Manual vibrocompression and nasotracheal suctioning in
               post-operative period of infants with heart deffects

Assumpção, Maíra Seabra de; Gonçalves, Renata Maba; Krygierowicz, Lúcia Cristina; Orlando, Ana Cristina T.; Schivinski, Camila Isabel S.

doi:10.1590/S0103-05822013000400014

Abstracts

OBJECTIVE:

To evaluate the impact of manual vibrocompression and nasotracheal suctioning on heart (hr) and respiratory (rr) rates, peripheral oxygen saturation (SpO₂), pain and respiratory distress in infants in the postoperative period of a cardiac surgery.

METHODS:

Randomized controlled trial, in which the assessments were performed by the same physiotherapist in two moments: before and after the procedure. The infants were randomly divided into two groups: Intervention (IG), with manual chest vibrocompression, nasotracheal suctioning and resting; and Control CG), with 30 minutes of rest. Cardiorespiratory data (SpO₂; hr; rr) were monitored and the following scales were used: Neonatal Infant Pain Scale (NIPS), for pain evaluation, and Bulletin of Silverman-Andersen (BSA), for respiratory distress assessment. The data were verified by analysis of variance (ANOVA) for repeated measures, being significant p<0.05.

RESULTS:

20 infants with heart disease, ten in each group (seven acyanotic and three cyanotic) were enrolled, with ages ranging from zero to 12 months. In the analysis of the interaction between group and time, there was a significant difference in the variation of SpO₂ (p=0.016), without changes in the other variables. Considering the main effect on time, only rr showed a significant difference (p=0.001). As for the group main effect, there were no statistical differences (SpO₂ - p=0.77, hr - p=0.14, rr - p=0.17, NIPS - p=0.49 and BSA - p=0.51 ).

CONCLUSIONS:

The manual vibrocompression and the nasotracheal suctioning applied to infants in postoperative of cardiac surgery did not altered SpO₂and rr, and did not trigger pain and respiratory distress. [Brazilian Registry of Clinical Trials (ReBEC): REQ: 1467].

physical therapy modalities; infant; thoracic surgery; pain; postoperative care

OBJETIVO:

Verificar la repercusión de la vibrocompresión manual y de la aspiración nasotraqueal sobre parámetros cardiorrespiratorios de frecuencia cardíaca (fc) y respiratoria (fr), saturación periférica de oxígeno (SpO₂), dolor y dificultad respiratoria, en lactantes en el post-operatorio de cirugías cardíacas.

MÉTODOS:

Estudio controlado y randomizado, con las evaluaciones realizadas por la misma fisioterapeuta, en dos momentos: antes y después del procedimiento. Se dividió el total de lactantes en dos grupos, por sorteo simple: Intervención (G_I), con vibrocompresión manual torácica, aspiración nasotraqueal y reposo; y Control (G_C), con 30 minutos de reposo. Se evaluaron los datos cardiorrespiratorios (SpO₂; fc; fr), aplicándose las escalas: Neonatal Infant Pain Scale (NIPS), para analizar el dolor, y Boletín de Silvermann-Andersen (BSA), para verificar la dificultad respiratoria. Los datos fueron tratados mediante análisis de variancia (ANOVA) para medidas repetidas, siendo significante p<0,05.

RESULTADOS:

Se evaluaron 20 lactantes cardiópatas, diez en cada grupo (siete acianóticos y tres cianóticos), con edades de cero a 12 meses. Para analizar la interacción entre el grupo y el tiempo, se observó diferencia significativa en la variación de la SpO₂ (p=0,016), sin alteración en las demás variables. El comportamiento de los parámetros en los tiempos, a su vez, presentó diferencia significativa solamente en la variación de la fr (p=0,001). Respecto a la evaluación del efecto en el grupo, no hubo diferencia estadística en cualquiera de los datos (SpO₂ - p=0,77; fc - p=0,14; fr - p=0,17; NIPS - p=0,49 e BSA - p=0,512).

CONCLUSIONES:

La vibrocompresión manual y la aspiración nasotraqueal aplicadas a lactantes en el post-operatorio de cirugías cardíacas no perjudican la SpO₂ y la fr, además de no desencadenar dolor y dificultad respiratoria. Registro Brasileño de Ensayos Clínicos (ReBEC): REQ: 1467.

modalidades de fisioterapia; lactante; cirugía torácica; dolor; cuidados post-operatorios

OBJETIVO:

Verificar a repercussão da vibrocompressão manual e da aspiração nasotraqueal sobre os parâmetros cardiorrespiratórios de frequência cardíaca (fc) e respiratória (fr), saturação periférica de oxigênio (SpO₂), dor e desconforto respiratório, em lactentes no pós-operatório de cirurgias cardíacas.

MÉTODOS:

Estudo controlado e randomizado, com as avaliações realizadas pela mesma fisioterapeuta, em dois momentos: antes e após o procedimento. Dividiu-se o total de lactentes, por sorteio simples, em dois grupos: Intervenção (G_I), com vibrocompressão manual torácica, aspiração nasotraqueal e repouso; e Controle (G_C), com 30 minutos de repouso. Avaliaram-se os dados cardiorrespiratórios (SpO₂; fc; fr), aplicando-se as escalas: Neonatal Infant Pain Scale (NIPS), para analisar a dor, e Boletim de Silvermann-Andersen (BSA), para verificar o desconforto respiratório. Os dados foram tratados por meio de análise de variância (ANOVA) para medidas repetidas, sendo significante p<0,05.

RESULTADOS:

Avaliaram-se 20 lactentes cardiopatas, dez em cada grupo (sete acianóticos e três cianóticos), com idades de zero a 12 meses. Para analisar a interação entre o grupo e o tempo, observou-se diferença significativa na variação da SpO₂ (p=0,016), sem alteração nas demais variáveis. Já o comportamento dos parâmetros nos tempos apresentou diferença significativa apenas na variação da fr (p=0,001). Quanto à avaliação do efeito no grupo, não houve diferença estatística em nenhum dos dados (SpO₂ - p=0,77; fc - p=0,14; fr - p=0,17; NIPS - p=0,49 e BSA - p=0,51).

CONCLUSÕES:

A vibrocompressão manual e a aspiração nasotraqueal aplicadas em lactentes no pós-operatório de cirurgias cardíacas não prejudicaram a SpO₂ e a fr, além de não desencadearem dor e desconforto respiratório. [Registro Brasileiro de Ensaios Clínicos (ReBEC): REQ: 1467].

modalidades de fisioterapia; lactente; cirurgia torácica; dor; cuidados pós-operatórios

Introduction

Congenital hearts diseases are one of the main causes of death in newborn infants⁽ ¹1. Silva ZM, Perez A, Pinzon AD, Ricachinewsky CP, Rech DR, Lukrafka JL et al. Factors associated with failure in ventilatory weaning of children undergone pediatric cardiac surgery. Rev Bras Cir Cardiovasc 2008;23:501-6. ⁾ and, in most cases, their etiology is not known yet. However, it is known that several causes are associated with their occurrence, such as prenatal and genetic factors, as well as maternal age⁽ ²2. Souza P, Scatolin BE, Ferreira LM, Croti UA. The nursing team relationship with the child and the family in immediate postoperative period of congenital heart defects. Arq Cienc Saude 2008;15:163-9. ⁾. Congenital heart diseases may be classified and divided into two groups: acyanotic and cyanotic, based on pulmonary circulation conditions, such as blood volume, flow, venocapillary pressure, and resistance⁽ ³3. Vieira TC, Trigo M, Alonso RR, Ribeiro RH, Cardoso MR, Cardoso AC et al. Assessment of food intake in infants between 0 and 24 months with congenital heart disease. Arq Bras Cardiol 2007;89:219-24. ⁾.

