Predictors of extubation failure and reintubation in
               newborn infants subjected to mechanical ventilation

Costa, Ana Cristina de Oliveira; Schettino, Renata de Carvalho; Ferreira, Sandra Clecêncio

doi:10.5935/0103-507X.20140008

Abstracts

Objective:

To identify risk factors for extubation failure and reintubation in newborn infants subjected to mechanical ventilation and to establish whether ventilation parameters and blood gas analysis behave as predictors of those outcomes.

Methods:

Prospective study conducted at a neonatal intensive care unit from May to November 2011. A total of 176 infants of both genders subjected to mechanical ventilation were assessed after extubation. Extubation failure was defined as the need to resume mechanical ventilation within less than 72 hours. Reintubation was defined as the need to reintubate the infants any time after the first 72 hours.

Results:

Based on the univariate analysis, the variables gestational age <28 weeks, birth weight <1,000g and low Apgar scores were associated with extubation failure and reintubation. Based on the multivariate analysis, the variables length of mechanical ventilation (days), potential of hydrogen (pH) and partial pressure of oxygen (pO₂) remained associated with extubation failure, and the five-minute Apgar score and age at extubation were associated with reintubation.

Conclusion:

Low five-minute Apgar scores, age at extubation, length of mechanical ventilation, acid-base disorders and hyperoxia exhibited associations with the investigated outcomes of extubation failure and reintubation.

Infant, newborn; Infant; premature; Respiration, artificial; Intubation, intratracheal/adverse effects; Ventilator weaning/adverse effects; Treatment failure

Objetivo:

Identificar os fatores de risco para falha de extubação e reintubação em recém-nascidos submetidos à ventilação pulmonar mecânica, e determinar se parâmetros ventilatórios e dados gasométricos são fatores preditores desses eventos.

Métodos:

Estudo prospectivo, realizado no período entre maio a novembro de 2011, em uma unidade de terapia intensiva neonatal. Foram avaliados 176 recém-nascidos de ambos os gêneros, submetidos à ventilação pulmonar mecânica posterior à extubação. Considerou-se falha na extubação se o retorno à ventilação pulmonar mecânica ocorresse antes de 72 horas. A reintubação ocorreu quando, em algum momento após as 72 horas, os recém-nascidos necessitassem de ser reintubados.

Resultados:

Na análise univariada, idade gestacional <28 semanas, peso <1.000g e valores baixos de Apgar estiveram associados a falha de extubação e a reintubação. Já na análise multivariada, as variáveis que se mantiveram associadas à falha na extubação foram dias de ventilação mecânica, potencial hidrogeniônico e pressão parcial de oxigênio, e, para a reintubação, foram Apagar no 5º minuto e idade na extubação.

Conclusão:

Menores Apgar no 5º minuto, idade na extubação e tempo de ventilação mecânica, além da presença de distúrbios ácido-base e hiperóxia foram variáveis que apresentaram relação com os eventos analisados.

Recém-nascido; Prematuro; Respiração artificial; Intubação intratraqueal/efeitos adversos; Desmame do respirador/efeitos adversos; Falha de tratamento

INTRODUCTION

Mechanical ventilation (MV) is a life support procedure that contributes to increasing the survival of premature and full-term infants and is one of the therapeutic resources most widely used in neonatal intensive care units (NICU).⁽¹1. Fávero RA, Schuster RC, Wojahn VW, Tartari JL. Incidência e principais fatores associados à falha na extubação em recém-nascidos prematuros. Pediatria (São Paulo). 2011;33(1):13-20.^,²2. Davidson J, Miyoshi MH, Santos AM, Carvalho WB. Medida da frequência respiratória e do volume corrente para prever a falha na extubação de recém-nascidos de muito baixo peso em ventilação mecânica. Rev Paul Pediatr. 2008;26(1):36-42.⁾

Despite its crucial role in reducing the mortality rate, MV is associated with morbidity, risks and complications, prominently including bronchopulmonary dysplasia and periventricular hemorrhage.⁽³3. Cruces P, Donoso A, Montero M, López A, Fernández B, Díaz F, et al. Predicción de fracaso de extubación en pacientes pediátricos: experiencia de dos años en una UCI polivalente. Rev Chil Med Intensiv. 2008;23(1):12-7.^,⁴4. Victor S; Extubate Trial Group. EXTUBATE: a randomised controlled trial of nasal biphasic positive airway pressure vs. nasal continuous positive airway pressure following extubation in infants less than 30 weeks' gestation: study protocol for a randomised controlled trial. Trials. 2011;12:257.⁾

