Evaluation of Swallowing in Infants with Congenital Heart
                    Defect

Pereira, Karine da Rosa; Firpo, Cora; Gasparin, Marisa; Teixeira, Adriane Ribeiro; Dornelles, Silvia; Bacaltchuk, Tzvi; Levy, Deborah Salle

doi:10.1055/s-0034-1384687

Abstract

Introduction

Surgical repair of congenital heart disease in the first years of life compromises the coordination of the suction, breathing, and swallowing functions.

Objective

To describe the alterations in swallowing found in infants with congenital heart defect during their hospitalization.

Methods

Prospective, cross-sectional study in a reference hospital for heart disease. The sample consisted of 19 postsurgical patients who underwent an evaluation of swallowing. The infants included were younger than 7 months and had a diagnosis of congenital heart defect and suspected swallowing difficulties.

Results

Of the 19 infants with congenital heart defect, the median age was 3.2 months. A significant association was found between suction rhythm and dysphagia (p = 0.036) and between oral-motor oral feeding readiness and dysphagia (p = 0.014).

Conclusions

The data suggest that dysphagia often occurs after surgery in infants with congenital heart defect. Infants with congenital heart defect had very similar behavior to preterm infants in terms of oral feeding readiness.

congenital heart; defects; infant; deglutition disorders; respiratory aspiration; speech; language and hearing sciences

Introduction

Congenital heart defect is defined as a malformation of the heart or blood vessels that develops during the fetal period.¹1 Teixeira FM, Coelho RM, Proença C, et al. Quality of life experienced by adolescents and young adults with congenital heart disease. Pediatr Cardiol 2011;32(8):1132-1138 The prevalence is 9:1,000 live births, corresponding to 1.35 million newborns per year.²2 van der Linde D, Konings EE, Slager MA, et al. Birth prevalence of congenital heart disease worldwide: a systematic review and meta-analysis. J Am Coll Cardiol 2011;58(21):2241-2247 Most of these children require surgical intervention, often in early childhood.³3 Gerdes M, Flynn T. Clinical assessment of neurobehavioral outcomes in infants and children with congenital heart disease. Progress in Pediatr Cardiol 2010;29(2):97-105

The multiple surgeries to correct the heart defect are debilitating and often hinder the quality of life.⁴4 Bruneau BG. The developmental genetics of congenital heart disease. Nature 2008;451(7181):943-948 The presence of chromosomal abnormalities, cyanosis, and heart failure increase the complexity and challenge involved in the treatment.⁵5 Medoff-Cooper B, Naim M, Torowicz D, Mott A. Feeding, growth, and nutrition in children with congenitally malformed hearts. Cardiol Young 2010;20(3, Suppl 3):149-153 The life expectancy of patients with congenital heart defect has increased due to advances in early diagnosis,¹1 Teixeira FM, Coelho RM, Proença C, et al. Quality of life experienced by adolescents and young adults with congenital heart disease. Pediatr Cardiol 2011;32(8):1132-1138³3 Gerdes M, Flynn T. Clinical assessment of neurobehavioral outcomes in infants and children with congenital heart disease. Progress in Pediatr Cardiol 2010;29(2):97-105⁶6 Sables-Baus S, Kaufman J, Cook P, da Cruz EM. Oral feeding outcomes in neonates with congenital cardiac disease undergoing cardiac surgery. Cardiol Young 2012;22(1):42-48 care after birth, and surgical techniques.³3 Gerdes M, Flynn T. Clinical assessment of neurobehavioral outcomes in infants and children with congenital heart disease. Progress in Pediatr Cardiol 2010;29(2):97-105⁶6 Sables-Baus S, Kaufman J, Cook P, da Cruz EM. Oral feeding outcomes in neonates with congenital cardiac disease undergoing cardiac surgery. Cardiol Young 2012;22(1):42-48 However, with improved survival, new challenges have arisen in the growth and development of these children.⁶6 Sables-Baus S, Kaufman J, Cook P, da Cruz EM. Oral feeding outcomes in neonates with congenital cardiac disease undergoing cardiac surgery. Cardiol Young 2012;22(1):42-48

In childhood, oral feeding is established as a reciprocal process,⁷7 Delaney AL, Arvedson JC. Development of swallowing and feeding: prenatal through first year of life. Dev Disabil Res Rev 2008;14(2): 105-117 one that is essential in the life experience of young children.⁸8 Newman LA, Keckley C, Petersen MC, Hamner A. Swallowing function and medical diagnoses in infants suspected of dysphagia. Pediatrics 2001;108(6):E106 Swallowing is a complex process that involves neurologic and aerodigestive coordination.⁹9 Weckmueller J, Easterling C, Arvedson J. Preliminary temporal measurement analysis of normal oropharyngeal swallowing in infants and young children. Dysphagia 2011;26(2):135-143 Neurobehavioral markers, such as postural control, regulation of the sleep-wake cycle, and maturation of coordination of the suck-swallow-breathe process, provide the clinical picture necessary for the child to advance toward oral feeding readiness.¹⁰10 Silberstein D, Geva R, Feldman R, et al. The transition to oral feeding in low-risk premature infants: relation to infant neurobehavioral functioning and mother-infant feeding interaction. Early Hum Dev 2009;85(3):157-162