In the last two decades, technological advances and improvements, both in the identification and treatment of congenital heart diseases, contributed to the knowledge of their pathophysiology and their impact. In this sense, it is currently known that cardiac surgical corrections lead to a number of complications in the newborn and the infant, especially respiratory alterations. These complications are related to poor pulmonary and cardiac function in the preoperative period, prolonged extracorporeal circulation, and high degree of sedation⁽ ⁴4. João PR, Faria Junior F. Immediate post-operative care following cardic surgery. J Pediatr (Rio J) 2003;79 (Suppl 2):S213-22. ⁾.

In this context, these children usually exhibit abnormalities of respiratory mechanics. Increases in pulmonary artery pressure and pulmonary blood flow are associated with decreased lung compliance and increased airway resistance⁽ ⁵5. Stayer SA, Diaz LK, East DL, Gouvion JN, Vencill TL, McKenzie ED et al. Changes in respiratory mechanics among infants undergoing heart surgery. Anesth Analg 2004;98:49-55. ⁾. Hence, alterations in cardiorespiratory data become evident, as well as the manifestation of signs of respiratory distress, defined, according to the Brazilian Society of Pediatrics, as increased respiratory rate, effort or inadequate thoracic excursion, decrease in peripheral breath sounds, groaning breath or shortness of breath, decreased level of consciousness or response to pain, decreased muscle tone, or the presence of cyanosis⁽ ⁶6. Sociedade Brasileira de Pediatria [homepage on the Internet]. Portal da Sociedade Brasileira de Pediatria [cited 2012 Dec 12]. Available from: http://www.sbp.com.br/
Available from: htt... ⁾. The analysis of these parameters is routine in the care of infants with heart disease at Intensive Care Units (ICU). The measurement and quantification of these data contribute to more comprehensive evaluations, especially in the control of manipulations, therapies and interventions. Pain is another element that requires attention, because it causes behavioral changes due to the lability of this group and its clinical condition.

In face of impaired breathing, a common event in the postoperative period, respiratory physiotherapy is recommended and significantly acts for a better prognosis in pediatric patients who underwent cardiac surgery. Its role is recognized in the prevention and treatment of pulmonary complications, by means of specific techniques⁽ ⁷7. Cavenaghi S, Moura SC, Silva TH, Venturinelli TD, Marino LH, Lamari NM. Importance of pre- and postoperative physiotherapy in pediatric cardic surgery. Rev Bras Cir Cardiovasc 2009;24:397-400. ^, ⁸8. Moerman D, Clément de Cléty S. La kinésithérapie respiratoire chez l'enfant après chirurgie cardiaque congénitale. Réanimation 2010;19:179-84. ⁾. However, in the pediatric population with heart disease, there are still few studies on the impact of conventional respiratory techniques, described in the 1994 Consensus of Lyon⁽ ⁹9. Feltrim MI, Parreira VF. Fisioterapia respiratória. Proceedings of the 1ª Conferência de Consenso em Fisioterapia Respiratória; 1994 Dec 2-3; Lyon, França. p. 8-47. ⁾ as those designed to remove bronchial secretions, notably manual vibration, nasotracheal suctioning, postural drainage, chest percussion, chest compression, and cough. Despite of that, these are routine techniques in intensive care units⁽ ¹⁰10. Zimmerman AT, Ibsen LM. Advances in postoperative care of pediatric cardiac patients. Curr Opin Anaesthesiol 2004;17:241-6. ⁾, i.e., although the indication for physiotherapy in these patients is found in the literature⁽ ¹¹11. Felcar JM, Guitti JC, Marson AC, Cardoso JR. Preoperative physiotherapy in prevention of pulmonary complications in pediatric cardic surgery. Rev Bras Cir Cardiovasc 2008;23:383-8.

12. Ribeiro IF, de Melo AP, Davidson J. Chest physical therapy in newborn infants with patent ductus arteriosus and pulmonary complications. Rev Paul Pediatr 2008;26:77-83. ^- ¹³13. Arcêncio L, Souza MD, Bortolin BS, Fernandes AC, Rodrigues AJ, Evora PR. Pre-and postoperative care in cardiothoracic surgery: a physiotherapeutic approach. Rev Bras Cir Cardiovasc 2008;23:400-10. ⁾, the impact of these techniques is little discussed or addressed when it comes to infants diagnosed with acyanotic or cyanotic heart diseases, in the postoperative period of cardiac surgery.

In view of these factors, the present study evaluated the impact of manual vibrocompression and nasotracheal suctioning on cardiorespiratory parameters, such as heart rate (hr), respiratory rate (rr), and peripheral oxygen saturation (SpO₂), as well as on respiratory distress and pain, in infants in the postoperative period of cardiac surgery. In this sense, we expect that conventional physiotherapeutic techniques - manual vibrocompression and nasotracheal suctioning - may provide a positive impact on the above-mentioned parameters.

Method

This is a randomized controlled trial, approved by the Research Ethics Committee (CEP 998-11) of Hospital Pequeno Príncipe, Curitiba, Southern Brazil. Data from the cardiology ICU of the hospital were collected from November 2011 to February 2012. Before including the infants, their guardians were informed on the purposes, procedures, risks and benefits of the study and expressed their agreement in participating in the study by signing a written informed consent.

Infants of both genders from zero a 12 months and diagnosed with acyanotic or cyanotic congenital heart disease in the postoperative period of cardiac surgery were included in the study (Table 1). All of them were extubated, hemodynamically stable, and were not using sedatives or analgesics on data collection. Patients started respiratory physiotherapy only after medical authorization and prescription.

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Table 1
Demographic characteristics of the study patients

We excluded infants with neurological and/or neuromuscular diseases, syndromic alterations, open chest, hemodynamic instabilities and those who presented with anasarca or were on peritoneal dialysis. Table 2 describes heart diseases, according to groups, as for type of heart disease, surgical correction, postoperative time (PO), extracorporeal circulation time (ECC), and mechanical ventilation time (MV).

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Table 2
Description of cyanotic and acyanotic heart diseases according to groups, in terms of type of heart disease, surgical correction, postoperative time in days, extracorporeal circulation time in minutes and mechanical ventilation time in days

Sample size calculation considered a variation of 3% in SpO₂, with standard deviation equal to 3, taking into account a significance level of 5% and power of 85% in a two-tailed hypothesis test⁽ ¹⁴14. Armitage P, Berry G, Matthews JNS. The planning of statistical investigations. In: Armitage P, Berry G, editors. Statistical methods in medical research. 2nd ed. Oxford: Blackwell; 1987. p. 179-85. ⁾, obtaining a total of nine individuals in each group.

After checking medical charts and evaluating patient's clinical picture together with the medical team, the selected infants were randomly assigned into Control Group (CG) and Intervention Group (IG).

The CG remained at rest for 30 minutes. During this period, there was no manual contact, only visual observation of the parameters evaluated in the study. The IG underwent manual chest vibrocompression for ten minutes (rhythmic and rapid movements of isometric contraction of the forearm, manually applied on the anterior region of the chest, at the quadrants of right and left lung apices simultaneously, in the expiratory phase, associated with chest compression)⁽ ¹⁵15. Postiaux G. Fisioterapia respiratória pediátrica: o tratamento guiado por ausculta pulmonar. 2nd ed. Porto Alegre: Artmed; 2004. ⁾. Then nasotracheal suctioning was performed (for approximately 30 seconds)⁽ ¹⁶16. Autoria não referida. AARC clinical practice guideline. Nasotracheal suctioning - 2004 revision & update. Respir Care 2004;49:1080-4. ⁾. This procedure lasted for five minutes, including the preparation of the materials, the beginning and the end of the maneuver, and the positioning of the infant on bed; afterwards, 15 additional minutes of rest were considered (visual observation by the examiner). Thus, the session had an overall duration of 30 minutes (manual chest vibrocompression, nasotracheal suctioning, and rest). The intervention was carried out only once, always by the same physiotherapist (MSA), who also conducted all the described evaluations, always respecting the sequence of the procedures. The study considered the data of an only session for each infant.

