Multiple Sleep Latency Test (MSLT) and Maintenance of Wakefulness Test (MWT)
Number: 0330
Table Of Contents
PolicyApplicable CPT / HCPCS / ICD-10 Codes
Background
References
Policy
Scope of Policy
This Clinical Policy Bulletin addresses multiple sleep latency test (MSLT) and maintenance of wakefulness test (MWT).
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Medical Necessity
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Aetna considers the multiple sleep latency test (MSLT) and maintenance of wakefulness test (MWT) medically necessary for either of the following 2 indications:
- For evaluation of symptoms of narcolepsy, to confirm the diagnosis; or
- For evaluation of persons with suspected idiopathic hypersomnia to help differentiate idiopathic hypersomnia from narcolepsy.
- Repeat MSLT and MWT tests are considered not medically necessary, unless:
- The initial test was invalid or uninterpretable; or
- The initial test is affected by extraneous circumstances or when study conditions were not present during initial testing; or
- The patient is suspected to have narcolepsy but earlier MSLT or MWT evaluation did not provide polygraphic confirmation.
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Experimental and Investigational
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The following tests and procedures are considered experimental and investigational:
- Home MSLT because home MSLT has not been proven to be equivalent to formal MSLT performed in a sleep laboratory.
- Single nap studies because a full MSLT or MWT is required for accurate diagnosis of narcolepsy.
- MSLT and MWT are considered experimental and investigational for all other indications because its effectiveness for indications other than the ones listed in Section I have not been established, including (not an all-inclusive list):
- attention-deficit/hyperactivity disorder;
- chronic fatigue syndrome;
- circadian rhythm disorders;
- evaluation of common, uncomplicated or noninjurious parasomnias, such as typical disorders of arousal, bruxism, enuresis, nightmares or sleep talking;
- evaluation of the effectiveness of modafinil therapy in narcolepsy;
- insomnia;
- neurologic disorders other than narcolepsy (e.g., dementia (including Alzheimer's disease and dementia with Lewy bodies) and Parkinson's disease);
- obstructive sleep apnea syndrome;
- psychiatric hypersomnolence;
- restless leg syndrome.
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Related Policies
Code | Code Description |
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Information in the [brackets] below has been added for clarification purposes. Codes requiring a 7th character are represented by "+": |
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CPT codes covered if selection criteria are met: |
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95805 | Multiple sleep latency or maintenance of wakefulness testing, recording, analysis and interpretation of physiological measurements of sleep during multiple trials to assess sleepiness |
Other CPT codes related to the CPB: |
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95782 | Polysomnography; younger than 6 years, sleep staging with 4 or more additional parameters of sleep, attended by a technologist |
95806 - 95807 | Sleep study |
95808 - 95811 | Polysomnography; sleep staging, attended by a technologist |
ICD-10 codes covered if selection criteria are met: |
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G47.10 - G47.19 | Hypersomnia |
G47.411 - G47.429 | Narcolepsy and cataplexy |
G47.53 | Recurrent isolated sleep paralysis |
R44.0 - R44.3 | Hallucinations |
R53.81 - R53.83 | Other malaise and fatigue [excessive or extreme sleepiness] |
ICD-10 codes not covered for indications listed in the CPB (not all-inclusive list): |
|
F01.50 - F03.91 | Dementias |
F02.80 - F02.81 | Dementia in conditions classified elsewhere with or without behavioral disturbance or with behavioral disturbance |
F03.90 - F0391 | Unspecified dementia without behavioral disturbance |
F10.27 | Alcohol dependence with alcohol-induced persisting dementia |
F13.27, F13.97, F18.17, F18.27, F18.97, F19.17, F19.27, F19.97 | Drug-induced persisting dementia |
F51.01, F51.03, F51.09 | Primary, paradoxical and other insomnia |
F51.13 | Hypersomnia due to other mental disorder |
F51.5 | Nightmare disorder |
F90.0 - F90.9 | Attention-deficit hyperactivity disorders |
G20 | Parkinson's disease |
G21.11 - G21.3 | Other drug-induced secondary parkinsonism |
G21.4 | Vascular parkinsonism |
G21.8 - G21.9 | Other and unspecified secondary parkinsonism |
G25.81 | Restless legs syndrome |
G30.0 - G30.9 | Alzheimer's disease |
G31.09 | Other frontotemporal dementia |
G31.83 | Dementia with Lewy bodies |
G47.00 | Insomnia, unspecified |
G47.20 - G47.29 | Circadian rhythm sleep disorders |
G47.30 | Sleep apnea, unspecified |
G47.33 | Obstructive sleep apnea (adult) (pediatric) |
G47.50 | Parasomnias unspecified [typical disorders of arousal] |
G47.63 | Sleep related bruxism |
G47.9 | Sleep disorder, unspecified [sleep talking] |
R32 | Unspecified urinary incontinence [enuresis] |
Background
Multiple Sleep Latency Test (MSLT) is a facility based study that is used to measure levels of daytime sleepiness. The results of the study are primarily used to confirm the suspected diagnosis of narcolepsy.