Newborns with congenital heart defect may require a prolonged hospital stay, well beyond the neonatal period, during the most important period of development. In the long term, this could affect somatic growth as well as cognitive and social-emotional growth.⁶6 Sables-Baus S, Kaufman J, Cook P, da Cruz EM. Oral feeding outcomes in neonates with congenital cardiac disease undergoing cardiac surgery. Cardiol Young 2012;22(1):42-48 Among these infants, THE nutritional condition resulting from the inability to feed often leads to an imbalance in energy intake, resulting in impaired growth.¹¹11 Jadcherla SR, Vijayapal AS, Leuthner S. Feeding abilities in neonates with congenital heart disease: a retrospective study. J Perinatol 2009;29(2):112-118 Due to compromised cardiopulmonary function, these infants may need a longer time to feed or may present with a lack of appetite and food refusal.¹²12 Woodward CS. Keeping children with congenital heart disease healthy. J Pediatr Health Care 2011;25(6):373-378 Feeding difficulties may not be combined with oropharyngeal dysphagia.¹³13 Arvedson JC. Assessment of pediatric dysphagia and feeding disorders: clinical and instrumental approaches. Dev Disabil Res Rev 2008;14(2):118-127

In pediatrics, oropharyngeal dysphagia may have a varied clinical presentation, depending on its etiology, complexity, and impact on the lives of patients with feeding difficulties.¹⁴14 Arvedson J, Clark H, Lazarus C, Schooling T, Frymark T. The effects of oral-motor exercises on swallowing in children: an evidencebased systematic review. Dev Med Child Neurol 2010;52(11): 1000-1013 It is often observed in children with various medical diagnoses,¹⁵15 Sitton M, Arvedson J, Visotcky A, et al. Fiberoptic endoscopic evaluation of swallowing in children: feeding outcomes related to diagnostic groups and endoscopic findings. Int J Pediatr Otorhinolaryngol 2011;75(8):1024-1031 and it may be caused by several conditions, such as cerebral palsy, cleft lip or palate, and other structural abnormalities,¹⁶16 Heiss CJ, Goldberg L, Dzarnoski M. Registered dietitians and speechlanguage pathologists: an important partnership in dysphagia management. J Am Diet Assoc 2010;110(9):1290, 1292-1293 in addition to congenital heart defect. Dysphagia not only deprives one of the pleasure of eating, but also endangers health,¹⁷17 Hongama S, Nagao K, Toko S, et al. MI sensor-aided screening system for assessing swallowing dysfunction: application to the repetitive saliva-swallowing test. J Prosthodont Res 2012;56(1): 53-57 because it could lead to the development of complications, including impaired growth,¹⁸18 Hewetson R, Singh S. The lived experience of mothers of children with chronic feeding and/or swallowing difficulties. Dysphagia 2009;24(3):322-332 chronic aspiration, lung disease,¹⁸18 Hewetson R, Singh S. The lived experience of mothers of children with chronic feeding and/or swallowing difficulties. Dysphagia 2009;24(3):322-332¹⁹19 Christiaanse ME, Mabe B, Russell G, Simeone TL, Fortunato J, Rubin B. Neuromuscular electrical stimulation is no more effective than usual care for the treatment of primary dysphagia in children. Pediatr Pulmonol 2011;46(6):559-565 malnutrition,¹⁷17 Hongama S, Nagao K, Toko S, et al. MI sensor-aided screening system for assessing swallowing dysfunction: application to the repetitive saliva-swallowing test. J Prosthodont Res 2012;56(1): 53-57 and others.

The aim of this study was to describe the swallowing alterations found in infants with congenital heart defect evaluated during their hospitalization period.

Methods

This prospective, comparative, cross-sectional study was conducted at the Pediatric Intensive Care Unit at the Institute of Pediatric Cardiology in Porto Alegre, Brazil, from August 2011 to August 2012.

The inclusion criteria were as follows: infants under 7 months, diagnosed with congenital heart defect and with suspected swallowing disorders were included in the study. Infants with a neurologic or syndromic medical diagnosis, or awaiting surgical correction, were excluded from the research.

This study used a protocol to characterize the sample, the Preterm Oral Feeding Readiness Assessment Scale,²⁰20 Fujinaga CI, Scochi CGS, Santos CB, et al. Validação do conteúdo de um instrumento para avaliação da prontidão do prematuro para início da alimentação oral. Rev Bras SaudeMater Infant 2008;8(4): 391-399 and a protocol for the clinical evaluation of swallowing based on the study by Weir et al.²¹21 Weir K, McMahon S, Barry L, Masters IB, Chang AB. Clinical signs and symptoms of oropharyngeal aspiration and dysphagia in children. Eur Respir J 2009;33(3):604-611

The protocol for the clinical evaluation of swallowing had the following information: date of birth, gender, medical diagnosis, date of the cardiac surgery, time of the mechanical ventilation.

The Preterm Oral Feeding Readiness Assessment scale was used in this study. According to Fujinaga et al,²²22 Fujinaga CI, de Moraes SA, Zamberlan-Amorim NE, Castral TC, de Almeida e Silva A, Scochi CG. Clinical validation of the PretermOral Feeding Readiness Assessment Scale. Rev Lat Am Enfermagem 2013;21(Spec No):140-145 this instrument is divided into five categories: (1) corrected gestational age (≤32 weeks; 32 to 34 weeks, and ≥34 weeks); (2) behavior state (state of conscience, posture, and global tonus); (3) oral posture (lips and tongue posture); (4) oral reflexes (rooting, sucking, biting, and gag reflexes); (5) nonnutritive sucking (tongue movement, tongue cupping, jaw movement, sucking strength, sucking pauses, pause per sucking, maintenance of sucking rhythm, maintenance of alertness, and stress behavioral signs). Performance in every item is graded on a scale from 0 to 2 points, with a total score that varies from 0 to 36 points. However, the first category was not considered in our study.