Both groups were first evaluated in terms of cardiorespiratory parameters (hr, rr and SpO₂) and subsequently in terms of signs of respiratory distress and pain, before and after intervention or rest (T_pre and T_postrespectively).

To evaluate cardiorespiratory parameters, hr and SpO₂ were analyzed by checking the monitor available at the cardiology ICU (Dixtal Monitor Dx2021^(r)), recording the prevailing value during one minute. Rr was counted for one minute by observing infant's chest and abdominal movements, in order to confirm the beginning and the end of each respiratory cycle.

Subsequently, signs of respiratory distress were investigated by the Bulletin of Silvermann-Andersen (BSA), used in other studies with infants⁽ ¹⁷17. Ajambuja AZ, Parazzi PL, Ries LG, Schivinski CI. Immediate effects of thoraco-abdominal rebalance in children with gastroesophageal reflux disease - case series report. ConScientiae Saude 2012;11:607-17.

18. Barbié L, Caillat-Miousse JL, Vion V. La détresse respiratoire du nourrisson atteint de bronchiolite: aspiration ou désobstruction rhino-pharyngée? Rev Kinesither 2009;9:49-54.

19. Lanza FC, Cadrobbi C, Gazzotti MR, Faria R, Luque A, Solé D. Respiratory physiotherapy for nurslings with bronchiolitis: should we do it or not? Mundo Saude 2008;32:183-8.

20. Gómez-y-López RE, Hernández-Sierra JF, Torres-Ruvalcaba BA, Martínez-Puente E, Martínez-Garcia MC. Uso de dexametasona y salbutamol nebulizados en bronquiolitis aguda: estudio clínico comparativo. Gac Med Mex 2007;143:189-92. ^- ²¹21. Osnaya-Romero N, de Jesus Medina-Hernández T, Flores-Hernández SS, León-Rojas G. Clinical symptoms observed in children envenomated by scorpion stings, at the children's hospital from the State of Morelos, Mexico. Toxicon 2001;39:781-5. ⁾ and described for use beyond the neonatal period in the Série de Atualização de Reciclagem em Pneumologia of the Sociedade Paulista de Pneumologia e Tisiologia (SPPT), in 2011⁽ ²²22. Liberali J, Lanza FC. Atuação da fisioterapia respiratória no paciente pediátrico hospitalizado: novas perspectivas. In: Nápolis LM, Chiavegato LD, Nascimento O, editors. Fisioterapia Respiratória. Série Atualização e Reciclagem em Pneumologia - SPPT. São Paulo: Atheneu; 2011. p. 59-70. ⁾. The BSA assesses the following items: expiratory grunting, nostril flaring, intercostal retraction, sternal retraction, and paradoxical breathing. Its score ranges from zero (no respiratory distress) to ten (maximum respiratory distress), with the score from one to five being considered moderate distress, and, from six to ten, severe distress⁽ ²³23. Almeida MF, Kopelman BI. Rotinas médicas: disciplina de pediatria neonatal da Escola Paulista de Medicina. São Paulo: Atheneu; 1994. ⁾.

The Neonatal Infant Pain Scale (NIPS) was used to evaluate pain. This scale considers the following parameters: facial expression (zero or one point), cry (zero, one or two points), breathing patterns (zero or one point), position of legs (zero or one point), position of arms (zero or one point) and state of arousal (zero or one point). Pain is present when the score is higher than or equal to four⁽ ²⁴24. Lawrence J, Alcock D, McGrath P, Kay J, MacMurray SB, Dulberg C. The development of a tool to assess neonatal pain. Neonatal Netw 1993;12:59-66. ⁾. The NIPS was used in infants based on the study by Pereira et al ⁽ ²⁵25. Pereira e Silva Y, Gomez RS, Máximo TA, Simões e Silva AC. Pain evaluation in Neonatology. Rev Bras Anestesiol 2007;57:565-74. ⁾ and on the document entitled Atenção à saúde do recém-nascido: Guia para profissionais de saúde ⁽ ²⁶26. Brasil - Ministério da Saúde. Secretaria de atenção à saúde - Departamento de ações programáticas e estratégicas. Atenção à saúde do recém-nascido: guia para os profissionais de saúde - intervenções comuns, icterícia e infecções. Brasília: Ministério da Saúde; 2011. ⁾. None of these references validate the application of this scale beyond the neonatal period. Despite this limitation, its use is justified by the lack of instruments of this nature in the aforementioned age group.

Data were analyzed using the Statistical Package for the Social Sciences (SPSS) software, version 20.0. Results were presented by descriptive and frequency statistics and expressed as means and standard deviation. The behavior of the variables in the groups (IG and CG) and at the two time points of data collection, T_pre and T_post, was assessed by analysis of variance (ANOVA) for repeated measures, with three main effects: time, group and the interaction of both, with significance set at p<0.05.

Results

Twenty infants participated in the study, assigning ten in each group. Subjects' age ranged from zero to 12 months, with mean of 4.67±3.61 months in the CG (0.23 to 9.00) and of 5.04±4.10 in the IG (0.50 to 11.00) (p=0.790). Table 1 shows age, sex distribution, extubation time, type of corrected heart disease and surgical incision.

Table 3 describes descriptive data for hr, rr and SpO₂ in the IG and in the CG at the two study time points. There was no significant difference in SpO₂ (p=0.77), hr (p=0.146), rr (p=0.166), NIPS (p=0.4.88) and BSA (p=0.512) between T_pre and T_post, in any of the groups.

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Table 3
Descriptive data of the cardiorespiratory parameters hr, rr and SpO2, in IG and CG, before and after one of the procedu res (intervention or rest), and the result of the comparison of study parameters at Tpre and Tpost, according to the ANOVA test for repeated measures

Considering the interaction between group and time, it was observed that the group in which the infant was assigned at the two time points significantly interfered with the variation in SpO₂ (p=0.016), with CG showing a decrease from 91.5±4.38% (at T_pre) to 90.5±6.22% (at T_post); in the IG, there was an increase from 89.0±8.73 to 91.2±8.26%, at the T_pre and T_post, respectively. On the other hand, with regard to the remaining parameters (hr, rr, NIPS and BSA), group allocation did not have a significant effect (p=0.867; 0.585; 0.851; 0.170, respectively) (Table 3).

Considering the main effect on time, only rr showed a significant difference (p=0.001). In both groups, there was a decrease in this variable from T_pre to T_post (from 56.2±51.0 to 51.0±11.65 in the IG and from 48.6±11.50 to 44.7±10.58 in the CG). However, this behavior was not observed in the other variables (Table 3). Figure 1 graphically represents the change in means for rr, hr and SpO₂ before and after the procedures (rest or intervention), according to each group (CG and IG).

Figure 1
Behavior of mean values for respiratory rate (rr), heart rate (hr) and peripheral oxygen saturation (SpO2) of infants with heart disease at the different time points (Tpre and Tpost), in each of the two study groups

As for the main effect on the group, there was no significant difference in any of the study variables: rr (p=0.166), hr (p=0.146), SpO₂ (p=0.777), NIPS (p=0.488) and BSA (p=0.512) (Table 3).

In the IG, NIPS scores ranged from zero to seven (0.90±2.18); in the CG, this variation was also from zero to seven points (1.70±2.11). In the IG, one infant had a score compatible with pain at the beginning of the procedure and kept this pattern at the end of assessments. This also happened with one infant in the CG. In addition, eight infants in this group did not have a score corresponding to pain, four of which did not change their score before and after the procedure. One infant who initially had a score compatible with the presence of pain had a score corresponding to the absence of the symptom at the end of the procedure.

