Respiratory-related Leg Movements Research Articles

Obstructive sleep apnea and periodic limb movement in children: is there really an association?

PurposePeriodic limb movements (PLMs) can be found isolated or related to other sleep disorders, as Obstructive Sleep Apnea (OSA). Nevertheless, this association was described before the proposal for modification of the World Association of Sleep Medicine (WASM), which incorporated major changes modifying the definition of respiratory-related leg movements (RRLM) so that the relationship between OSA and PLM could be affected. MethodsA total of 131 PSG were studied (children with ages from 5 to 12 years old), all referred because of a suspicion of sleep-disordered breathing (65 children were diagnosed of OSA, and 66 presented snoring but no sleep apnea). Leg movements were manually scored according to both 2006 and 2016 WASM/IRLSSG criteria. ResultsAccording to 2006 WASM rules, statistical differences were found, not only for PLM index (p 0.002), but all indexes. Nevertheless, according to new 2016 WASM rules, no statistical differences were found for PLM index (p 0.677), non-REM PLM index (p 0.299), REM PLM index (P 0.511) or PLM with arousal index (p 0.180), between OSA and non-OSA group. Positive correlation between PLM and RRLM have been found with both set of rules. The percentage of children with PLM>5/h is higher when using the prior PLM scoring criteria developed in 2006 (38.93%) versus the updated PLM scoring criteria (19.08%). ConclusionThe lack of association when using the new WASM/IRLSSG scoring rules together with the absence of a previous clear etiopathology explanation may suggest that the association between OSA and PLM might be indeed overestimated and that, perhaps, it really did not exist.

Respiratory-Related Leg Movements of Sleep Are Associated With Serotonergic Antidepressants But Not Bupropion.

Respiratory-related leg movements (RRLMs) may contribute to the cardiovascular risk associated with obstructive sleep apnea (OSA). Selective serotonin reuptake inhibitors (SSRIs), but not bupropion, increase periodic leg movements in sleep. This study examines whether patients with OSA using SSRIs have more RRLMs than those taking bupropion or no antidepressant. Patients with an apnea-hypopnea index (AHI) of at least 10 events/h during a full-night diagnostic study or split-night study, who were taking bupropion (n = 32), an SSRI (n = 31), or no antidepressant (n = 31), were selected from a database of prestudy questionnaires. RRLMs were scored according to World Association of Sleep Medicine 2016 standards. Patients using SSRIs had significantly greater overall RRLM% (defined as the percentage of respiratory events associated with a leg movement, including apneas, hypopneas, and respiratory effort-related arousals), RRLM index, and periodic limb movement index relative to patients using bupropion and control patients. The difference between the RRLM% in the SSRI and bupropion groups was limited to patients undergoing split-night studies, and that of the SSRI and control groups was limited to patients undergoing full-night diagnostic studies. The greater number of RRLMs and PLMs in the SSRI group may contribute to treatment-emergent insomnia often seen with SSRI use. Fragmented sleep and elevated autonomic nervous system activation associated with increased RRLMs in patients with OSA taking SSRIs might also limit the tolerability of antidepressant treatment, as well as increase the risk for cardiovascular disease.

Sleep-Related Leg Movements in Patients with Transient Ischemic Attack and Controls

Background: Periodic leg movements during sleep (PLMS) have been associated with an increased risk for cardiovascular diseases and there is a high prevalence of PLMS found in patients with obstructive sleep apnea syndrome (OSAS). We evaluated patients with transient ischemic attack (TIA) for PLMS and respiratory related leg movements (RRLM), versus a control group without TIA. Methods: Twenty-five patients with TIA and 34 patients with no vascular diagnosis were referred for polysomnography. Diagnosis of PLMS was made if the periodic leg movement index (PLMI) was ≥5 and clinical significant as PLMI ≥15. Results: There was no significant difference in PLMI ≥5 and ≥15 between patients with and without TIA. In the absence of OSAS, 2 out of 5 TIA patients (40%) had a PLMI ≥15 compared to 1 of the 19 patients without TIA (5%; p = 0.037). There was no increase in RRLMs when OSAS was present. Conclusions: TIA patients did not have higher PLMI compared to controls, and in the presence of OSAS, there was no increase in RRLMs compared to patients without TIA. In selective patients, PLMS could be associated with cardiovascular diseases, since PLMS was clinically more often found in the TIA group without OSAS.

