Restless Legs Syndrome - Movement Disorders - Physical Exercise - Sleep Wake Disorders
INTRODUCTION
Sleep-Related Movement Disorders (SRMD) is characterized by simple, often stereotyped
movements related to sleep[1]. Among them, we can highlight the Restless Legs Syndrome (RLS) and Periodic Leg
Movement (PLM).
The RLS is a common neurological movement disorder characterized by motor restlessness
resulting in an uncontrolled urge to move the mostly the legs, causing difficulty
in initiating sleep[2]
,
[3]. Already the PLM is characterized by involuntary movements caused by specific muscle
contractions that occur during sleep causing nocturnal awakenings[4]
,
[5].
Most people with RLS also have Periodic Legs Movements[6]. Some studies demonstrate variability in the prevalence of these sleep disorders.
According to Kuchukhidze et al.but unknown in Georgia. This pilot study aimed to assess
RLS prevalence in a focused Georgian population. Methods: An RLS epidemiological questionnaire
[Allen et al.: Sleep Med 2003;4:101-119] was filled out by patients in five primary
healthcare centers in two Georgian cities between March and September 2006. Additionally,
questions related to RLS symptom onset, family history, treatment, sleep disturbance
and history of iron deficiency were included. RLS diagnosis was based on an expert
interview and an epidemiological questionnaire for RLS. Results: The total number
of respondents was 115 (75% women/25% men[7] prevalence in different proportions was explained by various studies, methods, genetic
predisposition, ethnicity and environment factors, and according to Montplaisir et
al.[6], the symptoms often start in childhood and adolescence.
Shin et al.[8] found that the prevalence of PLMS in Korean patients it was lower than that reported
in patients from Western countries. According to Phillips et al.often accompanied
by daytime behavioral problems. Treatment for this condition is available, but it
is suspected that most instances of RLS remain undiagnosed. The goal of this investigation
was to assess the prevalence and health status correlates of restless legs symptoms
(hereinafter referred to as restless legs[9] 3% of participants aged 18 to 29 years, 10% of those aged 30 to 79 years and 19%
of those 80 years old related experiencing RLS five or more nights per month. The
prevalence estimated by Ohayon et al.RLS has been studied as: 1[3] ranged between 1.9% and 15% in four different cases in the general adult population,
and the prevalence of RLS is higher in women than in men.
The main causes of RLS are passing through transmission, change in brain iron homeostasis,
and related to this change, a dopaminergic dysfunction, glutamatergic and adenosinérgica[10]
-
[14]. The alterations found in studies related to these systems are: increased levels
of presynaptic dopamine, decreased dopamine receptor D2[12], increased activity of tyrosine hiroxilase[11], increased glutamate[15] and reduces adenosine activity[14]. However, these changes are not fully understood, and little is known about the
impact of physical exercise on these mechanisms altered by RLS and PLM.
Different treatments are proposed to reduce the symptoms of RLS and PLM index. Winkelman
et al.[16] describe the significant benefits of dopamine and opioid agonists, vitamins C and
E, and iron treatment. Alternative types of non-pharmacologic therapy are also suggested
like sleep hygiene, lifestyle interventions, yoga, acupuncture, near-infrared light,
melatonin, vitamins, cold shower, brief walk before bedtime and Chinese herbs to improve
RLS symptoms and PLM index[17]. However, it seems that the physical exercise has been more efficient among the
alternatives treatments[18]
-
[21]. Additionally, several studies performed with animal models elucidated the mechanisms
and anticipated benefits of the physical exercise in the SRMD symptoms.
Thus, the purpose of this narrative review is clear the benefits of physical exercise
and your indication to improve RLS symptoms and PLM index and demonstrate different
methods and types of physical exercise, impact and duration and better time of the
day to practice.
To perform this review, the key words: restless legs syndrome, periodic leg movement,
physical exercise, non-pharmacologic treatment were used in the Pubmed platform ([Table 1]).