To minimize such risks and complications, it is recommended to discontinue MV as soon as infants are able to maintain spontaneous breathing and achieve appropriate gas exchange with minimal respiratory effort.⁽²2. Davidson J, Miyoshi MH, Santos AM, Carvalho WB. Medida da frequência respiratória e do volume corrente para prever a falha na extubação de recém-nascidos de muito baixo peso em ventilação mecânica. Rev Paul Pediatr. 2008;26(1):36-42.⁾

The ideal time for weaning from MV is frequently established based on clinical and laboratory parameters assessed at the time extubation is proposed for consideration. However, such parameters are not very objective, which makes MV discontinuation in NICUs a trial-and-error approach.⁽²2. Davidson J, Miyoshi MH, Santos AM, Carvalho WB. Medida da frequência respiratória e do volume corrente para prever a falha na extubação de recém-nascidos de muito baixo peso em ventilação mecânica. Rev Paul Pediatr. 2008;26(1):36-42.^,⁵5. Newth CJ, Venkataraman S, Willson DF, Meert KL, Harrison R, Dean JM, Pollack M, Zimmerman J, Anand KJ, Carcillo JA, Nicholson CE; Eunice Shriver Kennedy National Institute of Child Health and Human Development Collaborative Pediatric Critical Care Research Network. Weaning and extubation readiness in pediatric patients. Pediatr Crit Care Med. 2009;10(1):1-11.⁾

Based on the damage associated with the inappropriate duration of MV in newborn infants, there is a clear need to establish objective criteria for extubation, which would help to avoid undesirable outcomes, such as extubation failure⁽³3. Cruces P, Donoso A, Montero M, López A, Fernández B, Díaz F, et al. Predicción de fracaso de extubación en pacientes pediátricos: experiencia de dos años en una UCI polivalente. Rev Chil Med Intensiv. 2008;23(1):12-7.^,⁵5. Newth CJ, Venkataraman S, Willson DF, Meert KL, Harrison R, Dean JM, Pollack M, Zimmerman J, Anand KJ, Carcillo JA, Nicholson CE; Eunice Shriver Kennedy National Institute of Child Health and Human Development Collaborative Pediatric Critical Care Research Network. Weaning and extubation readiness in pediatric patients. Pediatr Crit Care Med. 2009;10(1):1-11.^,⁶6. Andrade LB, Melo TM, Morais DF, Lima MR, Albuquerque EC, Martimiano PH. Avaliação do teste de respiração espontânea na extubação de neonatos pré-termo. Rev Bras Ter Intensiva. 2010;22(2):159-65.⁾ and reintubation, which bear direct associations with morbidity and mortality.⁽⁷7. Johnston C, Piva JP, Carvalho WB, Garcia PC, Fonseca MC, Hommerding PX. Preditores de falha da extubação em crianças no pós-operatório de cirurgia cardíaca submetidas à ventilação pulmonar mecânica. Rev Bras Ter Intensiva. 2008;20(1):57-62.^,⁸8. Kurachek SC, Newth CJ, Quasney MW, Rice T, Sachdeva RC, Patel NR, et al. Extubation failure in pediatric intensive care: a multiple-center study of risk factors and outcomes. Crit Care Med. 2003;31(11):2657-64. Erratum in Crit Care Med. 2004;32(7):1632-3. Scanlon Mathew [corrected to Scanlon Matthew].⁾

For these reasons, the aims of this study were to identify risk factors for extubation failure and the need for reintubation in newborn infants and to establish whether ventilation parameters and blood gas analysis behave as predictors of extubation failure and the need for reintubation.

METHODS

This work was a prospective study based on the collection of data regarding newborn infants admitted to the NICU of Hospital Sofia Feldman (HSF) from May 1, 2011 to November 1, 2011 who were subjected to MV and extubation. The study was approved by the Research Ethics Committee of HSF under opinion CAAE 0014.0.439.308.11 (Certificate of Presentation for Ethical Appraisal/Certificado de Apresentação para Apreciação Ética - CAAE), with waivers of informed consent. Newborn infants of both genders born at HSF and subjected to MV and extubation during the data collection period were included in the study, whereas infants referred from other institutions and infants with heart and lung malformations were excluded.

Mechanical ventilation was performed using Inter 3 and Inter 5 (Intermed brand) ventilators. The infants' gestational age (GA) was established by means of ultrasound or calculated based on the date of the mother's last menstrual period (LMP). The infants' weight at birth (BW) was measured using the Filizola BP Baby scale.