Respiratory-related leg movements are associated with serotonergic antidepressants but not bupropion

Respiratory-related leg movements are associated with serotonergic antidepressants but not bupropion

Prevalence and associations of respiratory-related leg movements: the MrOS sleep study

ObjectivesObstructive respiratory events often terminate with an associated respiratory-related leg movement (RRLM). Such leg movements are not scored as periodic leg movements (periodic limb movements during sleep, PLMS), although the criteria for distinguishing RRLM from PLMS differ between the American Academy of Sleep Medicine (AASM) and the World Association of Sleep Medicine (WASM)/ International Restless Legs Syndrome Study Group (IRLSSG) scoring manuals. Such LMs may be clinically significant in patients with obstructive sleep apnea (OSA). The prevalence and correlation of RRLM in men with OSA were examined. MethodsA case–control sample of 575 men was selected from all men with an apnea–hypopnea index (AHI, ≥3% desaturation criteria) ≥ 10 and good data from piezoelectric leg movement sensors at the first in-home sleep study in the MrOS cohort (mean age = 76.8 years). Sleep studies were rescored for RRLMs using five different RRLM definitions varying in both latency of leg movement onset from respiratory event termination and duration of the leg movement. The quartile of RRLM% (the number of RRLM/the number of hypopneas + apneas) was derived. ResultsThe nonparametric densities of RRLM% were most influenced by alterations in the latency rather than the duration of the LM. The most liberal RRLM definition (latency 0–5 s, duration 0.5–10 s) led to a median RRLM% of 23.4 (interquartile range 12.41, 37.12) in this sample. The average AHI and arousal index increased as the quartile of RRLM% increased, as well as the prevalence of chronic obstructive pulmonary disease (COPD). The prevalence of those with a history of hypertension decreased as RRLM% increased. The non-Caucasian race was associated with lower RRLM%. ConclusionWithin an elderly sample with moderate to severe OSA, piezoelectric-defined RRLM% is associated with a number of sleep-related and demographic factors. Further study of the optimal definition, predictors, and consequences of RRLM is warranted.

An Evidence-Based Recommendation for a New Definition of Respiratory-Related Leg Movements

Current sleep scoring rules exclude leg movements that occur near respiratory events from being scored as periodic leg movements during sleep (PLMS) but differ in whether they exclude leg movements occurring at the end (WASM/ IRLSSG) or during a respiratory event (AASM). The aim of the present study was to describe the distribution of leg movements in relation to respiratory events and to contribute to an evidence-based rule for the identification and scoring of respiratory-related leg movements (RRLMs). Retrospective chart review and analysis of polysomnographic recordings. Clinical sleep laboratory. 64 patients with polysomnographic recordings between January 2010 and July 2011, aged 18 to 75 years, with AHI >20, ODI >10, more than 50% of apneas being obstructive, >15 leg movements of any type per hour of sleep, no more than 20% of total sleep time with artifacts and no medical condition or medication that could influence leg movements or respiratory disturbances. None. Back-averaging of leg movement activity (LMA) with respect to respiratory events revealed that LMA was present shortly before the end of the respiratory events, but occurred mostly following respiratory events with peak onset of LMA 2.5 s after respiratory event termination. Increased LMA before the beginning of the respiratory event consisted mainly of the tail of LMA after the end of the previous respiratory event. Change-point analysis indicated that LMA was increased over an interval of -2.0 s to +10.25 s around the end of respiratory events. Changing the definition of RRLMs had a significant influence on PLMS counts. The number of patients with obstructive sleep apnea (OSA) with PLMS index >15 was 80% when considering the WASM/ IRLSSG definition, 67% for the AASM criteria, and 41% when based on the interval identified by change-point analysis (-2.0 to 10.25 s). Leg movements are not augmented at the beginning or middle of respiratory events but are increased around the end of respiratory events over a period significantly longer than specified in the AASM and the WASM/ IRLSSG rules. Both rules underestimate the number of RRLMs and thus overestimate the number of PLMS in patients with OSA.