In this evaluation, the infants were placed on their mother's lap to assess oral posture, oral reflexes, and nonnutritive sucking. Verification of oral reflexes was performed using a gloved finger and/or a pacifier.

The clinical evaluation occurred through breast- or bottle-feeding. The infant who had previous experience of breast-feeding was evaluated at the first moment in breast-feeding, and if necessary afterward with a bottle. The first oral assessment using either bottle- or breast-feeding occurred after application of the Preterm Oral Feeding Readiness Assessment Scale. The bottle evaluated was filled with liquid and thickened liquid consistencies, and we observed coordination of sucking, swallowing, and breathing and presence of oral stasis, cough, fatigue after feeding, cyanosis, and desaturation. After swallowing evaluation, the sample was divided into two groups to compare the clinical findings for each group. The infants with normal swallowing comprise group 1 and those who had oropharyngeal dysphagia comprise group 2.

The study was approved by the Research Ethics Committees of the Universidade Federal do Rio Grande do Sul Postgraduate Program and of Instituto de Cardiologia, under registration No. 2010064 and No. 4603/11, respectively. Consent was obtained from the guardians before the study was conducted.

The database and the analyses were performed using SPSS version 19 (Statistical Package for the Social Sciences, New York, US). Fisher exact test was used to assess the association between groups and other qualitative variables. The nonparametric Mann-Whitney test was used to compare the duration of mechanical ventilation between the groups, and the Spearman test was used to correlate oral-motor readiness with the time of mechanical ventilation. Qualitative data were described as absolute and relative values. Qualitative variables were expressed through median, minimum, and maximum values. The present study adopted a significance level of p = 0.05.

Results

Demographic and cardiac characteristics of patients are shown in Table 1. Out of the 19 infants in the sample, 11 (58%) were boys. The median age was 3.2 months (minimum = 0.3, maximum = 6.2). Twelve infants had acyanotic congenital heart defect, and seven had cyanotic congenital heart defect.

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Table 1
Demographic characteristics of cardiac patients

Oropharyngeal dysphagia was identified in 16 (84%) of the infants under study. The most common clinical finding was the lack of suck-swallow-breathe coordination (p ≤ .001), which was observed in combination with oral leaking in 5 infants; stasis in the oral cavity in 4; cough during feeding in 5; fatigue during feeding in 4; desaturation in 3; and cyanosis during feeding in 1. Descriptions of the clinical evaluation and score for Preterm Oral Feeding Readiness Assessment Scale are described in Table 2.

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Table 2
Clinical evaluation and score of infants in the Preterm Oral Feeding Readiness Assessment scale

During the evaluation of readiness for oral feeding, no association was found between absence of sucking rhythm and the presence of oropharyngeal dysphagia (p = 0.036). However, 12 (63%) infants with oropharyngeal dysphagia presented arrhythmic sucking, and all infants with normal swallowing presented rhythmic sucking. There was no relation of sucking/pause and dysphagia between the groups. The comparative distribution between the two groups, regarding the variables, is shown in Table 3.

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Table 3
Comparative distribution of the variables between the two groups

The group of infants with normal swallowing and the group with oropharyngeal dysphagia had a median 24 and 48 hours in mechanical ventilation, respectively. There was no correlation between the duration of mechanical ventilation and the oral readiness score. Spearman correlation was r ≤ − 349.

Fig. 1 shows a comparison of performance in the readiness for oral feeding protocol between the group of infants who had normal swallowing and the group of infants who had oropharyngeal dysphagia. The group of infants with normal swallowing had a median score of 33 (minimum = 30, maximum = 36) and the group of infants with oropharyngeal dysphagia had a median score of 25 (minimum = 16, maximum = 33). The correlation between oral-motor readiness and dysphagia was p = 0.014.

Fig. 1
Comparison between the groups of infants with congenital heart defect, according to the preterm readiness for oral feeding protocol. Abbreviations: G1, group 1 (infants with no alterations in swallowing); G2, group 2 (infants with alterations in swallowing). *Mann-Whitney test.

Discussion

The present study showed that infants with congenital heart defect have low scores on the evaluation of readiness for oral feeding, which are very close to those of preterm infants.²²22 Fujinaga CI, de Moraes SA, Zamberlan-Amorim NE, Castral TC, de Almeida e Silva A, Scochi CG. Clinical validation of the PretermOral Feeding Readiness Assessment Scale. Rev Lat Am Enfermagem 2013;21(Spec No):140-145 It should be underscored that the evaluation of readiness for preterm infants differs from the evaluation of infants with congenital heart defect, because the coordination of the suck-swallow-breathe process improves with the maturation of the central nervous system in cases of preterm birth.²³23 Mizuno K, Ueda A. The maturation and coordination of sucking, swallowing, and respiration in preterm infants. J Pediatr 2003; 142(1):36-40

The mean values for the oral-motor readiness scores found in this survey were 25 for the group of infants with oropharyngeal dysphagia and 33 for the group of infants with normal swallowing. These results show that oral-motor skill is associated with oropharyngeal dysphagia and that the assessment of readiness before clinical evaluation is extremely important.

