METHODS
Eligibility criteria
Studies were selected according to predefined inclusion and exclusion criteria. “English-language
full-text articles on clinical and controlled trials indexed in the previously selected
electronic databases with adult populations presenting with oropharyngeal dysphagia
as a symptom after stroke” was defined as inclusion criteria. Studies involving (1)
pediatric population, (2) analysis of the application of evaluation protocols, (3)
studies aiming at decannulation of tracheotomized patients, (4) studies involving
esophageal dysphagia, and (5) studies in which the primary outcome was not related
to the degree of dysphagia and improvement of the swallowing pattern were excluded.
Review question
The guiding question for the research was: "What interventions are reported as effective
treatments for the rehabilitation of adult patients with dysphagia after stroke?".
Search strategy, study selection and data extraction
A review of articles published between January 2008 and January 2021 in indexed scientific
journals was carried out in the following electronic databases: MEDLINE-PubMed, LILACS,
Cochrane, and Clinical Trials.gov. The selection of descriptors was performed through
consultation in a Brazilian platform for descriptors in health sciences (DeCS - Descritores
de Ciências em Saúde). The selected English descriptors were: "dysphagia" AND "therapy"
AND "stroke".
The articles were selected based on the screening of titles or abstracts. However,
when title, keywords, and abstract did not have sufficient information to determine
the inclusion according to the established criteria, a full-text review was conducted.
After that, all the remaining papers were fully read, evaluated, and cataloged. All
steps in this study were performed independently by two researchers following the
protocol described above. Individual results were assessed and compared, and a consensus
was reached through discussion.
The following data were extracted after the assessment of full text of all selected
articles: country, number of patients, study design, outcome measures, types of intervention
groups, intervention time, summary of the results, and conclusions. These data were
then compiled into a standard table.
RESULTS
The search identified 154 references (117 in MEDLINE-Pubmed, 31 in Cochrane, 3 in
Clinical trials, and 3 in LILACS) of which 90 were excluded based on the title and
4 were duplicates. Therefore, 60 studies were selected for inclusion according to
their titles and abstracts, of which 38 clinical trials that met the inclusion criteria
were included in this review. A flow diagram showing the study selection process is
presented in [Figure 1].
Figure 1 Flow chart of the search strategy.
All included studies evaluated patients diagnosed with stroke. A total of 12 different
therapies have been studied with a variety of study designs: [1] electrical stimulation
(n = 14; 36.8% of the total)[7]
-
[20], [2] transcranial magnetic stimulation techniques (n = 3; 7.9%)[21]
-
[23], [3] active pharyngeal electrostimulation (n = 3; 7.9%)[24]
-
[26], [4] exercises with Mendelsohn maneuver (n = 2; 5.3%)[27],[28], [5] transcranial direct current stimulation (n = 3; 7.9%)[29]
-
[31], [6] CTAR exercise (n = 5; 13.6%)[32]
-
[36], [7] Shaker exercise (n = 2; 5.3%)[33],[37], [8] acupuncture (n = 3; 7.9%)[38]
-
[40], [9] resistance to tongue pressure (n = 2; 5.3%)[41],[42], [10] modified jaw opening exercise (n = 1; 2.6%)[43] and [11] cervical isometric exercises (n = 1; 2.6%)[44].
Even among studies focusing on the same type of therapy a wide variety of outcome
measures were found to assessing dysphagia. The sample sizes varied from 4[22] to 250[40]. More than half of the studies were from Asia, but some were from Europe and North
America.
The following sections present a summary of the articles’ results by type of interventions.
Electrotherapy (NMES)
Electrotherapy is a technique that can be used with motor stimuli, sensorial stimuli,
or both. In addition, depending on the muscular function affected in the swallowing
process and the degree of this change, variations in intensity, electric current pulse
duration, electrodes number and position are applied. Despite all these factors, there
is still little scientific evidence of the effectiveness of electrotherapy in improving
the swallowing pattern in oropharyngeal dysphagia, especially when this technique
is associated with conventional exercise therapy.
The Neuromuscular Electrical Stimulation (NMES) technique combined with Endoscopic
Evaluation of Swallowing (EES) and traditional swallowing rehabilitation improved
the swallowing quality in a study involving thirty-two patients with moderate to severe
post-stroke dysphagia. In addition, patient satisfaction was high and there were no
serious adverse events. Thus, the implementation of this promising combination in
clinical practice was recommended[7]. Similarly, the effects of applying sensory-level electrical stimulation (SES) on
masseter muscles in patients with acute stroke were evaluated in another study[8]. Applying SES (based on its oral and pharyngeal functions) on masseter muscles and
using SES to generate cortical reorganization was effective in treating dysphagia
in stroke patients.
In another study[17], selected patients were randomly assigned to a VitalStim electrotherapy group, a
conventional swallowing therapy group, and electrotherapy plus conventional therapy
group. The results suggested that VitalStim combined with conventional therapy is
capable of improving dysphagia after stroke. Xia et al.[18] also evaluated the effects of VitalStim in their patients and confirmed its effectiveness.
A limitation of this study, however, was the absence of a placebo stimulation group.