Respiratory-Related Leg Movements and Their Relationship with Periodic Leg Movements During Sleep

To describe the time structure of leg movements (LM) in obstructive sleep apnea (OSA) syndrome, in order to advance understanding of their clinical significance. Sleep Research Centre, Oasi Institute (IRCCS), Troina, Italy. Sleep laboratory. Eighty-four patients (16 females, 68 males, mean age 55.1 y, range 29-74 y). Respiratory-related leg movements (RRLM) and those unrelated to respiratory events (NRLM) were examined within diagnostic polysomnograms alone and together for their distributions within the sleep period and for their periodicity. Patients with OSA and RRLM exhibited more periodic leg movements in sleep (PLMS), particularly in NREM sleep. A gradual decrease in number of NRLM across the sleep period was observed in patients with RRLM. This pattern was less clear for RRLM. Frequency histograms of intermovement intervals of all LMs in patients with RRLM showed a prominent first peak at 4 sec, and a second peak at approximately 24 sec coincident with that of PLMS occurring in the absence of OSA. A third peak of lowest amplitude was the broadest with a maximum at approximately 42 sec. In patients lacking RRLM, NRLM were evident with a single peak at 2-4 sec. A stepwise linear regression analysis showed that, after controlling for a diagnosis of restless legs syndrome and apnea-hypopnea index, PLMS remained significantly associated with RRLM. The time structure of leg movements occurring in conjunction with respiratory events exhibit features of periodic leg movements in sleep occurring alone, only with a different and longer period. This brings into question the validity, both biologic and clinical, of scoring conventions with their a priori exclusion from consideration as periodic leg movements in sleep.

Respiratory-related leg movements and periodic leg movements during sleep

Introduction The aim of the study was to describe the time structure of leg movements (LM) in obstructive sleep apnea syndrome (OSAS), in order to add new knowledge to the understanding of their clinical significance. Materials and methods Eighty-four patients (16 females, 68 males, mean age 55.1 years, range 29–74) were recruited. All subjects underwent full-night polysomnography and the leg motor pattern was evaluated by means of advanced tools of analysis particularly able to detect and describe LM time structure (periodicity and distribution). In particular, respiratory-related LM (RRLM) were separated from those not related to respiratory events (NRLM). Results OSAS patients with RRLM had leg movement parameters generally higher subjects without RRLM; the effect was strong for the periodic LM during sleep (PLMS) index, in particular during NREM sleep. The NRLM intermovement interval distribution histogram of patients with RRLM showed a prominent first peak at 4 s, followed by another at approximately 24 s (corresponding to typical PLMS). In the same group, RRLM showed a single wide lower peak with a maximum at about 42 s. In patients without RRLM, NRLM were evident with a single peak at 2–4 s. Patients with RRLM showed a gradually decreasing number of NRLM, from the first to the last hours of sleep; this pattern was less clear for RRLM. A stepwise linear regression analysis showed that, even when controlling for RLS status and AHI, PLMS were highly significantly associated with RRLM. Conclusion This study shows that RRLM might be part of the true PLMS because they cluster clearly in the patients who also have typical PLMS not correlated with the respiratory events.

Respiratory-related leg movements: what is the evidence behind the rules?

Current sleep scoring rules exclude leg movements that occur near respiratory events from the scoring of periodic leg movements during sleep. While the AASM rules exclude leg movements that occur during a period of 0.5 s preceding to 0.5 s following an apnea or hypopnea, the WASM/IRLSSG rules consider only leg movements during 0.5 s before to 0.5 s after the end of an apnea or hypopnea. So far, the distribution of leg movements in relation to respiratory events is unknown and the aim of the present study was therefore to describe this distribution and contribute to the question whether there is evidence that favors one over the other of the two scoring rules Retrospective chart review and analysis of polysomnographic recordings. We included all patients with polysomnographic recordings between January 2010 and July 2011, aged 18 to 75 years, and AHI > 20, ODI > 10, more than 50% of apneas being obstructive, more than 15 leg movements/hour of sleep, no more than 20% of total sleep time with artifacts and no medical condition or medication that could influence leg movements or respiratory disturbances. Onset and duration of all leg movements (0.5–10 s), apneas, and hypopneas during sleep were extracted from the polysomnographic recordings. Polysomnographic recordings of 64 patients (55 male, 56 Â ± 11 years) were included in the analysis. Back-averaging of leg movement activity (LMA) with respect to the beginning, the middle, and the end of respiratory events revealed no indication that LMA was increased in the middle of respiratory events. Increased LMA before the beginning of the respiratory event consisted mainly of the longer tail of LMA after the end of the previous respiratory event. Importantly, LMA increased shortly before the end of the respiratory events, with peak onset of LMA 2.5 s after the end of the respiratory event. Our results showed that leg movements are not augmented at the beginning or middle of respiratory events but are increased around the end of respiratory events over a period significantly longer than specified in the AASM and the WASM/IRLSSG rules. Both rules therefore underestimate the number of respiratory leg movements in patients with obstructive sleep apnea.