Assessment included the occurrence of extubation failure in addition to clinical and treatment-related variables. Extubation was considered successful when the infants were able to remain without invasive ventilatory support for 72 hours; extubation failure was defined as the need for reintubation for any reason within 72 hours after extubation, while reintubation occurred when the infants needed to be reintubated any time after 72 hours without MV. Accidental extubation followed by immediate reintubation and the use of noninvasive ventilatory support were not considered as extubation failure. The time for extubation was determined by the medical staff based on, at minimum, the presence of clinical and hemodynamic stability, regular respiratory drive and the behavioral status of reactivity.

The data were recorded using an HSF standard form by two healthcare professionals. The variables analyzed included the following: date of birth, GA, chronological age, BW, one- and five-minute Apgar scores, gender, antenatal corticosteroids, postnatal corticosteroids, exogenous surfactant, postnatal xanthines, date of extubation, length of MV (days), orotracheal tube (OT) brand, last blood gas test before extubation, ventilation parameters at the time of extubation, extubation failure and reintubation. The samples for blood gas analysis were collected one hour after endotracheal aspiration by arterial puncture and a heparinized syringe. The samples were immediately analyzed using a model Abl5 radiometer (Radiometer Copenhagen).

The data were entered into tables and analyzed using the software Statistical Package for the Social Sciences (SPSS). To achieve 95% reliability with a margin of error of ±7.5%, the sample should comprise at least 161 infants subjected to MV.

Descriptive analysis was performed to identify the main treatment-related characteristics of the participants. The association of the participants and treatment-related variables with extubation failure and reintubation was investigated using a bivariate logistic regression model. Multiple logistic regression was used to assess the multiple relationships between extubation success and failure, need for reintubation or not and the participants' characteristics. The variables included in the multiple logistic regression analysis were the ones that exhibited minimal relationships with the investigated outcome, whose significance level was set to 0.25.

In addition to the logistic regression mode, regression analysis stratified by confounding factors was performed to assess the direct relationship between exposure to MV and outcome (extubation failure/reintubation) in addition to the causal relationship between exposure and outcome.

Based on the logistic regression model, the strength of the association between the participants' characteristics that exerted significant impact on the outcomes was assessed by calculating odds ratios (OR) and corresponding 95% confidence intervals (95%CI). Those data were used to analyze and interpret the final model, for which purpose differences and associations were considered significant when the p-value was ≤0.05.

RESULTS

A total of 433 infants were admitted to the HSF-NICU during the study period. Among them, 224 were subjected to MV, of whom 176 were eligible for this study. The exclusions corresponded to 34 infants who died, 5 who were transferred from another institution and 9 who had not been extubated by the end of the data collection period.

Regarding the risk factors for extubation failure, univariate analysis showed that the infants with lower one-minute Apgar scores exhibited higher odds of failure (p=0.049). The same was true for the infants with lower five-minute Apgar scores (p=0.006). The infants with lower chronological age and shorter length of MV at the time of extubation exhibited a greater propensity for extubation failure.

The bicarbonate concentration exhibited a significant association with increased frequency of extubation failure (p=0.054). The same tendency was exhibited by base excess (BE) and potential of hydrogen (pH), as the lower their values, the higher the odds of extubation failure (p=0.020 and p=0.019, respectively). With regard to the ventilation parameters, the higher the mean airway pressure (MAP) was, the higher the odds of extubation failure (p=0.063). These data are shown in table 1.

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Table 1
Demographic and treatment-related characteristics of the study population as predictors of extubation failure, controlled for gestational age and birth weight

The independent variables associated with increased risk of extubation failure identified through multivariate analysis were as follows: pH (p=0.016), PO₂ (p=0.024) and length of MV (p=0.021) (Table 2). In this regard, the higher the pH, the lower the risk of failure, the latter being 99.9% lower for each increase by one pH unit. The same relationship was found for the length of MV, as the risk of failure decreased 16% per day of MV use. An increase of one PO₂ unit was found to increase the risk of failure by 1.2%.

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Table 2
Risk factors for extubation failure, controlled for gestational age and birth weight

With regard to the risk factors for reintubation, GA (p<0.001) and BW (p=0.003) exhibited significant associations with reintubation according to univariate analysis. Table 3 describes the results regarding the impact of clinical and treatment-related characteristics on reintubation. The infants with the lowest values of OT fixation tended to exhibit greater odds of reintubation (p=0.007), as was also the case for the infants with the lowest one- and five-minute Apgar scores (±7.5). However, the one-minute Apgar score was not retained in the model following multivariate analysis. Shorter inspiration time (IT), lower flow and lower PO₂ were most frequently found among the infants who required reintubation (p=0.019). The bicarbonate concentration was higher among the infants who required reintubation (p=0.024).

