Along with the developments in medicine, the survival rate of preterm infants has also increased from 9.4% in 1981, to 10.6% in 1990, and 12.0% in 2002 [1]. Forty to 72% of preterm infants suffer from dysphagia [23] and there are increasing numbers of reported cases [45]. Appropriate swallowing procedures are important in the physical and functional development of preterm infants, but dysphagia can lead to problems such as nutritional disorders, delayed development, and complications in the respiratory system [67]. The many causes of dysphagia in preterm infants include low birth weight, gastroesophageal reflux, neuromuscular disorders, genetic disorders, and respiratory infections [4589101112].

Videofluoroscopic swallowing study (VFSS) is the standard diagnostic test for dysphagia [13]. However, its use is limited because of exposure to radiation and the preterm infants' low cooperation. Some studies report signs or symptoms of dysphagia, such as a decreased sucking ability, history of cyanosis or apnea, and desaturation or coughing during feeding [24141516171819]. Because of such problems, there are dysphagia screening tests for both adults and children [202122], but there are few for preterm infants.

The early prediction and diagnosis of dysphagia are important for its treatment and to prevent complications. Therefore, we developed the simple and easy-to-use Dysphagia Screening Test for Preterm Infants (DST-PI), based on the reported signs and symptoms of dysphagia in clinical settings.

Among the numerous reasons of requesting VFSS for the 42 preterm infants (24 males, 18 females), decreased SpO₂ was the highest with 36 cases. Four cases were requested due to suspicion of aspiration pneumonia and two to remove a feeding tube. The average gestational age was 31 weeks 1 day±2 weeks 5.6 days. Twenty-eight infants (66.7%) were born before 32 weeks, 7 (16.7%) between 32 and 34 weeks, and 7 (16.7%) between 34 and 37 weeks. It took 59 days on average from the time of the initial request to VFSS testing. The average corrected age at the VFSS was 39 weeks 5 days±6 weeks 4 days. Twenty-one were born via vaginal delivery and the other 21 were delivered by cesarean section. The average Apgar score was 8±2.04 at 5 minutes. The average body weight at birth was 1,656±511 g.

When investigating associated diseases, 31 infants (73.8%) suffered from respiratory distress syndrome, followed by atrial septal defects in 18 (42.9%), and patent ductus arteriosus in 10 (23.8%). Seven (16.7%) displayed bronchopulmonary dysplasia (Table 1). Among the 42 preterm infants, 20 were diagnosed with supraglottic penetration and 9 with subglottic aspiration.

As for the odds ratios with regard to supraglottic penetration or subglottic aspiration of the initial assessment items, ‘decreased oxygen saturation within 3 minutes of feeding’ was the highest at 11.57. ‘Sucking ability,’ ‘vomiting within 5 minutes of feeding,’ ‘the Apgar score at 5 minutes,’ ‘body weight at birth,’ ‘history of ventilator usage,’ and ‘history of pneumonia’ were not statistically significant with p-values greater than 0.1 (Table 2). We selected items with odds ratios greater than 1.0 and p-values less than 0.1 as the final assessment items. These final items were quantitatively assigned, their odds ratios compared, and their scores added up to 10 (Table 3).

The sensitivity and specificity of the DST-PI at 3.25 points were 96.6% and 76.9%, and at 6.25 points 88.9% and 75.8%, respectively. The AUC was 0.942 (confidence interval, 0.853–1.000), which indicates a high validity. The average total scores were 2.38±1.77 for group 1, 6.21±2.02 for group 2, and 8.20±1.68 for group 3, statistically significant with p<0.05. The Spearman correlation coefficient between total scores of all preterm infants and the PAS was statistically significant at 0.807 (p<0.001). As for inter-rater reliability, the kappa coefficients for ‘swallowing pattern,’ ‘coughs during or after feeding,’ ‘decreased oxygen saturation within 3 minutes of feeding,’ ‘voice change after feeding,’ and the VFSS report were 0.869, 1.000, 1.000, 0.757, and 0.883, respectively, all with statistically significant p-values <0.001.

Many studies reported that the symptoms of aspiration are more common in preterm infants than in full-term infants [45]. Dysphagia is due to preterm infants' immaturity and supraglottic penetration can increase the risk for subglottic aspiration [28]. According to the results of Uhm et al. [35] and Bae et al. [2], 40.0% and 72% of preterm infants showed signs of aspiration, respectively, while the ratio was 69.0% in this study.