The multiple sleep latency test (MSLT) involves multiple trials during a day to objectively assess sleep tendency by measuring the number of minutes it takes the patient to fall asleep. During a routine MSLT, an individual is given five nap trials that are separated by two hour intervals: each trial consists of a twenty-minute session in which the individual attempts to fall asleep. Onset of sleep and rapid eye movement, along with heartbeat and chin movements are recorded. The test is typically performed on the night following a polysomnography (PSG; where at least six hours of sleep were achieved) in order to rule out other sleep disorders as a cause of excessive daytime sleepiness. The patient may be instructed to lie down in a dark room, with permission or a suggestion given to sleep (MSLT) or to sit up in a dimly lit room and try to stay awake (maintenance of wakefulness test). The MSLT is the better test for demonstration of sleep-onset rapid eye movement (REM) periods, a determination that is important in establishing the diagnosis of narcolepsy. Parameters necessary for sleep staging (including 1 to 4 channels of EEG, EOG, and chin EMG) are recorded.
Maintenance of Wakefulness Test (MWT) is a facility based study that is used to measure the ability to stay awake and alert. The procedure protocol is similar to that of the MSLT, with the exception that an individual is given four nap trials, each trial consisting of a forty minute session in which the an individual attempts to fall asleep. The test is routinely performed the day after a nocturnal PSG and evaluates the ability to stay awake for a defined period of time. Results may be used to determine the efficacy of therapy for sleep disturbance disorders (such as narcolepsy) or to determine if the inability to stay awake is a public or personal safety concern.
According to AASM guidelines (Littner, et al., 2005), the MSLT is indicated as part of the evaluation of patients with suspected narcolepsy to confirm the diagnosis. The MSLT may be indicated as part of the evaluation of patients with suspected idiopathic hypersomnia to help differentiate idiopathic hypersomnia from narcolepsy. The MSLT is not routinely indicated in the initial evaluation and diagnosis of obstructive sleep apnea syndrome or in assessment of change following treatment with nasal CPAP (Littner, et al., 2005). The MSLT is not routinely indicated for evaluation of sleepiness in medical and neurological disorders (other than narcolepsy), insomnia, or circadian rhythm disorders. According to the AASM (Littner, et al., 2005), repeat MSLT testing may be indicated in the following situations:- when the initial test is affected by extraneous circumstances or when appropriate study conditions were not present during initial testing,
- when ambiguous or uninterpretable findings are present,
- when the patient is suspected to have narcolepsy but earlier MSLT evaluation(s) did not provide polygraphic confirmation.
Huang et al (2008) noted that the cause and pathogenesis of Kleine-Levin syndrome, a recurrent hypersomnia affecting mainly male adolescents, remain unknown, with only scant information on the sleep characteristics during episodes. These investigators described findings obtained with PSG and MSLT and correlation obtained between clinical and PSG findings from different episodes. A total of 19 patients (17 males) were investigated with PSG and MSLT; 10 had data during both symptomatic episode and asymptomatic interval. The analyses considered day of onset of symptoms and relationship between this time of onset and day of recording during the symptomatic period. When PSG was performed early (before the end of the first half of the symptomatic period), an important reduction in slow wave sleep (SWS) was always present with progressive return to normal during the second half (with percentages very similar to those monitored during the asymptomatic period) despite persistence of clinical symptoms. Rapid eye movement sleep remained normal in the first half of the episode but decreased in the second half: the differences between first and second half of episodes were significant for SWS (p = 0.014) and REM sleep (p = 0.027). The overall mean sleep latency at MSLT was 9.51 +/- 4.82 mins and 7 of 17 patients had 2 or more sleep onset REM periods during the symptomatic period. The authors concluded that important changes in sleep occur over time during the symptomatic period, with clear impairment of SWS at symptom onset. However, MSLT is of little help in defining sleep problems and findings from the MSLT do not correlate with symptom onset.