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Table 3
Demographic and treatment-related characteristics of the study population as predictors of reintubation, controlled for gestational age and birth weight

According to the multivariate analysis, the risk of reintubation was independently and significantly associated with the five-minute Apgar score (p≤0.001) and age at extubation (p≤0.001) (Table 4). The risk of reintubation increased by 37% with each decrease by one unit in the five-minute Apgar score, while it increased 13% with each increase of one unit in the age at extubation.

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Table 4
Risk factors for reintubation, controlled for gestational age and birth weight

DISCUSSION

This study analyzed risk factors that behave as predictors of extubation failure and reintubation, as determining the ideal time to perform extubation in newborn infants is quite difficult and a subject of controversy, where clinical judgment is required to balance the benefits of extubation with the damaging effects of reintubation.⁽²2. Davidson J, Miyoshi MH, Santos AM, Carvalho WB. Medida da frequência respiratória e do volume corrente para prever a falha na extubação de recém-nascidos de muito baixo peso em ventilação mecânica. Rev Paul Pediatr. 2008;26(1):36-42.^,⁶6. Andrade LB, Melo TM, Morais DF, Lima MR, Albuquerque EC, Martimiano PH. Avaliação do teste de respiração espontânea na extubação de neonatos pré-termo. Rev Bras Ter Intensiva. 2010;22(2):159-65.⁾

The results of this study show that the greater the chronological age, the greater the likelihood of reintubation as a function of the risk of complications, such as bronchopulmonary dysplasia,⁽⁴4. Victor S; Extubate Trial Group. EXTUBATE: a randomised controlled trial of nasal biphasic positive airway pressure vs. nasal continuous positive airway pressure following extubation in infants less than 30 weeks' gestation: study protocol for a randomised controlled trial. Trials. 2011;12:257.⁾ hospital-acquired infection, airway injury and longer hospital stay.⁽³3. Cruces P, Donoso A, Montero M, López A, Fernández B, Díaz F, et al. Predicción de fracaso de extubación en pacientes pediátricos: experiencia de dos años en una UCI polivalente. Rev Chil Med Intensiv. 2008;23(1):12-7.^,⁸8. Kurachek SC, Newth CJ, Quasney MW, Rice T, Sachdeva RC, Patel NR, et al. Extubation failure in pediatric intensive care: a multiple-center study of risk factors and outcomes. Crit Care Med. 2003;31(11):2657-64. Erratum in Crit Care Med. 2004;32(7):1632-3. Scanlon Mathew [corrected to Scanlon Matthew].⁾ Shorter MV length and older chronological age increased the odds of extubation failure. According to Kurachek et al.,⁽⁸8. Kurachek SC, Newth CJ, Quasney MW, Rice T, Sachdeva RC, Patel NR, et al. Extubation failure in pediatric intensive care: a multiple-center study of risk factors and outcomes. Crit Care Med. 2003;31(11):2657-64. Erratum in Crit Care Med. 2004;32(7):1632-3. Scanlon Mathew [corrected to Scanlon Matthew].⁾ both shorter MV length and extubation failure are related to a lack of resolution of the underlying problem that required intubation. For Hermeto et al.,⁽⁹9. Hermeto F, Martins BM, Ramos JR, Bhering CA, Sant'Anna GM. Incidence and main risk factors associated with extubation failure in newborns with birth weight < 1,250 grams. J Pediatr (Rio J). 2009;85(5):397-402.⁾ in turn, prematurity is one of the causes of extubation failure, as a function of the immaturity of the muscle and lung systems. Danan et al.⁽¹⁰10. Danan C, Durrmeyer X, Brochard L, Decobert F, Benani M, Dassieu G. A randomized trial of delayed extubation for the reduction of reintubation in extremely preterm infants. Pediatr Pulmonol. 2008;43(2):117-24.⁾ hypothesized that in extubated premature infants who are subjected to MV for a shorter time, there is not enough time for maturation of the respiratory system function and alveolar stabilization.