The combined application of electrical stimulation and conventional therapy in patients
with acute oropharyngeal dysphagia secondary to acquired brain injury[9] resulted in better outcomes than when conventional therapy with placebo stimulation
was adopted. A study conducted by Rofes et al.[10] evaluated and compared the efficacy and safety of a 10-day surface electrical stimulation
(e-STIM) treatment in sensory and motor intensities in patients with chronic oropharyngeal
dysphagia after chronic stroke. This study showed that e-STIM is a safe and effective
therapy to improve swallowing. However, further investigation involving a control
group, a larger number of patients, a prolonged follow-up, and the effect on clinical
outcomes is needed to confirm the clinical utility of this therapy.
Konecny and Elfmark (2018) showed that after four weeks of standard therapy with suprahyoid
muscles electrical stimulation, the duration of oral and pharyngeal transit time was
statistically improved[11]. In another study, electrical stimulation associated with conventional therapy was
performed. Electrodes were placed adjacent to the suprahyoid and upper and lower parts
of the thyroid, in the geniohyoid region, and in the mylohyoid region. When compared
to conventional therapy, a significant improvement was noted. However, the position
of electrodes did not generate significant differences[12].
Another study investigated the effects of forced swallowing combined to neuromuscular
electrical stimulation on the hyoid bone movement and on the swallowing function in
stroke patients[13]. The experimental group showed an increase in the anterior and superior movement
of the hyoid bone and an improvement in the pharyngeal phase swallowing function.
The neuromuscular electrical stimulation combined with thermal-tactile stimulation
were found to be a better treatment for patients with deglutition disorders after
stroke than isolated thermal-tactile stimulation therapy[14].
Electrical stimulation was performed by Park et al.[15] using two sets of electrodes placed in the segmentation area of the infrahyoid and
sternum-hyoid muscles. When using sensorial EE with forced swallowing, no significant
improve was observed in any of the evaluated parameters. However, the studied methodology
can only be applied to selected patients, as many patients with dysphagia fail to
elevate the hyolaryngeal complex during motor electrical stimulation.
The effects of NMES associated with electromyographic biofeedback (EMG-BF) were also
investigated[19]. EMG-BF is known to be an effective therapy for stroke rehabilitation. In this pilot
study, all subjects received NMES combined with EMG-BF in the suprahyoid area. The
results demonstrated that NMES combined with EMGBF had the potential to improve oropharyngeal
swallowing in stroke patients with dysphagia.
In a more recent study, the effects of neuromuscular transcutaneous electrical stimulation
(NMES) in 33 patients affected by dysphagia after sub-acute stroke were evaluated.
Both groups showed improvements[16]. Another recent study analyzed the McNeill's dysphagia therapy (MDTP) with NMES
for the treatment of post-stroke dysphagia[20]. MDTP showed a greater positive change than the NMES group, including increased
oral intake and improved functional outcome three months after the stroke. These data
support the inclusion of intense short-term behavioral interventions for an efficient
allocation of resources for acute stroke rehabilitation.
Studies that used electrotherapy as a therapeutic approach are detailed in [Table 1].
Table 1
Clinical studies using electrotherapy for patients after stroke or TBI.
|
References
|
Country
|
Patients
|
Diagnosis
|
Study design
|
Outcomes
|
Intervention
|
Intervention time
|
Results
|
Follow-up
|
|
Terré,R.; Mearin, F., 2014[9]
|
Spain
|
20
|
STROKE and TBI
|
Randomized; controlled; prospective
|
VFSS; FOIS
|
GI- EE and TC GC - EE placebo eTC
|
20 sessions/60 min-5 times a week
|
FOIS increased 4.9 points (GI); 3.1 points (GC).
|
1, 3 months
|
|
Sun, S.F et al., 2013[7]
|
Taiwan
|
29
|
STROKE
|
Clinic; prospective
|
FOIS; Dysphagia scale
|
EE e TC separately
|
NMES and TC 12 sessions/60 min - 3 times a week
|
FOIS and dysphagia scale improved after NMES, for 6 months and 2 years (p \ 0.001,
each)
|
6 months, 2 years
|
|
Rofes, L. et al., 2013[10]
|
Spain
|
20
|
STROKE
|
Randomized; double-blind
|
VFSS (PAS)
|
Motor EE group Sensory EE group
|
10 sessions/ 30 min - 5 times a week
|
Sensory and motor EE reduced the insecure deglutition number in (p < 0.001), and (p
= 0.002)
|
No follow-up
|
|
Park, J. S. et al., 2016[13]
|
Korea
|
50
|
STROKE
|
Randomized; Controlled; Single-blind
|
VFSS (PAS e VDS)
|
GI - EE and forced swallowing exercise GC - EE placebo and forced swallowing exercise
|
30 sessions/30 min - 5 times a week
|
GI increased oral and pharyngeal phase in VDS (P < 0.00, P = 002 and P < 0.00), and
PAS (P < 0.00).
|
No follow-up
|
|
Park, J. W. et al., 2012[15]
|
Korea
|
20
|
STROKE
|
Randomized; Controlled; Double-blind
|
VFSS (PAS; UES)
|
GI - Motor EE and forced swallowing GC- Sensory EE and forced deglutition
|
12 sessions/20 min - 3 times a week
|
GI increased vertical larynx movement (p\0.05).
