J Korean Dysphagia Soc 2023; 13(2): 77-106
Published online July 30, 2023 https://doi.org/10.34160/jkds.23.010
© The Korean Dysphagia Society.
1Department of Rehabilitation Medicine, Ewha Womans University Seoul Hospital, Ewha Womans University College of Medicine, Seoul, 2Department of Physical Medicine and Rehabilitation, Dongguk University Ilsan Hospital, Goyang, 3Department of Rehabilitation Medicine, CHA Bundang Medical Center, CHA University School of Medicine, Seongnam, 4Department of Otorhinolaryngology-Head and Neck Surgery, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 5Department of Occupational Therapy, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 6Department Audiology and Speech-Language Pathology, Daegu Catholic University, Gyoungsan, 7Department of Rehabilitation Medicine, International St. Mary’s Hospital, Catholic Kwandong University College of Medicine, Incheon, 8Department of Rehabilitation Medicine, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 9Department of Physical Medicine and Rehabilitation, Veterans Health Service Medical Center, Seoul, 10Department of Otorhinolaryngology-Head and Neck Surgery, Seoul National University Bundang Hospital, Seoul National University College of Medicine, Seongnam, 11Department of Otolaryngology, Inha University College of Medicine, Incheon, 12Department of Rehabilitation Medicine, Seoul National University Hospital, Seoul National University College of Medicine, Seoul, 13Department of Rehabilitation Medicine, Incheon St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Incheon, 14Department of Occupational Therapy, School of Medicine, Wonkwang University, Iksan, 15Department of Speech Therapy, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 16Department of Rehabilitation Medicine, Chungnam National University Hospital, College of Medicine, Chungnam National University, Daejeon, 17Department of Rehabilitation Medicine, Seoul Medical Center, Seoul, 18Department of Rehabilitation Medicine, Gil Medical Center, Gachon University College of Medicine, Incheon, 19Department of Otorhinolaryngology-Head and Neck Surgery, Kangwon National University Hospital, Kangwon National University College of Medicine, Chuncheon, 20Department of Otolaryngology-Head and Neck Surgery, St. Vincent’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, 21Department of Occupational Therapy, Konyang University, Daejeon, 22Department of Otorhinolaryngology-Head and Neck Surgery, Dongguk University Ilsan Hospital, Goyang, 23Deptartment of Rehabilitation Medicine, Konkuk University Medical Center, Seoul, 24Department of Rehabilitation Medicine, College of Medicine, The Catholic University of Korea, Seoul, 25Department of Physical Medicine and Rehabilitation, Dong-A University College of Medicine, Busan, 26Department of Otorhinolaryngology-Head and Neck Surgery, Seoul National University Hospital, Seoul National University College of Medicine, Seoul, 27Department of Physical Medicine and Rehabilitation, Korea University Anam Hospital, Korea University College of Medicine, Seoul, 28Department of Rehabilitation Medicine, National Traffic Injury Rehabilitation Hospital, Yangpyeong, 29Department of Rehabilitation Medicine, Seoul National University College of Medicine, Seoul, 30Department of Otorhinolaryngology, Gangnam Severance Hospital, Yonsei University College of Medicine, Seoul, 31Department of Otorhinolaryngology-Head and Neck Surgery, Samsung Changwon Hospital, Sungkyunkwan University School of Medicine, Changwon, 32Department of Otorhinolaryngology-Head and Neck Surgery, CHA Bundang Medical Center, CHA University School of Medicine, Seongnam, 33Department of Otorhinolaryngology-Head and Neck Surgery, Seoul National University Hospital, Seoul, 34Department of Rehabilitation Medicine, Bucheon St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Bucheon, 35Department of Rehabilitation Medicine, Pusan National University & Pusan National University Yangsan Hospital, Yangsan, 36Department of Rehabilitation Medicine, St. Vincent’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, 37Department of Gastroenterology, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 38Department of Gastroenterology, Konyang University College of Medicine, Daejeon, 39Deptartment of Nutrition & Food Control, Gangnam Severance Hospital, Seoul, 40Deptartment of Food & Nutrition, College of Human Ecology, Hanyang University, Seoul, 41Department of Otorhinolaryngology-Head and Neck Surgery, Kyung Hee University Hospital at Gangdong, Kyung Hee University School of Medicine, Seoul, 42Department of Otorhinolaryngology-Head and Neck Surgery, Chung-Ang University Gwangmyeong Hospital, Chung-Ang University College of Medicine, Gwangmyeong, 43Department of Food Service & Nutrition Care, Seoul National University Hospital, Seoul, 44Department of Rehabilitation Medicine, Yeouido St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, 45Namdarun Rehabilitation Clinic, Yongin, 46Department of Oral and Maxillofacial Surgery, University of Ulsan College of Medicine, Seoul, 47Department of Oral and Maxillofacial Surgery, Samsung Medical Center, Sungkyunkwan University School of Medicine, Seoul, 48Department of Clinical Nursing, University of Ulsan, Seoul, 49Department of Nursing, Seoul National University Bundang Hospital, Seongnam, 50Department of Physical Medicine and Rehabilitation, Korea University Anam Hospital, Seoul, 51Department of Otolaryngology-Head and Neck Surgery, Center for Thyroid Cancer, Research Institute and Hospital, National Cancer Center, Goyang, 52Department of Otorhinolaryngology-Head and Neck Surgery, Inje University Ilsan Paik Hospital, Inje University College of Medicine, Goyang, 53Department of Oral and Maxillofacial Surgery, Asan Medical Center, University of Ulsan College of Medicine, Seoul, Korea
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Objective: Dysphagia is a common clinical condition characterized by difficulty in swallowing. It is sub-classified into oropharyngeal dysphagia, which refers to problems in the mouth and pharynx, and esophageal dysphagia, which refers to problems in the esophageal body and esophagogastric junction. Dysphagia can have a significant negative impact one’s physical health and quality of life as its severity increases. Therefore, proper assessment and management of dysphagia are critical for improving swallowing function and preventing complications. Thus a guideline was developed to provide evidence-based recommendations for assessment and management in patients with dysphagia.
Methods: Nineteen key questions on dysphagia were developed. These questions dealt with various aspects of problems related to dysphagia, including assessment, management, and complications. A literature search for relevant articles was conducted using Pubmed, Embase, the Cochrane Library, and one domestic database of KoreaMed, until April 2021. The level of evidence and recommendation grade were established according to the Grading of Recommendation Assessment, Development and Evaluation methodology.
Results: Early screening and assessment of videofluoroscopic swallowing were recommended for assessing the presence of dysphagia. Therapeutic methods, such as tongue and pharyngeal muscle strengthening exercises and neuromuscular electrical stimulation with swallowing therapy, were effective in improving swallowing function and quality of life in patients with dysphagia. Nutritional intervention and an oral care program were also recommended.
Conclusion: This guideline presents recommendations for the assessment and management of patients with oropharyngeal dysphagia, including rehabilitative strategies.
Keywords: Deglutition disorders, Rehabilitation, Diagnosis, Treatment, Therapeutics
Dysphagia is a common clinical condition charac-terized by difficulty in swallowing. It is sub-classified into oropharyngeal dysphagia, which refers to pro-blems in the mouth and pharynx, and esophageal dysphagia, which refers to problems in the esopha-geal body and esophagogastric junction1. Oropharyngeal dysphagia is characterized by difficulty in initiating a swallow or passing food through the mouth or throat2, whereas esophageal dysphagia accompanies structural or inflammatory abnormalities or motility disorders3.
Dysphagia is associated with an acquired health condition, such as stroke, Parkinson’s disease, or motor neuron disease, as well as developmental disabilities. The prevalence of dysphagia is estimated to be 8% of the world’s population, and its prevalence increases in the older adult population4. The prevalence of dysphagia in older people dwelling in communities is approximately 15% and approximately 30% in hospi-talized patients1. It occurs most commonly in old patients with neurological disorders and dementia, with a prevalence of 64% and 80%, respectively5.
Dysphagia can have a significant negative impact on one’s physical health and quality of life as its severity increases6. If dysphagia is not properly evaluated and timely treated, it may worsen the quality of life and cause serious complications, such as dehydration, malnutrition, and aspiration pneumonia. Importantly, oropharyngeal dysphagia should be identified promptly considering the risk of aspiration. Various interventions such modifying food textures, positioning modification, or rehabilitative and com-pensatory strategies are designed to improve swallowing efficiency and reduce the risk of complications in patients with dysphagia7.
The purpose of this clinical practice guideline (CPG) was to provide a guideline supported by scientific evidence for physicians and other healthcare profe-ssions who diagnose and treat patients with symptoms of dysphagia. This CPG is aimed to assist in de-cision-making for appropriate treatment options to improve the clinical outcome of patients with dysphagia and reduce extravagant costs to patients and the overall health care system.
Assessment and management of dysphagia are mainly addressed in this CPG. Patients with progressive neurological disease and under 18 years of age were excluded from the scope of this CPG. This guideline does not aim to limit physicians’ medical practices and is not used to evaluate the quality of their practices.
The development group involved a development committee and an advisory committee, including three methodology experts. The development committee members consisted of 45 physicians (25 physiatrists, 15 otorhinolaryngologists, 2 gastro-enterologists, and 3 dentists), 2 nursing staff, 3 nutritionists, 3 occu-pational therapists, and 2 language therapists.
For each key question (KQ), 55 development com-mittee members determined the level of evidence and recommendation level.
This CPG consists of four categories: (1) assessment, (2) treatment, (3) nutritional management, and (4) complications and others. KQ was determined based on the Population Intervention Comparator Outcome (PICO) framework. According to the PICO strategy, adult patients of the population group who have symptoms or diagnosis of oropharyngeal dysphagia were included in this guideline. The number of KQs was determined by the number of interventions. The majority of outcomes focused mainly on improvement of dysphagia. If necessary, KQs were further divided into sub-KQs. Finally, a total of 19 KQs were for-mulated for this guideline.
A literature search was conducted for relevant articles using PubMed, Embase, the Cochrane Library, and one domestic database of KoreaMed, until April 2021. After establishing a highly sensitive strategy in combination with the natural language, the MeSH term was also used for PubMed and Cochrane Library, and the Emtree term was used for Embase. (Supple-mentary Data 1)
The search results were collated in EndNote. For each KQ, two independent reviewers excluded articles that did not meet the inclusion criteria of this CPG after reading titles and abstracts. Furthermore, full- text assessments were followed to reject those that did not fulfill the inclusion criteria. Articles that included patients with progressive neurological diseases (e.g., Parkinson’s disease or dementia) and patients who were under 18 years of age were exclu-ded. We also included articles written in languages other than English or Korean, articles that exist only in abstract form, case reports, technical reports, and animal studies. Study screening and data extraction were independently performed by two reviewers. The reviewers attempted to resolve any disagreement by consensus. If necessary, the opinion of a third reviewer was put into consideration to resolve the disagreement.
Quality assessment was performed on selected articles. The bias assessment was conducted using Cochrane risk-of-bias 2.0 for randomized controlled trials (RCTs) and the risk-of- bias assessment tool for non-randomized studies for non-RCTs8,9. The metho-dological quality of the systematic reviews (SRs) was evaluated using AMSTAR 1.0—a measurement tool to assess the methodological quality of SRs10. (Supple-mentary Data 2) The level of evidence and recom-mendation grade were established according to the Grading of Recommendation Assessment, Development and Evaluation (GRADE) methodology11. The level of evidence was evaluated by assessing the degree of bias, consistency, directness, accuracy, and publi-cation bias in the RCTs, non-RCTs, and SRs. The level of evidence for each KQ was based on the GRADE methodology as “high,” “medium,” “low,” and “very low”.(Table 1) The level of recommendation was determined according to a modified GRADE metho-dology divided into four levels.(Table 2) Several factors were considered, including the level of evidence, balance of benefits and harms, values and prefere-nces, obstacles and facilitating factors, resource and cost, and clinical applicability. The KQs that could not be further developed due to poor existing research were represented as expert consensus.
Table 1 . Grading of Recommendations Assessment, Development and Evaluation quality level of evidence and meaning..
Quality level | Definition |
---|---|
High | We are confident that the estimate of the effect is close to the actual effect |
Moderate | The estimates of the effect appear to be close to the actual effect but may vary considerably |
Low | The confidence in the estimate of the effect is limited. The actual effect may differ significantly from the estimate of the effect |
Very low | There is little confidence in the estimate of the effect. The actual effect will differ significantly from the estimate of the effect |
Table 2 . Grading of recommendations..
Strength of recommendations | Definition |
---|---|
Strong recommendation | The intervention/diagnostic test can be strongly recommended in most clinical practice, considering greater benefit than harm, evidence level, value and preference, and resources |
Conditional recommendation | The intervention/diagnostic test can be conditionally recommended in clinical practice considering the balance of benefit and harm, evidence level, value and preference, and resources |
Against recommendation | The harm caused by the intervention/diagnostic test maybe greater than its benefits. Moreover, considering the evidence level, value and preference, and resources, the intervention should not be recommended |
Inconclusive | It is not possible to determine the strength and direction of recommendation because of a very low or insufficient evidence level, uncertain or variable balance of benefit and harm, value and preference, and resources |
Expert consensusa) | Although clinical evidence is insufficient, it is recommended to be used in accordance with clinical experience and expert consensus when considering the benefits and risks of the treatment, the level of evidence, values and preferences, and resources |
Each statement is shown as a combination of the strength of recommendations and level of evidence..
a)In the case of a consensus statement by an expert opinion, the recommendation grade and level of evidence are not indicated..
For each KQ, at least two members of the develop-ment group participated in formulating and reviewing the draft recommendations. The working members continued discussions to reach consensus, and revisions were made there after in accordance with the opinions of the advisory committee. The recommen-dations were also revised through a review process via e-mail and a wired meeting with experts in the relevant field, and a formal consensus was achieved. The level of evidence and recommendations for 19 KQs were evaluated, and the content of the reco-mmendations and the recommendation grade was adjusted through in-depth discussion. The degree of consent for each committee member was selected from one (non-acceptance) to nine (acceptance) on a nine-point scale. If the score was ≥7, consent was considered to be present. If at least 75% of the committee members agreed to the final version of the recommendations, it was deemed to have reached a consensus. Finally, the final version of the 19 recommendations was accepted. This guideline will be revised every 5 years, when there is solid evidence that it can affect the management and treatment of patients with oropharyngeal dysphagia.
KQ 1. Early screening
A. Evidence level: high
B. Grade of recommendation: strong
KQ 2. Standardized screening test
A. Evidence level: not applicable
B. Grade of recommendation: expert consensus
KQ 3. Videofluoroscopic swallowing study (VFSS) vs. clinical evaluation
A. Evidence level: moderate
B. Grade of recommendation: strong
KQ 4. VFSS vs. fiberoptic endoscopic examination of swallowing (FEES)
A. Evidence level: inconclusive
B. Grade of recommendation: inconclusive
2) Treatment for oropharyngeal dysphagiaKQ 5. Oropharyngeal sensory stimulation
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 6. Exercises
KQ 6.1. Tongue and pharyngeal muscle strengthening exercise
A. Evidence level: moderate
B. Grade of recommendation: strong
KQ 6.2. Expiratory muscle strength training (EMST)
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 7. Compensatory swallowing technique
A. Evidence level: conditional
B. Grade of recommendation: very low
KQ 8. Neuromuscular electrical stimulation (NMES)
KQ 8.1. Swallowing therapy with or without NMES in non-progressive neurological disease
A. Evidence level: moderate
B. Grade of recommendation: strong
KQ 8.2. Swallowing therapy with or without NMES in head and neck cancer
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 8.3. Pharyngeal electrical stimulation (PES) in non-progressive neurological disease
A. Evidence level: low
B. Grade of recommendation: conditional against
KQ 9. Stimulation of the transient receptor potential (TRP) channel with drugs
A. Evidence level: moderate
B. Grade of recommendation: conditional
KQ 10. Biofeedback training
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 11. Specific treatment for cricopharyngeal (CP) dysfunction
KQ 11.1. CP botulinum toxin injection
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 11.2. CP myotomy
A. Evidence level: not applicable
B. Grade of recommendation: expert consensus
KQ 11.3. Balloon dilatation
A. Evidence level: moderate
B. Grade of recommendation: conditional
KQ 12. Swallowing education
A. Evidence level: very low
B. Grade of recommendation: conditional
KQ 13. Noninvasive brain stimulation
KQ 13.1. Transcranial direct current electrical stimulation (tDCS)
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 13.2. Repetitive transcranial magnetic stimulation (rTMS)
A. Evidence level: very low
B. Grade of recommendation: conditional
KQ 14. Tube feeding in patients with suspected long-term dysphagia
A. Evidence level: very low
B. Grade of recommendation: conditional
3) Nutrition for oropharyngeal dysphagiaKQ 15. Modifying food textures
A. Evidence level: very low
B. Grade of recommendation: conditional
KQ 16. Nutritional intervention
A. Evidence level: moderate
B. Grade of recommendation: strong
4) Complications and othersKQ 17. Incidence and mortality rates of aspiration pneumonia
A. Evidence level: high
B. Grade of recommendation: strong
KQ 18. The effect of oral care program
A. Evidence level: moderate
B. Grade of recommendation: strong
KQ 19. The effect of multidisciplinary team approach
A. Evidence level: low
B. Grade of recommendation: conditional
Dysphagia is a medical condition that increases the risk of various complications, such as dehydration, malnutrition, aspiration pneumonia, and airway obstruction, which can lead to serious disability or even death12-14. Various methods have been used to screen patients with dysphagia, and it is important to investigate whether early screening tools for dys-phagia are effective in improving prognosis and preventing complications that can occur due to dysphagia.