Yeh and Schenck (2010) compared MSLT and Epworth sleepiness scale (ESS) for evaluating the effectiveness of modafinil in treating excessive daytime sleepiness in patients with narcolepsy. A total of 10 consecutive patients with narcolepsy-with-cataplexy who were treated with 200 mg/day modafinil for more than 6 months were included in this study. This comparative study was prompted by the requirement of the Bureau of National Health Insurance in Taiwan that modafinil users need to be followed-up with MSLTs every 6 to 12 months. The mean age at onset of narcolepsy onset in these 10 patients was 11.8 +/- 3.3 years, and 8 (80 %) were male. These investigators compared the differences in MSLT and ESS between baseline and follow-up at 6 to 12 months after starting modafinil therapy using paired-t tests. Epworth Sleepiness Scale scores (p < 0.001) were considerably more sensitive than MSLT scores (p < 0.05) in documenting the effectiveness of modafinil and that improvements in MSLT scores were minimal and remained in the pathologically sleepy range. These findings suggested that the ESS is a more sensitive and clinically meaningful tool to evaluate the effectiveness of modafinil in narcolepsy.
Mariman et al (2013) evaluated undiagnosed and co-morbid disorders in patients referred to a tertiary care center with a presumed diagnosis of chronic fatigue syndrome (CFS). Patients referred for chronic unexplained fatigue entered an integrated diagnostic pathway, including internal medicine assessment, psychodiagnostic screening, physiotherapeutic assessment and PSG + MSLT. Final diagnosis resulted from a multi-disciplinary team discussion. Fukuda criteria were used for the diagnosis of CFS, DSM-IV-TR criteria for psychiatric disorders, ICSD-2 criteria for sleep disorders. Out of 377 patients referred, 279 (74.0 %) were included in the study [84.9 % female; mean age of 38.8years (SD 10.3)]. A diagnosis of unequivocal CFS was made in 23.3 %. In 21.1 %, CFS was associated with a sleep disorder and/or psychiatric disorder, not invalidating the diagnosis of CFS. A predominant sleep disorder was found in 9.7 %, 19.0 % had a psychiatric disorder and 20.8 % a combination of both. Only 2.2 % was diagnosed with a classical internal disease. In the total sample, a sleep disorder was found in 49.8 %, especially obstructive sleep apnea syndrome, followed by psychophysiologic insomnia and periodic limb movement disorder. A psychiatric disorder was diagnosed in 45.2 %; mostly mood and anxiety disorder. The authors concluded that a multi-disciplinary approach to presumed CFS yielded unequivocal CFS in only a minority of patients, and revealed a broad spectrum of exclusionary or co-morbid conditions within the domains of sleep medicine and psychiatry.
However, an UpToDate review on "Clinical features and diagnosis of chronic fatigue syndrome" (Gluckman, 2014) does not mention the use of MSLT as a diagnostic tool.
Ferman et al (2014) stated that excessive daytime sleepiness (EDS) is a commonly reported problem in dementia with Lewy bodies (DLB). These researchers examined the relationship between nighttime sleep continuity and the propensity to fall asleep during the day in clinically probable DLB compared to Alzheimer's disease (AD) dementia. A full-night polysomnography was carried out in 61 participants with DLB and 26 with AD dementia. Among this group, 32 participants with DLB and 18 with AD dementia underwent a daytime MSLT. Neuropathologic examinations of 20 participants with DLB were carried out. Although nighttime sleep efficiency did not differentiate diagnostic groups, the mean MSLT initial sleep latency was significantly shorter in participants with DLB than in those with AD dementia (mean of 6.4 ± 5 mins versus 11 ± 5 mins, p < 0.01). In the DLB group, 81 % fell asleep within 10 mins compared to 39 % of the AD dementia group (p < 0.01), and 56 % in the DLB group fell asleep within 5 mins compared to 17 % in the AD dementia group (p < 0.01). Daytime sleepiness in AD dementia was associated with greater dementia severity, but mean MSLT latency in DLB was not related to dementia severity, sleep efficiency the night before, or to visual hallucinations, fluctuations, parkinsonism or rapid eye movement sleep behavior disorder. These data suggested that EDS is a unique feature of DLB that does not depend on nighttime sleep fragmentation or the presence of the 4 cardinal DLB features. Of the 20 DLB participants who underwent autopsy, those with transitional Lewy body disease (brainstem and limbic) did not differ from those with added cortical pathology (diffuse Lewy body disease) in dementia severity, DLB core features or sleep variables. The authors concluded that daytime sleepiness is more likely to occur in persons with DLB than in those with AD dementia. They stated that daytime sleepiness in DLB may be attributed to disrupted brainstem and limbic sleep-wake physiology, and further work is needed to better understand the underlying mechanisms.