By exploring possible variables that could affect the performance of swallowing, we found that the duration of mechanical ventilation did not influence the oral-motor readiness or the outcome of the clinical evaluation. This finding diverges from the literature, which states that oropharyngeal dysphagia may occur after mechanical ventilation²⁴24 Brown CV, Hejl K,Mandaville AD, Chaney PE, Stevenson G, Smith C. Swallowing dysfunction after mechanical ventilation in trauma patients. J Crit Care 2011;26(1):e9-e13 and after prolonged intubation.²⁵25 Bordon A, Bokhari R, Sperry J, Testa D IV, Feinstein A, Ghaemmaghami V. Swallowing dysfunction after prolonged intubation: analysis of risk factors in trauma patients. Am J Surg 2011; 202(6):679-682, discussion 682-683

Clinical evaluation showed that in infants with congenital heart defect, oropharyngeal dysphagia is characterized by a lack of coordination of the suck-swallow-breathe process, whether or not this is combined with stasis of food in the oral cavity, cough, anterior leaking, and fatigue during breast-feeding. It is known that oropharyngeal dysphagia may occur in young children due to fatigue of the swallowing mechanism.²⁵25 Bordon A, Bokhari R, Sperry J, Testa D IV, Feinstein A, Ghaemmaghami V. Swallowing dysfunction after prolonged intubation: analysis of risk factors in trauma patients. Am J Surg 2011; 202(6):679-682, discussion 682-683 Moreover, oral feeding requires muscle strength to extract the milk from the bottle or from the mother's breast and coordination of the suck-swallow-breathe process; also, infants with congenital heart defect are likely to resist ingesting the total prescribed volume, due to surgical intervention, which hinders weight gain and growth of these newborns and infants.²⁶26 Tutor JD, Gosa MM. Dysphagia and aspiration in children. Pediatr Pulmonol 2012;47(4):321-337

Among the pediatric population with heart disease, risk factors for oropharyngeal dysphagia as follows: age under 3 years, preoperative intubation, intubation greater than 7 days, and operations for obstructive injuries on the left side. The use of transesophageal echocardiography in children weighing less than 5.5 kg is considered a predictor of dysphagia.²⁷27 Kohr LM, Dargan M, Hague A, et al. The incidence of dysphagia in pediatric patients after open heart procedures with transesophageal echocardiography. Ann Thorac Surg 2003;76(5):1450-1456 However, clinical evidence of oropharyngeal dysphagia in infants investigated postoperatively in this research emphasizes that dysphagia may take place with intubation times of less than 7 days.

Kohr et al aimed to determine the incidence and risk factors for oropharyngeal dysphagia in children after cardiac surgery and found that oropharyngeal dysphagia occurred in 9 (18%) of the 50 patients.²⁷27 Kohr LM, Dargan M, Hague A, et al. The incidence of dysphagia in pediatric patients after open heart procedures with transesophageal echocardiography. Ann Thorac Surg 2003;76(5):1450-1456 The videofluoroscopic findings were as follows: 7 (78%) cases of delayed triggering of swallowing; 2 (22%) cases of laryngeal penetration, with direct aspiration and vocal fold paralysis; 2 (22%) cases of occasional laryngeal penetration without aspiration; 1 (11%) case of laryngeal reduction; and 2 (22%) cases of direct aspiration resulting from vocal fold paralysis. Sachdeva et al,²⁸28 Sachdeva R, Hussain E,MossMM, et al. Vocal cord dysfunction and feeding difficulties after pediatric cardiovascular surgery. J Pediatr 2007;151(3):312-315, e1-e2 whose objective was to evaluate the impact of voice disorders and feeding in children after cardiac surgery, showed that swallowing dysfunction was observed in 34 (89%) children with vocal fold alterations. The swallowing examination was performed in 29 patients with congenital heart defects, ∼30 days after surgery. The most common pathophysiological finding was aspiration, which was observed in 23 (80%) children. Laryngeal penetration occurred in 5 of them (17%), and delayed triggering of swallowing in only 1 (3%). Through instrumental evaluation, researchers were able to identify oropharyngeal dysphagia in this population of children with congenital heart defects.

Yi et al performed a retrospective study in which the objective was to evaluate the prevalence and clinical predictors of dysphagia and determine the videofluoroscopic findings of swallowing in children who underwent cardiac surgery.²⁹29 Yi SH, Kim SJ, Huh J, Jun TG, Cheon HJ, Kwon JY. Dysphagia in infants after open heart procedures. Am J Phys Med Rehabil 2013; 92(6):496-503 Through videofluoroscopic findings, the authors concluded that 67.9% of the children had laryngeal penetration and 63.6% had tracheal aspiration, and of these 85.7% of symptoms were silent, without the presence of cough. In our clinical study, we also observed a low incidence of cough during swallowing. Only 4 of the 16 infants identified with oropharyngeal dysphagia showed cough while swallowing.

Our results corroborate the studies by Kohr et al,²⁷27 Kohr LM, Dargan M, Hague A, et al. The incidence of dysphagia in pediatric patients after open heart procedures with transesophageal echocardiography. Ann Thorac Surg 2003;76(5):1450-1456 Sachdeva et al,²⁸28 Sachdeva R, Hussain E,MossMM, et al. Vocal cord dysfunction and feeding difficulties after pediatric cardiovascular surgery. J Pediatr 2007;151(3):312-315, e1-e2 and Yi et al,²⁹29 Yi SH, Kim SJ, Huh J, Jun TG, Cheon HJ, Kwon JY. Dysphagia in infants after open heart procedures. Am J Phys Med Rehabil 2013; 92(6):496-503 which showed that oropharyngeal dysphagia often occurs postoperatively in infants, as most infants who had corrective surgery presented oropharyngeal dysphagia, even with thickened liquid. Thickening of food is a procedure adopted to minimize the pattern of dysphagia.²⁷27 Kohr LM, Dargan M, Hague A, et al. The incidence of dysphagia in pediatric patients after open heart procedures with transesophageal echocardiography. Ann Thorac Surg 2003;76(5):1450-1456