One RCT conducted by Schmidt Leuenberger et al.12 reported that the incidence of pneumonia decreased in patients who received a clinical assessment of dysphagia (early screening) after pulmonary resection. Ten retrospective studies, including patients with stroke, post extubation dysphagia in an intensive care unit (ICU), and traumatic cervical injuries, showed that respiratory complications were significantly reduced after the early screening of dysphagia12-21. Considering that the above studies showed consistent results, early screening is recommended in patients with suspected oropharyngeal dysphagia to reduce the occurrence of pneumonia. If patients with oro-pharyngeal dysphagia are screened early and are provided with appropriate treatment as early as possible, serious complications, such as pneumonia, can be prevented.
Early screening is strongly recommended in patients with suspected oropharyngeal dysphagia to reduce the occurrence of pneumonia with high levels of evidence.
If screening and appropriate treatments for dys-phagia are provided as early as possible, the occurrence of complications related to the disease can be reduced22. Various screening tests for dysphagia have been developed and used in clinical practice. Single screening tests, such as the 3-oz water swallow test or the volume-viscosity swallow test, are used, where food is swallowed directly to check the presence of aspiration by coughing, voice change, and change in oxygen saturation23. Standardized screening tests, such as the Burke dysphagia screening test (BDST), Gugging Swallowing Screening Test (GUSS), Standar-dized Swallowing Assessment (SSA), Toronto Bedside Swallowing Screening Test (TOR-BSST), and Clinical Functional Scale for Dysphagia, use a clinical scale by combining various clinical items24-26.
Shin et al.23 compared the screening abilities of the single screening test (3-oz water test) and standar-dized screening tools (GUSS, BDST, and SSA) based on the VFSS findings in patients with stroke. The results showed that there was no significant difference in the screening ability of GUSS compared to other screening tests. Lopes et al.27 also compared the water test and GUSS and reported that there were no differences in the occurrence of stroke-associated pneumonia, mo-rtality rate, ICU admission rate, and functional status between the two groups. Both studies reported that there was no difference in the accuracy of diagnosis or the occurrence of complications between standardized and single screening tests. However, a standardized screening test tool can evaluate a patient’s swallo-wing function without directly swallowing food. Therefore, for high-risk patients who cannot swallow their saliva properly, a standardized screening test seems safer than a single screening test that forces them to swallow water.
A standardized screening test may be considered to diagnose dysphagia in patients with suspected orop-haryngeal dysphagia (expert consensus).
Oropharyngeal dysphagia can be evaluated using various clinical assessment tools that can be performed at the bedside, as well as more comprehensive diagnostic tests, such as VFSS, can be applied. VFSS is considered a gold-standard evaluation tool for dysphagia, because it can visualize a series of swallo-wing processes occurring in the oral, pharyngeal, and esophageal phases28.
If VFSS is performed in patients with oropharyngeal dysphagia, the presence of dysphagia can be detected more accurately than during a clinical evaluation. Two SRs29,30 and four studies31-34 that compared the effectiveness of clinical evaluation and VFSS were identified. Both SRs that included patients with stroke showed that no statistically significant differences were found between clinical evaluation and VFSS in predicting the occurrence of aspiration pneumonia29,30. Other studies recommended that VFSS is cost- effective and superior when compared to a clinical bedside swelling evaluation31-34. Therefore, clinical evaluation can be useful as an early screening test, and VFSS can be additionally performed to accurately diagnose the presence of dysphagia.
VFSS is strongly recommended for diagnosis of dysphagia with moderate levels of evidence.
It is necessary to diagnose patients with oropha-ryngeal dysphagia accurately in order to prevent detrimental complications, such as aspiration pneu-monia, and to provide sufficient nutrition as early as possible. In addition, a diagnostic test for dysphagia is necessary to evaluate the recovery of swallowing function before and after treatment.
Diagnostic tests for dysphagia include bedside screening, VFSS, and FESS. VFSS is widely used as a standard diagnostic tool for oropharyngeal dysphagia, and FEES is applied to visualize the swallowing function; it can easily be performed repeatedly, even while lying down. Recently, FEES has been frequently performed to diagnose oropharyngeal dysphagia, and many studies on its usefulness have been reported.
One RCT conducted by Aviv35 compared the effec-tiveness of VFSS and FESS in 126 patients with dysphagia. The results showed that there were no statistically significant differences in determining the prevalence of aspiration pneumonia between patients who received FEES and VFSS. A study conducted by Wu et al.36 reported that FESS was more sensitive in detecting penetration, aspiration, pharyngeal retention, and cough reflex, while Fattori et al.37 recommended that FESS was useful in visualizing pharyngeal resi-due. FEES showed superior results in observing airway penetration and pharyngeal residue than VFSS38,39.
Similar levels of safety and efficacy have been observed between FEES and VFSS in patients with dysphagia. There is no radiation exposure, and it can be easily inspected even in medical institutions that do not have fluoroscopy equipment. The endoscopic swallo-wing test has a high diagnostic benefit since laryngeal movement can be detected during actual swallowing when dysphagia is suspected. In addition, it has the advantage of being performed repeatedly in various places, and there are no significant complications nor patient discomfort during the procedure. However, it is difficult to observe the whole swallowing process using FEES. The phases of swallowing cannot be assessed, especially the oral phase.
There is insufficient evidence to conclude whether FEES is more effective than VFSS. The two test methods can be performed complementary to each other.
Sensory stimulation therapy is believed to be a potential strategy for treating dysphagia as it activates the peripheral sensory nerves in the larynx and the pharynx to protect the airway from aspira-tion. It has been reported that the use of NMES can improve swallowing in patients with dysphagia by stimulating the afferent nerves and increasing the sensory input to the central nervous system40.
A RCT conducted by Maeda et al.41 showed that 20 patients with oropharyngeal dysphagia who received sensory stimulation showed improvement in oral nutritional intake and functional oral intake scale (FOIS). Zhang et al.42 also conducted a RCT and compared the effectiveness of the traditional swallowing therapy, sensory approach (NMES on the sensory input) combined with traditional swallowing therapy, and motor approach (NMES on the motor muscle) combined with traditional swallowing therapy. All the groups showed improvement in swallowing function and quality of life after 4 weeks of treatment, but the sensory approach combined with traditional swallowing therapy showed a statistically significant improvement compared to the other groups42. Another RCT performed by Rofes et al.43 showed that after 10 days of treatment with sensory or motor surface electrical stimulation, 20 patients with chronic post stroke dys-phagic (10 sensory vs. 10 motor) showed improve-ment in swallowing function after treatment compared to that before treatment. These studies suggest that oropharyngeal sensory stimulation therapy in patients with oropharyngeal dysphagia may contribute to an improvement in swallowing function and an increase in quality of life.
Oropharyngeal sensory stimulation therapy is reco-mmended in patients with oropharyngeal dysphagia to improve swallowing function and improve quality of life.
Tongue and pharyngeal muscle strengthening exer-cises are one of the treatment methods for dysphagia. Strengthening exercises are often applied for better lingual and pharyngeal strength and improvement in swallowing ability44. These exercises aimed to increase the diameter of the upper esophageal sphincter (UES) opening and decrease post deglutitive aspiration and dysphagic symptoms45.
Twelve RCTs investigated whether strengthening exercises for the tongue and laryngeal muscles were effective in improving the swallowing function and reducing the incidence of aspiration pneumonia compared to the control group. Three and eight RCTs on patients with brain lesions and head and neck cancer, respectively, were found. These studies applied rehabilitative techniques, such as head lift exercise, Shaker exercise, Mendelsohn maneuver, and muscle strengthening exercises of the tongue and larynx.
Regarding patients with stroke, in a RCT conducted by Kang and Kim1, patients with dysphagia showed a significant improvement in the neck strength and swallowing function when head lift exercises were performed for 30 minutes, 5 times a week for 6 weeks. RCTs conducted by McCullough et al.46 and McCullough and Kim47 also showed that the 2 weeks of the Mendelsohn method training improved hyoid anterior and superior movements and increased UES opening and swallow physiology in 18 patients with stroke and dysphagia. Regarding patients with oropharyngeal cancer, Kotz et al.48 investigated the effect of prophylactic swallowing exercises in 26 patients with head and neck cancer. This study showed that patients who performed swallowing exercises (five exercises, including effortful swallowing, super- supraglottic swallowing, tongue hold, tongue retraction, and Mendelsohn maneuver, 10 times per day, and three times a day) showed better swallowing outcomes than patients who did not perform the exercises at 3 and 6 months after the treatment48. A RCT con-ducted by Lazarus et al.44 also showed that tongue- strengthening exercises improved swallowing function in 12 patients with oropharyngeal cancer who under-went radiotherapy compared to 11 patients who were administered only conventional treatment. Notably, other studies also reported similar results.
In summary, tongue and pharyngeal muscle streng-thening exercises contribute to improving swallowing function and reducing aspiration pneumonia in patients with brain lesions and head and neck tumors. Since these exercises can be easily performed for inpatients and outpatients in rehabilitation clinics, they are recommended for the treatment of dysphagia.
Tongue and pharyngeal muscle strengthening exer-cises are recommended to improve swallowing function and reduce the incidence of pneumonia.
The EMST increases subglottic air pressure, while changes in motor unit recruitment and neuromo-dulation have been proposed as the mechanism of effect.
Four RCTs on EMST showed that it improved swa-llowing function in patients with dysphagia. Three RCTs on patients with stroke49-51 and one RCT on patients with multiple sclerosis52 used commercially available EMST 150 equipment (Aspire Products LLC., Cape Carteret, NC, USA) and compared the effect with the sham treatment. As for EMST, a protocol of five sets per day was applied for 5 days a week. One set included five vigorous exhalations at 70% of the maximum expiratory pressure. All of these studies showed that EMST was effective in improving swallo-wing function compared to the control group49-52, and the study conducted by Silverman et al.52 also reported that it improved swallowing-related quality of life. EMST can improve swallowing function as well as respiratory function in patients with non-progressive neurological disease, thereby contributing to improving swallowing-related quality of life, but it can be only applied to patients who can fully understand the training method. Clinicians should be aware of its side effects, as performing strong expiratory pressure can cause hypotension, hyperventilation, or dizziness.
EMSTs are suggested to improve swallowing func-tion and quality of life.
Compensatory maneuvers are one of the rehabili-tative strategies for dysphagia management. The com-pensatory swallowing maneuvers aim to keep patients safe when swallowing and promote temporary stability without permanently changing the swallowing mecha-nism. Compensatory swallowing maneuvers include chin tuck, chin down, head extension, head rotation, effortful swallow, Mendelsohn maneuver, tongue- hold maneuver, or Masako maneuver, supraglottic swallow, and super-supraglottic swallow. Compensatory swallowing maneuvers can induce immediate stability of the swallowing; however, as the same method must be applied every time swallowing occurs, patients may get tired easily due to the repeated application.
According to the observational study conducted by Solazzo et al.53, compensatory swallowing techniques, such as a chindown posture, head turned posture, and a hyperextended head posture, promoted safe swallowing in 66 (88.0%) of 75 patients with dysphagia. Furthermore, a study published by Ra et al.54 also showed the effect of chin tuck, and the study conducted by Miyamoto et al.55 reported that the chin-down maneuver was beneficial to swallowing function. The evidence for the effect of effortful swallowing seems to be weak at present, and no studies were found regarding the effect of Men-delsohn maneuver and tongue hold maneuver as compensatory swallowing techniques. Regarding supra-glottic and super-supraglottic swallowing, a study reported that super-supraglottic swallow changes the airway closure and hyoid-larynx movement56, while another study reported that supraglottic swallow does not change the propelling pressure of food lumps57. Further studies on their direct effect on swallowing function are needed in the future.
Compensatory swallowing maneuvers do not require a large burden of time and cost and can positively affect swallowing function and prevent complications. To date, there has been no RCT studying compensatory swallowing maneuvers; therefore, the level of evidence was considered very low.
The compensatory swallowing technique is suggested to improve the swallowing function.
Conventional swallowing therapy includes streng-thening exercises for muscles involved in swallowing, compensatory maneuvers, sensory and tactile stimu-lation, and biofeedback58. In 2001, U.S. Food and Drug Administration approved the use of NMES, such as VitalStimⓇ (Chattanooga Group, Hixson, TN, USA), for dysphagia treatment. This treatment method involves attaching electrodes to the skin and transmitting electrical signals to the muscles involved in swallowing to induce contraction.
Various studies evaluated the combined effect of surface NMES, including 10 RCTs42,59-67 and two non-RCTs68,69. In most studies, the combination of NMES and swallowing therapy significantly improved objective and subjective indicators of swallowing function. A RCT conducted by Lee et al.62 showed that when combined with NMES and conventional swallo-wing therapy, the FOIS was higher at 3 and 6 weeks after treatment compared to conventional swallowing therapy alone. A RCT conducted by Terré and Mearin66 reported that the combination of NMES and conventional swallowing therapy improved oral intake function and reduced aspiration in patients with dysphagia. A RCT conducted by Xia et al.67 also showed that the combination of NMES and conven-tional swallowing therapy was conducive to recovery from poststroke dysphagia. Nine out of ten studies showed similar results, reporting that the combina-tion of NMES and conventional swallowing therapy helped improve the swallowing questionnaire scores or swallowing test results more significantly than swallowing therapy alone. This treatment method is considered safe and effective. Therefore, NMES, in conjunction with swallowing therapy, is recommended for the treatment of dysphagia.
The combination of surface NMES and swallowing therapy is recommended for improving the swallowing function in patients with non-progressive neuropathic lesions.
Dysphagia after head and neck cancer surgery depends on the type and extent of the damage to the structures removed during surgery. It can also occur after radiation therapy, which induces progressive fibrosis of muscles or soft tissues that leads to progressive dysphagia70.
For the treatment of dysphagia after head and neck cancer surgery, strengthening exercises of remaining muscles, postural maneuvers, and biofeedback tech-niques have been used to replace the original functions of the resected structures and minimize the weakening of the muscles70. The surface NMES has also been applied as an alternative treatment to strengthen the muscles through direct muscle contra-ctions and prevent the atrophy of denervated muscles.
One RCT and two case-control studies investigated the effectiveness of the combination of NMES and conventional swallowing therapy. A RCT conducted by Ryu et al.71 showed that NMES combined with traditional swallowing training (14 patients) was superior to traditional swallowing training alone (12 patients) in patients with head and neck cancer. Two case-control studies showed that NMES induced significant scores in the FOIS assessment and the degree of movement in the speed of the hyoid bone72,73. The combination of NMES and swallowing therapy is beneficial for improving dysphagia in patients with head and neck cancer.
The combination of surface NMES and swallowing therapy is suggested for improving the swallowing function in patients with head and neck cancer.
PES, which provides electrical stimulation directly to the pharynx, induces activation of the pharyngeal motor cortex via the corticobulbar pathway74. PES aims for cortical plasticity by activating the cerebral motor cortex by transmitting repetitive electrical stimulation into the pharynx.
Five RCTs on the PES compared its effect with sham stimulation74-78. Four RCTs reported that PES did not significantly improve the swallowing function or prevent pneumonia74,75,77,78, while only Jayasekeran et al.76 reported that PES was safe, reduced aspiration, and improved feeding status. Therefore, evidence of the positive effect of PES on improving swallowing function and preventing pneumonia is lacking.
It is difficult to recommend the application of PES in patients with oropharyngeal dysphagia caused by non-progressive nerve lesions since the effects of improving the swallowing function and preventing pneumonia are not clear.
Although drug treatment for dysphagia is not currently widely applied in clinical practice, a number of drugs have been studied for their effect of improving swallowing response and preventing airway aspiration. TRP channel is a receptor that converts temperature stimuli into electrical signals and transmits them to the central nervous system. A number of substances, including a TRPV1 agonist (capsaisin) and a TRPM8 agonist (menthol), were used in several studies to induce swallowing responses in patients with dysphagia.