Cochen De Cock and colleagues (2014) stated that EDS is a frequent complaint in Parkinson's disease (PD); however the frequency and risk factors for objective sleepiness remain mostly unknown. These researchers investigated both the frequency and determinants of self-reported and objective daytime sleepiness in patients with PD using a wide range of potential predictors. A total of 134 consecutive patients with PD, without selection bias for sleep complaint, underwent a semi-structured clinical interview and a 1-night polysomnography followed by a MSLT. Demographic characteristics, medical history, PD course and severity, daytime sleepiness, depressive and insomnia symptoms, treatment intake, pain, restless legs syndrome, REM sleep behavior disorder, and nighttime sleep measures were collected. Self-reported daytime sleepiness was defined by an ESS score above 10. A mean sleep latency on MSLT below 8 mins defined objective daytime sleepiness. Of 134 patients with PD, 46.3 % had subjective and only 13.4 % had objective sleepiness with a weak negative correlation between ESS and MSLT latency. A high body mass index (BMI) was associated with both ESS and MSLT, a pain complaint with ESS, and a higher apnea/hypopnea index with MSLT. However, no associations were found between both objective and subjective sleepiness, and measures of motor disability, disease onset, medication (type and dose), depression, insomnia, restless legs syndrome, REM sleep behavior disorder and nighttime sleep evaluation. The authors concluded that they found a high frequency of self-reported EDS in PD, a finding which is however not confirmed by the gold standard neurophysiological evaluation.
Bjornara et al (2014) noted that sleep disturbances, such as REM-sleep behavior disorder (RBD) and EDS, are more common in patients with PD than in the general population. Apart from that, their relation to PD seems to diverge considerably. These researchers explored the frequency and associated motor- and non-motor features of sleep related symptoms in PD. A total of 107 patients with PD, 65 men and 42 women, were included in a cross-sectional study. Excessive daytime sleepiness was examined by the ESS; probable RBD (pRBD) was diagnosed by the validated RBD screening questionnaire. Further sleep symptoms were explored by the PD sleep scale. Motor- and non-motor symptoms were assessed and compared in patients with and without pRBD and EDS, respectively. pRBD was present in 38 % and EDS was present in 29 % of the patients. As opposed to EDS, pRBD showed no association to disease duration or severity. Parkinson’s disease patients with pRBD reported more cognitive problems. There was a trend towards more autonomic dysfunction in patients with pRBD. Nocturia and sleep fragmentation were the most frequent general sleep problems reported by the patients. The authors concluded that these findings suggested that EDS is related to disease duration, and possibly caused by progressive neurodegeneration. They stated that pRBD seems to be a distinct feature present in only a proportion of PD patients.
Ataide et al (2014) noted that sleep disorders are major non-motor manifestations of patients with PD, and EDS is one of the most common symptoms. These investigators reviewed a current literature concerning major factors that influence EDS in PD patients, using MSLT. A Medline search found 23 studies. The presence of EDS was observed in 12.7 % to 47 % in patients without complaints of daytime sleepiness and 47 % to 66.7 % with complaints of daytime sleepiness. Despite being recognized by several authors, major factors that influence EDS, such as severity of motor symptoms, use of dopaminergic medications, and associated sleep disturbances, presented contradictory data. The authors concluded that available data suggested that the variability of the results may be related to the fact that it was conducted with a small sample size, not counting the neuropathological heterogeneity of the disease. Thus, before carrying out longitudinal studies with significant samples, careful analysis should be done by assigning a specific agent on the responsibility of EDS in PD patients.
Schrempf et al (2014) noted that sleep disorders in patients with PD are very common and have an immense negative impact on their quality of life. Insomnia, daytime sleepiness with sleep attacks, restless-legs syndrome (RLS) and RBD are the most frequent sleep disorders in PD. Neurodegenerative processes within sleep regulatory brain circuitries, anti-parkinsonian (e.g., levodopa and dopamine agonists) and concomitant medication (e.g., anti-depressants) as well as co-morbidities or other non-motor symptoms (such as depression) were discussed as causative factors. For the diagnosis of sleep disturbances these researchers recommended regular screening using validated questionnaires such as the Pittsburgh Sleep Quality Index (PSQI) or the Medical Outcomes Study Sleep Scale (MOS), for evaluating daytime sleepiness these investigators suggested to use the ESS, the inappropriate sleep composite score (ISCS) or the Stanford sleepiness scale (SSS). All of these questionnaires should be used in combination with a detailed medical history focusing on common sleep disorders and medication. If necessary, patients should be referred to sleep specialists or sleep laboratories for further investigations. Management of sleep disorders in PD patients usually starts with optimization of (dopaminergic) anti-parkinsonian therapy followed by specific treatment of the sleep disturbances. Aside from these clinical issues of sleep disorders in PD, the concept of RBD as an early sign for emerging neurodegenerative diseases is of pivotal interest for future research on biomarkers and neuroprotective treatment strategies of neurodegenerative diseases, and particularly PD.