Table 1
Studies Details.
|
Study Details
|
N Validated
|
Experimental Model
|
Patient Detail (Humans)
|
Period and Type of Exercise
|
|
de Mello et al. (2002)
|
12
|
None
|
Complete spinal cord injury between T7 and T12
|
Chronic
Aerobic Exercise
|
|
de Mello et al. (2004)
|
13
|
None
|
Complete spinal cord injury between T7 and T12
|
Chronic
Aerobic Exercise
|
|
Aukerman et al. (2006)
|
41
|
None
|
Adults with RLS
|
Chronic
Aerobic and Resistance Exercise
|
|
Sakkas et al. (2008)
|
14
|
None
|
Patients on hemodialysis
|
Chronic Aerobic Exercise
|
|
Esteves et al. (2009)
|
22
|
None
|
Patients with PLM
|
Acute/Chronic
Aerobic Exercise
|
|
Giannaki et al. (2010)
|
18
|
None
|
Patients on hemodialysis
|
Acute
Aerobic and Resistance Exercise
|
|
Esteves et al. (2011)
|
11
|
None
|
Adults with RLS
|
Chronic
Aerobic Exercise
|
|
Cavagnolli et al. (2013)
|
16
|
None
|
Patients with PLM
|
Acute
Aerobic Exercise
|
|
Esteves et al. (2013)
|
27
|
SHRs and Wistar
|
None
|
Chronic
Aerobic Exercise
|
|
Giannaki et al. (2013)
|
24
|
None
|
Patients with uraemic restless legs syndrome
|
Chronic
Aerobic Exercise
|
|
Giannaki et al. (2013)
|
32
|
None
|
Hemodialysis patients with restless legs syndrome
|
Chronic
Aerobic Exercise
|
|
Mortazavi et al. (2013)
|
26
|
None
|
End stage renal disease patients
|
Chronic
Aerobic Exercise
|
|
Simon et al. (2013)
|
25
|
None
|
Patients accurately complaining of Exercise Intolerance
|
Chronic
Aerobic and Resistance Exercise
|
|
Esteves et al. (2014)
|
221
|
None
|
Adult sedentary volunteers
|
Acute
Aerobic and Resistance Exercise
|
|
Giannaki et al. (2015)
|
14
|
None
|
Patients with RLS on dialysis
|
Chronic
Aerobic Exercise
|
|
Aliasgharpour et al. (2016)
|
33
|
None
|
Patients on hemodialysis
|
Chronic
Stretching Exercises
|
|
Esteves et al. (2016)
|
48
|
Wistar strain (A11 dopaminergic nuclei lesion with 6-OHDA)
|
None
|
Chronic
Aerobic Exercise
|
|
Frank et al. (2016)
|
80
|
Male NWRs and SHRs
|
None
|
Chronic
Aerobic Exercise
|
ACUTE PHYSICAL EXERCISE
Human
Some studies have evaluated whether only one exercise session would be enough to minimize
the symptoms of RLS/PLM.
Esteves et al.[21] conducted a study with sedentary individuals diagnosed with PLM to evaluate the
effects of a single maximum effort test (MET) on their sleep patterns. The individuals
classified as mild PLM presented improvements with a significant difference in the
wake after sleep onset (WASO), REM sleep and PLM index parameters when compared before
and after the MTE session. However, the results of the volunteers classified as moderate
and severe PLM showed no significant difference, but a trend of improvement was found
in all parameters. Also, a significant negative correlation was found between PLM
index and β-endorphin release, that is a single exercise session caused an increase
in β-endorphin values and a decrease in PLM index.
Cavagnolli et al.[22] obtained similar results with one of its objectives being to evaluate the influence
of a single MET session on the sleep pattern of men diagnosed with PLM and the relationship
with a density of the dopamine transporter (DAT) in the putamen. Their results demonstrated
a significant increase in stage 1 of NREM (non-rapid eyes movement) sleep and a decrease
in PLM index values of participants with PLM after MET. The group of patients with
PLM showed lower numbers of DAT density against the control group, but a single exercise
session was not enough to alter these values.