The effect of a capsaicin tablet was compared with a placebo tablet for 4 weeks before meals, and upper respiratory protective reflexes significantly improved in 64 older residents in a nursing home79. When TRPV1 agonist (capsaicin 1×10-5 M) was admini-stered for 10 days, the penetration–aspiration scale (PAS) score on the VFSS significantly decreased from 5.23±2.04 to 3±1.47 (P=0.002)80,81. The stimulation of TRPV1 improved swallowing safety and shortened the swallow response in older adult patients with oropha-ryngeal dysphagia. In two RTCs conducted by Cui et al.82 and Wang et al.83, capsaicin in conjunction with ice or thermal tactile stimulation was beneficial to the recovery of the swallowing function in patients with stroke and dysphagia. In addition to capsaicin, the effect of menthol (TRPM8 agonist) and piperine (TRPV1/ TRPA1 agonist) injection studies on the swallowing function have also been reported84,85. Most RCTs (11 out of 12) reported that TRP channel stimulation improved swallowing function in the short term, and four non-RCTs reported that TRP stimulation improved the swallow response and swallowing function.
Currently, little is known about pharmacological approaches for the treatment of oropharyngeal dys-phagia. Stimulation of the TRP channel via TRPV agonists (including capsaicin), administered through the oral cavity, oropharynx, or through stimulation of the ear canal, showed improvement in the swallowing function for a short period. However, its long-term use should be further investigated. The administration of a TRPV agonist, such as capsaicin, showed a short-term improvement in the swallowing effect, and it can be easily applied in Korea as capsaicin- rich red pepper is a very common food in Korea. The regular stimulation of the TRP channel seems to promote the recovery of the swallowing function in patients with dysphagia, but a clear standard for the dosage and the long-term use of drugs are needed in the future.
Pharmacological stimulation of the TRP channel is suggested for improving swallowing function.
Biofeedback is a technique that provides biological information to patients in real-time and facilitates normal movement patterns or induces sufficient muscle contractions during muscle-strengthening training86. Using biofeedback, the exercise performance is notified to the patients through audio-visual infor-mation to empower effective rehabilitation. Neuro-muscular biofeedback methods include electromyo-graphy (EMG) biofeedback and real-time ultrasound imaging biofeedback. EMG biofeedback measures myoelectric signals through surface electrodes attached to target muscles and converts them into visual and auditory signals to induce sufficient muscle contrac-tions87.
A RCT conducted by Shin et al.88 showed that suprahyoid muscle activity improved after 4 weeks of biofeedback training using surface EMG, compared to that before treatment in 45 patients with dysphagia after stroke. The effect of visuoauditory biofeedback is superior to visual biofeedback or self-exercise alone88. Another RCT conducted by Moon et al.89 showed that swallowing training (effortful swallow and Mendelsohn maneuver) with surface EMG bio-feedback training was more effective than swallowing training alone. Other case-control studies also showed that surface EMG biofeedback induced improvement in swallowing scores, such as functional dysphagia scale (FDS), PAS, videofluoroscopic dysphagia scale (VDS), or FOIS90-94.
In summary, swallowing treatment using biofeed-back is an effective adjunct to conventional swallowing therapy to improve swallowing function in patients with dysphagia. Although there is not much evidence, the benefit is clear compared to the harm. Since there are many hospitals that do not have biofeed-back equipment, if applicable, biofeedback in con-junction with conventional swallowing therapy is recommended.
Biofeedback training is suggested for improving swallowing function.
The CP muscle, which is located between the throat and esophagus, is the main component of UES. CP dysfunction or impaired relaxation due to various diseases, such as neurological disease, head and neck cancer, and Zenker’s diverticulum, causes symptoms of dysphagia, aspiration, and weight loss95,96. In patients with CP dysfunction, the cricopharyngeus fails to open during swallowing. Treatments for CP dysfunction include swallowing therapy and interven-tional techniques, such as botulinum toxin injection, dilatation, and myotomy. The effectiveness of CP botulinum toxin injection, which was first introduced by Blitzer in 1993, has been reported in previous studies97.
Several studies reported the effects of CP botu-linum injection, including two studies conducted by Alfonsi et al.98 and Kelly et al.99, which included 69 and 49 patients with CP dysfunction, respectively. Scores obtained from the eating assessment tool and Dysphagia Outcome and Severity Scale (DOSS) showed improvement after botulinum toxin injection. Botuli-num toxin injection was highly effective in the treatment of dysphagia. In the study published by Jeong et al.100 and Kim et al.101, the success rate of botulinum toxin injection was 63.9% and 78.6%, respectively. The complication rate was very only, with only one patient showing temporary unilateral vocal fold para-lysis101. The relative risk of the CP botulinum toxin injection seems to be low, and the benefits seem greater than the harms.
CP botulinum toxin injection is suggested to be performed while carefully considering the character-istics of dysphagia of each patient and the advantages and disadvantages of treatment.
CP myotomy is one of the surgical interventions applied for the treatment of CP dysfunction. CP myotomy is a treatment method that induces func-tional improvement by performing a complete incision of the CP muscle. Two approaches have been developed: the external transcervical approach, which has been performed for a long time, and the endoscopic CP myotomy, which has been performed relatively rece-ntly. In patients with defective CP relaxation, ade-quate oral and pharyngeal propulsion and laryngeal elevation may have a positive effect on improving the swallowing function. However, it has been reported that the effect of CP myotomy is inconclusive for patients who complain of subjective symptoms without clear abnormalities in anatomy and function102.
McKenna and Dedo103 conducted a study on the effects of CP myotomy through an external transcer-vical approach on 47 patients with CP dysfunction in 1992. After surgery, 45% and 30% of patients showed normal and improved swallowing function, respectively, in the clinical symptom evaluation. Brigand et al.104 showed that among 253 patients with severe dysfun-ctional pharyngo-esophageal junction who underwent CP myotomy through an external transcervical approach, 75% of patients reported improvement in oropharyngeal. In addition, postoperative compli-cations were observed in 15.8% of the patients, with the most common complications being mucosal break and pulmonary infection. Dauer et al.105 compared eight patients who underwent CP myotomy through an external transcervical approach and 14 patients who underwent endoscopic CP myotomy. The laser technique was as effective as the transce-rvical approach, with a low risk of major compli-cations. Takes et al.106 and Ho et al.107 showed that most patients reported improvement in dysphagia symptoms after endoscopic CP myotomy at 3 and 6 months, respectively.
Symptomatic improvement after CP myotomy seems to be approximately 60%–70% in patients with CP dysfunction. However, the clinician should consider that CP myotomy is invasive, irreversible, and permanent treatment with a possible risk of complications. Therefore, it seems difficult to judge whether the risks will be significantly higher than the relative risk for benefits, so an individual approach based on the patient’s condition seems necessary.
CP myotomy is suggested to be performed carefully in selective cases who receive refractory to conven-tional treatment while considering the potential side effects, advantages, and disadvantages of the treatment. An individual approach based on the patient’s condition seems necessary.
Balloon dilatation is a treatment method for CP dysfunction and is known as a relatively safe and efficacious in relieving UES dysfunction108. One of the dilatation techniques is the use of bougies, which reduces UES pressure and increases relaxation. Balloon dilatation for CP dysfunction restored UES resting pressure, improved UES relaxation, strengthened pharyngeal propulsion, and improved functional oral intake108.
A RCT conducted by Wei et al.109 showed that conventional swallowing therapy with modified balloon dilatation increased the excitability of affected projection and induced better improvement in FOIS compared to conventional swallowing alone at 3 weeks of treatment. When balloon dilatation was compared with laser myotomy, both improved UES opening for at least 6 months after the treatment110. Other studies also reported the effectiveness of balloon dilatation for treating CP dysfunction.
Balloon dilatation is a procedure that secures the visual field through an endoscope, and the risk of side effects is not high compared to other interven-tional procedures. It is considered valuable for treating CP dysfunction, but it is still invasive to a degree and may, therefore, require repeated procedures when CP dysfunction recurs.
Balloon dilatation is suggested to be performed carefully in selective cases that are refractory to conventional treatment, considering the advantages and disadvantages of the treatment. An individual approach based on the patient’s condition seems necessary.
For the treatment of dysphagia, various methods, including electrical stimulation therapy and swallowing exercises, are effectively used in clinical practice for the recovery of swallowing function. Recently, the need for a comprehensive swallowing education pro-gram that includes an understanding of dysphagia, self-swallowing exercise, and management has been emphasized.
Kang et al.111 applied a comprehensive bedside swallowing exercise education program for 2 months in addition to the conventional swallowing therapy for patients with stroke and dysphagia. A video recor-ding of the swallowing exercises, including oral, pha-ryngeal, laryngeal, and respiratory exercises, were played in the ward. These videos led to an improve-ment in swallowing function, emotional state, and quality of life in the patient group who received swallowing education. Cho et al.112 also showed that the supervised self-exercise swallowing training pro-gram for 4 weeks induced improvement in the VDS in patients with stroke. Mashhour et al.113 showed that swallowing exercise programs are also effective in patients with dysphagia due to the presence of head and neck tumors during radiation therapy. In addition, Chen et al.114 confirmed that the swallowing exercise education program was effective in improving emotional dysphagia quality of life 6 months after treatment of oral cavity cancer.
The swallowing education program is effective in improving swallowing function. There is no harm that can be caused by performing the program, and the motivation for participation in the program is necessary to maximize its effect. The swallowing edu-cation program can be used as a modality for reha-bilitation for patients with dysphagia. are mild and include local erythema, tingling, or itching. In con-clusion, tDCS applied to the contralateral or bilateral hemispheres is beneficial for the improvement of swallowing function when combined with swallowing therapy in patients with dysphagia.
The comprehensive swallowing education program, including self-exercise swallowing training, is suggested for improving swallowing function.
tDCS, one of the non-invasive brain stimulation treatment methods, aims to induce functional impro-vement through neuroplasticity by controlling the activity of neural networks in the cortical areas. Positive therapeutic effects of tDCS on the recovery of language, motor, and cognitive function in patients with stroke have been reported in previous studies115. Regarding the effect of tDCS on patients with dyspha-gia, Jefferson et al.116 first investigated the applica-bility of anodal tDCS stimulation to the pharyngeal motor cortex, and later, several studies reported the effects of tDCS stimulation on dysphagia after stroke.
In 2011, Kumar et al.117 conducted a RCT wherein anodal tDCS was applied to the pharyngeal motor cortex area contralateral to the lesion site in patients with dysphagia with subacute stroke. There was a significant difference after anodal tDCS (seven patients) compared with sham tDCS (seven patients) in DOSS scores. Other RCTs also reported that anodal tDCS induced better swallowing function when comparing the effect of anodal tDCS with sham tDCS118-122. Most recently, in a RCT conducted by Sawan et al.123, 20 patients who received anodal tDCS with conventional rehabilitation therapy for 5 days showed significant improvement in the swallowing function (VFSS and DOSS score) compared with 20 patients who received sham tDCS. Another recent RCT conducted by Wang et al.124 reported a significantly higher improvement in the swallowing function after treating with an anodal tDCS, conventional swallowing rehabilitation therapy and catheter balloon dilatation in patients with CP dysfunction after brain-stem stroke.
In tDCS, a weak direct current is used to stimulate the cerebral cortex125. tDCS has the advantage that it is easy to apply and safe with relatively few side effects. The side effects of tDCS are mild and include local erythema, tingling, or itching. In conclusion, tDCS applied to the contralateral or bilateral hemi- spheres is beneficial for the improvement of swallowing function when combined with swallowing therapy in patients with dysphagia.
tDCS is suggested for improving the swallowing function in patients with non-progressive brain lesions.
rTMS is one of the non-invasive brain stimulation methods that is widely used to induce changes in the activity and neuroplasticity of the brain. In stroke, interhemispheric imbalance is observed with decreased excitability of the ipsilesional hemisphere and increased excitability of the contralesional hemi-sphere. rTMS directly delivers cortical stimulation. Low-frequency (LF) rTMS decreases cortical excita-bility, while high-frequency (HF) rMTS increases it. Several studies have investigated the effects of rTMS treatment on dysphagia.
A RCT conducted by Khedr et al.126 showed that 3 Hz bilateral rTMS (10 minutes for 5 days) led to a significantly greater improvement in the swallowing function compared with sham rTMS in patients with stroke and dysphagia. Kim et al.127 conducted a RCT to compare HF (5 Hz) ipsilateral rTMS (20 minutes for 10 days), LF (1 Hz) ipsilateral rTMS (20 minutes for 10 days), and sham rTMS in patients with brain injury and dysphagia. The results showed that FDS and PAS scores significantly improved after LF rTMS. Lim et al.128 reported that both rTMS and NMES were effective for improving dysphagia and no significant differences were found between rTMS and NMES. Both HF and LF rTMS (3 Hz and 1 Hz, respectively) were reported to be effective for dysphagia in a RCT by Du et al.129. A study conducted by Park et al.130 showed that bilateral stimulation was superior to unilateral or sham stimulation in 35 patients with stroke and dysphagia. Similarly, Zhang et al.131 explained that bilateral rTMS combined with NMES produced higher cortical excitability and better swallowing function recovery compared to unilateral or sham rTMS.
Applying unilateral (LF and HF rTMS over the unaffected and affected hemispheres, respectively) or bilateral rTMS are recommended to improve the swallowing function and induce cortical neuroplasticity in patients with dysphagia. Since rTMS is a relatively new intervention in terms of applicability, additional costs are expected in addition to existing interventions, so cost-resource allocation needs to be considered. In addition, since rTMS treatment is not currently covered by medical insurance benefits, active attention by medical staff and institutional arrangements are needed.
rTMS is suggested for improving swallowing function in patients with non-progressive brain lesions.
Under nutrition is common in patients with dysphagia and nutritional status can deteriorate as the disease persists. There are two different methods for enteral tube feeding for patients with severe dysphagia. For nasogastric feeding, a tube is inserted through the nose to supply nutrition to the stomach. During a percutaneous endoscopic gastrostomy (PEG), a tube is inserted through a hole directly into the stomach to supply nutrients. Nutrition supply using a nasogastric tube is the most commonly used non- invasive treatment, but complications such as aspi-ration pneumonia, reflux esophagitis, and eso-phageal ulcers caused by mechanical stimulation may occur. Also, a nasogastric tube must be replaced once a month. If nasogastric tube feeding is expected to be required for a long period of time, gastrostomy is recommended. However, gastrostomy is an invasive procedure that can sometimes cause complications, such as inflammation and bleeding in the procedure site. It is still controversial whether feeding through a gastrostomy, rather than maintaining a nasogastric tube, affects the clinical course and mortality of patients.
Six RCTs investigated the effect of early or preve-ntive enteral tube feeding, including one study on patients with stroke and five studies on patients with head and neck cancer. The usefulness of early (within 72 hours after stroke) and prophylactic enteral tube feeding was investigated in patients with oropharyngeal dysphagia due to stroke and head and neck cancer. A RCT conducted by Dennis et al.132 reported that early enteral tube feeding (early defined as tube feeding within 7 days of admission) was associated with an absolute reduction in risk of death and a reduction in death or poor outcome in 741 patients with stroke. Among the five RCTs conducted on patients with head and neck cancer133-137, three studies assessing the survival rate did not show an association between the application of early or prophylactic enteral tube feeding and the improve-ment in survival rate134,136,137. However, Silander et al.134 and Salas et al.133 reported that prophylactic PEG was associated with significantly fewer malnou-rished patients over time and improved quality of life at 6 months. These studies showed that early enteral tube feeding showed overall improvement in the clinical course or survival rate in patients with oro-pharyngeal dysphagia.
Five RCTs studies investigated whether to supply nutrients through nasogastric and gastrostomy tubes when tube feeding is to be maintained for a long period of time138-142. In most studies, patients who underwent gastrostomy showed better results in nutritional status, including blood albumin and body weight. A higher frequency of gastrointestinal bleeding, pneumonia, or urinary tract infection was reported in the nasogastric tube group compared to the gastro-stomy group140. Gastrostomy feeding showed a positive effect on nutritional status and weight gain compared to nasogastric feeding. Gastrostomy tube feeding is likely to bring more benefits than nasogastric tube feeding when enteral tube feeding is required for a long period of time. Therefore, switching to a gastrostomy tube is recommended in patients who need to continue nasogastric tube feeding for a long time.
Since adequate nutrition and prevention of weight loss are very important issues in clinical practice, appropriate enteral tube feeding is recommended for patients who need sufficient nutrition. If it is likely that nasogastric tube feeding will continue for a long time, selecting an appropriate candidate who would benefit from gastrostomy tube feeding is recommended.
In patients who are likely to have oropharyngeal dysphagia for a long period of time, early enteral tube feeding is suggested for improving the clinical course, survival rate, and neurological prognosis.