It is important to note that feeding problems are common among children with congenital heart defect.⁶6 Sables-Baus S, Kaufman J, Cook P, da Cruz EM. Oral feeding outcomes in neonates with congenital cardiac disease undergoing cardiac surgery. Cardiol Young 2012;22(1):42-48¹¹11 Jadcherla SR, Vijayapal AS, Leuthner S. Feeding abilities in neonates with congenital heart disease: a retrospective study. J Perinatol 2009;29(2):112-118²⁷27 Kohr LM, Dargan M, Hague A, et al. The incidence of dysphagia in pediatric patients after open heart procedures with transesophageal echocardiography. Ann Thorac Surg 2003;76(5):1450-1456²⁸28 Sachdeva R, Hussain E,MossMM, et al. Vocal cord dysfunction and feeding difficulties after pediatric cardiovascular surgery. J Pediatr 2007;151(3):312-315, e1-e2 ²⁹29 Yi SH, Kim SJ, Huh J, Jun TG, Cheon HJ, Kwon JY. Dysphagia in infants after open heart procedures. Am J Phys Med Rehabil 2013; 92(6):496-503³⁰30 Medoff-Cooper B, Irving SY. Innovative strategies for feeding and nutrition in infants with congenitally malformed hearts. Cardiol Young 2009;19(Suppl 2):90-95³¹31 Maurer I, Latal B, Geissmann H, Knirsch W, Bauersfeld U, Balmer C. Prevalence and predictors of later feeding disorders in children who underwent neonatal cardiac surgery for congenital heart disease. Cardiol Young 2011;21(3):303-309 According to Arvedson,¹³13 Arvedson JC. Assessment of pediatric dysphagia and feeding disorders: clinical and instrumental approaches. Dev Disabil Res Rev 2008;14(2):118-127 feeding difficulties are characterized by refusal, disruptive behavior, preference, and lack of feeding competence expected for the subjects' level of development. Newborns who were born with a serious heart condition requiring heart surgery in the first month of life have a high risk of presenting feeding difficulties until 2 years of age.³⁰30 Medoff-Cooper B, Irving SY. Innovative strategies for feeding and nutrition in infants with congenitally malformed hearts. Cardiol Young 2009;19(Suppl 2):90-95 The speech therapist should be aware of these behaviors during the evaluation of swallowing.

The results of the present study suggest that dysphagia often occurs in infants after corrective surgery for congenital heart condition. The use of the preterm readiness for an oral feeding protocol enabled us to verify that infants with congenital heart defect may present with very similar behavior to those of preterm newborns.

Conclusion

In the present study, the occurrence of oropharyngeal dysphagia in infants under 7 months of age with congenital heart defect was observed, and the same finding was detected by clinical evaluation. Infants with congenital heart defect showed a very similar behavior to that of preterm newborns. However, oropharyngeal dysphagia is a variable that still needs to be further studied to determine the epidemiologic data and identify the best clinical management outcome among this population.