As for BSA score for respiratory distress, three infants showed improvement in signs (from moderate to absence) and none of them showed moderate to severe distress after intervention in the IG. In the CG, four infants did not show changes in any of the time points and three showed improvement, with two cases from severe to moderate and one from moderate to absence.

Discussion

Despite the frequent recommendation of respiratory physiotherapy in the postoperative period of cardiac surgery and the wide range of physiotherapeutic techniques used to revert pulmonary dysfunction or negative pathophysiological changes⁽ ¹²12. Ribeiro IF, de Melo AP, Davidson J. Chest physical therapy in newborn infants with patent ductus arteriosus and pulmonary complications. Rev Paul Pediatr 2008;26:77-83. ^, ²⁷27. Wallis C, Prasad A. Who needs chest physiotherapy? Moving from anecdote to evidence. Arch Dis Child 1999;80:393-7. ⁾ in this period, there is no consensus about the best method to use⁽ ²⁸28. Renault JA, Costa-Val R, Rossetti MB. Respiratory physiotherapy in the pulmonary dysfunction after cardic surgery. Rev Bras Cir Cardiovasc 2008;23:562-9. ⁾.

Manual vibrocompression aims for a better lung deflation, to displace middle airways secretions to proximal airways and thus to the trachea, facilitating the process of mucus elimination⁽ ²⁹29. McIlwaine M. Physiotherapy and airway clearance techniques and devices. Paediatr Respir Rev 2006;7 (Suppl 1):S220-2.

30. Van der Schans CP. Airway clearance: assessment of techniques. Paediatr Respir Rev 2002;3:110-4. ^- ³¹31. Johnston C, Zanetti NM, Comaru T, Ribeiro SN, Andrade LB, Santos SL. I Brazilian guidelines for respiratory physiotherapy in pediatric and neonatal intensive care units. Rev Bras Ter Intensiva 2012;24:119-29. ⁾. This mechanism of action is an important aspect to be considered when one aims to assess the efficacy of manual techniques in intensive care⁽ ³²32. Shannon H, Stiger R, Gregson RK, Stocks J, Main E. Effect of chest wall vibration timing on peak expiratory flow and inspiratory pressure in a mechanically ventilated lung model. Physiotherapy 2010;96:344-9. ⁾, like in the present study.

In this study, manual vibrocompression was complemented with nasotracheal suctioning, because infants with heart disease have inefficient physiological mechanisms to remove secretions, and nasotracheal suctioning is recommended as an airway clearance method in these situations⁽ ¹⁶16. Autoria não referida. AARC clinical practice guideline. Nasotracheal suctioning - 2004 revision & update. Respir Care 2004;49:1080-4. ⁾. The concern to investigate the effect of combined physiotherapeutic techniques (manual vibrocompression and nasotracheal suctioning) had the purpose of portraying the routine care of physiotherapists in ICUs for the management of infants with heart disease, since compromised respiratory function and mechanics is a frequent finding in this clinical situation⁽ ¹¹11. Felcar JM, Guitti JC, Marson AC, Cardoso JR. Preoperative physiotherapy in prevention of pulmonary complications in pediatric cardic surgery. Rev Bras Cir Cardiovasc 2008;23:383-8. ^, ³³33. Oliveira PM, Held PA, Grande RA, Ribeiro MA, Bobbio TG, Schivinski CI. Profile of children undergoing congenital heart surgery and analysis of their respiratory complications. Rev Paul Pediatr 2012;30:116-21. ⁾.

In view of the foregoing, it was observed that the results shown in this study did not have a negative impact on cardiorespiratory parameters. There was an increase in SpO₂ after therapy, which did not happen with the group that did not receive the intervention (CG). Although this 2% increase (from 89% to 91%) has arguable clinical relevance, because it is a little variation that is within the margin of error of pulse oximetry, it become evident that physiotherapeutic procedures are not harmful for this type of patient, a topic that is routinely discussed in the postoperative management of patients with heart disease. This is because the physiotherapeutic procedures analyzed here did not cause clinical harms, such as hemodynamic instability, tachycardia or bradycardia, tachypnea and desaturation. On the contrary, there was an increase in oxygenation and reduction in respiratory rate, which deserves further investigations. The increase in sample size could reveal greater differences between the groups.

A study that evaluated the effects of manual vibration in infants with acute viral bronchiolitis, conducted by Pupin et al ⁽ ³⁴34. Pupin MK, Riccetto AG, Ribeiro JD, Baracat EC. Comparison of the effect that two different respiratory physical therapy techniques have on cardiorespiratory parameters in infants with acute viral bronchiolitis. J Bras Pneumol 2009;35:860-7. ⁾, combined this maneuver with postural drainage and compared them with the expiratory flow increase technique (EFIT). In the sample of 27 infants who underwent manual vibration (intervention group), no benefit was observed in terms of oxygenation. None of the techniques used lead to an improvement in the cardiorespiratory parameters hr, rr and SpO₂. The authors reported that the effect of the two therapies, when analyzed over time (ten minutes after the end of the procedure), seems to contribute to decrease only rr.

Following this same line of studies evaluating the effects of manual vibration on cardiorespiratory parameters, Lanza et al ⁽ ³⁵35. Lanza FC, Kim AH, Silva JL, Vasconcelos A, Tsopanoglou SP. Does chest vibration during respiratory physiotherapy in neonates cause pain? Rev Paul Pediatr 2010;28:10-4. ⁾ evaluated the behavior of 13 preterm newborns after performing the maneuver, for approximately 17 minutes. No detrimental effects were identified after this therapy in terms of pain signs (according to the Neonatal Facial Coding System scale) and of the parameters rr, hr and SpO_2,which remained within the normal range. The authors descriptively observed an increase in hr immediately after the maneuver, as well as a decrease in rr and an increase in SpO₂, which remained after 30 minutes.

With regard to the effects of nasotracheal suctioning, Falcão and Silva⁽ ³⁶36. Falcão FR, Silva MA. Contenção durante a aspiração traqueal em recém-nascidos. Rev Cienc Med Biol 2008;7:123-31. ⁾ found a decrease in SpO₂ in 13 newborns who underwent this procedure alone, compared to the group that received the same procedure, but combined with containment maneuvers. Hr also had a greater variation after the use of nasotracheal suctioning alone.

It is important to emphasize that confronting the findings from the present research with studies involving different populations is justified by the lack of clinical trials with children with heart diseases.

One of the few investigations on the subject was developed by Reines et al ⁽ ³⁷37. Reines HD, Sade RM , Bradford BF, Marshall J. Chest physiotherapy fails to prevent postoperative atelectasis in children after cardiac surgery. Ann Surg 1982;195:451-5. ⁾, who were not able to prove the benefits of respiratory physiotherapy in patients who underwent surgical correction of congenital heart diseases. This study included 44 children, aged from three months to nine years and randomized into two groups. One of them underwent maneuvers of postural drainage, vibration, decubitus positions, nasotracheal suctioning of airways, deep breathing, and requested or stimulated cough. In the other group, patients received only nasotracheal suctioning, deep breathing, and requested or stimulated cough, without physiotherapeutic maneuvers. According to the authors, respiratory physiotherapy should be recommended to patients in whom its benefits have been proven, especially those with large amount of sputum production, and not as a routine for the prophylaxis of atelectasis in the postoperative period, because the group that received physiotherapeutic maneuvers developed atelectasis with a significantly higher frequency than the group that did not.

