation had hyperglycemia (blood sugar ≥143 mg/dl). The proportions of patients with APACHEⅡ score ≥10, chronic obstructive pulmonary disease (COPD) or hypoxemia in the hyperglycemic group were significantly higher than those in the non-hyperglycemic group (P<0.05). APACHEⅡ ≥10, COPD and hypoxemia were significant risk factors for hyperglycemia. At the same time, the proportions of patients in the death group with hyperglycemia ≥143 mg/dl ( OR=8.354, 95%CI 1.067-65.388, P=0.018), APACHEⅡ≥10 ( OR=2.545, 95%CI 1.109-6.356, P=0.046), COPD ( OR=2.871, 95%CI 1.203-6.852, P=0.015), and hypoxemia ( OR=3.500, 95%CI 1.556-7.874, P=0.002) were significantly higher than those in the survival group. Kaplan-Meier curve analysis found that the overall survival of the hyperglycemic patients with acute respiratory failure was significantly lower than that in the non-hyperglycemic patients (P<0.001). Conclusion Blood sugar level can be used as an independent predictor for acute respiratory failure patients undergoing mechanical ventilation.
Objective To systematically review the efficacy of noninvasive positive pressure ventilation (NPPV) by helmet in adults with acute respiratory failure. Methods Randomized controlled trials (RCTs) or cohort studies about noninvasive positive pressure ventilation (NPPV) by helmet in adults with acute respiratory failure were retrieved in PubMed, The Cochrane Library (Issue 11, 2016), Web of Science, EMbase, CBM, CNKI and WanFang Data databases from inception to November 2016. Two reviewers independently screened literature, extracted data and assessed the risk of bias of included studies. Stata 12.0 software was then used to perform meta-analysis. Results A total of eight studies were included. The results of meta-analysis showed that, NPPV by helmet could significantly reduce the carbon dioxide partial pressure (cohort study: SMD=–0.46, 95%CI –0.75 to –0.18, P=0.001), tracheal intubation rate (RCT: OR=0.36, 95%CI 0.17 to 0.77, P=0.008) and hospital mortality (RCT: OR=0.48, 95%CI 0.24 to 0.98, P=0.044), improve the positive end expiratory pressure (RCT: SMD=1.27, 95%CI 0.87 to 1.67, P<0.05) and respiratory status (RCT: SMD=–0.45, 95%CI –0.81 to –0.08,P=0.017). There was no significant difference in the duration of NPPV(cohort study: OR=–0.20, 95%CI –0.50 to 0.09, P=0.177; RCT: OR=–0.24, 95%CI –0.86 to 0.38, P=0.445). Conclusion NPPV by helmet can reduce the carbon dioxide partial pressure, tracheal intubation rate, hospital mortality and improve the positive end expiratory pressure, respiratory status. But the effects in the duration of NPPV and oxygenation index are uncertain. Due to limited quality and quantity of the included studies, more high quality studies are needed to verify above conclusion.