The lowest one- and five-minute Apgar scores exhibited a positive association with extubation failure and the need for reintubation, whereas only the five-minute Apgar score remained associated with the need for reintubation based on multivariate analysis. Similar results were reported by Hermeto et al.,⁽¹¹11. Hermeto F, Bottino MN, Vaillancourt K, Sant'Anna GM. Implementation of a respiratory therapist-driven protocol for neonatal ventilation: impact on the premature population. Pediatrics. 2009;123(5):e907-16.⁾ who found that the infants with extubation success exhibited higher scores compared to the cases with extubation failure.

Low pH, BE and bicarbonate are indicators of metabolic acidosis, leading to changes in the cell metabolism, and all three exhibited association with extubation failure. Metabolic acidosis might account for low or normal PaCO₂ levels, as a reduction in PaCO₂ is a response to metabolic acidosis.⁽¹²12. Aschner JL, Poland RL. Sodium bicarbonate: basically useless trerapy. Pediatrics. 2008;122(4):831-5.⁾ High bicarbonate levels were associated with the risk of reintubation; such an increase might be a post-hypercapnic effect because while the PaCO₂ might be corrected by adjusting the ventilation parameters, the renal response requires a longer time, and thus, the bicarbonate level remains initially high.⁽¹³13. Sociedade Portuguesa de Neonatologia. Acidose e alcalose: consenso nacional. [citado 2012 Dez 15]. Viseu, Portugal; 2008. Disponível em: http://www.lusoneonatologia.com/admin/ficheiros_projectos/201107201805-acidose_e_alcalose__2008.pdf
http://www.lusoneonatologia.com/admin/fi... ⁾

Hyperoxia, i.e., the condition defined by PO₂>80 mmHg, causes oxidative stress, inflammation and bronchopulmonary dysplasia in premature infants due to the deficiency of the antioxidative system,⁽¹⁴14. Teixeira AB, Xavier CC, Lamounier JA, Tavares EC. Hiperóxia e risco aumentado de displasia broncopulmonar em prematuros. Rev Paul Pediatr. 2007;25(1):47-52.⁾ which depends on maturation and nutritional factors,⁽¹⁰10. Danan C, Durrmeyer X, Brochard L, Decobert F, Benani M, Dassieu G. A randomized trial of delayed extubation for the reduction of reintubation in extremely preterm infants. Pediatr Pulmonol. 2008;43(2):117-24.⁾ and thus accounts for the association of hyperoxia with extubation failure.

Although variable GA did not show significant association based on multivariate analysis, it has been described as a risk factor for extubation failure and the need for reintubation, exhibiting an inverse correlation with those outcomes, as the study by Fávero et al.⁽¹1. Fávero RA, Schuster RC, Wojahn VW, Tartari JL. Incidência e principais fatores associados à falha na extubação em recém-nascidos prematuros. Pediatria (São Paulo). 2011;33(1):13-20.⁾ showed. That fact might be related to the anatomical and physiological immaturity of the respiratory system,⁽¹⁵15. Oliveira CH, Moran CA. Estudo descritivo: ventilação mecânica não invasiva em recém-nascidos pré-termo com síndrome do desconforto respiratório. ConScientiae Saúde. 2009;8(3):485-9.⁾ leading to greater chest and upper airway instability that hinder successful extubation.⁽¹¹11. Hermeto F, Bottino MN, Vaillancourt K, Sant'Anna GM. Implementation of a respiratory therapist-driven protocol for neonatal ventilation: impact on the premature population. Pediatrics. 2009;123(5):e907-16.⁾ Similarly, although in contrast to the results of the multivariate analysis in the present study, infants with BW<1,000 g exhibit high morbidity rates, which increase their energy expenditure and nutritional requirements, thus impairing the respiratory function, which is nutrition dependent.⁽¹⁶16. Martin CR, Brown YF, Ehrenkranz RA, O'Shea TM, Allred EN, Belfort MB, McCormick MC, Leviton A; Extremely Low Gestational Age Newborns Study Investigators. Nutritional practices and growth velocity in the first month of life in extremely premature infants. Pediatrics. 2009;124(2):649-57.⁾