Attention-Deficit/Hyperactivity Disorder
Prihodova et al (2010) evaluated sleep macrostructure, sleep disorders incidence and daytime sleepiness in attention-deficit/hyperactivity disorder (ADHD) affected children compared with controls. A total of 31 patients (26 boys, 5 girls, mean age of 9.3 ± 1.7 years, range of 6 to 12) with ADHD diagnosed according to DSM-IV criteria, without co-morbid psychiatric or other disorders, as never before pharmacologically treated for ADHD were included in this study. The controls were 26 age- and sex-matched children (22 boys, 4 girls, mean age of 9.2 ± 1.5 years, range of 6 to 12). Nocturnal polysomnography was performed for 2 nights followed by the MSLT. No differences between the 2 groups comparing both nights were found in the basic sleep macrostructure parameters or in the time (duration) of sleep onset. A 1st-night effect on sleep variables was apparent in the ADHD group. Occurrence of sleep disorders (sleep-disordered breathing [SDB], periodic limb movements in sleep [PLMS], parasomnias) did not show any significant differences between the investigated groups. A statistically significant difference (p = 0.015) was found in the trend of the periodic limb movement index (PLMI) between 2 nights (a decrease of PLMI in the ADHD group and an increase of PLMI in the control group during the 2nd night). While the mean sleep latency in the MSLT was comparable in both groups, children with ADHD showed significant (sleep latency) inter-test differences (between tests 1 and 2, 1 and 4, 1 and 5, p < 0.01). The authors concluded that after the inclusion of adaptation night and exclusion of psychiatric co-morbidities, PSG showed no changes in basic sleep parameters or sleep timing, or in the frequency of sleep disorders (SDB, PLMS) in children with ADHD compared with controls, thus not supporting the hypothesis that specific changes in the sleep macrostructure and sleep disturbances are connected with ADHD. A 1st-night effect on sleep variables was apparent only in the ADHD group. The authors concluded that although they found no proof of increased daytime sleepiness in children with ADHD against the controls, they did find significant vigilance variability during MSLT in the ADHD group, possibly a sign of dysregulated arousal.
Furthermore, an UpToDate review on "Attention deficit hyperactivity disorder in adults: Epidemiology, pathogenesis, clinical features, course, assessment, and diagnosis" (Bukstein, 2016) does not mention MSLT as a management tool.
Sobanski and colleagues (2016) evaluated sleep latency (SL) during the MSLT and subjective daytime sleepiness in adult ADHD and controls. Subjective daytime sleepiness was assessed by ESS in 27 un-medicated adults with ADHD and in 182 controls; 13 ADHD patients and 26 controls underwent MSLT after 1 night of PSG. Mean MSLT-SL was 10.6 ± 4.8 mins in ADHD and 12.2 ± 4.2 mins in controls (n.s.). Mean ESS score was 9.3 ± 4.9 points in ADHD and 6.9 ± 3.4 points in controls (p < 0.005); MSLT-SL and ESS scores correlated inversely by trend (r = -0.45, p < 0.1) but not with ADHD symptoms or ADHD subtype. The authors concluded that adults with ADHD did not differ from controls in mean MSLT-SL but experienced increased subjective daytime sleepiness. Patients with subjective higher daytime tiredness fell asleep faster during MSLT.