P6. Leg movements during sleep in patients with obstructive sleep apnea

Introduction Leg movements (LMs) during sleep are frequent in patients with obstructive sleep apnea syndrome (OSAS). Current giudelines distinguish LMs associated with respiratory events from periodic leg movements (PLM), excluding the former when assessing PLM. The aim of the current study was to describe the time structure of global LMs, the relationship between PLM and respiratory related movements (RRM), and the relationship between RRMs and the main respiratory parameters in patients with OSAS. Methods Retrospective chart review of all patients visiting the sleep lab of the Sleep and Epilepsy Center of the Neurocenter of Southern Switzerland between January 2010 and July 2011, which (1) had undergone full polysomnographic recording, (2) were between 18 and 75 years, (3) had an apnea-hypopnea index >20 and oxygen desaturation index >10 with more than half of all apneas being obstructive and (4) had >15 LMs/h (leg movements index (LMI)). We excluded patients with (1) any medical condition, that could influence LMs or apnea (such as narcolepsy, parasomnias, neurological disorders, renal or heart failure), (2) medication known or suspected to affect LMs (e.g. dopaminergic, benzodiazepines, antidepressants, etc.) and (3) recordings with artefacts of tibialis anterior or flow for more than 20% of the total sleep time. All LMs were scored and classifed as RRM, PLM, or isolated LMs according to WASM-IRLSSG criteria (2006). Intermovement intervals of LMs were analysed with distribution mixture analysis and differences between subjects with and without respiratory-related LMs were explored with non-parameteric tests. Results Fifty six patients have been included (8F 48 M, 56 ± 12 years). Distribution mixture analysis of intermovement intervals (IMI) of all LMs identified 3 classes of LMs which could be distinguished based on their peak frequencies ( Fig. 1 ). These were around 5 s, 20 s, and 40 s. The latter class (IMIs ∼40 s) could be traced back to the respiratory-related LMs, while the 20 s peak corresponds to periodic LMs, also found in patients with restless legs syndrome (RLS). LMs with very short IMIs (∼5 s) are related to wakefullness and arousal. Within the total group, 10 patients had no respiratory LMs ( Conclusions Our preliminary results show that respiratory LMs can be distinguished from periodic LMs based on their time structure (IMI). Importantly, respiratory LMs are found predominantly in patients with periodic LMs suggesting a possible shared trait for increased motor activity during sleep. The time structure analysis of LMs may be able provide information on the pathogenesis and meaning of LMs in OSAS patients and might explain the different response of LMs to ventilatory treatment.

Heart Rate and Spectral EEG Changes Accompanying Periodic and Isolated Leg Movements During Sleep