The postnatal use of corticosteroids or xanthines did not exhibit a significant association with extubation failure and the need for reintubation. Other studies found that postnatal corticosteroids improve lung function and reduce the incidence of chronic pulmonary disease in newborns.⁽¹⁷17. Halliday HL, Ehrenkranz RA, Doyle LW. Early (< 8 days) postnatal corticosteroids for preventing chronic lung disease in preterm infants. Cochrane Database Syst Rev. 2010;(1):CD001146.⁾ Similarly, other studies have indicated the effectiveness of xanthines in the prevention of prematurity-related apnea and the reduction of extubation failure through the stimulation of the central nervous system.⁽¹⁸18. Zhao J, Gonzalez M, Mu D. Apnea of prematurity: from cause to treatment. Eur J Pediatr. 2011;170(9):1097-105^,¹⁹19. Aranda JV, Beharry K, Valencia GB, Natarajan G, Davis J. Caffeine impact on neonatal morbidities. J Matern Fetal Neonatal Med. 2010;23 Suppl 3:20-3. Review.⁾

Some of the limitations of this study derive from the fact that it was conducted at a single center and had an observational nature, and thus, it does not allow for any causal inference but only for the identification of significant associations. Furthermore, the investigator who performed the data collection was not blinded to the infants' outcomes. In addition, the minimum period of time between sample collection for blood gas analysis and extubation was not standardized, which is relevant, as although the samples were collected when the infants were clinically stable, factors such as crying, irritability and instability caused by pain might have interfered with the results. Finally, only survivors were analyzed, which is an intrinsic limitation of the object under study but might also be a source of bias.

CONCLUSION

The variables five-minute Apgar score, MV length, acid-base disorders and hyperoxia exhibited association with the investigated outcomes of extubation failure and reintubation. These data might contribute to decision-making regarding favorable time and conditions for extubation success and non-reintubation in newborn infants.

REFERÊNCIAS

¹
Fávero RA, Schuster RC, Wojahn VW, Tartari JL. Incidência e principais fatores associados à falha na extubação em recém-nascidos prematuros. Pediatria (São Paulo). 2011;33(1):13-20.
²
Davidson J, Miyoshi MH, Santos AM, Carvalho WB. Medida da frequência respiratória e do volume corrente para prever a falha na extubação de recém-nascidos de muito baixo peso em ventilação mecânica. Rev Paul Pediatr. 2008;26(1):36-42.
³
Cruces P, Donoso A, Montero M, López A, Fernández B, Díaz F, et al. Predicción de fracaso de extubación en pacientes pediátricos: experiencia de dos años en una UCI polivalente. Rev Chil Med Intensiv. 2008;23(1):12-7.
⁴
Victor S; Extubate Trial Group. EXTUBATE: a randomised controlled trial of nasal biphasic positive airway pressure vs. nasal continuous positive airway pressure following extubation in infants less than 30 weeks' gestation: study protocol for a randomised controlled trial. Trials. 2011;12:257.
⁵