|
No follow-up
|
|
Konecny, P.; Elfmark, M., 2018[11]
|
Czech Republic
|
108
|
STROKE
|
Randomized; Controlled; Prospective
|
VFSS
|
GI - Motor EE and TC GC - TC
|
20 sessions/20 min - 5 times a week
|
The difference in the oral and pharynx transit time after therapy between the GI and
the GC (P = 0.01 e P= 0.009)
|
No follow-up
|
|
Lim, K. B. et al., 2009[14]
|
Korea
|
28
|
STROKE
|
Randomized; Controlled
|
VFSS
|
GI - EE muscular and tactile-thermic stimulation GC - Tactile-thermic stimulation
|
20 sessions/60 min - 5 times a week
|
GI with higher scores in PAS; 2 in semi-solid (p < 0.05) and 2.5 in liquids (p < 0.05)
|
No follow-up
|
|
Meng, P. et al., 2017[12]
|
China
|
30
|
STROKE
|
Randomized
|
VFSS; DOSS
|
GA - EE with electrodes along the suprahyoid and along with the superior and inferior
thyroid parts and TC GB - EE with 1 pair of electrodes in the geniohyoid region and
1 pair in the mylohyoid region and TC GC - TC
|
10 sessions/30 min - 5 times a week
|
Improvement in DOSS in groups A and B (P<0.005) in relation to GC.
|
No follow-up
|
|
Xia, W. et al.,2011[18]
|
China
|
120
|
STROKE
|
Randomized; prospective
|
SSA; VFSS
|
G1 - Conventional therapy G2 - EE G3 - Conventional therapy and EE
|
40 sessions/30 min - 2 times a day, 5 times a week for 4 weeks
|
SSA, VFSS increased more in G3 than in G1 and G2 (P < 0.01).
|
No follow-up
|
|
LI, L et al., 2015[17]
|
China
|
135
|
STROKE
|
Randomized; controlled
|
SSA
|
G1 - EE G2 - TC G3 - EE and TC
|
20 sessions/60 min - 5 times per week for 4 weeks
|
SSA improved in G3 (P <0.01)
|
4 weeks
|
|
Ploumis, A. et al., 2018[44]
|
Greece
|
70
|
STROKE
|
Randomized, controlled, prospective.
|
VFSS; PAS
|
GI - Cervical exercises and conventional therapy GC - Conventional therapy
|
30 min daily sessions/12 weeks
|
Improved swallowing (P < 0.05) and PAS (P < 0.001)
|
No follow-up
|
|
Umay, E. et al., 2017[8]
|
India
|
98
|
STROKE
|
Randomized; controlled
|
MASA; SSA
|
GI - Sensory EE and TC GC - Sensory EE placebo and TC
|
20 sessions/60 min - 5 times a week for 4 weeks
|
All parameters improved in G1 (P <0.025).
|
No follow-up
|
|
Park, S.J. et al., 2019[34]
|
Korea
|
10
|
STROKE
|
Clinical; prospective
|
VFS; PAS
|
NMES and EMG-BF
|
20 sessions/30 min - 5 times a week
|
Significant differences between oral (P = 0.015) and pharyngeal (P = 0.016) VFS. Improved
PAS (P = 0.031).
|
No follow-up
|
|
Carnaby, G.D et al., 2020[20]
|
USA
|
53
|
STROKE
|
Randomized; controlled; double-blind
|
FOIS, MASA
|
G1 - TC and EENM G2 - TC and EENM placebo G3 - TC
|
15 sessions/60 min - 3 weeks
|
MASA was different among groups different (p ≤ 0.0001) G2 had the best FOIS result
(p≤0.0001).
|
3 months
|
DOSS: Dysphagia Outcome and Severity Scale; EE: Electrical Stimulation; NMES: Neuromuscular
Electrical Stimulation ; FOIS: Functional Oral Intake Scale; GA: Group A; GB: Group
B; GC: Control group; GI: Intervention group; MASA: Mann Assessment of Swallowing
Ability; PAS: Penetration-Aspiration Scale; SSA: Standardized Swallowing Assessment;
TC: Conventional therapy; TBI: Traumatic Brain Injury; VDS: videofluoroscopic dysphagia
scale; UES: Upper esophageal sphincter; VFSS: Video Fluoroscopic Swallowing Study.
Neuromodulation
The nervous system has the ability to modulate and modify itself in response to external
stimuli. The term neuromodulation has been used to describe procedures in which electrical
stimulation is applied directly to structures of the nervous system for therapeutic
purposes. A summary of these approaches is shown in [Table 2].
Table 2
Intervention clinical studies using neuromodulation for stroke patients.
|
Reference
|
Country
|
Patients
|
Diagnosis
|
Study design
|
Outcomes
|
Intervention
|
Intervention time
|
Results
|
Follow-up
|
|
Hyun, Y. et al., 2017[29]
|
Korea
|
26
|
Stroke
|
Randomized; multicenter controlled; prospective; double-blind.
|
DOSS
|
GI - ETCC and TC. GC - Placebo ETCC and TC
|
10 sessions/20 min - 5 times a week
|
DOSS - Significant improvement (0.62 points on GI)
|
No follow-up
|
|
Cheng, I. K. Y. et al., 2017[21]
|
China
|
15
|
Stroke
|
Randomized; controlled; double-blind.
|
VFSS; IOPI
|
GI - Active EMTr GC - Simulated EMTr
|
10 applications - 5 times a week
|
No significant results
|
2, 6 and 12 months
|
|
Cheng, I. K. Y. et al., 2014[22]
|
China
|
4
|
Stroke
|
Randomized; controlled.