‘Coughs during or after feeding,’ ‘decreased oxygen saturation within 3 minutes of feeding,’ and ‘history of apnea’ were highly related to dysphagia, consistent with the studies that reported statistical significance for ‘gestational age,’ ‘history of cyanosis during feeding,’ ‘swallowing pattern,’ and ‘voice change after feeding.’

In the study of Lee et al. [15], cyanosis with coughs during feeding displayed a higher statistical significance with aspiration than in our study. Delzell et al. [29] reported that aspiration is associated to a low degree with decreased oxygen saturation; however, there was a high correlation between dysphagia and ‘decreased oxygen saturation within 3 minutes of feeding’ in this study, as also found by Roger et al. [30].

There is a report that indicates a higher frequency of dysphagia of preterm infants born before 32 weeks of gestational age [14]. However, according to Bae et al. [2], preterm infancy with birth before 34 weeks highly affects aspiration. Preterm infants born before 32 weeks were at a higher risk of dysphagia compared to those born after 32 weeks in this study. We suggest that this variation occurred, because maturation of deglutition takes place between 32 and 34 weeks of gestation [1431].

A disorganized sucking pattern is reported more often in preterm infants than dysfunctional sucking [31], which corresponds with our study that included 7 preterm infants with a disorganized sucking pattern and three with a dysfunctional sucking pattern.

The items ‘Apgar score at 5 minutes,’ ‘body weight at birth,’ ‘history of ventilator usage,’ ‘history of pneumonia,’ ‘sucking ability,’ and ‘vomiting within 5 minutes of feeding’ were not statistically significant.

Casey et al. [26] reported that the Apgar score was related to mortality and Simbron et al. [23] stated that ‘the Apgar score at 5 minutes’ was related to dysphagia. However, corresponding associations were not statistically significant in this study, indicating that the differences in the diagnostic method of the swallowing difficulty are irrelevant. We diagnosed dysphagia through VFSS, whereas Simbron et al. [23] scrutinized abnormal swallowing patterns for this purpose.

Lee et al. [10] reported that dysphagia was more frequent in infants with a very low birth weight, but this relationship was not statistically significant in our study. The subjects were different compared to those described in Lee et al. [10] who displayed desaturation at a gestational age of under 28 weeks. Rommel et al. [8] reported that preterm infants with birth weights under the 10th percentile according to gestational age showed a higher dysphagia frequency for. However, we could not observe this, due to the small number of subjects under the gestational age's 10th percentile.

Greenough and Milner [34] reported that pneumonia, which occurred in 10% of preterm infants, was more affected by underlying medical diseases than by dysphagia. We considered that the risk of aspiration pneumonia may be decreased by defense mechanisms.

Oral food intake and proper oral stimulation aid infant development. There are reports that intubation interrupts the development of the swallowing function [1733]. We assumed that a ‘history of ventilator usage’ affected dysphagia, but no relationship could be detected. Investigating medical records, periods of ventilator usage were short and none of the preterm infants used one when testing with VFSS.

Rosenbek et al. [27] developed the PAS to determine supraglottic penetration and subglottic aspiration for stroke patients, but Lee et al. [15] applied it to infants. The subjects differed in these studies and this investigation added preterm infants to the list. We found a relationship between total scores of the DST-PI and the PAS using the Spearman correlation coefficient.

Associated diseases were investigated retrospectively through medical records, but there was a limitation due to missing information about disease duration and severity. Large randomized, controlled, and prospective studies are needed to confirm the benefits of the DST-PI.

The sensitivities of the Toronto Bedside Swallowing Screening Test (TOR-BSST) and the Gugging Swallowing Screen (GUSS) which are known as dysphagia screening tests for stroke patients, were 91.3% and 100.0%, respectively [2021]. The sensitivity of the DST-PI was 96.6% at 3.25 points. Although the subjects were different compared to the TOR-BSST and GUSS studies, the DST-PI is considered to be useful in a clinical setting. The examination is easy to perform and there is no exposure to radiation as with the VFSS. It is notable that the DST-PI prevents complications, such as pneumonia or developmental delays, by early screening for dysphagia.