To assess the efficacy of a 4-week swallowing rehabilitation program combined with pyriform sinus ballooning in patients with post-stroke dysphagia (PSD).
We evaluated a total of 30 patients (n=30) with PSD who were admitted to our medical institution between May of 2014 and October of 2016. These patients were randomly assigned to either the trial group (n=15; a 20-minute conventional rehabilitation followed by a 10-minute pyriform sinus ballooning) or the control group (n=15; a 30-minute conventional rehabilitation). In these patients, the efficacy outcome measures were pharyngeal remnant, the pharyngeal transit time, the Penetration Aspiration Scale (PAS) scores and the Videofluoroscopic Dysphagia Scale (VDS) scores. We compared the differences in efficacy outcome measures at 4 weeks from baseline between the two groups.
There were significant changes in the pharyngeal remnant, the pharyngeal transit time, the PAS scores and the VDS scores at 4 weeks from baseline between the two groups (p<0.0001, p=0.0001, p<0.0001, and p=0.0048, respectively). There were no treatment-emergent adverse events in our series.
Our 4-week rehabilitation program combined with pyriform sinus ballooning is an effective and safe modality in patients with PSD. However, further large-scale, long-term, and multi-center studies are needed to corroborate our results.
Stroke has been considered the leading cause of death, and its prevalence is higher than that of cancer or cardiovascular diseases [
Treatment modalities for patients with PSD may include compensatory strategies and direct or indirect therapies. Compensatory strategies are used to relieve symptoms without improving swallowing dysfunctions; these include modification of food consistency and postural maneuver (e.g., chin tuck). Direct therapies are associated with diet adjustment. Indirect therapies include stimulation of swallowing or behavioral swallowing interventions. On the other hand, only a limited number of patients with PSD accompanied by cognitive impairment are indicated for conventional exercise interventions such as the Shaker exercise or Mendelsohn maneuver. Furthermore, patients with PSD receiving nasogastric or gastrostomy tube feeding are contraindicated for direct therapies because they are at risk of developing aspiration pneumonia; they are also vulnerable to decreased swallowing frequency as well as dependence on tube feeding [
In patients with PSD, pyriform sinus and vallecular space are two sites of residue accumulation [
In previous studies, however, treatment regimens using a Foley balloon catheter were solely performed during fluoroscopy, which suggests challenges in clinical application. Furthermore, they revealed limitations in continuity and convenience of the treatment. Based on previous studies, we considered using a blind technique without fluoroscopy and placed a Foley balloon catheter till the pharynx. This procedure led to speculation that a ballooning in the pyriform sinus is more advantageous than in the vallecular space. Both sites share similar approach. However, access to the vallecular space was suggested through a U-turn of an endoscope in the oropharynx during transnasal endoscopy. On the other hand, the pyriform sinus can be naturally accessed along the posterior wall of the oropharynx [
It is known that a repetitive, task-oriented training is effective for post-stroke rehabilitation [
The purpose of this study is to evaluate the efficacy of a 4-week course of a conventional dysphagia rehabilitation program combined with a non-fluorosopy-guided pyriform sinus ballooning in patients with PSD.
The current single-center, prospective, randomized, observer-blind, controlled study was conducted in a total of 45 patients with PSD who were admitted to our medical institution between May of 2014 and October of 2016.
Inclusion criteria were as follows: (1) PSD with an onset period of <3 years; (2) aspiration or post-swallow residue (≥10%) in the pyriform sinus at baseline VFSS; and (3) tube feeding at the time of study entry. Exclusion criteria were as follows: (1) acute stroke with an onset period of <1 month; (2) swallowing rehabilitation treatment using balloon catheterization or botulinum toxin injections within 6 months before study entry; (3) facial deformity or fracture or cervical hyperflexion/hyperextension; (4) vocal cord palsy; (5) airway obstruction or anatomical abnormalities of the pharynx or larynx confirmed on fiberoptic laryngoscope; (6) a history of underlying neurological diseases that may affect swallowing reflex (e.g., Parkinson disease, dementia, or motor neuron disease); and (7) patients considered ineligible for study participation.
After excluding 15 patients, we enrolled a total of 30 in the current analysis. The study was approved by the Institutional Review Board of Myongji Hospital (No. 14-019). All the patients submitted a written informed consent for study participation. The current study was conducted in accordance with the Declaration of Helsinki.