|
VFSS; IOPI
|
GI - Active EMTr/ Tongue motor cortex stimulation GC - Simulated EMTr
|
10 sessions/30 min - 5 times a week
|
No significant deglutition improvement on GI
|
1 week, 1 month
|
|
Du, J. et al., 2016[23]
|
China
|
40
|
Ischemic stroke
|
Randomized; controlled; double-blind.
|
SSA
|
G1 - High-frequency EMTr (3Hz) G2 - Low-frequency EMTr (1Hz) G3 - Simulated EMTr
|
5 sessions
|
Better G1 and G2 dysphagia improvement after 5 days compared to the other group, remaining
for 5 months.
|
1, 2 and 3 months
|
|
Park, J.W. et al., 2013[15]
|
Korea
|
18
|
Stroke
|
Randomized; controlled; double-blind.
|
VFSS (PAS and VDS)
|
GI - Contralesional pharyngeal motor cortex EMTr 5Hz GC - Placebo (same conditions)
|
20 sessions/10 min
|
VDC and PAS improved significantly on the GI (P<0.005)
|
2 weeks
|
|
Shigematsu, T. et al., 2013[30]
|
Japan
|
20
|
Stroke
|
Prospective; double-blind.
|
DOSS
|
GI - TC and 1-mA ETCC (contralesional pharyngeal motor cortex) GC - Simulated ETCC
and TC
|
10 sessions/20min - Once a day
|
1.4 points (P=0.006) improvement and after 1 month 2.8 points (P=0.004) improvement
on the GI.
|
1 month
|
|
Krueger, S. S. et al., 2018[31]
|
Germany
|
59
|
Ischemic stroke
|
Randomized; double-blind.
|
FEDSS; SSA
|
Contralesional pharyngeal motor cortex ETCC group Placebo ETCC group
|
4 sessions/20min
|
Significant dysphagia improvement on the ETCC group when compared to the placebo group
(P<0.0005)
|
No follow-up
|
DOSS: Dysphagia Outcome and Severity Scale; ETCC: TC: Conventional Therapy; GI: Intervention
group GC: Control group; VFSS: Videofluoroscopy; IOPI: Iowa Oral Performance Instrument;
EMTr: PAS: Penetration-Aspiration Scale; VDS: Functional Dysphagia Scale; SSA: Standardized
Swallow Assessment; FEDSS: fiberoptic endoscopic dysphagia severity scale.
Repetitive Transcranial Magnetic Stimulation
Repetitive Transcranial Magnetic Stimulation (rTMS) has been proposed as an alternative
treatment for dysphagia after stroke. It is a noninvasive technique that modulates
brain activity using electromagnetic induction and thus induces physiological changes.
An advantage of rTMS is that patients do not need to be actively engaged during treatment[21].
One of the included studies indicated that 5 Hz rTMS applied over the tongue area
of the motor cortex for 10 days was not effective in improving the swallowing function
in patients with stroke and chronic dysphagia. However, given he small and unbalanced
sizes of the groups in this study, the therapeutic effects of the protocol remain
uncertain[21]. Another study also evaluated the therapeutic effect of 5 Hz high-frequency rTMS
on the unaltered pharyngeal motor cortex in 4 post-stroke dysphagic patients. In disagreement
with the previous study, the authors indicated that 5Hz high-frequency rTMS applied
to the tongue region of the motor cortex may be beneficial for patients with dysphagia
after hemispheric unilateral stroke and with dysfunction in the swallowing phase.
Further investigations with larger samples are required to support the benefit of
this protocol[22]. Finally, a study of 40 patients showed that the use of high frequency (3 Hz) and
low frequency (1 Hz) rTMS improved dysphagia (after 5 days) more than the simulated
group, with the effects remaining for at least 3 months after the intervention[23].
Transcranial direct current stimulation (tDCS)
tDCS is a non-invasive brain stimulation method based on the principle of neuroplasticity.
It provides a constant low-intensity electric current between the anode and the cathode
applied to the scalp area associated with the segmentation of the cerebral cortex.
In general, cathodic tDCS decreases cortical excitability and anodic tDCS increases
cortical excitability[29]. Recently, noninvasive cortical stimulation has been used to improve neural plasticity
and treat hemiplegia and aphasia. However, little is known about the possible effects
of tDCS on swallowing function[30], and few studies were conducted on the mater.
The association of the tDCS technique with conventional therapy was evaluated in patients
with chronic post-stroke dysphagia. Although the result of this study shows that the
bihemispheric anodic tDCS group did not have a statistically superior improvement
compared with the control group, the detailed dysphagia outcome scale (using videofluoroscopy),
patient symptom report, or patient and caregiver satisfaction may reflect the clinical
improvement of dysphagia[29]. The study conducted by Shigematsu et al.[30] investigated the effects of cerebral pharyngeal cortex noninvasive stimulation combined
with intensive swallowing therapy on dysphagia recovery and found that the combined
therapies effectively improve post-stroke dysphagia compared to isolated therapy.
Krueger et al.[31] evaluated patients with acute and dysphagic stroke that received contralesional
anode stimulation or placebo tDCS for 4 consecutive days. Applying objective instrumental
diagnosis in parallel with functional neuroimaging, a greater improvement in the swallowing
function was observed after tDCS compared with the placebo intervention. Thus, tDCS
seems to be a safe and beneficial therapeutic option for patients with oropharyngeal
dysphagia during the early stage of stroke.