Psychiatric Hypersomnolence
Nofzinger et al (1991) characterized objectively the hypersomnia frequently seen in the depressed phase of bipolar affective disorder. On the basis of previous work in sleep and affective disorders, it has been hypothesized that the hypersomnia is related to greater REM sleep. This hypothesis was tested by using a MSLT to compare bipolar affective disorder with narcolepsy, a well-defined primary sleep disorder associated with known REM sleep dysfunction. A total of 25 bipolar depressed patients were selected on the basis of complaints of hypersomnia. They underwent 2 nights of PSG followed by a MSLT. Data on their nocturnal sleep and daytime naps were compared with similar data on 23 non-depressed narcoleptic patients referred for sleep evaluation. Despite their complaints of hypersomnia, no abnormalities were noted for the bipolar group in the results from the MSLT. Contrary to the working hypothesis, REM sleep was notably absent during daytime naps in the depressed patients, in marked contrast to the findings for the narcoleptic group. The authors concluded that the complaint of sleepiness in the hypersomnic bipolar depressed patient appeared to be related to the lack of interest, withdrawal, decreased energy, or psychomotor retardation inherent in the anergic depressed condition, rather than an increase in true sleep propensity or REM sleep propensity.
Plante (2016) noted that hypersomnolence plays a sizeable role in the course and morbidity of psychiatric disorders. Current sleep medicine nosology is reliant on the MSLT to segregate hypersomnolence associated with psychiatric disorders from other central nervous system causes. However, the evidence base regarding sleep propensity in psychiatric hypersomnolence as measured by the MSLT has not been systematically evaluated, which is vital to clarify the utility and validity of current nosological schema. In this review, the use of sleep propensity assessed by the MSLT in patients with psychiatric hypersomnolence was systematically evaluated, using both qualitative and quantitative assessment. Findings demonstrated high heterogeneity and potential for bias among studies, with a pooled estimate of sleep propensity among patients with psychiatric hypersomnolence similar to normative values. Additionally, approximately 25 % of patients with psychiatric hypersomnolence demonstrated a mean sleep latency below 8 minutes, the current cut-point to define pathologic sleepiness. The authors concluded that these data underscored the limitations of the MSLT in segregating psychiatric hypersomnolence from other central nervous system hypersomnias. They stated that further research is needed to evaluate novel measures and biomarkers of excessive sleepiness to advance clinical practice, as well as dimensional approaches to classification of hypersomnolence disorders.
Home Multiple Sleep Latency Test
In a randomized, cross-over, single-blinded study, Beiske and colleagues (2017) compared mean sleep latencies and number of sleep-onset rapid eye movement periods (SOREMPs) between modified MSLT performed in the unattended home and in-hospital laboratory setting. A total of 34 subjects referred to MSLT for suspected hypersomnia or narcolepsy were included. Participants were randomized to perform modified MSLT in the unattended home or in the hospital first. Scores in the 2 settings were compared using Wilcoxon signed-rank test or exact McNemar test. Agreement between home and hospital categorized mean sleep latency and number of SOREMPs was assessed using simple kappa (κ) and proportion agreement. Agreement between home and hospital mean sleep latency was assessed using a Bland-Altman plot and an intra-class correlation coefficient. There was no difference between home and hospital assessment of mean sleep latency (p = 0.86); 2 or more SOREMPs were found more frequently on modified MSLTs performed at home compared with those at the hospital (7 and 2, respectively; p = 0.025). Agreement was moderate for categorized sleep latency (κ = 0.53) and fair for categorized SOREMPs (κ = 0.39) in the 2 settings. Analysis of mean sleep latency using intra-class correlation coefficient showed a very good agreement between the 2 settings. The authors concluded that group mean sleep latency for home modified MSLTs appeared to be reliable compared with that for the attended sleep-laboratory setting. Higher rate of SOREMP in the unattended home suggested that napping in a familiar environment facilitated the transition into REM sleep. Moreover, they stated that further studies are needed to evaluate the normal limit, sensitivity, and specificity for SOREMP at home before the clinical utility of home-based napping can be determined.