As previously described, efficacy outcome measures include the following [
Pharyngeal transit time (ms): The period of time that a bolus remains in the pharynx, during which food passes from the pharyngeal fornix into the UES.
Pharyngeal remnant (%): The amount of food retained in the pharyngeal space, whose width corresponds to the area calculated based on the reference value.
Penetration Aspiration Scale (PAS): An 8-point multidimensional indicator of airway invasion, which was used to record the presence of airway penetration (entry of contrast material into the laryngeal vestibule) and aspiration (below the level of the true vocal folds). Videofluoroscopic Dysphagia Scale (VDS): A reliable, objective and quantifiable 100-poins predictor of a longterm, persistent presence of the PSD.
In the current study, changes in the pharyngeal transit time, pharyngeal remnant, PAS and VDS scores at 4 weeks from baseline served as efficacy outcome measures. For efficacy assessment, we compared differences in changes in efficacy outcome measures at 4 weeks from the baseline between the two groups.
For safety assessment, we examined whether patients presented with the treatment-emergent adverse events (TEAEs) at the sites of pyriform sinus ballooning.
Depending on whether our patients additionally received pyriform sinus ballooning, they were divided into two groups: the trial group and the control group. Thus, the patients were randomized into either of the two groups using a permuted block design. Swallowing rehabilitation was performed for 30 minutes daily 5 times a week for 4 weeks. In the trial group, a 20-minute conventional treatment was combined with a 10-minute pyriform sinus ballooning. In the control group, a 30-minute conventional treatment was solely performed.
At baseline, we examined whether the patients met the inclusion/exclusion criteria and analyzed their baseline characteristics—e.g., age, sex, modified Rankin Scale (mRS) scores, National Institutes of Health Stroke Scale (NIHSS) scores, time from the onset of stroke to the VFSS, Korean version of modified Mini-Mental State Examination (K-MMSE) scores, type of feeding, type of stroke and diagnoses. Further, we performed a transnasal endoscopic evaluation of the surface or mucosa using the MAJ-922 (Olympus Medical Systems Corp., Tokyo, Japan), to examine the vocal cord movement, laryngopharyngeal reflux, laryngeal sensation and airway patency. In the trial group, we also measured the balloon diameter. We performed a swallowing rehabilitation followed by posttreatment assessment and comparative evaluation of differences in efficacy outcome measures between the two groups (
The VFSS was performed with a 4-mL bolus of semisolid paste in the chin-tucked position. The semisolid paste was pudding-like without lumps, chunks, or pulp, prepared as a 2:1 volumetric mixture of dysphagia formula level 1 and contrast barium solution (Solotop-HD provided by Taejoon Pharm Company, Yongin, Korea). In addition, 375 g barium sulfate powder was mixed with 90 mL water for the contrast solution. In the current study, we used a semisolid whose remnant amount was calculated. Patients with cognitive decline or who had difficulty maintaining head control were seated on a wheelchair, and an assistant held their head to maintain the aforementioned position [
We performed a non-fluoroscopy-guided pyriform sinus ballooning using the VFSS [
Conventional rehabilitation program for swallowing was performed by an occupational therapist. To minimize risks of developing aspiration as well as to reduce the pharyngeal remnant, we performed chin tuck, supraglottic swallow and Shaker exercise for the patients in the control group. In addition, we performed effortful or multiple swallowing and Mendelsohn maneuvers to improve bolus transport. Furthermore, we performed tongue strengthening exercise, tongue holding maneuver, laryngeal adduction and elevation exercises for oral motor facilitation [
The conventional rehabilitation was also combined with nutritional supplementation [
Non-fluoroscopy-guided pyriform sinus ballooning was performed by an occupational therapist under the supervision of a physician who was blinded to the current study. Pyriform sinus ballooning is based on voluntary swallowing or swallowing reflex, without deliberately relaxing the UES or inducing swallowing. The lubricant gel was applied to the tip of a 12-Fr Foley balloon catheter, which was inserted in the nasal cavity. In patients complaining of severe discomfort, it was done orally. Thus, the Foley balloon catheter was advanced to sites of marking immediately before swallowing on the VFSS. As the catheter reached the pyriform sinus, we performed inflation and deflation of air at a volume of approximately 0.5–1 mL until the repeated maneuver triggered the swallowing reflex. This approach was based on the volume of air equivalent to that of contrast media used to maximize the diameter of the balloon during the initial VFSS. We performed the pyriform sinus ballooning for 30 seconds maximum. Without completely ruling out the possibility of relaxation of the UES, we triggered the voluntary swallowing or swallowing reflex using the above maneuver.