References

¹
Teixeira FM, Coelho RM, Proença C, et al. Quality of life experienced by adolescents and young adults with congenital heart disease. Pediatr Cardiol 2011;32(8):1132-1138
²
van der Linde D, Konings EE, Slager MA, et al. Birth prevalence of congenital heart disease worldwide: a systematic review and meta-analysis. J Am Coll Cardiol 2011;58(21):2241-2247
³
Gerdes M, Flynn T. Clinical assessment of neurobehavioral outcomes in infants and children with congenital heart disease. Progress in Pediatr Cardiol 2010;29(2):97-105
⁴
Bruneau BG. The developmental genetics of congenital heart disease. Nature 2008;451(7181):943-948
⁵
Medoff-Cooper B, Naim M, Torowicz D, Mott A. Feeding, growth, and nutrition in children with congenitally malformed hearts. Cardiol Young 2010;20(3, Suppl 3):149-153
⁶
Sables-Baus S, Kaufman J, Cook P, da Cruz EM. Oral feeding outcomes in neonates with congenital cardiac disease undergoing cardiac surgery. Cardiol Young 2012;22(1):42-48
⁷
Delaney AL, Arvedson JC. Development of swallowing and feeding: prenatal through first year of life. Dev Disabil Res Rev 2008;14(2): 105-117
⁸
Newman LA, Keckley C, Petersen MC, Hamner A. Swallowing function and medical diagnoses in infants suspected of dysphagia. Pediatrics 2001;108(6):E106
⁹
Weckmueller J, Easterling C, Arvedson J. Preliminary temporal measurement analysis of normal oropharyngeal swallowing in infants and young children. Dysphagia 2011;26(2):135-143
¹⁰
Silberstein D, Geva R, Feldman R, et al. The transition to oral feeding in low-risk premature infants: relation to infant neurobehavioral functioning and mother-infant feeding interaction. Early Hum Dev 2009;85(3):157-162
¹¹
Jadcherla SR, Vijayapal AS, Leuthner S. Feeding abilities in neonates with congenital heart disease: a retrospective study. J Perinatol 2009;29(2):112-118
¹²
Woodward CS. Keeping children with congenital heart disease healthy. J Pediatr Health Care 2011;25(6):373-378
¹³
Arvedson JC. Assessment of pediatric dysphagia and feeding disorders: clinical and instrumental approaches. Dev Disabil Res Rev 2008;14(2):118-127
¹⁴
Arvedson J, Clark H, Lazarus C, Schooling T, Frymark T. The effects of oral-motor exercises on swallowing in children: an evidencebased systematic review. Dev Med Child Neurol 2010;52(11): 1000-1013
¹⁵
Sitton M, Arvedson J, Visotcky A, et al. Fiberoptic endoscopic evaluation of swallowing in children: feeding outcomes related to diagnostic groups and endoscopic findings. Int J Pediatr Otorhinolaryngol 2011;75(8):1024-1031
¹⁶
Heiss CJ, Goldberg L, Dzarnoski M. Registered dietitians and speechlanguage pathologists: an important partnership in dysphagia management. J Am Diet Assoc 2010;110(9):1290, 1292-1293
¹⁷
Hongama S, Nagao K, Toko S, et al. MI sensor-aided screening system for assessing swallowing dysfunction: application to the repetitive saliva-swallowing test. J Prosthodont Res 2012;56(1): 53-57
¹⁸
Hewetson R, Singh S. The lived experience of mothers of children with chronic feeding and/or swallowing difficulties. Dysphagia 2009;24(3):322-332
¹⁹
Christiaanse ME, Mabe B, Russell G, Simeone TL, Fortunato J, Rubin B. Neuromuscular electrical stimulation is no more effective than usual care for the treatment of primary dysphagia in children. Pediatr Pulmonol 2011;46(6):559-565
²⁰
Fujinaga CI, Scochi CGS, Santos CB, et al. Validação do conteúdo de um instrumento para avaliação da prontidão do prematuro para início da alimentação oral. Rev Bras SaudeMater Infant 2008;8(4): 391-399
²¹
Weir K, McMahon S, Barry L, Masters IB, Chang AB. Clinical signs and symptoms of oropharyngeal aspiration and dysphagia in children. Eur Respir J 2009;33(3):604-611
²²
Fujinaga CI, de Moraes SA, Zamberlan-Amorim NE, Castral TC, de Almeida e Silva A, Scochi CG. Clinical validation of the PretermOral Feeding Readiness Assessment Scale. Rev Lat Am Enfermagem 2013;21(Spec No):140-145
²³
Mizuno K, Ueda A. The maturation and coordination of sucking, swallowing, and respiration in preterm infants. J Pediatr 2003; 142(1):36-40
²⁴
Brown CV, Hejl K,Mandaville AD, Chaney PE, Stevenson G, Smith C. Swallowing dysfunction after mechanical ventilation in trauma patients. J Crit Care 2011;26(1):e9-e13
²⁵
Bordon A, Bokhari R, Sperry J, Testa D IV, Feinstein A, Ghaemmaghami V. Swallowing dysfunction after prolonged intubation: analysis of risk factors in trauma patients. Am J Surg 2011; 202(6):679-682, discussion 682-683
²⁶
Tutor JD, Gosa MM. Dysphagia and aspiration in children. Pediatr Pulmonol 2012;47(4):321-337
²⁷
Kohr LM, Dargan M, Hague A, et al. The incidence of dysphagia in pediatric patients after open heart procedures with transesophageal echocardiography. Ann Thorac Surg 2003;76(5):1450-1456
²⁸
Sachdeva R, Hussain E,MossMM, et al. Vocal cord dysfunction and feeding difficulties after pediatric cardiovascular surgery. J Pediatr 2007;151(3):312-315, e1-e2
²⁹
Yi SH, Kim SJ, Huh J, Jun TG, Cheon HJ, Kwon JY. Dysphagia in infants after open heart procedures. Am J Phys Med Rehabil 2013; 92(6):496-503
³⁰
Medoff-Cooper B, Irving SY. Innovative strategies for feeding and nutrition in infants with congenitally malformed hearts. Cardiol Young 2009;19(Suppl 2):90-95
³¹
Maurer I, Latal B, Geissmann H, Knirsch W, Bauersfeld U, Balmer C. Prevalence and predictors of later feeding disorders in children who underwent neonatal cardiac surgery for congenital heart disease. Cardiol Young 2011;21(3):303-309

Publication Dates

Publication in this collection
Jan-Mar 2015

History

Received
03 Mar 2014
Accepted
09 June 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
Teixeira FM, Coelho RM, Proença C, et al. Quality of life experienced by adolescents and young adults with congenital heart disease. Pediatr Cardiol 2011;32(8):1132-1138

[2] ²
van der Linde D, Konings EE, Slager MA, et al. Birth prevalence of congenital heart disease worldwide: a systematic review and meta-analysis. J Am Coll Cardiol 2011;58(21):2241-2247

[3] ³
Gerdes M, Flynn T. Clinical assessment of neurobehavioral outcomes in infants and children with congenital heart disease. Progress in Pediatr Cardiol 2010;29(2):97-105

[4] ⁴
Bruneau BG. The developmental genetics of congenital heart disease. Nature 2008;451(7181):943-948

[5] ⁵
Medoff-Cooper B, Naim M, Torowicz D, Mott A. Feeding, growth, and nutrition in children with congenitally malformed hearts. Cardiol Young 2010;20(3, Suppl 3):149-153

[6] ⁶
Sables-Baus S, Kaufman J, Cook P, da Cruz EM. Oral feeding outcomes in neonates with congenital cardiac disease undergoing cardiac surgery. Cardiol Young 2012;22(1):42-48