Giannaki et al.[23] showed essential results in hemodialysis patients diagnosed with RLS/PLM. Volunteers
were divided into three groups: two of them performed a physical exercise session
(light and heavy), and the third group did not perform any type of exercise. The groups
that performed the exercise showed significant differences in PLM index after the
workout when compared to the group without exercise.
Esteves et al.[24] conducted a study with individuals with and without PLM, where participants were
divided between a single resistance exercise session, aerobic exercise, and interval
exercise. Also, participants were divided by practice time (morning, afternoon or
evening). The results showed that, regardless of the type of exercise, all participants
(with and without PLM) who practiced at night had a decrease in sleep latency in the
night after the exercise session. The group with and without PLM, regardless of time
and type of exercise, had an increase in REM (rapid eye movement) sleep on the night
after exercise. The PLM group did not improve PLM index.
A study with spinal cord injuries (T7- T12), by de Mello et al.[25], showed that after a test of incremental maximum effort session, participants had
significant improvements in total sleep time (TST), REM sleep time, number of awakenings
and the PLM index.
Facing with the results of studies with acute exercise used in this review, it was
revealed that all had results with improvements in sleep, such as increased total
sleep time or even the reduction of periodic leg movements. Only two studies performed
physiological analyzes. The study Esteves et al.[21] found correlation of PLM decrease with the increase of beta-endorphin levels, where
beta-endorphin is a neurotransmitter found in the nervous system responsible for feelings
of relaxation and well-being 45, can then have helped in improving the symptoms of
this disorder of sleep-related movement. In the other study conducted by Cavagnolli
et al.[22], DAT analysis was performed, which is the dopamine transporter responsible for the
reuptake of dopamine in the synaptic cleft for the presynaptic, and a reduction of
this transporter was found in patients with RLS, but without alteration after exercise.
DAT alterations have already been found in other studies[12]
,
[13] in patients with RLS; however, the role of DAT in physical exercise and in the improvement
of symptoms caused by it is still unknown.
Until the moment, there are few studies in patients SPI and acute physical exercise,
especially with physiological and molecular analysis to help understand the mechanisms
responsible for the improvement of RLS symptoms and PLM.
CHRONIC PHYSICAL EXERCISE
CHRONIC PHYSICAL EXERCISE
Animal Model
Chronic physical exercise has been observed as a possible treatment to minimize the
symptoms of RLS and PLM index. In this context, animal models are essential to improve
means and methods of treatment, to search new lines of investigations and different
protocol.
Esteves et al.[26] conducted a study in Spontaneously Hypertensive Rats (SHR), considered a RLS animal
model. The sleep patterns were based on the simultaneous analyses of electrocorticographic
and limb electromyographic signals. As a form of acute pharmacological manipulation,
the animals were treated with pramipexole; as a non- pharmacological treatment, the
animals were subjected to four weeks of physical exercise. The results showed that
the number of limb movement (LM) was reduced when the animals were submitted to a
physical exercise treatment (five sessions per week during four weeks), and pramipexole
treatment significantly attenuated the increased wakefulness presented by the SHRs
before the beginning of the predominant sleep period (light period) when compared
with the normotensive Wistar rats (NWR) group.
Frank et al.[27] analyzed the physical exercise and pharmacological treatment (enalapril) for an
animal model of SRMD (SHR). The results showed that physical exercise (8 weeks) and
enalapril conferred protection for both hypertension and the observed behavioral changes.
In addition, these treatments led to changes in dopaminergic signaling in the striatal
region (D2 receptor, TH, and DAT). The locomotor activity was evaluated in an open
field test, and blood pressure was assessed by tail plethysmography.