Multiple Sleep Latency Test for the Diagnosis of Pediatric Narcolepsy Type 1
Pizza and colleagues (2019) attempted to validate polysomnographic markers (sleep latency and sleep-onset REM periods [SOREMPs] at the Multiple Sleep Latency Test [MSLT] and nocturnal polysomnography [PSG]) for pediatric narcolepsy type 1 (NT1) against CSF hypocretin-1 (hcrt-1) deficiency and presence of cataplexy, as no criteria are currently validated in children. Clinical, neurophysiologic, and, when available, biological data (HLA-DQB1*06:02 positivity, CSF hcrt-1 levels) of 357 consecutive children below 18 years of age evaluated for suspected narcolepsy were collected. Best MSLT cutoffs were obtained by receiver operating characteristic (ROC) curve analysis by contrasting among patients with available CSF hcrt-1 assay (n = 228) with versus without CSF hcrt-1 deficiency, and further validated in patients without available CSF hcrt-1 against cataplexy (n = 129). Patients with CSF hcrt-1 deficiency were best recognized using a mean MSLT sleep latency less than or equal to 8.2 mins (area under the ROC curve of 0.985), or by at least 2 SOREMPs at the MSLT (area under the ROC curve of 0.975), or the combined PSG + MSLT (area under the ROC curve of 0.977). Although specificity and sensitivity of reference MSLT sleep latency of less than or equal to 8 mins and greater than or equal to 2 SOREMPs (nocturnal SOREMP included) was 100 % and 94.87 %, the combination of MSLT sleep latency and SOREMP counts did not improve diagnostic accuracy. Age or sex also did not significantly influence these results in this pediatric cohort. The authors concluded that at least 2 SOREMPs or a mean sleep latency of less than or equal to 8.2 mins at the MSLT were valid and reliable markers for pediatric NT1 diagnosis, a result contrasting with adult NT1 criteria. This study provided Class III evidence that for children with suspected narcolepsy, polysomnographic and MSLT markers accurately identified those with narcolepsy type 1.
References
The above policy is based on the following references:
- AIM Specialty Health. Multiple sleep latency testing (MSLT) and maintenance of wakefulness testing (MWT). Chicago, IL: AIM Specialty Health; May 20, 2014.
- American Academy of Sleep Medicine. Practice parameters for the evaluation of chronic insomnia. Sleep. 2000;23(2):237-241.
- American Sleep Disorders Association Standards of Practice Committee, Polysomnography Task Force. Practice parameters for the indications for polysomnography and related procedures. Sleep. 1997;20(6):406-422.
- Arand DL, Bonnet MH. The multiple sleep latency test. Handb Clin Neurol. 2019;160:393-403.
- Ataide M, Franco CM, Lins OG. Daytime sleepiness and Parkinson's disease: The contribution of the multiple sleep latency test. Sleep Disord. 2014;2014:767181.
- Beiske KK, Sand T, Rugland E, Stavem K. Comparison of sleep latency and number of SOREMPs in the home and hospital with a modified multiple sleep latency test: A randomized crossover study. J Clin Neurophysiol. 2017;34(3):261-267.
- Bjornara KA, Dietrichs E, Toft M. Clinical features associated with sleep disturbances in Parkinson's disease. Clin Neurol Neurosurg. 2014;124:37-43.
- Boon P, Pevernagie D, Schrans D. Hypersomnolence and narcolepsy: A pragmatic diagnostic neurophysiological approach. Acta Neurol Belg. 2002;102(1):11-18.
- Bukstein O. Attention deficit hyperactivity disorder in adults: Epidemiology, pathogenesis, clinical features, course, assessment, and diagnosis. UpToDate [online serial]. Waltham, MA: UpToDate; reviewed January 2016.
- Chakravorty SS, Rye DB. Narcolepsy in the older adult: Epidemiology, diagnosis and management. Drugs Aging. 2003;20(5):361-376.
- Chen L, Ho CK, Lam VK, et al. Interrater and intrarater reliability in multiple sleep latency test. J Clin Neurophysiol. 2008;25(4):218-221.
- Chesson AL Jr, Ferber RA, Fry JM, et al. The indications for polysomnography and related procedures. An American Sleep Disorders Association Report. Sleep. 1997;20(6):423-487.
- Cochen De Cock V, Bayard S, Jaussent I, et al. Daytime sleepiness in Parkinson's disease: A reappraisal. PLoS One. 2014;9(9):e107278.
- Ferman TJ, Smith GE, Dickson DW, et al. Abnormal daytime sleepiness in dementia with Lewy bodies compared to Alzheimer's disease using the Multiple Sleep Latency Test. Alzheimers Res Ther. 2014;6(9):76.
- Fong SY, Ho CK, Wing YK. Comparing MSLT and ESS in the measurement of excessive daytime sleepiness in obstructive sleep apnoea syndrome. J Psychosom Res. 2005;58(1):55-60.
- Fronczek R, van der Zande WL, van Dijk JG, et al. Narcolepsy: A new perspective on diagnosis and treatment. Ned Tijdschr Geneeskd. 2007;151(15):856-861.
- Gluckman SJ. Clinical features and diagnosis of chronic fatigue syndrome. UpToDate [online serial]. Waltham, MA: UpToDate; reviewed January 2014.
- Guilleminault C, Pelayo R. Narcolepsy in children: A practical guide to its diagnosis, treatment and follow-up. Paediatr Drugs. 2000;2(1):1-9.