[7] ⁷
Delaney AL, Arvedson JC. Development of swallowing and feeding: prenatal through first year of life. Dev Disabil Res Rev 2008;14(2): 105-117

[8] ⁸
Newman LA, Keckley C, Petersen MC, Hamner A. Swallowing function and medical diagnoses in infants suspected of dysphagia. Pediatrics 2001;108(6):E106

[9] ⁹
Weckmueller J, Easterling C, Arvedson J. Preliminary temporal measurement analysis of normal oropharyngeal swallowing in infants and young children. Dysphagia 2011;26(2):135-143

[10] ¹⁰
Silberstein D, Geva R, Feldman R, et al. The transition to oral feeding in low-risk premature infants: relation to infant neurobehavioral functioning and mother-infant feeding interaction. Early Hum Dev 2009;85(3):157-162

[11] ¹¹
Jadcherla SR, Vijayapal AS, Leuthner S. Feeding abilities in neonates with congenital heart disease: a retrospective study. J Perinatol 2009;29(2):112-118

[12] ¹²
Woodward CS. Keeping children with congenital heart disease healthy. J Pediatr Health Care 2011;25(6):373-378

[13] ¹³
Arvedson JC. Assessment of pediatric dysphagia and feeding disorders: clinical and instrumental approaches. Dev Disabil Res Rev 2008;14(2):118-127

[14] ¹⁴
Arvedson J, Clark H, Lazarus C, Schooling T, Frymark T. The effects of oral-motor exercises on swallowing in children: an evidencebased systematic review. Dev Med Child Neurol 2010;52(11): 1000-1013

[15] ¹⁵
Sitton M, Arvedson J, Visotcky A, et al. Fiberoptic endoscopic evaluation of swallowing in children: feeding outcomes related to diagnostic groups and endoscopic findings. Int J Pediatr Otorhinolaryngol 2011;75(8):1024-1031

[16] ¹⁶
Heiss CJ, Goldberg L, Dzarnoski M. Registered dietitians and speechlanguage pathologists: an important partnership in dysphagia management. J Am Diet Assoc 2010;110(9):1290, 1292-1293

[17] ¹⁷
Hongama S, Nagao K, Toko S, et al. MI sensor-aided screening system for assessing swallowing dysfunction: application to the repetitive saliva-swallowing test. J Prosthodont Res 2012;56(1): 53-57

[18] ¹⁸
Hewetson R, Singh S. The lived experience of mothers of children with chronic feeding and/or swallowing difficulties. Dysphagia 2009;24(3):322-332

[19] ¹⁹
Christiaanse ME, Mabe B, Russell G, Simeone TL, Fortunato J, Rubin B. Neuromuscular electrical stimulation is no more effective than usual care for the treatment of primary dysphagia in children. Pediatr Pulmonol 2011;46(6):559-565

[20] ²⁰
Fujinaga CI, Scochi CGS, Santos CB, et al. Validação do conteúdo de um instrumento para avaliação da prontidão do prematuro para início da alimentação oral. Rev Bras SaudeMater Infant 2008;8(4): 391-399

[21] ²¹
Weir K, McMahon S, Barry L, Masters IB, Chang AB. Clinical signs and symptoms of oropharyngeal aspiration and dysphagia in children. Eur Respir J 2009;33(3):604-611

[22] ²²
Fujinaga CI, de Moraes SA, Zamberlan-Amorim NE, Castral TC, de Almeida e Silva A, Scochi CG. Clinical validation of the PretermOral Feeding Readiness Assessment Scale. Rev Lat Am Enfermagem 2013;21(Spec No):140-145

[23] ²³
Mizuno K, Ueda A. The maturation and coordination of sucking, swallowing, and respiration in preterm infants. J Pediatr 2003; 142(1):36-40

[24] ²⁴
Brown CV, Hejl K,Mandaville AD, Chaney PE, Stevenson G, Smith C. Swallowing dysfunction after mechanical ventilation in trauma patients. J Crit Care 2011;26(1):e9-e13

[25] ²⁵
Bordon A, Bokhari R, Sperry J, Testa D IV, Feinstein A, Ghaemmaghami V. Swallowing dysfunction after prolonged intubation: analysis of risk factors in trauma patients. Am J Surg 2011; 202(6):679-682, discussion 682-683

[26] ²⁶
Tutor JD, Gosa MM. Dysphagia and aspiration in children. Pediatr Pulmonol 2012;47(4):321-337

[27] ²⁷
Kohr LM, Dargan M, Hague A, et al. The incidence of dysphagia in pediatric patients after open heart procedures with transesophageal echocardiography. Ann Thorac Surg 2003;76(5):1450-1456

[28] ²⁸
Sachdeva R, Hussain E,MossMM, et al. Vocal cord dysfunction and feeding difficulties after pediatric cardiovascular surgery. J Pediatr 2007;151(3):312-315, e1-e2

[29] ²⁹
Yi SH, Kim SJ, Huh J, Jun TG, Cheon HJ, Kwon JY. Dysphagia in infants after open heart procedures. Am J Phys Med Rehabil 2013; 92(6):496-503

[30] ³⁰
Medoff-Cooper B, Irving SY. Innovative strategies for feeding and nutrition in infants with congenitally malformed hearts. Cardiol Young 2009;19(Suppl 2):90-95

[31] ³¹
Maurer I, Latal B, Geissmann H, Knirsch W, Bauersfeld U, Balmer C. Prevalence and predictors of later feeding disorders in children who underwent neonatal cardiac surgery for congenital heart disease. Cardiol Young 2011;21(3):303-309