In patients who are likely to have oropharyngeal dysphagia for a long period of time, a gastrostomy tube feeding is suggested for improving the clinical course, survival rate, neurological prognosis, and nutritional status.
In patients with oropharyngeal dysphagia, aspiration may occur when food is not controlled in the oral cavity during the oral phase or when an appropriate pharyngeal swallowing response is not initiated during the pharyngeal phase. If the muscle strength of the oral muscles is reduced or coordi-nated movements for swallowing are not appropria-tely performed, bolus formation or oral transit of food becomes difficult. In particular, in the case of oropharyngeal dysphagia caused by neurogenic problems, the risk of aspiration of low-viscosity food, such as water, is high due to lack of bolus control, reduced lingual propulsion, or delayed swallowing response in the pharyngeal phase143. Aspiration occurring during swallowing can cause poor nutritional status and impede sufficient fluid intake, increasing the risk of aspiration pneumonia144. Therefore, texture modification is one of the compensatory strategies for the treatment of dysphagia.
Five RCTs reported the beneficial effect of texture modification for preventing aspiration or aspiration pneumonia. A RCT conducted by Diniz et al.145 reported that the use of a spoonthick consistency reduced the risk of aspiration compared with the liquid consistency in 61 patients with stroke and dysphagia. Kyodo et al.146 suggested that pureed diets containing a gelling agent might reduce the risk of aspiration pneumonia possibly by decreasing pharyngeal residues in patients with moderate to severe dysphagia.
In contrast, Robbins et al.147 reported that texture modification did not affect the incidence of aspira-tion pneumonia. In 515 patients with dementia and Parkinson’s disease who presented aspiration on a liquid diet, the 3-month cumulative incidence of pneumonia did not show any difference when texture modification (nectar or honey) was applied compared to chindown posture. More patients who had thickened liquids showed dehydration, urinary tract infection, and fever compared to those who ingested liquid with the chin-down posture.
There were differences in disease conditions, texture modification settings, and outcome scales among the studies; however, the positive effects of texture modification on the clinical course for patients with dysphagia seem to be significant, especially for the reduction of the risk of aspiration. Texture modifi-cation is relatively easy to apply and does not require large costs; therefore, applying texture modification is recommended based on the severity of dysphagia.
Texture modification of food and fluids is suggested based on the severity of dysphagia to improve the clinical course (nutrition status or dehydration) of patients with oropharyngeal dysphagia.
Nutrition intervention is a process related to setting specific goals to solve the patient’s nutritional problems and establishing and executing plans for nutrition management. It aims to improve the quality of life by inducing changes in eating behavior and improving the patient’s nutritional status148. Patients with stroke often show malnutrition after hospitalization, which is presented by a reduction in muscle mass, low body mass, and low serum protein levels. Impaired oral function and dysphagia are associated with decreased oral intake, which increases the risk of malnutrition149. Nutrition intervention can reduce complication rates, admission rates, length of hospital stay, cost of care, and mortality150. Thus, a multidisciplinary team approach addressing nutritional problems can help patients with oropharyngeal dysphagia.
Eight studies149,151-157 assessing the effectiveness of nutrition intervention in patients with dysphagia, including three RCTs and five non-randomized intervention studies, were found. A RCT conducted by Germain et al.151 showed that older patients who received a dysphagia-specific nutrition care program showed significant differences in weight and calorie and protein intake compared to the control group. Reyes-Torres et al.152 also reported that patients with dysphagia showed increased body weight, consum-ption of energy and protein, and handgrip strength after a 12-week nutrition intervention (modified consistency diet with a nectar or pudding viscosity) compared to the control group. Another RCT con-ducted by Taylor and Barr153 showed that nutrition intervention (small and frequent meals) was associa-ted with increased fluid intake. Five more observa-tional studies showed some or no statistically signifi-cant differences in intake and nutritional status after a nutrition intervention; however, overall, nutrition intervention seems positively affect patients with dysphagia.
Nutrition intervention is suggested for improving intake or nutritional status in patients with orophary-ngeal dysphagia.
Pneumonia is the third leading cause of death in all age groups in Korea, and it is continuously increasing with aging158. Aspiration pneumonia is a bacterial pneumonia caused by aspiration of the contents of the oropharynx or upper gastrointestinal tract colonized by pathogenic bacteria and is more severe than non-aspiration pneumonia. It has been reported that aspiration pneumonia accounts for approximately 14.2% of community-acquired pneu-monia; it is more common in older adults, requires more frequent ICU treatment, and has a longer hospital stay compared to non-aspiration pneumo-nia159. A major risk factor for aspiration pneumonia is known as dysphagia. Dysphagia is frequently observed in vulnerable patient groups, such as older adults and patients with neurological diseases, and is associated with an increase in mortality rate, hospi-talization period, and medical costs159-163. Therefore, it is necessary to identify the relationship between dysphagia and aspiration pneumonia and diagnose and monitor high-risk groups to provide appropriate treatment quickly and accurately.
According to the study by Lo et al.164, which compared 6,979 newly diagnosed patients with dysphagia and 20,937 undiagnosed patients, the incidence of aspiration pneumonia (1.75% vs. 0.92%, P<0.0001) and mortality (23.83% vs. 13.39%, P< 0.001) was higher in the dysphagia group than in the control group. The incidence of 1-, 3-, and 5-year aspiration pneumonia and 1-, 3-, and 5-year mor-tality rates after stroke diagnosis was also higher in patients with dysphagia compared to the control group160. Another study also reported that among 9,930 adults aged 65 years or older who were admitted to 1,121 facilities, the presence and severity of dysphagia were related to the occurrence of aspiration pneumonia. Patients diagnosed with aspiration pneumonia had a statistically significant decline in swallowing function within 3 months compared to patients without a diagnosis (32.8% vs. 5.7%, P<0.001)165. In addition, other studies reported that the presence and severity of dysphagia were reported to be related to the occurrence of aspiration pneumonia166-168.
In summary, oropharyngeal dysphagia increases the risk of aspiration, and patients with oropha-ryngeal dysphagia have a higher incidence and mortality of aspiration pneumonia than those without dysphagia.
The incidence and mortality of aspiration pneu-monia are higher in patients with oropharyngeal dysphagia than in those without dysphagia. There-fore, patients with dysphagia should watch out for the occurrence of pneumonia.
Clean hygienic conditions in the oral cavity prevent dental caries and dryness and improve oral health and swallowing by improving oral sensation and salivation. Normal oral swallowing function can prevent swallowing problems at the pharynx stage by properly pulverizing and mixing food and saliva to form an appropriate mass that passes into the pharynx169,170.
A RCT conducted by Chen et al.171 showed that patients who received the oral care program showed significant improvement in the oral health assessment tool but not in FOIS compared with patients who had usual oral care. Chipps et al.172 also conducted a RCT and showed that bacteria colonization decreased after the oral care program. Only two studies were found on the effectiveness of the oral care program; however, overall, it seems that there are no potential risks or side effects in the process of the oral care program, and it is easy to perform. Applying the oral care program can reduce bacterial colonization in the oral cavity and improve oral health and swallowing function.
The oral health care program is recommended for improving oral health and food intake in patients with oropharyngeal dysphagia.
The multidisciplinary rehabilitation team is made up of health care professionals who work collabo-ratively with patients and caregivers to evaluate and manage dysphagia. In the multidisciplinary team, doctors, speech-language pathologists, nutritionists, and nurses are usually involved. Prosthodontists and dentists can sometimes also be involved in identifying structural problems related to swallowing, and social workers can be involved in discharge plans. The goal of the multidisciplinary team approach is to identify patients at risk for dysphagia, evaluate the severity of dysphagia, and provide appropriate treatment173-175.
A RCT conducted by Zheng et al.176 showed that swallowing function significantly improved in patients with acute stroke who received a multidisciplinary team approach compared to the controls who re-ceived the conventional treatment. In four obser-vational studies, patients who received care via the multidisciplinary team approach showed a signifi-cantly lower risk of dysphagia, pneumonia, and requirement for respiratory support, as well as greater patient satisfaction regarding swallowing function than patients who received conventional treatment149,177-179.
Although the level of evidence is low, the multi-disciplinary team approach should be performed because it can contribute to the improvement of swallowing function and reduce the occurrence of pneumonia. Overall, the multidisciplinary team approach seems to be effective in reducing the incidence of pneumonia during rehabilitation treat-ment of dysphagia.
A multidisciplinary team approach (doctors, nurses, therapists, etc.) is suggested for preventing compli-cations (such as mortality, pneumonia, and other respiratory infections) in patients with oropharyngeal dysphagia.
This CPG aimed to review the literature and provide evidence-based guidelines for the assessment and management of dysphagia. This guideline is intended to help medical staff and related subjects in charge of patients with oropharyngeal dysphagia to make safer and more effective decisions by presenting assessment and treatment guidelines based on scien-tific and objective evidence. Therefore, this guideline aims to effectively deliver the information necessary for decision-making and provide patients with dysphagia with appropriate education, evaluation, and treatment. This will enable patients to improve their symptoms of dysphagia and improve their quality of life. The ultimate goal is to reduce com-plications and mortality due to the presence of dysphagia.
First, the effectiveness of diagnostic testing for oropharyngeal dysphagia was assessed. Early screening was effective in patients with suspected oropharyngeal dysphagia to reduce the occurrence of pneumonia with a high level of evidence. The recommendation levels were strong, and we concluded that if patients with oropharyngeal dysphagia are screened early and are provided with appropriate treatment as early as possible, serious complications, such as pneumonia, can be prevented. Standardized screening tests, such as BDST, GUSS, SSA, TOR-BSST, or Clinical Func-tional Scale for Dysphagia, were effective in diagno-sing dysphagia, as well as single screening tests, such as the 3-oz water swallow test or the volume-viscosity swallow test. For high-risk patients who are unable to swallow their saliva properly, a standardized screening test was safer than a single screening test, which requires swallowing water. A standardized screening test tool can evaluate a patient’s swal-lowing function without directly swallowing food, and it was recommended to diagnose dysphagia in patients with suspected oropharyngeal dysphagia. To visualize a series of swallowing processes occurring in the oral, pharyngeal, and esophageal phases, and detect dysphagia, VFSS was strongly recommended for diagnosis of dysphagia with moderate levels of evidence. FEES can also be used to visualize the swallowing function, but FEES does not seem to be more effective than VFSS. Considering the benefits of the two diagnostic methods, we concluded that the two test methods complement each other and can be performed together.
There are various treatment methods for managing dysphagia. We investigated the efficacy of various rehabilitative strategies that are commonly used for the treatment of dysphagia. Oropharyngeal sensory stimulation therapy was effective in improving swal-lowing function and quality of life, as well as tongue and pharyngeal muscle strengthening exercises, which improved the swallowing function and reduced aspiration pneumonia in patients with brain lesions and head and neck tumors. EMSTs were also effective in improving the swallowing function and quality of life. Compensatory maneuvers, including chin tuck, chin down, and effortful swallow, were useful for improving the swallowing function and were recom-mended as effective rehabilitative techniques for dysphagia management. The combination of NMES and swallowing therapy was also recommended for improving the swallowing function in patients with non-progressive neuropathic lesions and head and neck cancer. The efficacy of PES for improving swallowing function and preventing pneumonia was unclear.
Treating dysphagia with drugs by stimulating the TRP channel, such as capsaicin, menthol, or piperine, was effective for improving the swallowing function, although it is well applied in clinical practice. Thus, future studies should investigate the effect of drug treatment. In addition, swallowing treatment using biofeedback as an adjunct to conventional swallowing therapy was effective in improving swallowing func-tion. CP botulinum toxin injection, CP myotomy, and balloon dilatation seem to be effective treatment options for patients with CP dysfunction but should be performed after considering the advantages and disadvantages of the treatments. The effect of non-invasive brain stimulation treatment methods, such as tDCS and rTMS, were also investigated, and both of them were effective in improving the swallowing function in patients with non-progressive brain lesions.
As for the nutrition issues, we concluded that early enteral tube feeding improved the clinical course, survival rate, and neurological prognosis for patients who are likely to have oropharyngeal dysphagia for a prolonged period. In addition, gastrostomy tube feeding should also be considered to improve the clinical course, survival rate, neurological prognosis, and nutritional status in patients who are likely to have oropharyngeal dysphagia for an extended period. In addition, texture modification of food and fluids based on the severity of dysphagia improved the clinical course of patients with oropharyngeal dysphagia, especially in reducing the risk of aspira-tion. Nutrition intervention, including addressing nutritional problems and establishing plans for nutrition management, was recommended because a literature search showed that ithelps improve intake or nutritional status in patients with oropharyngeal dysphagia.
Other issues associated with dysphagia have also been addressed in this CPG. The current evidence showed that the incidence and mortality of aspiration pneumonia were, in fact, higher in patients with oropharyngeal dysphagia than those without dyspha-gia. Providing the oral health care program improved oral health and food intake in patients with oro-pharyngeal dysphagia. Additionally, a multidiscipli-nary team approach, including doctors in various fields, nurses, and therapists, was effective in pre-venting complications (such as mortality, pneumonia, and other respiratory infections). Various methods for the treatment of dysphagia should be performed, considering various aspects in patients with oro-pharyngeal dysphagia.
This CPG has several limitations. First, the stati-stical significance was not evaluated, and meta- analysis was not performed. Second, although the level of evidence for each clinical question was established based on the results of studies abroad, the recommendations of this CPG were primarily based on the applicability of the resources and healthcare system in Korea.
In conclusion, this CPG is the first guideline that provides the levels of evidence of relevant literature and the consensus of multidisciplinary experts re-garding issues related to oropharyngeal dysphagia. Physicians, patients, caregivers, and other healthcare professionals are expected to widely read this CPG to improve their understanding and treatment of dysphagia.
This guideline was developed with financial support from the Korean Academy of Rehabilitation Medicine and the Korean Dysphagia Society. The development of this CPG was not influenced by the supporting academies and was not supported by other groups.
The members who were involved in this guideline had no other conflicts of interest (COI). The COI was required to determine whether or not these persons should be involved in the development of similar guidelines, employment, financial interests, and other potential interests. No potential conflicts of interest relevant to this article were reported.
J Korean Dysphagia Soc 2023; 13(2): 77-106
Published online July 30, 2023 https://doi.org/10.34160/jkds.23.010
Copyright © The Korean Dysphagia Society.