- Huang YS, Lin YH, Guilleminault C. Polysomnography in Kleine-Levin syndrome. Neurology. 2008;70(10):795-801.
- Kasravi N, Legault G, Jewell D, Murray BJ. Minimal impact of inadvertent sleep between naps on the MSLT and MWT. J Clin Neurophysiol. 2007;24(4):363-365.
- Kushida CA, Littner MR, Morgenthaler T, et al. Practice parameters for the indications for polysomnography and related procedures: An update for 2005. Sleep. 2005;28(4):499-521.
- Li Y, Vgontzas AN, Fernandez-Mendoza J, et al. Insomnia with physiological hyperarousal is associated with hypertension. Hypertension. 2015;65(3):644-650.
- Littner M, Hirshkowitz M, Kramer M, et al. Practice parameters for using polysomnography to evaluate insomnia: An update. Sleep. 2003;26(6): 754-760.
- Littner M, Johnson SF, McCall WV, et al. Practice parameters for the treatment of narcolepsy: An update for 2000. Sleep. 2001;24(4):451-466.
- Littner MR, Kushida C, Wise M, et al. Practice parameters for clinical use of the multiple sleep latency test and the maintenance of wakefulness test. Sleep. 2005;28(1):113-121.
- Lopez R, Doukkali A, Barateau L, et al. Test-retest reliability of the multiple sleep latency test in central disorders of hypersomnolence. Sleep. 2017 40(12).
- Manni R, Tartara A. Evaluation of sleepiness in epilepsy. Clin Neurophysiol. 2000;111(Suppl 2):S111-S114.
- Mariman A, Delesie L, Tobback E, et al. Undiagnosed and comorbid disorders in patients with presumed chronic fatigue syndrome. J Psychosom Res. 2013;75(5):491-496.
- Nofzinger EA, Thase ME, Reynolds CF 3rd, et al. Hypersomnia in bipolar depression: A comparison with narcolepsy using the multiple sleep latency test. Am J Psychiatry. 1991;148(9):1177-1181.
- Pizza F, Barateau L, Jaussent I, et al. Validation of multiple sleep latency test for the diagnosis of pediatric narcolepsy type 1. Neurology. 2019;93(11):e1034-e1044.
- Plante DT. Sleep propensity in psychiatric hypersomnolence: A systematic review and meta-analysis of multiple sleep latency test findings. Sleep Med Rev. 2016;31:48-57.
- Prihodova I, Paclt I, Kemlink D, et al. Sleep disorders and daytime sleepiness in children with attention-deficit/hyperactivity disorder: A two-night polysomnographic study with a multiple sleep latency test. Sleep Med. 2010;11(9):922-928.
- Richert AC, Baran AS. A review of common sleep disorders. CNS Spectr. 2003;8(2):102-109.
- Sateia MJ, Doghramji K, Hauri PJ, Morin CM. Evaluation of chronic insomnia. An American Academy of Sleep Medicine review. Sleep. 2000;23(2):243-308.
- Schrempf W, Brandt MD, Storch A, Reichmann H. Sleep disorders in Parkinson's disease. J Parkinsons Dis. 2014;4(2):211-221.
- Scottish Intercollegiate Guidelines Network (SIGN). Management of obstructive sleep apnoea/hypopnoea syndrome in adults. A national clinical guideline. SIGN Publication No. 73. Edinburgh, Scotland: SIGN; June 2003.
- Sobanski E, Alm B, Hennig O, et al. Daytime sleepiness in adults with ADHD: A pilot trial with a multiple sleep latency test. J Atten Disord. 2016;20(12):1023-1029.
- Sullivan SS, Kushida CA. Multiple sleep latency test and maintenance of wakefulness test. Chest. 2008;134(4):854-861.
- Thorpy MJ. The clinical use of the multiple sleep latency test. The Standards of Practice Committee of the American Sleep Disorders Association. Sleep. 1992;15(3):268-276.
- Um YH, Kim TW, Jeong JH, et al. A longitudinal follow-up study on multiple sleep latency test and body mass index of patients with narcolepsy type 1 in Korea. J Clin Sleep Med. 2017;13(12):1441-1444.
- Wise MS. Objective measures of sleepiness and wakefulness: Application to the real world? J Clin Neurophysiol. 2006;23(1):39-49.
- Yeh SB, Schenck CH. Efficacy of modafinil in 10 Taiwanese patients with narcolepsy: Findings using the multiple sleep latency test and Epworth sleepiness scale. Kaohsiung J Med Sci. 2010;26(8):422-427.