Pharyngeal electrical stimulation (PES)
In one of the included studies, PES interventions were performed at the bedside. The
effects of PES on dysphagia in stroke patients remained inconclusive because the recruitment
goal was smaller than predicted. Despite this, there is an indication for the use
of this treatment considering some potentially favorable results, such as the observed
improvement in the number of safe swallows. In addition, PES was well tolerated without
any adverse effects[25]. In another study with the same objective, it was found that PES did not reduce
radiological aspiration or clinical dysphagia[24].
In addition, there are currently a wide variety of candidate genes that can be studied
in the context of brain plasticity and response to PES. BDNF is the most abundant
growth factor in the brain and is involved in long-term brain plasticity. It has attracted
much interest and is considered a candidate for neurological and swallowing function
recovery in patients treated with electrical stimulation of the pharynx[26]. The study conducted by Essa et al.[26] aimed to test the possible influence of a single but common BDNF polymorphism on
the functional recovery in a population with dysphagia after stroke. An association
between the Val66Met BDNF allele and level of swallowing recovery was observed when
pharyngeal stimulation was performed. On the other hand, the BDNF showed no correlation
in the simulated group, suggesting that such genetic polymorphisms may be less relevant
in natural recovery than in treatment-induced recovery.
A summary of studies using the pharynx electrostimulation technique is shown in [Table 3].
Table 3
Interventional clinical studies using electrostimulation of the larynx, tongue pressure
resistance exercise and precision training for patients after stroke.
|
References
|
Country
|
Patients (n)
|
Diagnosis
|
Study Design
|
Outcomes
|
Intervention
|
Intervention time
|
Results
|
Follow-up
|
|
Bath, P. M. et al., 2016[24]
|
United Kingdom
|
162
|
Stroke
|
Multicenter; Randomized; Controlled; Double-blind
|
VFSS (PAS)
|
GI - active PES GC - simulated PES
|
3 sessions/10 min
|
No GI improvements in relation to the GC
|
2,6 and 12 weeks
|
|
Vasant, D, H et al., 2016[25]
|
United Kingdom
|
36
|
Stroke
|
Multicenter; Randomized; Controlled
|
DSR
|
GI - active PES GC - simulated PES
|
3sessions/10 min
|
In relation to the simulated group, a probability ratio (OR)> 1 indicated a favorable
outcome for the active group in DSR punctuations.
|
2 weeks and 3 months
|
|
Essa, H., 2017[26]
|
United Kingdom
|
38
|
Stroke
|
Randomized; Controlled; Double-blind
|
DRS
|
GI - active PES GC - simulated PES
|
3 sessions/10 min
|
In the GI, patients with the allele Met BDNF showed improvements in DERD after 3 months
in relation to patients in the GC (P = 0.009)
|
2 weeks and 3 months
|
|
Moon, J. H et al., 2018[41]
|
Korea
|
16
|
Stroke
|
Randomized; Controlled
|
IOPI; MASA
|
GI - TPSAT in the morning and TC in the afternoon GC - TC
|
80 sessions/30 min - 2 times a day, 5 times a week for 8 weeks
|
Anterior (P = 0.001) and posterior (P = 0.001) PMI improvement in the GI in relation
to the GC; GI and GC MASA improvement (P = 0.012)
|
No follow-up
|
|
Kim, H. D. et al., 2016[35]
|
Korea
|
35
|
Stroke
|
Randomized; Controlled
|
IOPI; VFSS (VDS and PAS)
|
GI - TPRT and TC GC - TC
|
20 sessions - 5 times a week
|
GI tongue strength improvement (anterior and posterior, p = 0.009, 0.015) and oral
and pharynx phases punctuations improvement in VDS (p = 0.029, 0.007), but not in
PAS (p = 0.471) in relation to the control group.
|
No follow-up
|
VFSS: Video Fluoroscopic Swallowing Study; PAS: Penetration-Aspiration Scale; DSR:
Dysphagia Gravity Scale; DERD/DSRS: Dysphagia Severity Rating Scale; GI: Intervention
Group; GC: Control Group; PES: Pharyngeal electric stimulation; BDNF: brain-derived
neurotrophic factor; DRS: Dementia Rating Scale; PMI: maximum isometric pressure;
VDS:videofluoroscopic dysphagia scale; TPRT: tongue to palate resistance training;
IOPI: Iowa Oral Performance Instrument.
Tongue pressure resistance exercise and precision training
Tongue function can affect both the oral and the pharyngeal stages of the swallowing
process. Adequate tongue strength is vital for safe oropharyngeal swallowing. [Table 3] has a summary of the studies on tongue pressure resistance exercises and precision
training.
Kim et al.[42] investigated the effect of tongue-pressure resistance training (TPRT) on tongue
strength and oropharyngeal swallowing function in patients with stroke and dysphagia.
The results showed that TPRT increased tongue muscle strength and improved swallowing
function in patients with post-stroke dysphagia. This study also confirmed that TPRT
improved the oral and pharyngeal phases of deglutition. Therefore, TPRT is recommended
as an easy and simple rehabilitation strategy to improve swallowing in patients with
dysphagia. However, these results do not reflect a pure TPRT effect, as this therapy
was conducted in conjunction with conventional therapy[42]. Another study published the following year aimed to investigate the effects of
tongue pressure strength and accuracy training (TPSAT) on tongue pressure strength
and its ability to improve quality of life in patients with dysphagia after stroke.
TPSAT consisted of an isometric exercise of anterior and posterior tongue strength
and an isometric tongue precision exercise. TPSAT combined with traditional therapy
improved outcomes compared to pre-intervention levels[41].