Case no.	Gender	Age	Cardiac diagnosis	Type of cardiology	Surgical repair	Intubation time (h)	Extubation failed
1	F	5 mo 1 d	Complex cyanotic congenital heart disease	Cyanotic	Yes	1,536	Yes
2	F	28 d	Pulmonary stenosis	Acyanotic	Yes	456	Yes
3	F	6 mo 7 d	Interventricular communication	Acyanotic	Yes	4	No
4	F	4 mo 2 d	Aortic stenosis	Acyanotic	Yes	2.5	No
5	M	3 mo 9 d	Aortic coarctation	Acyanotic	Yes	24	No
6	M	3 mo 2 d	Total anomalous pulmonary venous drainage	Acyanotic	Yes	48	Yes
7	M	20 d	Aortic coarctation and aortic stenosis	Acyanotic	Yes	144	No
8	M	19 d	Aortic stenosis	Acyanotic	Yes	336	Yes
9	M	3 mo 3 d	Pulmonary atresia and atrial septal defects	Cyanotic	Yes	216	Yes
10	M	4 mo 2 d	Atrial septal defects, interventricular communication and aortic coarctation	Acyanotic	Yes	960	Yes
11	M	15 d	Transposition of great vessels	Cyanotic	Yes	9	No
12	M	4 mo 17 d	Interventricular communication	Acyanotic	Yes	192	No
13	F	10 d	Aortic stenosis	Acyanotic	Yes	24	No
14	M	5 mo 25 d	Interventricular communication, patent ductus arteriosus, and aortic coarctation	Acyanotic	Yes	288	Yes
15	F	15 d	Pulmonary atresia	Cyanotic	Yes	168	No
16	M	2 mo 10 d	Atrial septal defects, interventricular communication, and patent ductus arteriosus	Acyanotic	Yes	48	No
17	F	4 mo 24 d	Tetralogy of Fallot	Cyanotic	Yes	24	No
18	M	16 d	Transposition of great vessels	Cyanotic	Yes	168	No
19	F	4 mo	Tetralogy of Fallot	Cyanotic	Yes	648	Yes

Case no.	Consistencies	Utensils	Clinical findings	Result	Score
1	Liquid thickened	Latex nipple, orthodontic nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration	Oropharyngeal dysphagia	20
2	Liquid	Breast-feeding	Incoordination of suck, swallow, and respiration; desaturation fatigue	Oropharyngeal dysphagia	23
3	Liquid thickened	Latex nipple, orthodontic nipple, reduced flow (water/tea hole)	Incoordination of suck, swallow, and respiration	Oropharyngeal dysphagia	25
4	Liquid	Silicone nipple, orthodontic nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration; cough fatigue	Oropharyngeal dysphagia	30
5	Liquid thickened	Silicone nipple, conventional nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration	Oropharyngeal dysphagia	33
6	Liquid	Breast-feeding; silicone nipple, orthodontic nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration; oral spillage; cough	Oropharyngeal dysphagia	25
7	Liquid	Silicone nipple, conventional nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration	Oropharyngeal dysphagia	33
8	Liquid	Latex nipple, orthodontic nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration	Oropharyngeal dysphagia	28
9	Liquid	Silicone nipple, conventional nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration; stasis in the oral cavity; cyanosis	Oropharyngeal dysphagia	22
10	Liquid thickened	Latex nipple, orthodontic nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration; fatigue	Oropharyngeal dysphagia	25
11	Liquid thickened	Latex nipple, conventional nipple, conventional flow (milk hole)	Desaturation Incoordination of suck, swallow, and respiration; fatigue; stasis in the oral cavity	Oropharyngeal dysphagia	16
12	Liquid	silicone nipple, conventional nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration; oral spillage; cough	Oropharyngeal dysphagia	29
13	Liquid	Latex nipple, conventional nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration; oral spillage; cough	Oropharyngeal dysphagia	29
14	Liquid	Breast-feeding	–	Normal swallowing	30
15	Liquid	Latex nipple, conventional nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration; stasis in the oral cavity oral spillage	Oropharyngeal dysphagia	25
16	Liquid	Breast-feeding	Incoordination of suck, swallow, and respiration	Oropharyngeal dysphagia	24
17	Liquid	Breast-feeding	–	Normal swallowing	36
18	Liquid	Breast-feeding	–	Normal swallowing	33
19	Liquid thickened	Silicone nipple, conventional nipple, conventional flow (milk hole)	Incoordination of suck, swallow, and respiration; stasis in the oral cavity; oral spillage	Oropharyngeal dysphagia	23

	Group 1	Group 2	p value^a Fisher exact test.
Male	2 (18%)	9 (82%)	>0.999
Acyanotic heart defect	1 (33%)	11 (58%)	0.422
Arrhythmic suction	0 (0%)	12 (75%)	0.036
<5 sucks/pause	0 (0%)	6 (37.5%)	0.427
5–8 sucks/pause	1(33%)	4 (25%)
>8 sucks/pause	2 (67%)	6 (37.5%)
Strong suck	3 (100%)	8 (50%)	0.228
Weak suck	0 (0%)	8 (50%)	0.228
Lack of suck, swallow, respiration coordination	0 (0%)	16 (100%)	<0.001
Cough	0 (0%)	5 (31.3%)	0.278

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Evaluation of Swallowing in Infants with Congenital Heart Defect

Abstract

Introduction

Objective

Methods

Results

Conclusions

Introduction

Methods

Results

Discussion

Conclusion

References

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History