Newth CJ, Venkataraman S, Willson DF, Meert KL, Harrison R, Dean JM, Pollack M, Zimmerman J, Anand KJ, Carcillo JA, Nicholson CE; Eunice Shriver Kennedy National Institute of Child Health and Human Development Collaborative Pediatric Critical Care Research Network. Weaning and extubation readiness in pediatric patients. Pediatr Crit Care Med. 2009;10(1):1-11.
⁶
Andrade LB, Melo TM, Morais DF, Lima MR, Albuquerque EC, Martimiano PH. Avaliação do teste de respiração espontânea na extubação de neonatos pré-termo. Rev Bras Ter Intensiva. 2010;22(2):159-65.
⁷
Johnston C, Piva JP, Carvalho WB, Garcia PC, Fonseca MC, Hommerding PX. Preditores de falha da extubação em crianças no pós-operatório de cirurgia cardíaca submetidas à ventilação pulmonar mecânica. Rev Bras Ter Intensiva. 2008;20(1):57-62.
⁸
Kurachek SC, Newth CJ, Quasney MW, Rice T, Sachdeva RC, Patel NR, et al. Extubation failure in pediatric intensive care: a multiple-center study of risk factors and outcomes. Crit Care Med. 2003;31(11):2657-64. Erratum in Crit Care Med. 2004;32(7):1632-3. Scanlon Mathew [corrected to Scanlon Matthew].
⁹
Hermeto F, Martins BM, Ramos JR, Bhering CA, Sant'Anna GM. Incidence and main risk factors associated with extubation failure in newborns with birth weight < 1,250 grams. J Pediatr (Rio J). 2009;85(5):397-402.
¹⁰
Danan C, Durrmeyer X, Brochard L, Decobert F, Benani M, Dassieu G. A randomized trial of delayed extubation for the reduction of reintubation in extremely preterm infants. Pediatr Pulmonol. 2008;43(2):117-24.
¹¹
Hermeto F, Bottino MN, Vaillancourt K, Sant'Anna GM. Implementation of a respiratory therapist-driven protocol for neonatal ventilation: impact on the premature population. Pediatrics. 2009;123(5):e907-16.
¹²
Aschner JL, Poland RL. Sodium bicarbonate: basically useless trerapy. Pediatrics. 2008;122(4):831-5.
¹³
Sociedade Portuguesa de Neonatologia. Acidose e alcalose: consenso nacional. [citado 2012 Dez 15]. Viseu, Portugal; 2008. Disponível em: http://www.lusoneonatologia.com/admin/ficheiros_projectos/201107201805-acidose_e_alcalose__2008.pdf
» http://www.lusoneonatologia.com/admin/ficheiros_projectos/201107201805-acidose_e_alcalose__2008.pdf
¹⁴
Teixeira AB, Xavier CC, Lamounier JA, Tavares EC. Hiperóxia e risco aumentado de displasia broncopulmonar em prematuros. Rev Paul Pediatr. 2007;25(1):47-52.
¹⁵
Oliveira CH, Moran CA. Estudo descritivo: ventilação mecânica não invasiva em recém-nascidos pré-termo com síndrome do desconforto respiratório. ConScientiae Saúde. 2009;8(3):485-9.
¹⁶
Martin CR, Brown YF, Ehrenkranz RA, O'Shea TM, Allred EN, Belfort MB, McCormick MC, Leviton A; Extremely Low Gestational Age Newborns Study Investigators. Nutritional practices and growth velocity in the first month of life in extremely premature infants. Pediatrics. 2009;124(2):649-57.
¹⁷
Halliday HL, Ehrenkranz RA, Doyle LW. Early (< 8 days) postnatal corticosteroids for preventing chronic lung disease in preterm infants. Cochrane Database Syst Rev. 2010;(1):CD001146.
¹⁸
Zhao J, Gonzalez M, Mu D. Apnea of prematurity: from cause to treatment. Eur J Pediatr. 2011;170(9):1097-105
¹⁹
Aranda JV, Beharry K, Valencia GB, Natarajan G, Davis J. Caffeine impact on neonatal morbidities. J Matern Fetal Neonatal Med. 2010;23 Suppl 3:20-3. Review.