Seoyon Yang, M.D., Ph.D.1, Jin-Woo Park, M.D., Ph.D2, Kyunghoon Min, M.D., Ph.D3, Yoon Se Lee, M.D., Ph.D4, Young-Jin Song, O.T.5, Seong Hee Choi, Ph.D6, Doo Young Kim, M.D.7, Seung Hak Lee, M.D., Ph.D8, Hee Seung Yang, M.D., Ph.D9, Wonjae Cha, M.D., Ph.D10, Ji Won Kim, M.D., Ph.D11, Byung-Mo Oh, M.D., Ph.D12, Han Gil Seo, M.D., Ph.D12, Min-Wook Kim, M.D., Ph.D13, Hee-Soon Woo, O.T., Ph.D14, Sung-Jong Park, S.T.15, Sungju Jee, M.D.16, Ju Sun Oh, M.D.17, Ki Deok Park, M.D., Ph.D18, Young Ju Jin, M.D.19, Sungjun Han, M.D.20, DooHan Yoo, O.T., Ph.D21, Bo Hae Kim, M.D., Ph.D22, Hyun Haeng Lee, M.D., M.S.23, Yeo Hyung Kim, M.D., Ph.D24, Min-Gu Kang, M.D.25, Eun-Jae Chung, M.D., Ph.D26, Bo Ryun Kim, M.D., Ph.D27, Tae-Woo Kim, M.D.28,29, Eun Jae Ko, M.D., Ph.D8, Young Min Park, M.D., Ph.D30, Hanaro Park, M.D.31, Min-Su Kim, M.D., Ph.D32, Jungirl Seok, M.D.33, Sun Im, M.D., Ph.D34, Sung-Hwa Ko, M.D., Ph.D35, Seong Hoon Lim, M.D., Ph.D36, Kee Wook Jung, M.D., Ph.D37, Tae Hee Lee, M.D., Ph.D38, Bo Young Hong, M.D., Ph.D36, Woojeong Kim, M.S., R.D.39, Weon-Sun Shin, Ph.D40, Young Chan Lee, M.D.41, Sung Joon Park, M.D.42, Jeonghyun Lim, Ph.D, R.D.43, Youngkook Kim, M.D., Ph.D44, Jung Hwan Lee, M.D., Ph.D45, Kang-Min Ahn, D.D.S., M.S.D., Ph.D46, Jun-Young Paeng, D.D.S., Ph.D47, JeongYun Park, R.N., Ph.D48, Young Ae Song, M.S.N., R.N.49, Kyung Cheon Seo, M.D.50, Chang Hwan Ryu, M.D.51, Jae-Keun Cho, M.D., Ph.D52, Jee-Ho Lee, D.D.S.53, Kyoung Hyo Choi, M.D., Ph.D8
1Department of Rehabilitation Medicine, Ewha Womans University Seoul Hospital, Ewha Womans University College of Medicine, Seoul, 2Department of Physical Medicine and Rehabilitation, Dongguk University Ilsan Hospital, Goyang, 3Department of Rehabilitation Medicine, CHA Bundang Medical Center, CHA University School of Medicine, Seongnam, 4Department of Otorhinolaryngology-Head and Neck Surgery, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 5Department of Occupational Therapy, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 6Department Audiology and Speech-Language Pathology, Daegu Catholic University, Gyoungsan, 7Department of Rehabilitation Medicine, International St. Mary’s Hospital, Catholic Kwandong University College of Medicine, Incheon, 8Department of Rehabilitation Medicine, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 9Department of Physical Medicine and Rehabilitation, Veterans Health Service Medical Center, Seoul, 10Department of Otorhinolaryngology-Head and Neck Surgery, Seoul National University Bundang Hospital, Seoul National University College of Medicine, Seongnam, 11Department of Otolaryngology, Inha University College of Medicine, Incheon, 12Department of Rehabilitation Medicine, Seoul National University Hospital, Seoul National University College of Medicine, Seoul, 13Department of Rehabilitation Medicine, Incheon St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Incheon, 14Department of Occupational Therapy, School of Medicine, Wonkwang University, Iksan, 15Department of Speech Therapy, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 16Department of Rehabilitation Medicine, Chungnam National University Hospital, College of Medicine, Chungnam National University, Daejeon, 17Department of Rehabilitation Medicine, Seoul Medical Center, Seoul, 18Department of Rehabilitation Medicine, Gil Medical Center, Gachon University College of Medicine, Incheon, 19Department of Otorhinolaryngology-Head and Neck Surgery, Kangwon National University Hospital, Kangwon National University College of Medicine, Chuncheon, 20Department of Otolaryngology-Head and Neck Surgery, St. Vincent’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, 21Department of Occupational Therapy, Konyang University, Daejeon, 22Department of Otorhinolaryngology-Head and Neck Surgery, Dongguk University Ilsan Hospital, Goyang, 23Deptartment of Rehabilitation Medicine, Konkuk University Medical Center, Seoul, 24Department of Rehabilitation Medicine, College of Medicine, The Catholic University of Korea, Seoul, 25Department of Physical Medicine and Rehabilitation, Dong-A University College of Medicine, Busan, 26Department of Otorhinolaryngology-Head and Neck Surgery, Seoul National University Hospital, Seoul National University College of Medicine, Seoul, 27Department of Physical Medicine and Rehabilitation, Korea University Anam Hospital, Korea University College of Medicine, Seoul, 28Department of Rehabilitation Medicine, National Traffic Injury Rehabilitation Hospital, Yangpyeong, 29Department of Rehabilitation Medicine, Seoul National University College of Medicine, Seoul, 30Department of Otorhinolaryngology, Gangnam Severance Hospital, Yonsei University College of Medicine, Seoul, 31Department of Otorhinolaryngology-Head and Neck Surgery, Samsung Changwon Hospital, Sungkyunkwan University School of Medicine, Changwon, 32Department of Otorhinolaryngology-Head and Neck Surgery, CHA Bundang Medical Center, CHA University School of Medicine, Seongnam, 33Department of Otorhinolaryngology-Head and Neck Surgery, Seoul National University Hospital, Seoul, 34Department of Rehabilitation Medicine, Bucheon St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Bucheon, 35Department of Rehabilitation Medicine, Pusan National University & Pusan National University Yangsan Hospital, Yangsan, 36Department of Rehabilitation Medicine, St. Vincent’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, 37Department of Gastroenterology, Asan Medical Center, University of Ulsan College of Medicine, Seoul, 38Department of Gastroenterology, Konyang University College of Medicine, Daejeon, 39Deptartment of Nutrition & Food Control, Gangnam Severance Hospital, Seoul, 40Deptartment of Food & Nutrition, College of Human Ecology, Hanyang University, Seoul, 41Department of Otorhinolaryngology-Head and Neck Surgery, Kyung Hee University Hospital at Gangdong, Kyung Hee University School of Medicine, Seoul, 42Department of Otorhinolaryngology-Head and Neck Surgery, Chung-Ang University Gwangmyeong Hospital, Chung-Ang University College of Medicine, Gwangmyeong, 43Department of Food Service & Nutrition Care, Seoul National University Hospital, Seoul, 44Department of Rehabilitation Medicine, Yeouido St. Mary’s Hospital, College of Medicine, The Catholic University of Korea, Seoul, 45Namdarun Rehabilitation Clinic, Yongin, 46Department of Oral and Maxillofacial Surgery, University of Ulsan College of Medicine, Seoul, 47Department of Oral and Maxillofacial Surgery, Samsung Medical Center, Sungkyunkwan University School of Medicine, Seoul, 48Department of Clinical Nursing, University of Ulsan, Seoul, 49Department of Nursing, Seoul National University Bundang Hospital, Seongnam, 50Department of Physical Medicine and Rehabilitation, Korea University Anam Hospital, Seoul, 51Department of Otolaryngology-Head and Neck Surgery, Center for Thyroid Cancer, Research Institute and Hospital, National Cancer Center, Goyang, 52Department of Otorhinolaryngology-Head and Neck Surgery, Inje University Ilsan Paik Hospital, Inje University College of Medicine, Goyang, 53Department of Oral and Maxillofacial Surgery, Asan Medical Center, University of Ulsan College of Medicine, Seoul, Korea
Correspondence to:Kyoung Hyo Choi, Department of Rehabilitation Medicine, Asan Medical Center, University of Ulsan College of Medicine, 88 Olympic-ro 43-gil, Seoul 05505, Korea
Tel: +82-2-3010-3800, Fax: +82-2-3010-6964, E-mail: kyounghyochoi@gmail.com
This clinical practice guideline was developed jointly by the Korean Academy of Rehabilitation Medicine and the Korean Dysphagia Society and was published in Annals of Rehabilitation Medicine and the Journal of Korean Dysphagia Society simultaneously on July 30, 2023.
This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (https://creativecommons.org/licenses/by-nc/4.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Objective: Dysphagia is a common clinical condition characterized by difficulty in swallowing. It is sub-classified into oropharyngeal dysphagia, which refers to problems in the mouth and pharynx, and esophageal dysphagia, which refers to problems in the esophageal body and esophagogastric junction. Dysphagia can have a significant negative impact one’s physical health and quality of life as its severity increases. Therefore, proper assessment and management of dysphagia are critical for improving swallowing function and preventing complications. Thus a guideline was developed to provide evidence-based recommendations for assessment and management in patients with dysphagia.
Methods: Nineteen key questions on dysphagia were developed. These questions dealt with various aspects of problems related to dysphagia, including assessment, management, and complications. A literature search for relevant articles was conducted using Pubmed, Embase, the Cochrane Library, and one domestic database of KoreaMed, until April 2021. The level of evidence and recommendation grade were established according to the Grading of Recommendation Assessment, Development and Evaluation methodology.
Results: Early screening and assessment of videofluoroscopic swallowing were recommended for assessing the presence of dysphagia. Therapeutic methods, such as tongue and pharyngeal muscle strengthening exercises and neuromuscular electrical stimulation with swallowing therapy, were effective in improving swallowing function and quality of life in patients with dysphagia. Nutritional intervention and an oral care program were also recommended.
Conclusion: This guideline presents recommendations for the assessment and management of patients with oropharyngeal dysphagia, including rehabilitative strategies.
Keywords: Deglutition disorders, Rehabilitation, Diagnosis, Treatment, Therapeutics
Dysphagia is a common clinical condition charac-terized by difficulty in swallowing. It is sub-classified into oropharyngeal dysphagia, which refers to pro-blems in the mouth and pharynx, and esophageal dysphagia, which refers to problems in the esopha-geal body and esophagogastric junction1. Oropharyngeal dysphagia is characterized by difficulty in initiating a swallow or passing food through the mouth or throat2, whereas esophageal dysphagia accompanies structural or inflammatory abnormalities or motility disorders3.
Dysphagia is associated with an acquired health condition, such as stroke, Parkinson’s disease, or motor neuron disease, as well as developmental disabilities. The prevalence of dysphagia is estimated to be 8% of the world’s population, and its prevalence increases in the older adult population4. The prevalence of dysphagia in older people dwelling in communities is approximately 15% and approximately 30% in hospi-talized patients1. It occurs most commonly in old patients with neurological disorders and dementia, with a prevalence of 64% and 80%, respectively5.
Dysphagia can have a significant negative impact on one’s physical health and quality of life as its severity increases6. If dysphagia is not properly evaluated and timely treated, it may worsen the quality of life and cause serious complications, such as dehydration, malnutrition, and aspiration pneumonia. Importantly, oropharyngeal dysphagia should be identified promptly considering the risk of aspiration. Various interventions such modifying food textures, positioning modification, or rehabilitative and com-pensatory strategies are designed to improve swallowing efficiency and reduce the risk of complications in patients with dysphagia7.
The purpose of this clinical practice guideline (CPG) was to provide a guideline supported by scientific evidence for physicians and other healthcare profe-ssions who diagnose and treat patients with symptoms of dysphagia. This CPG is aimed to assist in de-cision-making for appropriate treatment options to improve the clinical outcome of patients with dysphagia and reduce extravagant costs to patients and the overall health care system.
Assessment and management of dysphagia are mainly addressed in this CPG. Patients with progressive neurological disease and under 18 years of age were excluded from the scope of this CPG. This guideline does not aim to limit physicians’ medical practices and is not used to evaluate the quality of their practices.
The development group involved a development committee and an advisory committee, including three methodology experts. The development committee members consisted of 45 physicians (25 physiatrists, 15 otorhinolaryngologists, 2 gastro-enterologists, and 3 dentists), 2 nursing staff, 3 nutritionists, 3 occu-pational therapists, and 2 language therapists.
For each key question (KQ), 55 development com-mittee members determined the level of evidence and recommendation level.
This CPG consists of four categories: (1) assessment, (2) treatment, (3) nutritional management, and (4) complications and others. KQ was determined based on the Population Intervention Comparator Outcome (PICO) framework. According to the PICO strategy, adult patients of the population group who have symptoms or diagnosis of oropharyngeal dysphagia were included in this guideline. The number of KQs was determined by the number of interventions. The majority of outcomes focused mainly on improvement of dysphagia. If necessary, KQs were further divided into sub-KQs. Finally, a total of 19 KQs were for-mulated for this guideline.
A literature search was conducted for relevant articles using PubMed, Embase, the Cochrane Library, and one domestic database of KoreaMed, until April 2021. After establishing a highly sensitive strategy in combination with the natural language, the MeSH term was also used for PubMed and Cochrane Library, and the Emtree term was used for Embase. (Supple-mentary Data 1)
The search results were collated in EndNote. For each KQ, two independent reviewers excluded articles that did not meet the inclusion criteria of this CPG after reading titles and abstracts. Furthermore, full- text assessments were followed to reject those that did not fulfill the inclusion criteria. Articles that included patients with progressive neurological diseases (e.g., Parkinson’s disease or dementia) and patients who were under 18 years of age were exclu-ded. We also included articles written in languages other than English or Korean, articles that exist only in abstract form, case reports, technical reports, and animal studies. Study screening and data extraction were independently performed by two reviewers. The reviewers attempted to resolve any disagreement by consensus. If necessary, the opinion of a third reviewer was put into consideration to resolve the disagreement.
Quality assessment was performed on selected articles. The bias assessment was conducted using Cochrane risk-of-bias 2.0 for randomized controlled trials (RCTs) and the risk-of- bias assessment tool for non-randomized studies for non-RCTs8,9. The metho-dological quality of the systematic reviews (SRs) was evaluated using AMSTAR 1.0—a measurement tool to assess the methodological quality of SRs10. (Supple-mentary Data 2) The level of evidence and recom-mendation grade were established according to the Grading of Recommendation Assessment, Development and Evaluation (GRADE) methodology11. The level of evidence was evaluated by assessing the degree of bias, consistency, directness, accuracy, and publi-cation bias in the RCTs, non-RCTs, and SRs. The level of evidence for each KQ was based on the GRADE methodology as “high,” “medium,” “low,” and “very low”.(Table 1) The level of recommendation was determined according to a modified GRADE metho-dology divided into four levels.(Table 2) Several factors were considered, including the level of evidence, balance of benefits and harms, values and prefere-nces, obstacles and facilitating factors, resource and cost, and clinical applicability. The KQs that could not be further developed due to poor existing research were represented as expert consensus.
Table 1 . Grading of Recommendations Assessment, Development and Evaluation quality level of evidence and meaning..
Quality level | Definition |
---|---|
High | We are confident that the estimate of the effect is close to the actual effect |
Moderate | The estimates of the effect appear to be close to the actual effect but may vary considerably |
Low | The confidence in the estimate of the effect is limited. The actual effect may differ significantly from the estimate of the effect |
Very low | There is little confidence in the estimate of the effect. The actual effect will differ significantly from the estimate of the effect |
Table 2 . Grading of recommendations..
Strength of recommendations | Definition |
---|---|
Strong recommendation | The intervention/diagnostic test can be strongly recommended in most clinical practice, considering greater benefit than harm, evidence level, value and preference, and resources |
Conditional recommendation | The intervention/diagnostic test can be conditionally recommended in clinical practice considering the balance of benefit and harm, evidence level, value and preference, and resources |
Against recommendation | The harm caused by the intervention/diagnostic test maybe greater than its benefits. Moreover, considering the evidence level, value and preference, and resources, the intervention should not be recommended |
Inconclusive | It is not possible to determine the strength and direction of recommendation because of a very low or insufficient evidence level, uncertain or variable balance of benefit and harm, value and preference, and resources |
Expert consensusa) | Although clinical evidence is insufficient, it is recommended to be used in accordance with clinical experience and expert consensus when considering the benefits and risks of the treatment, the level of evidence, values and preferences, and resources |
Each statement is shown as a combination of the strength of recommendations and level of evidence..
a)In the case of a consensus statement by an expert opinion, the recommendation grade and level of evidence are not indicated..
For each KQ, at least two members of the develop-ment group participated in formulating and reviewing the draft recommendations. The working members continued discussions to reach consensus, and revisions were made there after in accordance with the opinions of the advisory committee. The recommen-dations were also revised through a review process via e-mail and a wired meeting with experts in the relevant field, and a formal consensus was achieved. The level of evidence and recommendations for 19 KQs were evaluated, and the content of the reco-mmendations and the recommendation grade was adjusted through in-depth discussion. The degree of consent for each committee member was selected from one (non-acceptance) to nine (acceptance) on a nine-point scale. If the score was ≥7, consent was considered to be present. If at least 75% of the committee members agreed to the final version of the recommendations, it was deemed to have reached a consensus. Finally, the final version of the 19 recommendations was accepted. This guideline will be revised every 5 years, when there is solid evidence that it can affect the management and treatment of patients with oropharyngeal dysphagia.