A more recent study involving infants with heart disease reported a series of 14 cases of babies diagnosed with acyanotic congenital heart diseases. They were randomized into three groups: control; placebo (only gentle manual contact in the chest); and intervention group, whose participants received two supports of the method of thoracic-abdominal rebalance (TAR) during ten minutes. Cardiorespiratory parameters, respiratory distress and pain were assessed by the same instruments used in the present study. Results showed that the four infants in the intervention group had an increase in hr and SpO₂ and a decrease in rr. None of the infants expressed pain after the physiotherapeutic intervention with TAR⁽ ³⁸38. Coelho R, Assumpção MS, Gonçalves RM, Mondo JM, Schivinski CI. Cardiac infants undergoing support to the method of Thoracic-Abdominal-Rebalance (TAR). Ter Man 2012;10:154-60. ⁾. Although this study analyzes a physiotherapeutic technique different from that used in the present investigation, both studies exhibit positive results with respiratory physiotherapy performed in this type of patient.

Another issue to be discussed is the fact that pain, as well as alterations in cardiorespiratory parameters and the presence of respiratory distress, leads to changes in infant's behavior. Therefore, its quantification contributes to more comprehensive assessments. When it comes to heart diseases, pain is the main manifestation reported by patients who underwent cardiac surgery and has a multifactorial nature⁽ ³⁹39. Baumgarten MC, Garcia GK, Frantzeski MH, Giacomazzi CM, Lagni VB, Dias AS et al. Pain and pulmonary function in patients submitted to heart surgery via sternotomy. Rev Bras Cir Cardiovasc 2009;24:497-505. ⁾. The factors that influence in pain may be: surgical incision, intraoperative tissue retraction and dissection, multiple intravenous cannulations, chest tubes, and invasive procedures that these patients undergo during their therapeutic regimen⁽ ⁴⁰40. Mueller XM, Tinguely F, Tevaearai HT, Revelly JP, Chioléro R, von Segesser LK. Pain location, distribution, and intensity after cardiac surgery. Chest 2000;118:391-6. ⁾. Considering that pediatric patients do not verbalize their painful feeling and that it may be caused or potentiated by different procedures and manipulations, assessing it after the use of physiotherapeutic techniques is of great clinical relevance. In this sense, it was observed that manual vibrocompression and nasotracheal suctioning, applied in infants with heart disease, were not triggering factors for pain. The divergence between the findings from the present study and those from other publications may result from different clinical situations, patients' age, and severity of the disease. Additionally, in this investigation, there was a concern about how to apply vibrocompression. Considering that the type of surgical incision may itself have an influence on pain, the manual technique was carefully performed so that it was not applied with an aggressive manual pressure on infant's chest. Regardless of the type of incision, both in lateral incision and in median sternotomy (which corresponded to 80% of the cases), we took the same level of care.

Another important issue refers to the scales used in this paper. Our small study sample included newborns and infants, applying scales for pain and respiratory distress validated for neonates (NIPS and BSA), since the literature does not provide specific compatible tools that take exactly into account the second age group (infants). However, other researchers who evaluated infants used similar instruments in their investigations⁽ ¹⁷17. Ajambuja AZ, Parazzi PL, Ries LG, Schivinski CI. Immediate effects of thoraco-abdominal rebalance in children with gastroesophageal reflux disease - case series report. ConScientiae Saude 2012;11:607-17.

18. Barbié L, Caillat-Miousse JL, Vion V. La détresse respiratoire du nourrisson atteint de bronchiolite: aspiration ou désobstruction rhino-pharyngée? Rev Kinesither 2009;9:49-54.

19. Lanza FC, Cadrobbi C, Gazzotti MR, Faria R, Luque A, Solé D. Respiratory physiotherapy for nurslings with bronchiolitis: should we do it or not? Mundo Saude 2008;32:183-8.

20. Gómez-y-López RE, Hernández-Sierra JF, Torres-Ruvalcaba BA, Martínez-Puente E, Martínez-Garcia MC. Uso de dexametasona y salbutamol nebulizados en bronquiolitis aguda: estudio clínico comparativo. Gac Med Mex 2007;143:189-92. ^- ²¹21. Osnaya-Romero N, de Jesus Medina-Hernández T, Flores-Hernández SS, León-Rojas G. Clinical symptoms observed in children envenomated by scorpion stings, at the children's hospital from the State of Morelos, Mexico. Toxicon 2001;39:781-5. ^, ²⁵25. Pereira e Silva Y, Gomez RS, Máximo TA, Simões e Silva AC. Pain evaluation in Neonatology. Rev Bras Anestesiol 2007;57:565-74. ^, ²⁶26. Brasil - Ministério da Saúde. Secretaria de atenção à saúde - Departamento de ações programáticas e estratégicas. Atenção à saúde do recém-nascido: guia para os profissionais de saúde - intervenções comuns, icterícia e infecções. Brasília: Ministério da Saúde; 2011. ⁾. These scales are simple, based on the evaluation of clinical signs routinely observed in the management of the pediatric patient and, thus, we decided for its use in the entire sample, standardizing the assessment instrument. However, future studies should be conducted to develop scales designed for this type of assessment in infants, contributing for the adequacy of methodology and of the results obtained in this line of research.

In view of the foregoing, the association of manual vibrocompression and nasotracheal suctioning was favorable in the postoperative of pediatric cardiac surgery, both due to the increase in SpO₂ and the decrease in rr and due to the absence of detrimental effects in pain and respiratory distress. Studies point out the effectiveness of physiotherapy in these cases, emphasizing its use as a routine procedure for the reduction in pulmonary complications⁽ ¹³13. Arcêncio L, Souza MD, Bortolin BS, Fernandes AC, Rodrigues AJ, Evora PR. Pre-and postoperative care in cardiothoracic surgery: a physiotherapeutic approach. Rev Bras Cir Cardiovasc 2008;23:400-10. ^, ⁴¹41. Silva ME, Feuser MR, Silva MP, Uhlig S, Parazzi PL, Rosa GJ et al. Pediatric cardiac surgery: what to expect from physiotherapeutic intervention? Rev Bras Cir Cardiovasc 2011;26:264-72. ^, ⁴²42. Padovani C, Cavenaghi OM. Alveolar recruitment in patients in the immediate postoperative period of cardic surgery. Rev Bras Cir Cardiovasc 2011;26:116-21. ⁾. However, there is little scientific evidence about the most appropriate techniques and their effects in this context and on this age group. The existing studies also show small samples, variability in therapeutic protocols and different clinical situations, which makes comparisons difficult. Its consensus⁽ ³¹31. Johnston C, Zanetti NM, Comaru T, Ribeiro SN, Andrade LB, Santos SL. I Brazilian guidelines for respiratory physiotherapy in pediatric and neonatal intensive care units. Rev Bras Ter Intensiva 2012;24:119-29. ⁾ that the choice for the pediatric therapy for airway clearance should have as basic principles anatomic and physiological differences, the existing pathological processes, and the specificities of each age group⁽ ⁴³43. Schechter MS. Airway clearance applications in infants and children. Respir Care 2007;52:1382-90. ⁾.

It is important to point out some limitations of the study. Data collection was a difficult procedure, due to the complexity of the cases and the rigorous physiotherapeutic protocol. This prevented the sample from being larger. The classification of patients' clinical severity into mild, moderate or severe would also have contributed even more to the quality of the investigation. Another factor to be discussed refers to the use of neonatal scales (NIPS and BSA) in older children. The application of instruments specific for infants may improve the accuracy of the results. Finally, the scarcity of investigations on the subject made it impossible to perform more detailed analyses and comparisons of the results obtained in this study with those obtained by other methods and conducts.

It can be considered that the physiotherapeutic techniques of manual vibrocompression and nasotracheal suctioning, applied to infants in the postoperative period of cardiac surgery, did not alter SpO₂ and rr in the treated group and did not trigger pain signs and respiratory distress.