CTAR exercise
Recently, CTAR (Chin Tuck Against Resistance) exercise has been reported as a treatment
for pharyngeal dysphagia. However, clinical evidence of its effect is still unclear.
Park et al.[32] investigated the effect of CTAR on the swallowing function in patients with dysphagia
after subacute stroke and found that the exercise improved swallowing.
Game-based CTAR was also proposed[34]. The experimental group performed game-based CTAR, while the control group performed
traditional head lifting exercises. The LES 100 (Cybermedic Inc., Iksan in South Korea)
consists of a tablet screen, a resistance bar, and a Bluetooth connector, and it implements
a game-based exercise in which the chin is tucked down against a bar in order to strengthen
suprahyoid muscles. The game-based CTAR not only has a similar effect on the swallowing
function of patients with dysphagia as the lifting exercise, but is also a less rigorous,
more enjoyable and interesting rehabilitation method.
Because the CTAR involves hand-holding a device, physically weak patients may find
it difficult. A study investigated the effect of modified CTAR (mCTAR) in patients
with post-stroke dysphagia[35] and found that it reduced aspiration and improved nutritional levels of patients.
I can thus be assumed that the mCTAR is beneficial for physically vulnerable patients
with dysphagia who have limited hand strength and movement.
The aim of the study was to investigate the effect of jaw opening exercise (JOE) and
hyoid bone movement compared to head lifting exercise, or Shaker exercise (HLE) in
patients with dysphagia after stroke. The JOE/CTAR group performed an exercise using
a resistance bar. The Shaker group performed traditional exercises. The total duration
of the intervention was 6 weeks. The thickness of the digastric and mylohyoid muscles
was measured by ultrasound. The CTAR and Shaker had similar effects in increasing
the thickness of the suprahyoid muscle and improving the movement of the hyoid bone.
However, CTAR required less perceived effort than Shaker[36].
Shaker exercise
The Shaker exercise (SE) has been considered a popular rehabilitation training for
dysphagia[33]. This is an isometric and isotonic exercise based on the upward and forward movement
of the larynx structures resulting from the traction of the thyroid, mylohyoid, and
geniohyoid muscles and the anterior belly of the digastric muscle. First, patients
perform 3 head raises for 60 s in a supinated position without movement; there is
a 60 s pause between the elevations. Next, participants perform 30 repeated head raises
in the supine position. Participants raise their head high enough to observe the toes
without raising the shoulders[37].
Gao & Zhang[33] compared the effects of Shaker exercises, CTAR and conventional exercises on dysphagia
and psychological status. Traditional rehabilitation included tongue exercises such
as tongue extension movement and mouth exercises such as mouth opening, teeth clicking,
and voluntary swallowing. The main conclusion of this study was that the CTAR exercise
has a similar effect on improving swallowing function as the Shaker exercise. However,
the rehabilitation effect of CTAR exercises on dysphagia should be more explored in
younger patients with stroke, since all patients assessed in this study were 60 years
old or older.
Choi et al.[37] investigated the effects of the Shaker exercise on aspiration and oral diet level
in stroke survivors with dysphagia. This study suggested that the SE is an effective
exercise for swallowing function recovery in stroke survivors, reducing aspiration
and improving oral diet level. As aspiration severity is closely related to the feeding
tube and to the oral diet level, the results of this study indicate that performing
SE can lead to tube withdrawal in stroke survivors with dysphagia. Some limitations,
such as a relatively small sample, no follow-up after the intervention, and failure
to observe long-term effects prevent the results of this work from being generalized.
Important data from the articles about CTAR and SE are shown in [Table 4].
Table 4
Intervention clinical studies using CTAR and Shake exercises for patients after stroke.
|
Reference
|
Country
|
Patients
|
Diagnosis
|
Study design
|
Outcomes
|
Intervention
|
Intervention time
|
Results
|
Follow-up
|
|
Gao, J.; Zhang, H.J., 2017[33]
|
China
|
90
|
Ischemic stroke
|
Clinical; Random
|
VFSS (PAS)
|
GC - TC Shaker - TC and Shaker exercise CTAR - TC and CTAR
|
42 sessions - 3 times a day
|
A better swallowing improvement in the CTAR group when compared to the Shaker group
|
2, 4 and 6 weeks
|
|
Park, J. S. et al., 2018[32]
|
Korea
|
22
|
Stroke
|
Randomized; Controlled
|
VFSS (PAS; FDS)
|
GI - CTAR and TC GC - TC
|
20 sessions/30 min - 5 times a week
|
Significant improvement in the PAS and FDS in the GI when compared to the GC
|
No follow-up
|
|
Choi, J. B. et al., 2017[37]
|
Korea
|
31
|
Stroke
|
Randomized; Controlled; Double-blind
|
VFSS (PAS); FOIS
|
GI - TC and Shaker exercise GC - TC
|
20 sessions/30 min - 5 times a week
|
PAS and FOIS significantly improved the GI in relation to the GC
|
No follow-up
|
|
Park, J. S et al., 2019
[34]
|
Korea
|
37
|
Stroke
|
Randomized; Controlled
|
VFSS (PAS); FOIS
|
GI - Game-based CTAR GC - CTAR
|
20 sessions/30min - 5 times a week
|
There were no differences in improvement between groups
|
No follow-up
|
|
Kim, H. H.; Park, J. S, 2019[35]
|
Korea
|
30
|
Stroke
|
Clinical; Randomized
|
PAS; FOIS
|
GI - CTAR and TC GC - TC
|
30 sessions/30 min - 5 times a week
|
GI had a significant improvement in PAS and FOIS (P <0.001, both)
|
No follow-up
|
VFSS: Videofluoroscopy; PAS: Penetration-Aspiration Scale; FDS: Functional Dysphagia
Scale; GI: Intervention group; GC: Control group; TC: Conventional therapy; FOIS:
Functional Oral Intake Scale; CTAR: Chin Tuck Against Resistance.