IN THE JUNE 2007 ISSUE OF SLEEP, GUGGISBERG ET AL1 REPORTED THAT HEART-RATE CHANGES ASSOCIATED WITH SLEEP-RELATED LEG MOVEMENTS PRECEDE both the leg movements and the associated electroencephalogram (EEG) changes by as much as 6 seconds. They also reported that the heart-rate changes were greater when occurring with periodic leg movements in sleep (PLMS) than with either isolated (ILMS) or respiratory-related leg movements. We2 and others3 have previously reported essentially opposite findings, i.e., that heart-rate changes associated with ILMS are greater than those with PLMS. In our study, the spectral EEG changes were also greater for ILMS than for PLMS. This discrepancy in leg movement-related heart-rate changes was not addressed by Guggisberg et al.1 Careful consideration of the 2 works reveals methodologic differences that might account for these discrepancies. In our previous study,2 we analyzed only PLMS that were separated by at least 30 seconds, as opposed to the 10 seconds used by Guggisberg et al.1 Our selection of 30 seconds was derived from a preliminary analysis that revealed that leg movement-related heart-rate changes usually persist up to 15 seconds after the onset of the movement. Our choice of a minimum interval of 30 seconds comfortably avoided the potential confounding effects of persisting heart-rate changes from a leg movement preceding the one under analysis. Our heart-rate analyses, extended from 20 seconds before to 30 seconds after each leg movement, with the first 10 seconds used as baseline. This allowed us to be comfortable that the baseline heart rate was not affected by a recent leg movement. Guggisberg et al1 included PLMS separated by only 10 seconds in their analysis, and their baseline heart rate was therefore determined by a period that was within 10 seconds of the prior movement and would likely include the relative bradycardia occurring after the prior movement. This methodologic problem negatively impacts their results in 2 important ways. First, the simple return to baseline from the natural bradycardia that follows a preceding leg movement has been misinterpreted as part of an increase in heart rate associated with the subsequent leg movement. Second, this artifactual difference would occur for frequent PLMS spaced closely together but not for ILMS that are spaced, by definition, further apart. As an example, the Figure depicts the heart-rate changes accompanying 2 consecutive leg movements during sleep, separated by approximately 15 seconds, the first of which is not preceded by another leg movement; in this example, it is clear that heart-rate values preceding the second leg movement are significantly lower than the stable baseline values preceding the first leg movement. Such a methodologic problem, if carried through the entire analysis, leads to a misinterpretation of the results. This provides a parsimonious explanation for the discrepancies between this study and the results of previous reports in the literature.2,3 Figure 1 Heart rate changes accompanying 2 consecutive leg movements during sleep showing the difficulty in setting reliable baseline values for movements occurring shortly after a previous movement. EOG refers to electrooculogram; ECG, electrocardiogram; Tib, ... Guggisberg et al1 also did not control for 3 other factors affecting leg movement-related heart rate and EEG changes: first, bilateral PLMS or ILMS have been reported to be accompanied by larger heart-rate and EEG changes than those occurring unilaterally.2 Guggisberg et al1 did not specify how many of the PLMS and ILMS were unilateral or bilateral, and different proportions would alter their results. Second, sleep stages, particularly rapid eye movement versus non-rapid eye movement, are associated with differing degrees of leg movement-related heart-rate changes.2,4 The proportion of ILMS or PLMS occurring in each sleep stage needs to be considered. Finally, the presence or absence of leg movement-related arousal is an important factor that significantly impacts heart rate and spectral EEG.5 Unfortunately these 3 well-documented factors affecting leg movement-related heart-rate changes were not evaluated in the data presented by Guggisberg et al,1 further complicating evaluating their results. The study of the clinical and biologic aspects of PLMS has recently benefited from the development of analytic methods that provide enhanced measurements of their patterns.6 Moreover, the recent report7 of an association of PLMS with a specific gene on chromosome 6 further supports the potential biologic significance of PLMS. But neither a genetic association nor enhanced measurement establishes biologic or clinical significance. This requires careful evaluation of both the PLMS and of the physiology and biology associated with them. Advancing the evaluation of PLMS therefore particularly requires, in future investigations, consideration of the methodologic concerns presented above regarding the study reported by Guggisberg et al.1

The Significance of the Sympathetic Nervous System in the Pathophysiology of Periodic Leg Movements in Sleep

Periodic leg movements in sleep (PLMS) are frequently accompanied by arousals and autonomic activation, but the pathophysiologic significance of these manifestations is unclear. Changes in heart rate variability (HRV), HRV spectra, and electroencephalogram (EEG) spectra associated with idiopathic PLMS were compared with changes associated with isolated leg movements and respiratory-related leg movements during sleep. Furthermore, correlations between electromyographic activity, HRV changes, and EEG changes were assessed. Sleep laboratory. Whole-night polysomnographic studies of 24 subjects fulfilling the criteria of either periodic leg movements disorder (n = 8), obstructive sleep apnea syndrome (n = 7), or normal polysomnography (n = 9) were used. Spectral HRV changes started before all EEG changes and up to 6 seconds before the onset of all types of leg movements. An initial weak autonomic activation was followed by a sympathetic activation, an increase of EEG delta activity, and finally a progression to increased higher-frequency EEG rhythms. After movement onset, HRV indicated a vagal activation, and, the EEG, a decrease in spindle activity. Sympathetic activation, as measured by HRV spectra, was greater for PLMS than for all other movement types. In EEG, gamma synchronization began 1 to 2 seconds earlier for isolated leg movements and respiratory-related leg movements than for PLMS. Significant correlations were found between autonomic activations and electromyographic activity, as well as between autonomic activations and EEG delta activity, but not between higher-frequency EEG rhythms and EMG activity or HRV changes. These results suggest a primary role of the sympathetic nervous system in the generation of PLMS.