References

¹
Silva ZM, Perez A, Pinzon AD, Ricachinewsky CP, Rech DR, Lukrafka JL et al. Factors associated with failure in ventilatory weaning of children undergone pediatric cardiac surgery. Rev Bras Cir Cardiovasc 2008;23:501-6.
²
Souza P, Scatolin BE, Ferreira LM, Croti UA. The nursing team relationship with the child and the family in immediate postoperative period of congenital heart defects. Arq Cienc Saude 2008;15:163-9.
³
Vieira TC, Trigo M, Alonso RR, Ribeiro RH, Cardoso MR, Cardoso AC et al. Assessment of food intake in infants between 0 and 24 months with congenital heart disease. Arq Bras Cardiol 2007;89:219-24.
⁴
João PR, Faria Junior F. Immediate post-operative care following cardic surgery. J Pediatr (Rio J) 2003;79 (Suppl 2):S213-22.
⁵
Stayer SA, Diaz LK, East DL, Gouvion JN, Vencill TL, McKenzie ED et al. Changes in respiratory mechanics among infants undergoing heart surgery. Anesth Analg 2004;98:49-55.
⁶
Sociedade Brasileira de Pediatria [homepage on the Internet]. Portal da Sociedade Brasileira de Pediatria [cited 2012 Dec 12]. Available from: http://www.sbp.com.br/
» Available from: http://www.sbp.com.br/
⁷
Cavenaghi S, Moura SC, Silva TH, Venturinelli TD, Marino LH, Lamari NM. Importance of pre- and postoperative physiotherapy in pediatric cardic surgery. Rev Bras Cir Cardiovasc 2009;24:397-400.
⁸
Moerman D, Clément de Cléty S. La kinésithérapie respiratoire chez l'enfant après chirurgie cardiaque congénitale. Réanimation 2010;19:179-84.
⁹
Feltrim MI, Parreira VF. Fisioterapia respiratória. Proceedings of the 1ª Conferência de Consenso em Fisioterapia Respiratória; 1994 Dec 2-3; Lyon, França. p. 8-47.
¹⁰
Zimmerman AT, Ibsen LM. Advances in postoperative care of pediatric cardiac patients. Curr Opin Anaesthesiol 2004;17:241-6.
¹¹
Felcar JM, Guitti JC, Marson AC, Cardoso JR. Preoperative physiotherapy in prevention of pulmonary complications in pediatric cardic surgery. Rev Bras Cir Cardiovasc 2008;23:383-8.
¹²
Ribeiro IF, de Melo AP, Davidson J. Chest physical therapy in newborn infants with patent ductus arteriosus and pulmonary complications. Rev Paul Pediatr 2008;26:77-83.
¹³
Arcêncio L, Souza MD, Bortolin BS, Fernandes AC, Rodrigues AJ, Evora PR. Pre-and postoperative care in cardiothoracic surgery: a physiotherapeutic approach. Rev Bras Cir Cardiovasc 2008;23:400-10.
¹⁴
Armitage P, Berry G, Matthews JNS. The planning of statistical investigations. In: Armitage P, Berry G, editors. Statistical methods in medical research. 2nd ed. Oxford: Blackwell; 1987. p. 179-85.
¹⁵
Postiaux G. Fisioterapia respiratória pediátrica: o tratamento guiado por ausculta pulmonar. 2nd ed. Porto Alegre: Artmed; 2004.
¹⁶
Autoria não referida. AARC clinical practice guideline. Nasotracheal suctioning - 2004 revision & update. Respir Care 2004;49:1080-4.
¹⁷
Ajambuja AZ, Parazzi PL, Ries LG, Schivinski CI. Immediate effects of thoraco-abdominal rebalance in children with gastroesophageal reflux disease - case series report. ConScientiae Saude 2012;11:607-17.
¹⁸
Barbié L, Caillat-Miousse JL, Vion V. La détresse respiratoire du nourrisson atteint de bronchiolite: aspiration ou désobstruction rhino-pharyngée? Rev Kinesither 2009;9:49-54.
¹⁹
Lanza FC, Cadrobbi C, Gazzotti MR, Faria R, Luque A, Solé D. Respiratory physiotherapy for nurslings with bronchiolitis: should we do it or not? Mundo Saude 2008;32:183-8.
²⁰
Gómez-y-López RE, Hernández-Sierra JF, Torres-Ruvalcaba BA, Martínez-Puente E, Martínez-Garcia MC. Uso de dexametasona y salbutamol nebulizados en bronquiolitis aguda: estudio clínico comparativo. Gac Med Mex 2007;143:189-92.
²¹
Osnaya-Romero N, de Jesus Medina-Hernández T, Flores-Hernández SS, León-Rojas G. Clinical symptoms observed in children envenomated by scorpion stings, at the children's hospital from the State of Morelos, Mexico. Toxicon 2001;39:781-5.
²²
Liberali J, Lanza FC. Atuação da fisioterapia respiratória no paciente pediátrico hospitalizado: novas perspectivas. In: Nápolis LM, Chiavegato LD, Nascimento O, editors. Fisioterapia Respiratória. Série Atualização e Reciclagem em Pneumologia - SPPT. São Paulo: Atheneu; 2011. p. 59-70.
²³
Almeida MF, Kopelman BI. Rotinas médicas: disciplina de pediatria neonatal da Escola Paulista de Medicina. São Paulo: Atheneu; 1994.
²⁴
Lawrence J, Alcock D, McGrath P, Kay J, MacMurray SB, Dulberg C. The development of a tool to assess neonatal pain. Neonatal Netw 1993;12:59-66.
²⁵
Pereira e Silva Y, Gomez RS, Máximo TA, Simões e Silva AC. Pain evaluation in Neonatology. Rev Bras Anestesiol 2007;57:565-74.
²⁶
Brasil - Ministério da Saúde. Secretaria de atenção à saúde - Departamento de ações programáticas e estratégicas. Atenção à saúde do recém-nascido: guia para os profissionais de saúde - intervenções comuns, icterícia e infecções. Brasília: Ministério da Saúde; 2011.
²⁷
Wallis C, Prasad A. Who needs chest physiotherapy? Moving from anecdote to evidence. Arch Dis Child 1999;80:393-7.
²⁸
Renault JA, Costa-Val R, Rossetti MB. Respiratory physiotherapy in the pulmonary dysfunction after cardic surgery. Rev Bras Cir Cardiovasc 2008;23:562-9.
²⁹
McIlwaine M. Physiotherapy and airway clearance techniques and devices. Paediatr Respir Rev 2006;7 (Suppl 1):S220-2.
³⁰
Van der Schans CP. Airway clearance: assessment of techniques. Paediatr Respir Rev 2002;3:110-4.
³¹
Johnston C, Zanetti NM, Comaru T, Ribeiro SN, Andrade LB, Santos SL. I Brazilian guidelines for respiratory physiotherapy in pediatric and neonatal intensive care units. Rev Bras Ter Intensiva 2012;24:119-29.
³²
Shannon H, Stiger R, Gregson RK, Stocks J, Main E. Effect of chest wall vibration timing on peak expiratory flow and inspiratory pressure in a mechanically ventilated lung model. Physiotherapy 2010;96:344-9.
³³
Oliveira PM, Held PA, Grande RA, Ribeiro MA, Bobbio TG, Schivinski CI. Profile of children undergoing congenital heart surgery and analysis of their respiratory complications. Rev Paul Pediatr 2012;30:116-21.
³⁴
Pupin MK, Riccetto AG, Ribeiro JD, Baracat EC. Comparison of the effect that two different respiratory physical therapy techniques have on cardiorespiratory parameters in infants with acute viral bronchiolitis. J Bras Pneumol 2009;35:860-7.
³⁵
Lanza FC, Kim AH, Silva JL, Vasconcelos A, Tsopanoglou SP. Does chest vibration during respiratory physiotherapy in neonates cause pain? Rev Paul Pediatr 2010;28:10-4.
³⁶
Falcão FR, Silva MA. Contenção durante a aspiração traqueal em recém-nascidos. Rev Cienc Med Biol 2008;7:123-31.
³⁷
Reines HD, Sade RM , Bradford BF, Marshall J. Chest physiotherapy fails to prevent postoperative atelectasis in children after cardiac surgery. Ann Surg 1982;195:451-5.
³⁸
Coelho R, Assumpção MS, Gonçalves RM, Mondo JM, Schivinski CI. Cardiac infants undergoing support to the method of Thoracic-Abdominal-Rebalance (TAR). Ter Man 2012;10:154-60.
³⁹
Baumgarten MC, Garcia GK, Frantzeski MH, Giacomazzi CM, Lagni VB, Dias AS et al. Pain and pulmonary function in patients submitted to heart surgery via sternotomy. Rev Bras Cir Cardiovasc 2009;24:497-505.
⁴⁰
Mueller XM, Tinguely F, Tevaearai HT, Revelly JP, Chioléro R, von Segesser LK. Pain location, distribution, and intensity after cardiac surgery. Chest 2000;118:391-6.
⁴¹
Silva ME, Feuser MR, Silva MP, Uhlig S, Parazzi PL, Rosa GJ et al. Pediatric cardiac surgery: what to expect from physiotherapeutic intervention? Rev Bras Cir Cardiovasc 2011;26:264-72.
⁴²
Padovani C, Cavenaghi OM. Alveolar recruitment in patients in the immediate postoperative period of cardic surgery. Rev Bras Cir Cardiovasc 2011;26:116-21.
⁴³
Schechter MS. Airway clearance applications in infants and children. Respir Care 2007;52:1382-90.