Modified jaw opening exercise (MJOE)
The viability and effectiveness of a new method (modified jaw opening exercise - MJOE)
for promoting anterior displacement of the hyoid bone during swallowing was studied.
The MJOE differs from the conventional JOE, in which an upward vertical resistance
is applied to the jaw while the mouth is closed with the tongue held in the swallowing
tilting position to prevent mouth opening. In the MJOE, surface electrodes connected
to the sternohyoid muscle in the mandibular midline were connected to the biofeedback
equipment. The results showed that MJOE is feasible in elderly post-stroke patients,
without adverse events and promotes anterior displacement of the hyoid bone during
swallowing[43].
Mendelsohn maneuver
The Mendelsohn maneuver, a voluntary prolongation of laryngeal elevation during swallowing,
has been widely used as a compensatory strategy to improve the opening of the upper
esophageal sphincter (UES) and bolus flow. When used as a rehabilitation exercise,
it significantly improves the duration of the hyoid movement and the duration of the
UES opening[27].
McCullough et al.[28] performed a research to determine if the intensive exercise using the Mendelsohn
maneuver would improve swallowing physiology. The Mendelsohn maneuver, used as a rehabilitation
exercise, improved the duration of the anterior and superior maxillary movement of
the hyoid and the duration of the UES opening. With a similar goal, McCullough et
al.[27] stated that it seems possible that the use of the Mendelsohn maneuver as a rehabilitation
exercise may have a greater impact on swallowing durations than on structural movements.
Changes in the coordination of structural movements with duration measures, however,
require further investigation. When the Mendelsohn maneuver was used as a compensation
mechanism, duration measures also appeared to be more affected than measures of structural
movements. Thus, the data reported in this research support the use of the Mendelsohn
maneuver as an exercise to improve the swallowing physiology[27].
A synthesis of the results discussed above is shown in [Table 5].
Table 5
Interventional clinical studies using the Mendelsohn maneuver and EMG with biofeedback
and acupuncture for stroke patients.
|
Reference
|
Country
|
Patients
|
Diagnosis
|
Study design
|
Outcomes
|
Intervention
|
Intervention time
|
Results
|
Follow-up
|
|
McCullough, G.H. et al., 2012
[28]
|
USA
|
18
|
Stroke
|
Randomized
|
VFSS (DOHME and DOHAME)
|
Group A - 2 weeks of treatment with the Mendelsohn maneuver and EMG with feedback
and 2 weeks without treatment. Group B - 2 weeks without treatment and 2 weeks with
treatment.
|
45 min sessions, 2 times a day
|
DOHME and DOHMAE significantly improved (P = 0.011 and 0.009) after treatment.
|
No follow-up
|
|
McCullough, G.H; Kim, Y., 2013
[27]
|
USA
|
18
|
Stroke
|
Randomized
|
VFSS (HME, HMAE, UES)
|
Group A - 2 weeks of treatment with the Mendelsohn maneuver and EMG with feedback
and 2 weeks without treatment. Group B - 2 weeks without treatment and 2 weeks with
treatment.
|
45 min sessions, 2 times a day
|
No significant improvement after treatment
|
1 month, 1 year
|
|
Xia, W. et al., 2015[38]
|
China
|
124
|
Stroke
|
Clinical; Randomized; Double blind
|
SSA; DOSS
|
GI- TC and acupuncture GC - TC
|
24 sessions/30 minutes - 6 times a week
|
SSA and DOSS GI improvement in relation to the GC (P<0.01)
|
No follow-up
|
|
Mao, L. et al., 2016
[39]
|
China
|
98
|
Stroke
|
Prospective
|
VFSS; SSA
|
GI - TC and acupuncture GC - TC
|
20 sessions/30 minutes - 5 times a week
|
VFSS and SSA GI improvement in relation to the GC (P=0.007 and P=0.007)
|
No follow-up
|
|
Chen, L. et al., 2016
[40]
|
China
|
250
|
Stroke
|
Randomized; Double-blind; Controlled
|
NIHSS; VFSS; SSA
|
GI - TC and acupuncture GC - TC
|
18 sessions/30 minutes - 6 times a week
|
GI improvement in relation to the GC: NIHSS (p < 0.001), VFSS (p < 0.001) and SSA
(p =0.037)
|
1, 3, 7 weeks
|
VFSS: Videofluoroscopy; DOHME: Duration of Hyoid Maximum Elevation; DOHAME: Duration
of Hyoid Maximum Anterior Excursion HME: Hyoid Maximum Elevation; HMAE: Hyoid Maximum
Anterior Excursion; UES: Upper Esophageal Sphincter; EMG: Surface Electromyography;
SSA: Standardized Swallow Assessment; NIHSS: NIH Stroke Scale; DOSS: Dysphagia Outcome
and Severity Scale; GI: Intervention group; GC: Control group; TC: Conventional Therapy.