In addition, these treatments carried out separately led to changes in striatal dopaminergic
signaling in the region, increasing levels of D2 receptor, DAT TH and analyzed by
western blotting. The authors believe that training and enalapril regulate somehow
dopaminergic dysfunction, and that this regulation may be due to changes in D2, TH
and DAT leading to increased dopamine in the striatum.
Esteves et al.[28] found that the number of Limb Movements in Wistar rats with an A11 lesion that had
performed physical exercise (5 x per week - moderate intensity) reduced substantially
with six weeks of treadmill physical exercise. The sleep of was verified by Polysomnographic
and the physical exercise was performed before and after the injury in the A11 nuclei.
The findings consistently demonstrate that non-pharmacological manipulations had a
beneficial effect on the symptoms of SRMD.
Animal studies have shown that physical exercise causes changes in the dopaminergic
system, such as increase in dopamine, increase of D2 and decrease of DAT[29]
,
[30]. However, there are few studies with animal models for movement disorders related
to sleep, physical exercise and dopaminergic system, making it difficult to understand
the possible mechanisms associated with the improvement of symptoms by training.
Human
The chronic physical exercise is considerate a positive agent for treatment of several
diseases. This function has also considered when analyzing RLS and PLM.
In the study conducted by de Mello et al.[18], the researchers found decreased results on PLM/h when submitted male individuals
with complete spinal cord injury between T7 and T12 to execute a physical training
program for 44 days using an arm crank ergometer.
Two years later de Mello et al.[19] verified one more time the benefits of physical exercise in patients with spinal
cord injury. All volunteers were submitted to the administration of LDOPA and physical
training. L-DOPA (200 mg) in combination with benserazide chloride (50 mg), or placebo
was administered for 30 days, 1 h prior to sleeping time. This period of drug administration
was followed by a 15-day washout period to physical exercise. The authors of both
studies associate the decrease of PLM with the release of beta-endorphin and dopamine
from exercise, where beta-endorphin interacts with opioid receptors in the brain,
and the increase in dopamine results in a neurochemical balance that prevents the
occurrence of these movements during sleep. The result of the increase in dopamine
caused by exercise seems to be the same caused by dopaminergic agonists, used as pharmacological
treatment of RLS and PLM.
Aukerman et al.[31] showed in humans a randomized controlled trial of 12 weeks consisted of resistance
exercises and aerobic exercise performed three times a week, and the exercise group
had a significant improvement in symptoms compared with the control group according
to IRLSSG scale. The authors report the importance of further studies with these sleep-related
movement disorders and physical exercise, since the effects caused are promising,
considering the numerous advantages that are known about exercise in sleep and in
the cardiovascular, metabolic and musculoskeletal systems.
In a study conducted by Esteves et al.[21], 11 sedentary volunteers were submitted to the chronic physical exercise (72 sessions
of aerobic training for six months), the results showed a reduction in sleep latency,
increasing in sleep efficiency and REM sleep and a decrease of PLM index. The authors
suggested that physical exercise may be a plausible alternative to pharmacological
treatment or may be used as a complement in severe cases of PLM. Another study[32] conducted by the same group of researchers, using the IRLSS questionnaire, demonstrated
that aerobic physical exercise performed at the intensity of the anaerobic ventilatory
threshold was effective in reducing the symptoms of RLS after 36 sessions of aerobic
physical exercise.
Several studies were performed with hemodialysis patients. Sakkas et al.[2] realized a longitudinal study and the results revealed 16-week aerobic training
improves RLS symptoms, functionality and exercise capacity, suggesting a significant
improvement in the quality of life of patients with dialysis RLS. Mortazavi et al.[33] developed a study where twenty-six patients were included and randomly divided into
control group (13 patients) and exercise group (13 patients). Aerobic exercise was
used during their hemodialysis for 16 weeks, and the patients pedaled three times
per week during 30 minutes. At the end of the study, researchers suggested using aerobic
exercise for improving signs of RLS.