Instituição: Hospital Pequeno Príncipe e Universidade do Estado de Santa Catarina (Udesc), Florianópolis, SC, Brasil

Publication Dates

Publication in this collection
Dec 2013

History

Received
16 Nov 2012
Accepted
15 May 2013

All the contents of this journal, except where otherwise noted, is licensed under a Creative Commons Attribution License.

[1] ¹
Silva ZM, Perez A, Pinzon AD, Ricachinewsky CP, Rech DR, Lukrafka JL et al. Factors associated with failure in ventilatory weaning of children undergone pediatric cardiac surgery. Rev Bras Cir Cardiovasc 2008;23:501-6.

[2] ²
Souza P, Scatolin BE, Ferreira LM, Croti UA. The nursing team relationship with the child and the family in immediate postoperative period of congenital heart defects. Arq Cienc Saude 2008;15:163-9.

[3] ³
Vieira TC, Trigo M, Alonso RR, Ribeiro RH, Cardoso MR, Cardoso AC et al. Assessment of food intake in infants between 0 and 24 months with congenital heart disease. Arq Bras Cardiol 2007;89:219-24.

[4] ⁴
João PR, Faria Junior F. Immediate post-operative care following cardic surgery. J Pediatr (Rio J) 2003;79 (Suppl 2):S213-22.

[5] ⁵
Stayer SA, Diaz LK, East DL, Gouvion JN, Vencill TL, McKenzie ED et al. Changes in respiratory mechanics among infants undergoing heart surgery. Anesth Analg 2004;98:49-55.

[6] ⁶
Sociedade Brasileira de Pediatria [homepage on the Internet]. Portal da Sociedade Brasileira de Pediatria [cited 2012 Dec 12]. Available from: http://www.sbp.com.br/
» Available from: http://www.sbp.com.br/

[7] ⁷
Cavenaghi S, Moura SC, Silva TH, Venturinelli TD, Marino LH, Lamari NM. Importance of pre- and postoperative physiotherapy in pediatric cardic surgery. Rev Bras Cir Cardiovasc 2009;24:397-400.

[8] ⁸
Moerman D, Clément de Cléty S. La kinésithérapie respiratoire chez l'enfant après chirurgie cardiaque congénitale. Réanimation 2010;19:179-84.

[9] ⁹
Feltrim MI, Parreira VF. Fisioterapia respiratória. Proceedings of the 1ª Conferência de Consenso em Fisioterapia Respiratória; 1994 Dec 2-3; Lyon, França. p. 8-47.

[10] ¹⁰
Zimmerman AT, Ibsen LM. Advances in postoperative care of pediatric cardiac patients. Curr Opin Anaesthesiol 2004;17:241-6.

[11] ¹¹
Felcar JM, Guitti JC, Marson AC, Cardoso JR. Preoperative physiotherapy in prevention of pulmonary complications in pediatric cardic surgery. Rev Bras Cir Cardiovasc 2008;23:383-8.

[12] ¹²
Ribeiro IF, de Melo AP, Davidson J. Chest physical therapy in newborn infants with patent ductus arteriosus and pulmonary complications. Rev Paul Pediatr 2008;26:77-83.

[13] ¹³
Arcêncio L, Souza MD, Bortolin BS, Fernandes AC, Rodrigues AJ, Evora PR. Pre-and postoperative care in cardiothoracic surgery: a physiotherapeutic approach. Rev Bras Cir Cardiovasc 2008;23:400-10.

[14] ¹⁴
Armitage P, Berry G, Matthews JNS. The planning of statistical investigations. In: Armitage P, Berry G, editors. Statistical methods in medical research. 2nd ed. Oxford: Blackwell; 1987. p. 179-85.

[15] ¹⁵
Postiaux G. Fisioterapia respiratória pediátrica: o tratamento guiado por ausculta pulmonar. 2nd ed. Porto Alegre: Artmed; 2004.

[16] ¹⁶
Autoria não referida. AARC clinical practice guideline. Nasotracheal suctioning - 2004 revision & update. Respir Care 2004;49:1080-4.

[17] ¹⁷
Ajambuja AZ, Parazzi PL, Ries LG, Schivinski CI. Immediate effects of thoraco-abdominal rebalance in children with gastroesophageal reflux disease - case series report. ConScientiae Saude 2012;11:607-17.

[18] ¹⁸
Barbié L, Caillat-Miousse JL, Vion V. La détresse respiratoire du nourrisson atteint de bronchiolite: aspiration ou désobstruction rhino-pharyngée? Rev Kinesither 2009;9:49-54.

[19] ¹⁹
Lanza FC, Cadrobbi C, Gazzotti MR, Faria R, Luque A, Solé D. Respiratory physiotherapy for nurslings with bronchiolitis: should we do it or not? Mundo Saude 2008;32:183-8.

[20] ²⁰
Gómez-y-López RE, Hernández-Sierra JF, Torres-Ruvalcaba BA, Martínez-Puente E, Martínez-Garcia MC. Uso de dexametasona y salbutamol nebulizados en bronquiolitis aguda: estudio clínico comparativo. Gac Med Mex 2007;143:189-92.

[21] ²¹
Osnaya-Romero N, de Jesus Medina-Hernández T, Flores-Hernández SS, León-Rojas G. Clinical symptoms observed in children envenomated by scorpion stings, at the children's hospital from the State of Morelos, Mexico. Toxicon 2001;39:781-5.

[22] ²²
Liberali J, Lanza FC. Atuação da fisioterapia respiratória no paciente pediátrico hospitalizado: novas perspectivas. In: Nápolis LM, Chiavegato LD, Nascimento O, editors. Fisioterapia Respiratória. Série Atualização e Reciclagem em Pneumologia - SPPT. São Paulo: Atheneu; 2011. p. 59-70.

[23] ²³
Almeida MF, Kopelman BI. Rotinas médicas: disciplina de pediatria neonatal da Escola Paulista de Medicina. São Paulo: Atheneu; 1994.

[24] ²⁴
Lawrence J, Alcock D, McGrath P, Kay J, MacMurray SB, Dulberg C. The development of a tool to assess neonatal pain. Neonatal Netw 1993;12:59-66.