Criteria for determining successful swallowing are as follows: the presence of downward force of the Foley balloon catheter according to the investigator’s judgment; the exact match of the sites of marking before and after swallowing on the VFSS; and a lack of cough reflex. A transoral approach was also permitted for patients without gag reflex. In the non-cooperative patients with cognitive impairment, we induced the swallowing reflex through manual stimulation. We meticulously monitored the patients for complications such as epistaxis, gag reflex, tachycardia, bradycardia or syncope during the procedure. Furthermore, balloon deflation was attempted to minimize the patients’ discomfort.
According to Kim et al. [
Data were expressed as mean±standard deviation. Statistical analysis was carried out using the SPSS version 18.0 for Windows (SPSS Inc., Chicago, IL, USA). We compared the baseline characteristics between the two groups using the independent samples t-test. In addition, we also compared differences in changes in efficacy outcome measures at 4 weeks from baseline between the two groups using the Student t-test. A p-value of <0.05 was considered statistically significant.
The 45 recruited patients were initially assigned to the trial group (n=22) and the control group (n=23). Among the patients in the trial group, 5 discontinued the study because of hospital-acquired pneumonia and 2 were lost to follow-up. In addition, 3 patients in the control group dropped out because of hospital-acquired pneumonia and 5 were lost to follow-up. Therefore, 15 patients were finally assigned to either the trial group or the control group (n=15).
Our clinical series of patients were divided equally into two groups: the trial group (n=15) and the control group (n=15). They consisted of 12 men and 18 women, with a mean age of 58.5±16.5 years. In addition, the patients’ mRS score was 4.1±1.1, NIHSS score 16.5±7.7, time from the onset of stroke to the VFSS was 312.6±207.8 days, and a K-MMSE score of 8.1±10.3. Baseline characteristics of the patients are represented in
As shown in
There were no TEAEs in our series.
Patients with stroke are at risk of paralysis of muscles due to degradation in motor skills and coordination ability. Paralysis of the cricopharyngeus muscle impairs the relaxation and contraction of the UES resulting in food remaining in the pharyngeal space without reaching the esophagus [
Pyriform sinus ballooning was first attempted by Kim et al. [
In the current study, we meticulously monitored for possible complications of balloon swallowing, to prevent TEAEs, which is also consistent with previous studies [
Pharyngeal phase is initiated when the swallowing material passes the anterior facial arch through a voluntary mechanism based on lingual action. In addition, it is also initiated via an involuntary mechanism by the stimulation of the specific area of the pharynx and larynx. It normally occurs in healthy individuals for 1 second or shorter periods [
Impaired swallow due to a variety of diseases induces voluntary compensation, including mechanical blending, the decreased size of the food bolus and tilting of head and neck. However, such compensation also occurs via an involuntary mechanism based on the adjustment of swallow apparatus. This pattern of pharyngeal swallow includes the posterior displacement of the tongue and larynx, the anterior displacement of the constrictor wall, the further upward and downward displacement of the larynx and the forward tilting of head. These phenomena occur as normal adaptation to the impaired swallow. In addition, a compensation failure leads to decompensation resulting in ineffective swallowing and accumulation of residue in the pyriform sinus, penetration and aspiration.
Based on previous studies, we performed a 4-week course of exercise intervention for dysphagia rehabilitation using a Foley balloon catheter of specific size. Presumably, it leads to compensation based on involuntary mechanism and speculation that the pyriform sinus ballooning is an adaptation to normal swallowing from a therapeutic perspective. Furthermore, the decreased decompensation might improve swallowing ability and decrease the pharyngeal remnant [
Pyriform sinus ballooning with the Foley balloon catheter allows adjustment of air volume and balloon size according to the swallowing ability of each patient, which plays a role in task-oriented training via repetitive swallowing. Kim et al. [
Limitations of the current study are as follows: we enrolled a relatively small number of patients. We could not therefore completely rule out the possibility of spontaneous recovery from PSD because of the relatively short period of study. We conducted the current study in the setting of a single, tertiary medical institution. We could not therefore completely rule out the possibility of selection bias. The observer was blinded to the ballooning procedure, but its outcomes may depend on his or her technical expertise. Even the small lesions may be a critical factor in patients with brainstem stroke because of clusters of reticular interneurons between cranial nerve nuclei, nerve tract and brainstem structure [
To summarize, our results revealed significant differences in changes associated with pharyngeal remnant, pharyngeal transit time, PAS scores and VDS scores at 4 weeks from baseline between the two groups (p<0.0001, p=0.0001, p<0.0001 and p=0.0048, respectively). There were no TEAEs in our series.