Giannaki et al.[34] conducted a study during six months with three times per week of cycling in patients
with uremic restless legs syndrome, and the results showed that physical exercise
was effective in reducing the symptom of the syndrome in 46%. According to authors,
6-months intradialytic progressive exercise training program has a useful approach
to reduce RLS symptom severity in hemodialysis patients. In the same year, Giannaki
et al.[35] found one more time that 6-months exercise training regimen was effective at a 6-month
low dosage dopamine agonist treatment in reducing restless legs syndrome and improving
depression score in uremic patients.
Aliasgharpour et al.[36] conducted a study with 33 hemodialysis patients from the hemodialysis of Tehran
Hospital. They divided the patients between the control group and intervention group,
and the results showed that stretching exercises on legs during hemodialysis three
times per week over eight weeks could help alleviate the severity of RLS symptoms.
Giannaki et al.[37] did a study with patients with RLS being on hemodialysis and found that the combination
of low-dose ropinirole and aerobic exercise training can reduce RLS symptoms as well
as the combination of aerobic exercise with placebo. One more time the importance
and the efect of physical exercise proved to reduce the symptoms of SRMD.
The results of the cited studies of chronic exercise were diverse and different. This
is due to the use of different methodologies and populations (sometimes even with
other pathologies) and by different exercise protocols. However, in general, all studies
have shown physical exercise as a tool to improve the symptoms of RLS and PLM.
CONCLUSION
The efficacy of physical exercise was evaluated in 19 studies (human and animal model)
demonstrating that the severity of RLS/PLM symptoms can be significantly ameliorated
by this non-pharmacologic treatment.
There are few studies that analyzed mechanisms involved in improving the symptoms
of RLS and PLM index with acute and chronic physical exercise. Only one human study
demonstrated the relationship of beta-endorphin release in aerobic physical exercises
with the reduction of PLM index[21]. The role of the opioid and dopaminergic system in the pathophysiology of RLS/PLM
is not fully understood in the literature however treatment with opioids and dopamine
resulted in a satisfactory improvement of RLS symptoms/PLM severity[38]
,
[39]. Interestingly, in a study carried out with animal models (SHR) it was verified
changes in dopaminergic signaling in the striatal region (D2 receptor, TH, and DAT)
after eight weeks of treadmill physical exercise[27]. Studies in animal models bring us new perspectives of further investigations related
to the physiological mechanisms, where it is possible to analyze the relation of the
expression of proteins that are involved in the pathophysiology of this SRMD.
In addition, the evidence is lacking about the efficacy of resistance and combined
exercises in the RLS/PLM symptoms. We found only two studies that demonstrated the
effectiveness of combined physical exercise[24]
,
[31] and no studies had demonstrated the effects of resistive physical exercise on the
reduction of RLS/PLM symptoms.
Another critical point is the relation of physical exercise intensity and the improvement
of SRMD symptoms. A review by Hening[40] demonstrated that patients experience an increase of symptoms later in the evening,
after extensive exercise during the day. However, three studies reported that after
the single maximum effort test (MET)[21]
,
[22], or heavy exercise - cycling for 45 minutes with a resistance set at 60%[26], showed that patients presented reduction of the PLM index.
In this context, it should be noted that there is still little research being conducted
to verify physical exercise treatment effects on RLS/PLM. Some results showed that
this relationship is positive and promising. Nevertheless, there is a lack of studies
with other populations that present RLS / PLM, such as pregnant women, children, and
even secondary RLS, also, to it is essential to tailor physical exercise to the need
of each patient. In addition, new mechanisms (dopaminergic, glutamatergic and adenosinergic
alterations) are being associated with these disorders, but the findings are new and
not fully understood, and little is known about their relationship with physical exercise
in the improvement of RLS symptoms and PLM.
Thus, future studies are needed to clarify that molecular mechanisms are involved
in the relationship of physical exercise in improving the SRMD symptoms, as well as
further clarification about types of physical exercise, duration and better time of
the day to practice.