Acupuncture
Acupuncture is a simple, inexpensive, primary medical procedure that has been widely
used in China and other parts of East Asia for many years. Needles are inserted at
acupuncture points to produce a "qi" response in which the patient feels pain or heaviness
in the area around the needle[38].
Xia et al.[38] evaluated the effect of acupuncture on swallowing function in patients with dysphagia
after stroke. The intervention group received standard therapy and acupuncture and
the control group received only standard therapy. Although it was concluded that acupuncture
combined with conventional swallowing therapy may be beneficial, the study had a significant
limitation due to the lack of a control group for acupuncture alone. In addition,
short-term evaluation and lack of follow-up were factors that prevented the evaluation
of a long-term therapeutic effect.
Another study found that acupuncture combined with swallowing therapy can improve
the swallowing function in post-stroke patients[39]. The study conducted by Mao et al.[39] proved that acupuncture in combination with standard swallowing therapy was effective
for post-stroke dysphagia, corroborating the findings presented by Xia et al.[38]. However, several limitations prevent this conclusion from being generalized, so
it cannot be said that acupuncture alone is capable of providing a high level of rehabilitation.
A similar study was conducted by Chen et al.[40]. This study has shown that acupuncture is safe and has several additional effects
in improving neurological deficits, swallowing disorder, cognitive impairment, and
lower limb function. However, no significant improvement in the upper limb function
was observed during this short-term study.
A summary of the results in the articles using acupuncture techniques is shown in
[Table 5].
Cervical isometric exercises
Cervical isometric exercises to improve dysphagia and cervical spine malalignment
was applied in 70 patients in a randomized controlled trial. The exercises were carried
out in all 4 directions (by placing their hand or the hand of their personal assistant
on their head and contracting their neck muscles under forward-backward-sideward resistance).
Swallowing was improved in the experimental group compared to the control group[44].
DISCUSSION
The purpose of this review was to assess recently studied therapies for dysphagia
rehabilitation. Numerous studies of a wide range of interventions were included. However,
they differed not only in terms of the therapy conducted, but also in terms of sample
size, outcome measurement methods, intervention times and follow-up time. These differences
presented a challenge to combine and summarize the results, and to compare and define
which is the most effective treatment for post-stroke dysphagia.
Considering that this neuromuscular process is complex and involves dozens of muscles
and six pairs of cranial nerves, there are many symptoms that affect a dysphagic individual.
Therefore, it is difficult to elaborate a single exercise protocol (in the case of
conventional therapy) that will effectively improve the condition. Scientific evidence
highlights the benefits of conventional therapy in improving the swallowing pattern
of a dysphagic individual. However, the search for new therapeutic techniques that
can increase this benefit is constant.
Studies on the efficacy of therapeutic interventions for rehabilitation of adult patients
with dysphagia after stroke are still limited. Most techniques are used in combination
with conventional therapies, which makes measuring the efficacy of other techniques
alone inconclusive. Among the reviewed therapies, electrotherapy, associated or not
with conventional therapy, was the most frequently used. In both cases, it proved
to be a method with significant results for the rehabilitation of dysphagia. Similarly,
neuromodulation applied in areas such as the motor cortex of the tongue and pharynx,
as mentioned in the included studies, also lead to an improvement in the swallowing
pattern. Tongue pressure resistance exercises and precision training, the Shaker exercise
and acupuncture also showed significant results for rehabilitation.
Neuromodulation is not a possibility in many healthcare institutions that admit patients
with acute stroke, making this therapy technique difficult to access, especially for
low-income patients. An advantage of the SE is that it is a non-invasive therapy,
does requires no any additional cost or equipment and can be easily performed at the
bedside with the assistance of a caregiver[37]. However, a limitation of the SE is that coordinated movements and resistance are
required, and many patients in the acute phase of stroke do not have this capability.
Pharyngeal electrical stimulation (PES) is also considered a promising treatment for
dysphagia after stroke. However, the results of the studies included in this review
are contrary to this. With regard to tongue pressure resistance exercise, it is important
to emphasize that isometric and isotonic exercises are commonly used in conventional
therapy to improve the amplitude and increase the force of tongue movements. The tongue
is an essential organ for the proper functioning of the safe swallowing process.
The majority of the studies used videofluoroscopy of swallowing as the gold standard
evaluation method. The method allows the swallowing dynamics to be visualized from
the preparatory phase to the opening of the upper esophageal sphincter. It is also
possible to identify the tracheal aspiration, laryngeal penetration, and oral and
pharyngeal residues, which is important for a detailed analysis of the various changes
that may occur in a dysphagia disorder of any degree. Videofluoroscopy helps in selecting
the most appropriate technique and therapeutic plan to improve the swallowing pattern.
Ideally, this examination should be available in all health centers admitting patients
in the acute phase of stroke.
In conclusion, this review highlights the main interventions for dysphagia of patients
after stroke. Among the techniques used, conventional therapy remains the best strategy,
achieving positive results alone or combined with various rehabilitation therapies.
However, greater consistency between science and clinical practice is needed to allow
a comparison between different techniques. Dysphagia is a potentially treatable symptom
in post-stroke patients and deserves attention, and its treatment may increase patients’
quality of life. In addition, even if conventional therapy is empirically considered
essential for the rehabilitation process, its effect would be strengthened by studies
that scientifically support this technique.