In conclusion, our results indicate that our 4-week rehabilitation program with pyriform sinus ballooning is an effective, safe and well-tolerated modality in patients with PSD. Pyriform sinus ballooning can be done by directly stretching and strengthening cricopharyngeus muscle. It is associated with fewer complications and induces swallowing reflex non-invasively and cost-effectively. However, further large-scale, long-term, multicenter studies are warranted to establish our results.
No potential conflict of interest relevant to this article was reported.
Study flow chart.
Passage of the Foley balloon catheter in the videofluoroscopic swallowing study before and during pyriform sinus ballooning. A 12-Fr Foley catheter was placed in the pyriform sinus via a transnasal or transoral approach. It was filled with varying volumes of contrast media in increasing order: 0, 1, 2, 3, 4 and 5 mL, followed by meticulous monitoring of the swallowing process. Thus, we determined the greatest diameter of the balloon tolerated by the patients. (A) the passage of the balloon in the upper esophageal sphincter before and (B) during swallowing. The white arrow indicates the passage of the balloon.
Baseline characteristics of the patients
Trial group (n=15) | Control group (n=15) | p-value | |
---|---|---|---|
Age (yr) | 58.7±16.0 | 58.4±16.9 | 0.9605 |
Male-to-female ratio | 4:11 | 8:7 | 0.2597 |
mRS | 3.7±1.3 | 4.5±0.6 | 0.0391 |
NIHSS | 14.5±8.7 | 18.6±5.8 | 0.1401 |
Time from the onset of stroke to the of stroke to the | 354.1±248.7 | 271±145.3 | 0.2733 |
K-MMSE | 9.1±11.3 | 7.1±9.0 | 0.5961 |
Type of feeding | |||
PEG | 5 | 2 | 0.2155 |
L-tube | 10 | 13 | 0.4283 |
Type of stroke | |||
Ischemic | 8 | 3 | 0.2824 |
Hemorrhagic | 7 | 12 | 0.3610 |
Side of lesion | |||
Right | 4 | 3 | 0.4206 |
Left | 6 | 4 | 0.3917 |
Multiple | 5 | 8 | 0.3766 |
Efficacy outcome measures | |||
Pharyngeal remnant | 43.3±21.4 | 44.2±13.2 | 0.8907 |
Pharyngeal transit time | 9.2±4.0 | 8.9±4.0 | 0.8387 |
PAS | 4.8±1.8 | 4.9±1.7 | 0.8768 |
VDS | 69.5±8.9 | 69.8±8.9 | 0.9271 |
Values are presented as mean±standard deviation.
mRS, modified Rankin Scale; NIHSS, National Institutes of Health Stroke Scale; VFSS, videofluoroscopic swallowing study; K-MMSE, Korean version of modified Mini-Mental State Examination; PEG, percutaneous endoscopic gastrostomy; PAS, Penetration Aspiration Scale; VDS, Videofluoroscopic Dysphagia Scale.
Efficacy outcomes
Trial group (n=15) |
Control group (n=15) |
p-value | |||||
---|---|---|---|---|---|---|---|
Baseline | 4 weeks | Δ | Baseline | 4 weeks | Δ | ||
Pharyngeal remnant | 43.3±21.4 | 22.4±13.3 | 20.9±8.1 | 44.2±13.2 | 33.8±11.6 | 10.4±1.6 | <0.0001 |
Pharyngeal transit time | 9.2±4.0 | 4.9±2.0 | 4.3±2.0 | 8.9±4.0 | 5.7±3.6 | 3.2±0.4 | 0.0001 |
PAS | 4.8±1.8 | 3.4±1.8 | 1.4±0.0 | 4.9±1.7 | 4.0±1.5 | 0.9±0.2 | <0.0001 |
VDS | 69.5±8.9 | 58.7±11.3 | 10.8±2.4 | 69.8±8.9 | 60.9±8.8 | 8.9±0.1 | 0.0048 |
Values are presented as mean±standard deviation.
PAS, Penetration Aspiration Scale; VDS, Videofluoroscopic Dysphagia Scale.
p<0.05 by Student t-test.