[25] ²⁵
Pereira e Silva Y, Gomez RS, Máximo TA, Simões e Silva AC. Pain evaluation in Neonatology. Rev Bras Anestesiol 2007;57:565-74.

[26] ²⁶
Brasil - Ministério da Saúde. Secretaria de atenção à saúde - Departamento de ações programáticas e estratégicas. Atenção à saúde do recém-nascido: guia para os profissionais de saúde - intervenções comuns, icterícia e infecções. Brasília: Ministério da Saúde; 2011.

[27] ²⁷
Wallis C, Prasad A. Who needs chest physiotherapy? Moving from anecdote to evidence. Arch Dis Child 1999;80:393-7.

[28] ²⁸
Renault JA, Costa-Val R, Rossetti MB. Respiratory physiotherapy in the pulmonary dysfunction after cardic surgery. Rev Bras Cir Cardiovasc 2008;23:562-9.

[29] ²⁹
McIlwaine M. Physiotherapy and airway clearance techniques and devices. Paediatr Respir Rev 2006;7 (Suppl 1):S220-2.

[30] ³⁰
Van der Schans CP. Airway clearance: assessment of techniques. Paediatr Respir Rev 2002;3:110-4.

[31] ³¹
Johnston C, Zanetti NM, Comaru T, Ribeiro SN, Andrade LB, Santos SL. I Brazilian guidelines for respiratory physiotherapy in pediatric and neonatal intensive care units. Rev Bras Ter Intensiva 2012;24:119-29.

[32] ³²
Shannon H, Stiger R, Gregson RK, Stocks J, Main E. Effect of chest wall vibration timing on peak expiratory flow and inspiratory pressure in a mechanically ventilated lung model. Physiotherapy 2010;96:344-9.

[33] ³³
Oliveira PM, Held PA, Grande RA, Ribeiro MA, Bobbio TG, Schivinski CI. Profile of children undergoing congenital heart surgery and analysis of their respiratory complications. Rev Paul Pediatr 2012;30:116-21.

[34] ³⁴
Pupin MK, Riccetto AG, Ribeiro JD, Baracat EC. Comparison of the effect that two different respiratory physical therapy techniques have on cardiorespiratory parameters in infants with acute viral bronchiolitis. J Bras Pneumol 2009;35:860-7.

[35] ³⁵
Lanza FC, Kim AH, Silva JL, Vasconcelos A, Tsopanoglou SP. Does chest vibration during respiratory physiotherapy in neonates cause pain? Rev Paul Pediatr 2010;28:10-4.

[36] ³⁶
Falcão FR, Silva MA. Contenção durante a aspiração traqueal em recém-nascidos. Rev Cienc Med Biol 2008;7:123-31.

[37] ³⁷
Reines HD, Sade RM , Bradford BF, Marshall J. Chest physiotherapy fails to prevent postoperative atelectasis in children after cardiac surgery. Ann Surg 1982;195:451-5.

[38] ³⁸
Coelho R, Assumpção MS, Gonçalves RM, Mondo JM, Schivinski CI. Cardiac infants undergoing support to the method of Thoracic-Abdominal-Rebalance (TAR). Ter Man 2012;10:154-60.

[39] ³⁹
Baumgarten MC, Garcia GK, Frantzeski MH, Giacomazzi CM, Lagni VB, Dias AS et al. Pain and pulmonary function in patients submitted to heart surgery via sternotomy. Rev Bras Cir Cardiovasc 2009;24:497-505.

[40] ⁴⁰
Mueller XM, Tinguely F, Tevaearai HT, Revelly JP, Chioléro R, von Segesser LK. Pain location, distribution, and intensity after cardiac surgery. Chest 2000;118:391-6.

[41] ⁴¹
Silva ME, Feuser MR, Silva MP, Uhlig S, Parazzi PL, Rosa GJ et al. Pediatric cardiac surgery: what to expect from physiotherapeutic intervention? Rev Bras Cir Cardiovasc 2011;26:264-72.

[42] ⁴²
Padovani C, Cavenaghi OM. Alveolar recruitment in patients in the immediate postoperative period of cardic surgery. Rev Bras Cir Cardiovasc 2011;26:116-21.

[43] ⁴³
Schechter MS. Airway clearance applications in infants and children. Respir Care 2007;52:1382-90.

Variable	CG	IG	p-value
Post-extubation time (days - mean±SD)	2.10±1.60	2.40±2.50	0.967
Age (months - mean±SD)	4.60±3.72	4.90±4.28	0.790
Gender (Male/female)	5/5	6/4	0.655
Type of surgical incision (MS/LT)	8/2	8/2	1.00
Heart diseases (cyanotic/acyanotic)	3/7	3/7	1.00

		Heart disease	Surgical correction	PO	ECC	MV
CG	Acyanotic	wide PDA/IVC	closure of IVC/ PDA	1	74"™	1
		wide PDA/IVC	closure of IVC/ PDA	1	80"™	1
		wide perimembranous IVC	closure of IVC/banding	3	65"™	1
		moderate subaortic IVC	correction of subaortic IVC /suture and ligation of PDA	4	71"™	3
		wide perimembranous IVC/PDA	closure of IVC/ligation of PDA	2	79"™	1
		OSIAC/LPSVC	atrioseptoplasty	4	37"™	1
		mitral valve prolapse and malformation/ mitral stenosis	implantation of mitral biological prosthesis	19	-	8
	Cyanotic	tricuspid atresia /moderate IVC/IAC	Blalock-Taussing	2	90"™	1
		TGV/PA/IVC/IAC/PDA/situs inversus	Blalock-Taussing	2	-	2
		type II truncus	closure of IVC and IAC/separation Ao from neopulmonary artery	9	89"™	8
IG	Acyanotic	AVSD/wide PDA	pulmonary artery bandage/closure of PDA	6	-	5
		wide IVC/PDA	closure of IVC	4	108"™	1
		wide perimembranous IVC/PDA	correction septoplasty/ligation and section of PDA	5	75"™	3
		type A AI with ventricular inversion/IVC/PDA	Damus Kaey/opening IAC/aortic pulmonary anastomosis	25	178"™	18
		IVC/PS IV	closure IVC with goretex patch, infundibular resection	2	85"™	1
		atrial isomerism/TAVSD/ VDRVVO/moderate pulmonary stenosis	drainage of pulmonary veins for LA	8	77"™	7
		wide aortopulmonary window/OSIAC/increased heart chambers	correction of aortopulmonary window/closure of IAC	4	36"™	2
	Cyanotic	tricuspid atresia/hypoplastic RV/ restrictive IVC/IAC	Blalock-Hanlon/anastomosisBlalock-Taussing	7	-	3
		TOF/PDA		11	101"™	10
		TOF of good anatomy	pulmonary infundibular resection/closure of IVC	3	115"™	4

Groups		hr (A)				rr (B)				SpO₂(C)
Groups		Min	Max	Mean±SD	p-value	Min	Max	Mean±SD	p-value	Min	Max	Mean±SD	p-value
CG	T_pre	92	154	130±20	0.26^0.87^0.15^**	30	70	49±11	0.001^0.59^0.17^**	82	97	92±4	0.33^0.02^0.78^**
CG	T_post	96	175	133±24		30	67	45±11		78	100	91±6
IG	T_pre	127	155	141±10		43	78	56±11		74	97	89±9
IG	T_post	123	161	145±14		31	72	51±12		76	100	91±8

Brasil

Brasil

Manual vibrocompression and nasotracheal suctioning in post-operative period of infants with heart deffects

Vibrocompresión manual y aspiración nasotraqueal en el post-operatorio de lactantes cardiópatas

Abstracts

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OBJETIVO:

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Introduction

Method

Results

Discussion

References

Publication Dates

History