KQ 1. Early screening
A. Evidence level: high
B. Grade of recommendation: strong
KQ 2. Standardized screening test
A. Evidence level: not applicable
B. Grade of recommendation: expert consensus
KQ 3. Videofluoroscopic swallowing study (VFSS) vs. clinical evaluation
A. Evidence level: moderate
B. Grade of recommendation: strong
KQ 4. VFSS vs. fiberoptic endoscopic examination of swallowing (FEES)
A. Evidence level: inconclusive
B. Grade of recommendation: inconclusive
2) Treatment for oropharyngeal dysphagiaKQ 5. Oropharyngeal sensory stimulation
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 6. Exercises
KQ 6.1. Tongue and pharyngeal muscle strengthening exercise
A. Evidence level: moderate
B. Grade of recommendation: strong
KQ 6.2. Expiratory muscle strength training (EMST)
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 7. Compensatory swallowing technique
A. Evidence level: conditional
B. Grade of recommendation: very low
KQ 8. Neuromuscular electrical stimulation (NMES)
KQ 8.1. Swallowing therapy with or without NMES in non-progressive neurological disease
A. Evidence level: moderate
B. Grade of recommendation: strong
KQ 8.2. Swallowing therapy with or without NMES in head and neck cancer
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 8.3. Pharyngeal electrical stimulation (PES) in non-progressive neurological disease
A. Evidence level: low
B. Grade of recommendation: conditional against
KQ 9. Stimulation of the transient receptor potential (TRP) channel with drugs
A. Evidence level: moderate
B. Grade of recommendation: conditional
KQ 10. Biofeedback training
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 11. Specific treatment for cricopharyngeal (CP) dysfunction
KQ 11.1. CP botulinum toxin injection
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 11.2. CP myotomy
A. Evidence level: not applicable
B. Grade of recommendation: expert consensus
KQ 11.3. Balloon dilatation
A. Evidence level: moderate
B. Grade of recommendation: conditional
KQ 12. Swallowing education
A. Evidence level: very low
B. Grade of recommendation: conditional
KQ 13. Noninvasive brain stimulation
KQ 13.1. Transcranial direct current electrical stimulation (tDCS)
A. Evidence level: low
B. Grade of recommendation: conditional
KQ 13.2. Repetitive transcranial magnetic stimulation (rTMS)
A. Evidence level: very low
B. Grade of recommendation: conditional
KQ 14. Tube feeding in patients with suspected long-term dysphagia
A. Evidence level: very low
B. Grade of recommendation: conditional
3) Nutrition for oropharyngeal dysphagiaKQ 15. Modifying food textures
A. Evidence level: very low
B. Grade of recommendation: conditional
KQ 16. Nutritional intervention
A. Evidence level: moderate
B. Grade of recommendation: strong
4) Complications and othersKQ 17. Incidence and mortality rates of aspiration pneumonia
A. Evidence level: high
B. Grade of recommendation: strong
KQ 18. The effect of oral care program
A. Evidence level: moderate
B. Grade of recommendation: strong
KQ 19. The effect of multidisciplinary team approach
A. Evidence level: low
B. Grade of recommendation: conditional
Dysphagia is a medical condition that increases the risk of various complications, such as dehydration, malnutrition, aspiration pneumonia, and airway obstruction, which can lead to serious disability or even death12-14. Various methods have been used to screen patients with dysphagia, and it is important to investigate whether early screening tools for dys-phagia are effective in improving prognosis and preventing complications that can occur due to dysphagia.
One RCT conducted by Schmidt Leuenberger et al.12 reported that the incidence of pneumonia decreased in patients who received a clinical assessment of dysphagia (early screening) after pulmonary resection. Ten retrospective studies, including patients with stroke, post extubation dysphagia in an intensive care unit (ICU), and traumatic cervical injuries, showed that respiratory complications were significantly reduced after the early screening of dysphagia12-21. Considering that the above studies showed consistent results, early screening is recommended in patients with suspected oropharyngeal dysphagia to reduce the occurrence of pneumonia. If patients with oro-pharyngeal dysphagia are screened early and are provided with appropriate treatment as early as possible, serious complications, such as pneumonia, can be prevented.
Early screening is strongly recommended in patients with suspected oropharyngeal dysphagia to reduce the occurrence of pneumonia with high levels of evidence.
If screening and appropriate treatments for dys-phagia are provided as early as possible, the occurrence of complications related to the disease can be reduced22. Various screening tests for dysphagia have been developed and used in clinical practice. Single screening tests, such as the 3-oz water swallow test or the volume-viscosity swallow test, are used, where food is swallowed directly to check the presence of aspiration by coughing, voice change, and change in oxygen saturation23. Standardized screening tests, such as the Burke dysphagia screening test (BDST), Gugging Swallowing Screening Test (GUSS), Standar-dized Swallowing Assessment (SSA), Toronto Bedside Swallowing Screening Test (TOR-BSST), and Clinical Functional Scale for Dysphagia, use a clinical scale by combining various clinical items24-26.
Shin et al.23 compared the screening abilities of the single screening test (3-oz water test) and standar-dized screening tools (GUSS, BDST, and SSA) based on the VFSS findings in patients with stroke. The results showed that there was no significant difference in the screening ability of GUSS compared to other screening tests. Lopes et al.27 also compared the water test and GUSS and reported that there were no differences in the occurrence of stroke-associated pneumonia, mo-rtality rate, ICU admission rate, and functional status between the two groups. Both studies reported that there was no difference in the accuracy of diagnosis or the occurrence of complications between standardized and single screening tests. However, a standardized screening test tool can evaluate a patient’s swallo-wing function without directly swallowing food. Therefore, for high-risk patients who cannot swallow their saliva properly, a standardized screening test seems safer than a single screening test that forces them to swallow water.
A standardized screening test may be considered to diagnose dysphagia in patients with suspected orop-haryngeal dysphagia (expert consensus).
Oropharyngeal dysphagia can be evaluated using various clinical assessment tools that can be performed at the bedside, as well as more comprehensive diagnostic tests, such as VFSS, can be applied. VFSS is considered a gold-standard evaluation tool for dysphagia, because it can visualize a series of swallo-wing processes occurring in the oral, pharyngeal, and esophageal phases28.
If VFSS is performed in patients with oropharyngeal dysphagia, the presence of dysphagia can be detected more accurately than during a clinical evaluation. Two SRs29,30 and four studies31-34 that compared the effectiveness of clinical evaluation and VFSS were identified. Both SRs that included patients with stroke showed that no statistically significant differences were found between clinical evaluation and VFSS in predicting the occurrence of aspiration pneumonia29,30. Other studies recommended that VFSS is cost- effective and superior when compared to a clinical bedside swelling evaluation31-34. Therefore, clinical evaluation can be useful as an early screening test, and VFSS can be additionally performed to accurately diagnose the presence of dysphagia.
VFSS is strongly recommended for diagnosis of dysphagia with moderate levels of evidence.
It is necessary to diagnose patients with oropha-ryngeal dysphagia accurately in order to prevent detrimental complications, such as aspiration pneu-monia, and to provide sufficient nutrition as early as possible. In addition, a diagnostic test for dysphagia is necessary to evaluate the recovery of swallowing function before and after treatment.
Diagnostic tests for dysphagia include bedside screening, VFSS, and FESS. VFSS is widely used as a standard diagnostic tool for oropharyngeal dysphagia, and FEES is applied to visualize the swallowing function; it can easily be performed repeatedly, even while lying down. Recently, FEES has been frequently performed to diagnose oropharyngeal dysphagia, and many studies on its usefulness have been reported.
One RCT conducted by Aviv35 compared the effec-tiveness of VFSS and FESS in 126 patients with dysphagia. The results showed that there were no statistically significant differences in determining the prevalence of aspiration pneumonia between patients who received FEES and VFSS. A study conducted by Wu et al.36 reported that FESS was more sensitive in detecting penetration, aspiration, pharyngeal retention, and cough reflex, while Fattori et al.37 recommended that FESS was useful in visualizing pharyngeal resi-due. FEES showed superior results in observing airway penetration and pharyngeal residue than VFSS38,39.
Similar levels of safety and efficacy have been observed between FEES and VFSS in patients with dysphagia. There is no radiation exposure, and it can be easily inspected even in medical institutions that do not have fluoroscopy equipment. The endoscopic swallo-wing test has a high diagnostic benefit since laryngeal movement can be detected during actual swallowing when dysphagia is suspected. In addition, it has the advantage of being performed repeatedly in various places, and there are no significant complications nor patient discomfort during the procedure. However, it is difficult to observe the whole swallowing process using FEES. The phases of swallowing cannot be assessed, especially the oral phase.
There is insufficient evidence to conclude whether FEES is more effective than VFSS. The two test methods can be performed complementary to each other.
Sensory stimulation therapy is believed to be a potential strategy for treating dysphagia as it activates the peripheral sensory nerves in the larynx and the pharynx to protect the airway from aspira-tion. It has been reported that the use of NMES can improve swallowing in patients with dysphagia by stimulating the afferent nerves and increasing the sensory input to the central nervous system40.
A RCT conducted by Maeda et al.41 showed that 20 patients with oropharyngeal dysphagia who received sensory stimulation showed improvement in oral nutritional intake and functional oral intake scale (FOIS). Zhang et al.42 also conducted a RCT and compared the effectiveness of the traditional swallowing therapy, sensory approach (NMES on the sensory input) combined with traditional swallowing therapy, and motor approach (NMES on the motor muscle) combined with traditional swallowing therapy. All the groups showed improvement in swallowing function and quality of life after 4 weeks of treatment, but the sensory approach combined with traditional swallowing therapy showed a statistically significant improvement compared to the other groups42. Another RCT performed by Rofes et al.43 showed that after 10 days of treatment with sensory or motor surface electrical stimulation, 20 patients with chronic post stroke dys-phagic (10 sensory vs. 10 motor) showed improve-ment in swallowing function after treatment compared to that before treatment. These studies suggest that oropharyngeal sensory stimulation therapy in patients with oropharyngeal dysphagia may contribute to an improvement in swallowing function and an increase in quality of life.
Oropharyngeal sensory stimulation therapy is reco-mmended in patients with oropharyngeal dysphagia to improve swallowing function and improve quality of life.
Tongue and pharyngeal muscle strengthening exer-cises are one of the treatment methods for dysphagia. Strengthening exercises are often applied for better lingual and pharyngeal strength and improvement in swallowing ability44. These exercises aimed to increase the diameter of the upper esophageal sphincter (UES) opening and decrease post deglutitive aspiration and dysphagic symptoms45.
Twelve RCTs investigated whether strengthening exercises for the tongue and laryngeal muscles were effective in improving the swallowing function and reducing the incidence of aspiration pneumonia compared to the control group. Three and eight RCTs on patients with brain lesions and head and neck cancer, respectively, were found. These studies applied rehabilitative techniques, such as head lift exercise, Shaker exercise, Mendelsohn maneuver, and muscle strengthening exercises of the tongue and larynx.
Regarding patients with stroke, in a RCT conducted by Kang and Kim1, patients with dysphagia showed a significant improvement in the neck strength and swallowing function when head lift exercises were performed for 30 minutes, 5 times a week for 6 weeks. RCTs conducted by McCullough et al.46 and McCullough and Kim47 also showed that the 2 weeks of the Mendelsohn method training improved hyoid anterior and superior movements and increased UES opening and swallow physiology in 18 patients with stroke and dysphagia. Regarding patients with oropharyngeal cancer, Kotz et al.48 investigated the effect of prophylactic swallowing exercises in 26 patients with head and neck cancer. This study showed that patients who performed swallowing exercises (five exercises, including effortful swallowing, super- supraglottic swallowing, tongue hold, tongue retraction, and Mendelsohn maneuver, 10 times per day, and three times a day) showed better swallowing outcomes than patients who did not perform the exercises at 3 and 6 months after the treatment48. A RCT con-ducted by Lazarus et al.44 also showed that tongue- strengthening exercises improved swallowing function in 12 patients with oropharyngeal cancer who under-went radiotherapy compared to 11 patients who were administered only conventional treatment. Notably, other studies also reported similar results.
In summary, tongue and pharyngeal muscle streng-thening exercises contribute to improving swallowing function and reducing aspiration pneumonia in patients with brain lesions and head and neck tumors. Since these exercises can be easily performed for inpatients and outpatients in rehabilitation clinics, they are recommended for the treatment of dysphagia.
Tongue and pharyngeal muscle strengthening exer-cises are recommended to improve swallowing function and reduce the incidence of pneumonia.
The EMST increases subglottic air pressure, while changes in motor unit recruitment and neuromo-dulation have been proposed as the mechanism of effect.
Four RCTs on EMST showed that it improved swa-llowing function in patients with dysphagia. Three RCTs on patients with stroke49-51 and one RCT on patients with multiple sclerosis52 used commercially available EMST 150 equipment (Aspire Products LLC., Cape Carteret, NC, USA) and compared the effect with the sham treatment. As for EMST, a protocol of five sets per day was applied for 5 days a week. One set included five vigorous exhalations at 70% of the maximum expiratory pressure. All of these studies showed that EMST was effective in improving swallo-wing function compared to the control group49-52, and the study conducted by Silverman et al.52 also reported that it improved swallowing-related quality of life. EMST can improve swallowing function as well as respiratory function in patients with non-progressive neurological disease, thereby contributing to improving swallowing-related quality of life, but it can be only applied to patients who can fully understand the training method. Clinicians should be aware of its side effects, as performing strong expiratory pressure can cause hypotension, hyperventilation, or dizziness.
EMSTs are suggested to improve swallowing func-tion and quality of life.
Compensatory maneuvers are one of the rehabili-tative strategies for dysphagia management. The com-pensatory swallowing maneuvers aim to keep patients safe when swallowing and promote temporary stability without permanently changing the swallowing mecha-nism. Compensatory swallowing maneuvers include chin tuck, chin down, head extension, head rotation, effortful swallow, Mendelsohn maneuver, tongue- hold maneuver, or Masako maneuver, supraglottic swallow, and super-supraglottic swallow. Compensatory swallowing maneuvers can induce immediate stability of the swallowing; however, as the same method must be applied every time swallowing occurs, patients may get tired easily due to the repeated application.
According to the observational study conducted by Solazzo et al.53, compensatory swallowing techniques, such as a chindown posture, head turned posture, and a hyperextended head posture, promoted safe swallowing in 66 (88.0%) of 75 patients with dysphagia. Furthermore, a study published by Ra et al.54 also showed the effect of chin tuck, and the study conducted by Miyamoto et al.55 reported that the chin-down maneuver was beneficial to swallowing function. The evidence for the effect of effortful swallowing seems to be weak at present, and no studies were found regarding the effect of Men-delsohn maneuver and tongue hold maneuver as compensatory swallowing techniques. Regarding supra-glottic and super-supraglottic swallowing, a study reported that super-supraglottic swallow changes the airway closure and hyoid-larynx movement56, while another study reported that supraglottic swallow does not change the propelling pressure of food lumps57. Further studies on their direct effect on swallowing function are needed in the future.
Compensatory swallowing maneuvers do not require a large burden of time and cost and can positively affect swallowing function and prevent complications. To date, there has been no RCT studying compensatory swallowing maneuvers; therefore, the level of evidence was considered very low.
The compensatory swallowing technique is suggested to improve the swallowing function.
Conventional swallowing therapy includes streng-thening exercises for muscles involved in swallowing, compensatory maneuvers, sensory and tactile stimu-lation, and biofeedback58. In 2001, U.S. Food and Drug Administration approved the use of NMES, such as VitalStimⓇ (Chattanooga Group, Hixson, TN, USA), for dysphagia treatment. This treatment method involves attaching electrodes to the skin and transmitting electrical signals to the muscles involved in swallowing to induce contraction.
Various studies evaluated the combined effect of surface NMES, including 10 RCTs42,59-67 and two non-RCTs68,69. In most studies, the combination of NMES and swallowing therapy significantly improved objective and subjective indicators of swallowing function. A RCT conducted by Lee et al.62 showed that when combined with NMES and conventional swallo-wing therapy, the FOIS was higher at 3 and 6 weeks after treatment compared to conventional swallowing therapy alone. A RCT conducted by Terré and Mearin66 reported that the combination of NMES and conventional swallowing therapy improved oral intake function and reduced aspiration in patients with dysphagia. A RCT conducted by Xia et al.67 also showed that the combination of NMES and conven-tional swallowing therapy was conducive to recovery from poststroke dysphagia. Nine out of ten studies showed similar results, reporting that the combina-tion of NMES and conventional swallowing therapy helped improve the swallowing questionnaire scores or swallowing test results more significantly than swallowing therapy alone. This treatment method is considered safe and effective. Therefore, NMES, in conjunction with swallowing therapy, is recommended for the treatment of dysphagia.
The combination of surface NMES and swallowing therapy is recommended for improving the swallowing function in patients with non-progressive neuropathic lesions.
Dysphagia after head and neck cancer surgery depends on the type and extent of the damage to the structures removed during surgery. It can also occur after radiation therapy, which induces progressive fibrosis of muscles or soft tissues that leads to progressive dysphagia70.
For the treatment of dysphagia after head and neck cancer surgery, strengthening exercises of remaining muscles, postural maneuvers, and biofeedback tech-niques have been used to replace the original functions of the resected structures and minimize the weakening of the muscles70. The surface NMES has also been applied as an alternative treatment to strengthen the muscles through direct muscle contra-ctions and prevent the atrophy of denervated muscles.
One RCT and two case-control studies investigated the effectiveness of the combination of NMES and conventional swallowing therapy. A RCT conducted by Ryu et al.71 showed that NMES combined with traditional swallowing training (14 patients) was superior to traditional swallowing training alone (12 patients) in patients with head and neck cancer. Two case-control studies showed that NMES induced significant scores in the FOIS assessment and the degree of movement in the speed of the hyoid bone72,73. The combination of NMES and swallowing therapy is beneficial for improving dysphagia in patients with head and neck cancer.
The combination of surface NMES and swallowing therapy is suggested for improving the swallowing function in patients with head and neck cancer.
PES, which provides electrical stimulation directly to the pharynx, induces activation of the pharyngeal motor cortex via the corticobulbar pathway74. PES aims for cortical plasticity by activating the cerebral motor cortex by transmitting repetitive electrical stimulation into the pharynx.