Publication Dates

Publication in this collection
Jan-Mar 2014

History

Received
22 Aug 2013
Accepted
14 Jan 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Fávero RA, Schuster RC, Wojahn VW, Tartari JL. Incidência e principais fatores associados à falha na extubação em recém-nascidos prematuros. Pediatria (São Paulo). 2011;33(1):13-20.

[2] ²
Davidson J, Miyoshi MH, Santos AM, Carvalho WB. Medida da frequência respiratória e do volume corrente para prever a falha na extubação de recém-nascidos de muito baixo peso em ventilação mecânica. Rev Paul Pediatr. 2008;26(1):36-42.

[3] ³
Cruces P, Donoso A, Montero M, López A, Fernández B, Díaz F, et al. Predicción de fracaso de extubación en pacientes pediátricos: experiencia de dos años en una UCI polivalente. Rev Chil Med Intensiv. 2008;23(1):12-7.

[4] ⁴
Victor S; Extubate Trial Group. EXTUBATE: a randomised controlled trial of nasal biphasic positive airway pressure vs. nasal continuous positive airway pressure following extubation in infants less than 30 weeks' gestation: study protocol for a randomised controlled trial. Trials. 2011;12:257.

[5] ⁵
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Variable	Failure	p value
Yes N (%)	No N (%)
Gestational age			0.017
≤28 weeks	3 (12.5)	5 (3.4)
>28 to ≤32 weeks	8 (33.3)	35 (23.5)
>32 to ≤36 weeks	3 (12.5)	47 (31.5)
>36 weeks	10 (41.7)	62 (41.6)
Weight			0.005
≤1,000g	12 (48.0)	27 (18.0)
1,000g to ≤1,500g	2 (8.0)	43 (28.7)
>1,500g to ≤2,000g	3 (12.0)	20 (13.3)
>2,000g to ≤2,500g	1 (4.0)	21 (14.0)
>2,500g	7 (28.0)	39 (26.0)
Female gender	15 (60.0)	74 (49.0)	0.631
Antenatal corticosteroids	11 (57.9)	69 (53.9)	0.475
Surfactant	16 (64.0)	86 (57.0)	0.619
Postnatal corticosteroids	23 (92.0)	144 (95.4)	0.227
Xanthines	9 (36.0)	64 (42.4)	0.551
1-minute Apgar	5.1 (2.9)	6.3 (2.4)
5-minute Apgar	7.1 (2.7)	8.2 (1.6)	0.006
MV length (days)	5.0 (5.3)	6.1 (7.8)	0.051
OT brand	8.3 (1.4)	8.5 (1.1)	0.346
Age at extubation	6.3 (7.3)	8.0 (9.2)	0.023
FiO₂	26.6 (6.4)	26.1 (8.9)	0.624
PIP	14.8 (0.4)	14.7 (0.7)	0.592
PEEP	4.8 (0.4)	4.7 (0.5)	0.910
TI	0.3 (0.04)	0.3 (0.03)	0.941
RR	28.2 (5.2)	27.5 (5.1)	0.607
MAP	7.4 (0.8)	7.0 (1.0)	0.063
Flow	6.8 (0.8)	6.9 (0.8)	0.661
pH	7.36 (0.08)	7.42 (0.09)	0.019
PaCO₂	32.0 (10.1)	31.7 (10.7)	0.987
PO₂	100.4 (76.1)	81.9 (39.5)	0.099
StO₂	90.6 (7.2)	90.2 (10.6)	0.559
Bicarbonate	17.8 (3.3)	19.9 (5.1)	0.054
BE	-5.1 (5.4)	-2.0 (5.4)	0.020

Independent variable	Categories	OR	95%CI OR	p value
Constant	-	-	-	0.015
MV length (days)	-	0.843	0.728-0.975	0.021
pH	-	0.001	0.001-0.220	0.016
PO₂	-	1.012	1.002-1.023	0.024

Variable	Reintubation	p value
No N (%)	Yes N (%)
Gestational age			<0.001
≤28 weeks	8 (4.6)	11 (17.7)
>28 to ≤32 weeks	43 (24.9)	28 (45.2)
>32 to ≤36 weeks	50 (28.9)	10 (16.1)
>36 weeks	72 (41.6)	13 (21.0)
Weight			0.003
≤1,000g	39 (22.3)	34 (52.3)
>1,000g a ≤1,500g	45 (25.7)	14 (21.5)
>1,500g a ≤2,000g	23 (13.1)	4 (6.2)
>2,000g a ≤2,500g	22 (12.6)	1 (1.5)
>2,500g	46 (26.3)	12 (18.5)
Female gender	89 (50.6)	43 (66.2)	0.186
Antenatal corticosteroids	67 (45.6)	13 (27.1)	0.319
Surfactant	74 (42.0)	15 (23.1)	0.547
Postnatal corticosteroids	167 (94.9)	55 (86.4)	0.138
Xanthines	73 (41.5)	16 (24.6)	0.683
1-minute Apgar	6.1 (2.5)	5.4 (2.7)
5-minute Apgar	8.0 (1.9)	7.5 (2.3)	0.001
MV length (days)	6.0 (7.5)	7.9 (7.8)	0.458
OT brand	8.5 (1.2)	8.1 (1.2)	0.007
Age at extubation	7.8 (9.0)	26.7 (17.8)	<0.001
FiO₂	26.2 (8.6)	28.9 (9.8)	0.405
PIP	14.7 (0.6)	14.8 (0.7)	0.384
PEEP	4.8 (0.5)	4.8 (0.6)	0.460
TI	0.34 (0.03)	0.33 (0.02)	<0.001
RR	27.6 (5.1)	28.7 (5.2)	0.166
MAP	7.0 (1.0)	7.0 (1.2)	0.869
Flow	6.96 (0.83)	6.85 (0.77)	0.009
PH	7.42 (0.09)	7.40 (0.06)	0.637
PaCO₂	31.7 (10.6)	35.2 (9.9)	0.072
PO₂	84.4 (46.1)	67.8 (33.0)	0.019
StO₂	90.2 (10.2)	87.6 (10.0)	0.374
Bicarbonate	19.6 (5.0)	21.4 (5.2)	0.024
BE	-2.4 (5.5)	-1.7 (4.8)	0.590

Independent variable	Categories	OR	95%CI OR	p value
Constant	-	-	-	0.631
5-minute Apgar	-	0.632	0.490-0.815	<0.001
Age at extubation	-	1.137	1.088-1.189	<0.001

Brasil

Brasil

Predictors of extubation failure and reintubation in newborn infants subjected to mechanical ventilation

Abstracts

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INTRODUCTION

METHODS

RESULTS

DISCUSSION

CONCLUSION

REFERÊNCIAS

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