Five RCTs on the PES compared its effect with sham stimulation74-78. Four RCTs reported that PES did not significantly improve the swallowing function or prevent pneumonia74,75,77,78, while only Jayasekeran et al.76 reported that PES was safe, reduced aspiration, and improved feeding status. Therefore, evidence of the positive effect of PES on improving swallowing function and preventing pneumonia is lacking.
It is difficult to recommend the application of PES in patients with oropharyngeal dysphagia caused by non-progressive nerve lesions since the effects of improving the swallowing function and preventing pneumonia are not clear.
Although drug treatment for dysphagia is not currently widely applied in clinical practice, a number of drugs have been studied for their effect of improving swallowing response and preventing airway aspiration. TRP channel is a receptor that converts temperature stimuli into electrical signals and transmits them to the central nervous system. A number of substances, including a TRPV1 agonist (capsaisin) and a TRPM8 agonist (menthol), were used in several studies to induce swallowing responses in patients with dysphagia.
The effect of a capsaicin tablet was compared with a placebo tablet for 4 weeks before meals, and upper respiratory protective reflexes significantly improved in 64 older residents in a nursing home79. When TRPV1 agonist (capsaicin 1×10-5 M) was admini-stered for 10 days, the penetration–aspiration scale (PAS) score on the VFSS significantly decreased from 5.23±2.04 to 3±1.47 (P=0.002)80,81. The stimulation of TRPV1 improved swallowing safety and shortened the swallow response in older adult patients with oropha-ryngeal dysphagia. In two RTCs conducted by Cui et al.82 and Wang et al.83, capsaicin in conjunction with ice or thermal tactile stimulation was beneficial to the recovery of the swallowing function in patients with stroke and dysphagia. In addition to capsaicin, the effect of menthol (TRPM8 agonist) and piperine (TRPV1/ TRPA1 agonist) injection studies on the swallowing function have also been reported84,85. Most RCTs (11 out of 12) reported that TRP channel stimulation improved swallowing function in the short term, and four non-RCTs reported that TRP stimulation improved the swallow response and swallowing function.
Currently, little is known about pharmacological approaches for the treatment of oropharyngeal dys-phagia. Stimulation of the TRP channel via TRPV agonists (including capsaicin), administered through the oral cavity, oropharynx, or through stimulation of the ear canal, showed improvement in the swallowing function for a short period. However, its long-term use should be further investigated. The administration of a TRPV agonist, such as capsaicin, showed a short-term improvement in the swallowing effect, and it can be easily applied in Korea as capsaicin- rich red pepper is a very common food in Korea. The regular stimulation of the TRP channel seems to promote the recovery of the swallowing function in patients with dysphagia, but a clear standard for the dosage and the long-term use of drugs are needed in the future.
Pharmacological stimulation of the TRP channel is suggested for improving swallowing function.
Biofeedback is a technique that provides biological information to patients in real-time and facilitates normal movement patterns or induces sufficient muscle contractions during muscle-strengthening training86. Using biofeedback, the exercise performance is notified to the patients through audio-visual infor-mation to empower effective rehabilitation. Neuro-muscular biofeedback methods include electromyo-graphy (EMG) biofeedback and real-time ultrasound imaging biofeedback. EMG biofeedback measures myoelectric signals through surface electrodes attached to target muscles and converts them into visual and auditory signals to induce sufficient muscle contrac-tions87.
A RCT conducted by Shin et al.88 showed that suprahyoid muscle activity improved after 4 weeks of biofeedback training using surface EMG, compared to that before treatment in 45 patients with dysphagia after stroke. The effect of visuoauditory biofeedback is superior to visual biofeedback or self-exercise alone88. Another RCT conducted by Moon et al.89 showed that swallowing training (effortful swallow and Mendelsohn maneuver) with surface EMG bio-feedback training was more effective than swallowing training alone. Other case-control studies also showed that surface EMG biofeedback induced improvement in swallowing scores, such as functional dysphagia scale (FDS), PAS, videofluoroscopic dysphagia scale (VDS), or FOIS90-94.
In summary, swallowing treatment using biofeed-back is an effective adjunct to conventional swallowing therapy to improve swallowing function in patients with dysphagia. Although there is not much evidence, the benefit is clear compared to the harm. Since there are many hospitals that do not have biofeed-back equipment, if applicable, biofeedback in con-junction with conventional swallowing therapy is recommended.
Biofeedback training is suggested for improving swallowing function.
The CP muscle, which is located between the throat and esophagus, is the main component of UES. CP dysfunction or impaired relaxation due to various diseases, such as neurological disease, head and neck cancer, and Zenker’s diverticulum, causes symptoms of dysphagia, aspiration, and weight loss95,96. In patients with CP dysfunction, the cricopharyngeus fails to open during swallowing. Treatments for CP dysfunction include swallowing therapy and interven-tional techniques, such as botulinum toxin injection, dilatation, and myotomy. The effectiveness of CP botulinum toxin injection, which was first introduced by Blitzer in 1993, has been reported in previous studies97.
Several studies reported the effects of CP botu-linum injection, including two studies conducted by Alfonsi et al.98 and Kelly et al.99, which included 69 and 49 patients with CP dysfunction, respectively. Scores obtained from the eating assessment tool and Dysphagia Outcome and Severity Scale (DOSS) showed improvement after botulinum toxin injection. Botuli-num toxin injection was highly effective in the treatment of dysphagia. In the study published by Jeong et al.100 and Kim et al.101, the success rate of botulinum toxin injection was 63.9% and 78.6%, respectively. The complication rate was very only, with only one patient showing temporary unilateral vocal fold para-lysis101. The relative risk of the CP botulinum toxin injection seems to be low, and the benefits seem greater than the harms.
CP botulinum toxin injection is suggested to be performed while carefully considering the character-istics of dysphagia of each patient and the advantages and disadvantages of treatment.
CP myotomy is one of the surgical interventions applied for the treatment of CP dysfunction. CP myotomy is a treatment method that induces func-tional improvement by performing a complete incision of the CP muscle. Two approaches have been developed: the external transcervical approach, which has been performed for a long time, and the endoscopic CP myotomy, which has been performed relatively rece-ntly. In patients with defective CP relaxation, ade-quate oral and pharyngeal propulsion and laryngeal elevation may have a positive effect on improving the swallowing function. However, it has been reported that the effect of CP myotomy is inconclusive for patients who complain of subjective symptoms without clear abnormalities in anatomy and function102.
McKenna and Dedo103 conducted a study on the effects of CP myotomy through an external transcer-vical approach on 47 patients with CP dysfunction in 1992. After surgery, 45% and 30% of patients showed normal and improved swallowing function, respectively, in the clinical symptom evaluation. Brigand et al.104 showed that among 253 patients with severe dysfun-ctional pharyngo-esophageal junction who underwent CP myotomy through an external transcervical approach, 75% of patients reported improvement in oropharyngeal. In addition, postoperative compli-cations were observed in 15.8% of the patients, with the most common complications being mucosal break and pulmonary infection. Dauer et al.105 compared eight patients who underwent CP myotomy through an external transcervical approach and 14 patients who underwent endoscopic CP myotomy. The laser technique was as effective as the transce-rvical approach, with a low risk of major compli-cations. Takes et al.106 and Ho et al.107 showed that most patients reported improvement in dysphagia symptoms after endoscopic CP myotomy at 3 and 6 months, respectively.
Symptomatic improvement after CP myotomy seems to be approximately 60%–70% in patients with CP dysfunction. However, the clinician should consider that CP myotomy is invasive, irreversible, and permanent treatment with a possible risk of complications. Therefore, it seems difficult to judge whether the risks will be significantly higher than the relative risk for benefits, so an individual approach based on the patient’s condition seems necessary.
CP myotomy is suggested to be performed carefully in selective cases who receive refractory to conven-tional treatment while considering the potential side effects, advantages, and disadvantages of the treatment. An individual approach based on the patient’s condition seems necessary.
Balloon dilatation is a treatment method for CP dysfunction and is known as a relatively safe and efficacious in relieving UES dysfunction108. One of the dilatation techniques is the use of bougies, which reduces UES pressure and increases relaxation. Balloon dilatation for CP dysfunction restored UES resting pressure, improved UES relaxation, strengthened pharyngeal propulsion, and improved functional oral intake108.
A RCT conducted by Wei et al.109 showed that conventional swallowing therapy with modified balloon dilatation increased the excitability of affected projection and induced better improvement in FOIS compared to conventional swallowing alone at 3 weeks of treatment. When balloon dilatation was compared with laser myotomy, both improved UES opening for at least 6 months after the treatment110. Other studies also reported the effectiveness of balloon dilatation for treating CP dysfunction.
Balloon dilatation is a procedure that secures the visual field through an endoscope, and the risk of side effects is not high compared to other interven-tional procedures. It is considered valuable for treating CP dysfunction, but it is still invasive to a degree and may, therefore, require repeated procedures when CP dysfunction recurs.
Balloon dilatation is suggested to be performed carefully in selective cases that are refractory to conventional treatment, considering the advantages and disadvantages of the treatment. An individual approach based on the patient’s condition seems necessary.
For the treatment of dysphagia, various methods, including electrical stimulation therapy and swallowing exercises, are effectively used in clinical practice for the recovery of swallowing function. Recently, the need for a comprehensive swallowing education pro-gram that includes an understanding of dysphagia, self-swallowing exercise, and management has been emphasized.
Kang et al.111 applied a comprehensive bedside swallowing exercise education program for 2 months in addition to the conventional swallowing therapy for patients with stroke and dysphagia. A video recor-ding of the swallowing exercises, including oral, pha-ryngeal, laryngeal, and respiratory exercises, were played in the ward. These videos led to an improve-ment in swallowing function, emotional state, and quality of life in the patient group who received swallowing education. Cho et al.112 also showed that the supervised self-exercise swallowing training pro-gram for 4 weeks induced improvement in the VDS in patients with stroke. Mashhour et al.113 showed that swallowing exercise programs are also effective in patients with dysphagia due to the presence of head and neck tumors during radiation therapy. In addition, Chen et al.114 confirmed that the swallowing exercise education program was effective in improving emotional dysphagia quality of life 6 months after treatment of oral cavity cancer.
The swallowing education program is effective in improving swallowing function. There is no harm that can be caused by performing the program, and the motivation for participation in the program is necessary to maximize its effect. The swallowing edu-cation program can be used as a modality for reha-bilitation for patients with dysphagia. are mild and include local erythema, tingling, or itching. In con-clusion, tDCS applied to the contralateral or bilateral hemispheres is beneficial for the improvement of swallowing function when combined with swallowing therapy in patients with dysphagia.
The comprehensive swallowing education program, including self-exercise swallowing training, is suggested for improving swallowing function.
tDCS, one of the non-invasive brain stimulation treatment methods, aims to induce functional impro-vement through neuroplasticity by controlling the activity of neural networks in the cortical areas. Positive therapeutic effects of tDCS on the recovery of language, motor, and cognitive function in patients with stroke have been reported in previous studies115. Regarding the effect of tDCS on patients with dyspha-gia, Jefferson et al.116 first investigated the applica-bility of anodal tDCS stimulation to the pharyngeal motor cortex, and later, several studies reported the effects of tDCS stimulation on dysphagia after stroke.
In 2011, Kumar et al.117 conducted a RCT wherein anodal tDCS was applied to the pharyngeal motor cortex area contralateral to the lesion site in patients with dysphagia with subacute stroke. There was a significant difference after anodal tDCS (seven patients) compared with sham tDCS (seven patients) in DOSS scores. Other RCTs also reported that anodal tDCS induced better swallowing function when comparing the effect of anodal tDCS with sham tDCS118-122. Most recently, in a RCT conducted by Sawan et al.123, 20 patients who received anodal tDCS with conventional rehabilitation therapy for 5 days showed significant improvement in the swallowing function (VFSS and DOSS score) compared with 20 patients who received sham tDCS. Another recent RCT conducted by Wang et al.124 reported a significantly higher improvement in the swallowing function after treating with an anodal tDCS, conventional swallowing rehabilitation therapy and catheter balloon dilatation in patients with CP dysfunction after brain-stem stroke.
In tDCS, a weak direct current is used to stimulate the cerebral cortex125. tDCS has the advantage that it is easy to apply and safe with relatively few side effects. The side effects of tDCS are mild and include local erythema, tingling, or itching. In conclusion, tDCS applied to the contralateral or bilateral hemi- spheres is beneficial for the improvement of swallowing function when combined with swallowing therapy in patients with dysphagia.
tDCS is suggested for improving the swallowing function in patients with non-progressive brain lesions.
rTMS is one of the non-invasive brain stimulation methods that is widely used to induce changes in the activity and neuroplasticity of the brain. In stroke, interhemispheric imbalance is observed with decreased excitability of the ipsilesional hemisphere and increased excitability of the contralesional hemi-sphere. rTMS directly delivers cortical stimulation. Low-frequency (LF) rTMS decreases cortical excita-bility, while high-frequency (HF) rMTS increases it. Several studies have investigated the effects of rTMS treatment on dysphagia.
A RCT conducted by Khedr et al.126 showed that 3 Hz bilateral rTMS (10 minutes for 5 days) led to a significantly greater improvement in the swallowing function compared with sham rTMS in patients with stroke and dysphagia. Kim et al.127 conducted a RCT to compare HF (5 Hz) ipsilateral rTMS (20 minutes for 10 days), LF (1 Hz) ipsilateral rTMS (20 minutes for 10 days), and sham rTMS in patients with brain injury and dysphagia. The results showed that FDS and PAS scores significantly improved after LF rTMS. Lim et al.128 reported that both rTMS and NMES were effective for improving dysphagia and no significant differences were found between rTMS and NMES. Both HF and LF rTMS (3 Hz and 1 Hz, respectively) were reported to be effective for dysphagia in a RCT by Du et al.129. A study conducted by Park et al.130 showed that bilateral stimulation was superior to unilateral or sham stimulation in 35 patients with stroke and dysphagia. Similarly, Zhang et al.131 explained that bilateral rTMS combined with NMES produced higher cortical excitability and better swallowing function recovery compared to unilateral or sham rTMS.
Applying unilateral (LF and HF rTMS over the unaffected and affected hemispheres, respectively) or bilateral rTMS are recommended to improve the swallowing function and induce cortical neuroplasticity in patients with dysphagia. Since rTMS is a relatively new intervention in terms of applicability, additional costs are expected in addition to existing interventions, so cost-resource allocation needs to be considered. In addition, since rTMS treatment is not currently covered by medical insurance benefits, active attention by medical staff and institutional arrangements are needed.
rTMS is suggested for improving swallowing function in patients with non-progressive brain lesions.
Under nutrition is common in patients with dysphagia and nutritional status can deteriorate as the disease persists. There are two different methods for enteral tube feeding for patients with severe dysphagia. For nasogastric feeding, a tube is inserted through the nose to supply nutrition to the stomach. During a percutaneous endoscopic gastrostomy (PEG), a tube is inserted through a hole directly into the stomach to supply nutrients. Nutrition supply using a nasogastric tube is the most commonly used non- invasive treatment, but complications such as aspi-ration pneumonia, reflux esophagitis, and eso-phageal ulcers caused by mechanical stimulation may occur. Also, a nasogastric tube must be replaced once a month. If nasogastric tube feeding is expected to be required for a long period of time, gastrostomy is recommended. However, gastrostomy is an invasive procedure that can sometimes cause complications, such as inflammation and bleeding in the procedure site. It is still controversial whether feeding through a gastrostomy, rather than maintaining a nasogastric tube, affects the clinical course and mortality of patients.
Six RCTs investigated the effect of early or preve-ntive enteral tube feeding, including one study on patients with stroke and five studies on patients with head and neck cancer. The usefulness of early (within 72 hours after stroke) and prophylactic enteral tube feeding was investigated in patients with oropharyngeal dysphagia due to stroke and head and neck cancer. A RCT conducted by Dennis et al.132 reported that early enteral tube feeding (early defined as tube feeding within 7 days of admission) was associated with an absolute reduction in risk of death and a reduction in death or poor outcome in 741 patients with stroke. Among the five RCTs conducted on patients with head and neck cancer133-137, three studies assessing the survival rate did not show an association between the application of early or prophylactic enteral tube feeding and the improve-ment in survival rate134,136,137. However, Silander et al.134 and Salas et al.133 reported that prophylactic PEG was associated with significantly fewer malnou-rished patients over time and improved quality of life at 6 months. These studies showed that early enteral tube feeding showed overall improvement in the clinical course or survival rate in patients with oro-pharyngeal dysphagia.
Five RCTs studies investigated whether to supply nutrients through nasogastric and gastrostomy tubes when tube feeding is to be maintained for a long period of time138-142. In most studies, patients who underwent gastrostomy showed better results in nutritional status, including blood albumin and body weight. A higher frequency of gastrointestinal bleeding, pneumonia, or urinary tract infection was reported in the nasogastric tube group compared to the gastro-stomy group140. Gastrostomy feeding showed a positive effect on nutritional status and weight gain compared to nasogastric feeding. Gastrostomy tube feeding is likely to bring more benefits than nasogastric tube feeding when enteral tube feeding is required for a long period of time. Therefore, switching to a gastrostomy tube is recommended in patients who need to continue nasogastric tube feeding for a long time.
Since adequate nutrition and prevention of weight loss are very important issues in clinical practice, appropriate enteral tube feeding is recommended for patients who need sufficient nutrition. If it is likely that nasogastric tube feeding will continue for a long time, selecting an appropriate candidate who would benefit from gastrostomy tube feeding is recommended.
In patients who are likely to have oropharyngeal dysphagia for a long period of time, early enteral tube feeding is suggested for improving the clinical course, survival rate, and neurological prognosis.
In patients who are likely to have oropharyngeal dysphagia for a long period of time, a gastrostomy tube feeding is suggested for improving the clinical course, survival rate, neurological prognosis, and nutritional status.
In patients with oropharyngeal dysphagia, aspiration may occur when food is not controlled in the oral cavity during the oral phase or when an appropriate pharyngeal swallowing response is not initiated during the pharyngeal phase. If the muscle strength of the oral muscles is reduced or coordi-nated movements for swallowing are not appropria-tely performed, bolus formation or oral transit of food becomes difficult. In particular, in the case of oropharyngeal dysphagia caused by neurogenic problems, the risk of aspiration of low-viscosity food, such as water, is high due to lack of bolus control, reduced lingual propulsion, or delayed swallowing response in the pharyngeal phase143. Aspiration occurring during swallowing can cause poor nutritional status and impede sufficient fluid intake, increasing the risk of aspiration pneumonia144. Therefore, texture modification is one of the compensatory strategies for the treatment of dysphagia.
Five RCTs reported the beneficial effect of texture modification for preventing aspiration or aspiration pneumonia. A RCT conducted by Diniz et al.145 reported that the use of a spoonthick consistency reduced the risk of aspiration compared with the liquid consistency in 61 patients with stroke and dysphagia. Kyodo et al.146 suggested that pureed diets containing a gelling agent might reduce the risk of aspiration pneumonia possibly by decreasing pharyngeal residues in patients with moderate to severe dysphagia.
In contrast, Robbins et al.147 reported that texture modification did not affect the incidence of aspira-tion pneumonia. In 515 patients with dementia and Parkinson’s disease who presented aspiration on a liquid diet, the 3-month cumulative incidence of pneumonia did not show any difference when texture modification (nectar or honey) was applied compared to chindown posture. More patients who had thickened liquids showed dehydration, urinary tract infection, and fever compared to those who ingested liquid with the chin-down posture.
There were differences in disease conditions, texture modification settings, and outcome scales among the studies; however, the positive effects of texture modification on the clinical course for patients with dysphagia seem to be significant, especially for the reduction of the risk of aspiration. Texture modifi-cation is relatively easy to apply and does not require large costs; therefore, applying texture modification is recommended based on the severity of dysphagia.
Texture modification of food and fluids is suggested based on the severity of dysphagia to improve the clinical course (nutrition status or dehydration) of patients with oropharyngeal dysphagia.
Nutrition intervention is a process related to setting specific goals to solve the patient’s nutritional problems and establishing and executing plans for nutrition management. It aims to improve the quality of life by inducing changes in eating behavior and improving the patient’s nutritional status148. Patients with stroke often show malnutrition after hospitalization, which is presented by a reduction in muscle mass, low body mass, and low serum protein levels. Impaired oral function and dysphagia are associated with decreased oral intake, which increases the risk of malnutrition149. Nutrition intervention can reduce complication rates, admission rates, length of hospital stay, cost of care, and mortality150. Thus, a multidisciplinary team approach addressing nutritional problems can help patients with oropharyngeal dysphagia.
Eight studies149,151-157 assessing the effectiveness of nutrition intervention in patients with dysphagia, including three RCTs and five non-randomized intervention studies, were found. A RCT conducted by Germain et al.151 showed that older patients who received a dysphagia-specific nutrition care program showed significant differences in weight and calorie and protein intake compared to the control group. Reyes-Torres et al.152 also reported that patients with dysphagia showed increased body weight, consum-ption of energy and protein, and handgrip strength after a 12-week nutrition intervention (modified consistency diet with a nectar or pudding viscosity) compared to the control group. Another RCT con-ducted by Taylor and Barr153 showed that nutrition intervention (small and frequent meals) was associa-ted with increased fluid intake. Five more observa-tional studies showed some or no statistically signifi-cant differences in intake and nutritional status after a nutrition intervention; however, overall, nutrition intervention seems positively affect patients with dysphagia.
Nutrition intervention is suggested for improving intake or nutritional status in patients with orophary-ngeal dysphagia.
Pneumonia is the third leading cause of death in all age groups in Korea, and it is continuously increasing with aging158. Aspiration pneumonia is a bacterial pneumonia caused by aspiration of the contents of the oropharynx or upper gastrointestinal tract colonized by pathogenic bacteria and is more severe than non-aspiration pneumonia. It has been reported that aspiration pneumonia accounts for approximately 14.2% of community-acquired pneu-monia; it is more common in older adults, requires more frequent ICU treatment, and has a longer hospital stay compared to non-aspiration pneumo-nia159. A major risk factor for aspiration pneumonia is known as dysphagia. Dysphagia is frequently observed in vulnerable patient groups, such as older adults and patients with neurological diseases, and is associated with an increase in mortality rate, hospi-talization period, and medical costs159-163. Therefore, it is necessary to identify the relationship between dysphagia and aspiration pneumonia and diagnose and monitor high-risk groups to provide appropriate treatment quickly and accurately.
According to the study by Lo et al.164, which compared 6,979 newly diagnosed patients with dysphagia and 20,937 undiagnosed patients, the incidence of aspiration pneumonia (1.75% vs. 0.92%, P<0.0001) and mortality (23.83% vs. 13.39%, P< 0.001) was higher in the dysphagia group than in the control group. The incidence of 1-, 3-, and 5-year aspiration pneumonia and 1-, 3-, and 5-year mor-tality rates after stroke diagnosis was also higher in patients with dysphagia compared to the control group160. Another study also reported that among 9,930 adults aged 65 years or older who were admitted to 1,121 facilities, the presence and severity of dysphagia were related to the occurrence of aspiration pneumonia. Patients diagnosed with aspiration pneumonia had a statistically significant decline in swallowing function within 3 months compared to patients without a diagnosis (32.8% vs. 5.7%, P<0.001)165. In addition, other studies reported that the presence and severity of dysphagia were reported to be related to the occurrence of aspiration pneumonia166-168.
In summary, oropharyngeal dysphagia increases the risk of aspiration, and patients with oropha-ryngeal dysphagia have a higher incidence and mortality of aspiration pneumonia than those without dysphagia.
The incidence and mortality of aspiration pneu-monia are higher in patients with oropharyngeal dysphagia than in those without dysphagia. There-fore, patients with dysphagia should watch out for the occurrence of pneumonia.
Clean hygienic conditions in the oral cavity prevent dental caries and dryness and improve oral health and swallowing by improving oral sensation and salivation. Normal oral swallowing function can prevent swallowing problems at the pharynx stage by properly pulverizing and mixing food and saliva to form an appropriate mass that passes into the pharynx169,170.
A RCT conducted by Chen et al.171 showed that patients who received the oral care program showed significant improvement in the oral health assessment tool but not in FOIS compared with patients who had usual oral care. Chipps et al.172 also conducted a RCT and showed that bacteria colonization decreased after the oral care program. Only two studies were found on the effectiveness of the oral care program; however, overall, it seems that there are no potential risks or side effects in the process of the oral care program, and it is easy to perform. Applying the oral care program can reduce bacterial colonization in the oral cavity and improve oral health and swallowing function.
The oral health care program is recommended for improving oral health and food intake in patients with oropharyngeal dysphagia.
The multidisciplinary rehabilitation team is made up of health care professionals who work collabo-ratively with patients and caregivers to evaluate and manage dysphagia. In the multidisciplinary team, doctors, speech-language pathologists, nutritionists, and nurses are usually involved. Prosthodontists and dentists can sometimes also be involved in identifying structural problems related to swallowing, and social workers can be involved in discharge plans. The goal of the multidisciplinary team approach is to identify patients at risk for dysphagia, evaluate the severity of dysphagia, and provide appropriate treatment173-175.
A RCT conducted by Zheng et al.176 showed that swallowing function significantly improved in patients with acute stroke who received a multidisciplinary team approach compared to the controls who re-ceived the conventional treatment. In four obser-vational studies, patients who received care via the multidisciplinary team approach showed a signifi-cantly lower risk of dysphagia, pneumonia, and requirement for respiratory support, as well as greater patient satisfaction regarding swallowing function than patients who received conventional treatment149,177-179.
Although the level of evidence is low, the multi-disciplinary team approach should be performed because it can contribute to the improvement of swallowing function and reduce the occurrence of pneumonia. Overall, the multidisciplinary team approach seems to be effective in reducing the incidence of pneumonia during rehabilitation treat-ment of dysphagia.
A multidisciplinary team approach (doctors, nurses, therapists, etc.) is suggested for preventing compli-cations (such as mortality, pneumonia, and other respiratory infections) in patients with oropharyngeal dysphagia.
This CPG aimed to review the literature and provide evidence-based guidelines for the assessment and management of dysphagia. This guideline is intended to help medical staff and related subjects in charge of patients with oropharyngeal dysphagia to make safer and more effective decisions by presenting assessment and treatment guidelines based on scien-tific and objective evidence. Therefore, this guideline aims to effectively deliver the information necessary for decision-making and provide patients with dysphagia with appropriate education, evaluation, and treatment. This will enable patients to improve their symptoms of dysphagia and improve their quality of life. The ultimate goal is to reduce com-plications and mortality due to the presence of dysphagia.
First, the effectiveness of diagnostic testing for oropharyngeal dysphagia was assessed. Early screening was effective in patients with suspected oropharyngeal dysphagia to reduce the occurrence of pneumonia with a high level of evidence. The recommendation levels were strong, and we concluded that if patients with oropharyngeal dysphagia are screened early and are provided with appropriate treatment as early as possible, serious complications, such as pneumonia, can be prevented. Standardized screening tests, such as BDST, GUSS, SSA, TOR-BSST, or Clinical Func-tional Scale for Dysphagia, were effective in diagno-sing dysphagia, as well as single screening tests, such as the 3-oz water swallow test or the volume-viscosity swallow test. For high-risk patients who are unable to swallow their saliva properly, a standardized screening test was safer than a single screening test, which requires swallowing water. A standardized screening test tool can evaluate a patient’s swal-lowing function without directly swallowing food, and it was recommended to diagnose dysphagia in patients with suspected oropharyngeal dysphagia. To visualize a series of swallowing processes occurring in the oral, pharyngeal, and esophageal phases, and detect dysphagia, VFSS was strongly recommended for diagnosis of dysphagia with moderate levels of evidence. FEES can also be used to visualize the swallowing function, but FEES does not seem to be more effective than VFSS. Considering the benefits of the two diagnostic methods, we concluded that the two test methods complement each other and can be performed together.
There are various treatment methods for managing dysphagia. We investigated the efficacy of various rehabilitative strategies that are commonly used for the treatment of dysphagia. Oropharyngeal sensory stimulation therapy was effective in improving swal-lowing function and quality of life, as well as tongue and pharyngeal muscle strengthening exercises, which improved the swallowing function and reduced aspiration pneumonia in patients with brain lesions and head and neck tumors. EMSTs were also effective in improving the swallowing function and quality of life. Compensatory maneuvers, including chin tuck, chin down, and effortful swallow, were useful for improving the swallowing function and were recom-mended as effective rehabilitative techniques for dysphagia management. The combination of NMES and swallowing therapy was also recommended for improving the swallowing function in patients with non-progressive neuropathic lesions and head and neck cancer. The efficacy of PES for improving swallowing function and preventing pneumonia was unclear.
Treating dysphagia with drugs by stimulating the TRP channel, such as capsaicin, menthol, or piperine, was effective for improving the swallowing function, although it is well applied in clinical practice. Thus, future studies should investigate the effect of drug treatment. In addition, swallowing treatment using biofeedback as an adjunct to conventional swallowing therapy was effective in improving swallowing func-tion. CP botulinum toxin injection, CP myotomy, and balloon dilatation seem to be effective treatment options for patients with CP dysfunction but should be performed after considering the advantages and disadvantages of the treatments. The effect of non-invasive brain stimulation treatment methods, such as tDCS and rTMS, were also investigated, and both of them were effective in improving the swallowing function in patients with non-progressive brain lesions.
As for the nutrition issues, we concluded that early enteral tube feeding improved the clinical course, survival rate, and neurological prognosis for patients who are likely to have oropharyngeal dysphagia for a prolonged period. In addition, gastrostomy tube feeding should also be considered to improve the clinical course, survival rate, neurological prognosis, and nutritional status in patients who are likely to have oropharyngeal dysphagia for an extended period. In addition, texture modification of food and fluids based on the severity of dysphagia improved the clinical course of patients with oropharyngeal dysphagia, especially in reducing the risk of aspira-tion. Nutrition intervention, including addressing nutritional problems and establishing plans for nutrition management, was recommended because a literature search showed that ithelps improve intake or nutritional status in patients with oropharyngeal dysphagia.
Other issues associated with dysphagia have also been addressed in this CPG. The current evidence showed that the incidence and mortality of aspiration pneumonia were, in fact, higher in patients with oropharyngeal dysphagia than those without dyspha-gia. Providing the oral health care program improved oral health and food intake in patients with oro-pharyngeal dysphagia. Additionally, a multidiscipli-nary team approach, including doctors in various fields, nurses, and therapists, was effective in pre-venting complications (such as mortality, pneumonia, and other respiratory infections). Various methods for the treatment of dysphagia should be performed, considering various aspects in patients with oro-pharyngeal dysphagia.
This CPG has several limitations. First, the stati-stical significance was not evaluated, and meta- analysis was not performed. Second, although the level of evidence for each clinical question was established based on the results of studies abroad, the recommendations of this CPG were primarily based on the applicability of the resources and healthcare system in Korea.
In conclusion, this CPG is the first guideline that provides the levels of evidence of relevant literature and the consensus of multidisciplinary experts re-garding issues related to oropharyngeal dysphagia. Physicians, patients, caregivers, and other healthcare professionals are expected to widely read this CPG to improve their understanding and treatment of dysphagia.
This guideline was developed with financial support from the Korean Academy of Rehabilitation Medicine and the Korean Dysphagia Society. The development of this CPG was not influenced by the supporting academies and was not supported by other groups.
The members who were involved in this guideline had no other conflicts of interest (COI). The COI was required to determine whether or not these persons should be involved in the development of similar guidelines, employment, financial interests, and other potential interests. No potential conflicts of interest relevant to this article were reported.
Table 1 . Grading of Recommendations Assessment, Development and Evaluation quality level of evidence and meaning..
Quality level | Definition |
---|---|
High | We are confident that the estimate of the effect is close to the actual effect |
Moderate | The estimates of the effect appear to be close to the actual effect but may vary considerably |
Low | The confidence in the estimate of the effect is limited. The actual effect may differ significantly from the estimate of the effect |
Very low | There is little confidence in the estimate of the effect. The actual effect will differ significantly from the estimate of the effect |
Table 2 . Grading of recommendations..
Strength of recommendations | Definition |
---|---|
Strong recommendation | The intervention/diagnostic test can be strongly recommended in most clinical practice, considering greater benefit than harm, evidence level, value and preference, and resources |
Conditional recommendation | The intervention/diagnostic test can be conditionally recommended in clinical practice considering the balance of benefit and harm, evidence level, value and preference, and resources |
Against recommendation | The harm caused by the intervention/diagnostic test maybe greater than its benefits. Moreover, considering the evidence level, value and preference, and resources, the intervention should not be recommended |
Inconclusive | It is not possible to determine the strength and direction of recommendation because of a very low or insufficient evidence level, uncertain or variable balance of benefit and harm, value and preference, and resources |
Expert consensusa) | Although clinical evidence is insufficient, it is recommended to be used in accordance with clinical experience and expert consensus when considering the benefits and risks of the treatment, the level of evidence, values and preferences, and resources |
Each statement is shown as a combination of the strength of recommendations and level of evidence..
a)In the case of a consensus statement by an expert opinion, the recommendation grade and level of evidence are not indicated..
2019; 9(2): 55-60
2024; 14(2): 95-100