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The Effect of CPAP Intervention on Sleep Architecture and Cognition in Alzheimer’s Disease Patients with Obstructive Sleep Apnea

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16 July 2025

Posted:

18 July 2025

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Abstract
Background Obstructive sleep apnea (OSA) is highly prevalent in the early stages of Alzheimer’s disease (AD), and its hallmark, sleep fragmentation, may accelerate cognitive decline. Continuous positive airway pressure (CPAP) improves OSA-related hypoxia during slow-wave sleep, but its cognitive benefits in AD remain unclear. Methods We performed a 12-month sub-analysis of a prospective, longitudinal pilot study that enrolled 21 adults (median age = 77 yr; 71% women) with MCI with AD confirmed biomarkers and polysomnography-diagnosed OSA. All participants underwent baseline overnight PSG and neuropsychological testing (CDR, MMSE, RBANS) that were repeated after 12 months. Twelve participants were CPAP-compliant (moderate/severe OSA) and nine were non-users (mild OSA/intolerance). Cognitive change scores (Δ = 12 months – baseline) were compared with generalized linear models adjusted for baseline cognition and apnea-hypopnea index; associations between baseline sleep parameters and cognitive trajectories were examined. And the association of sleep variables with the use of CPAP was also evaluated. Results Compared with non-users, CPAP users showed significantly slower global decline (Δ MMSE: p = 1.60e-02) and improvements in overall cognition (Δ RBANS Total: p = 2.80e-02), and RBANS subdomains (Δ RBANS FC: p = 1.06e-02; Δ RBANS SF: p = 4.53e-02). Longer baseline NREM stage 3 and REM sleep, greater total sleep time and sleep efficiency, and right-side sleeping were each linked to better cognitive outcomes, whereas extended NREM stage 2, wakefulness, and supine sleeping were associated with poorer trajectories. Conclusions Twelve months of CPAP use was associated with attenuated cognitive decline and domain-specific gains in AD-related MCI with OSA. Sleep architecture and body position during sleep predicted cognitive outcomes, underscoring the therapeutic relevance of optimizing breathing and sleep quality. Larger, longer-term trials are warranted to confirm CPAP’s disease-modifying potential and to clarify the mechanistic role of sleep in AD progression.
Keywords: 
Alzheimer’s disease
;  
cognitive decline
;  
CPAP
;  
mild cognitive impairment
;  
obstructive sleep apnea
Subject: 
Medicine and Pharmacology  -   Neuroscience and Neurology

Introduction

Alzheimer’s disease (AD) is the most prevalent neurodegenerative disorder, accounting for approximately 60-70% of dementia cases globally, and is characterized by progressive cognitive decline, memory impairment, and behavioral disturbances [1,2]. The disease manifests through the accumulation of amyloid-beta (Aβ) plaques and neurofibrillary tangles of hyperphosphorylated tau protein in the brain, leading to synaptic dysfunction, widespread neuronal death, and atrophy, particularly in regions crucial for memory and cognitive function [3,4,5]. Despite extensive research and significant advances in the understanding of the molecular and cellular mechanisms underlying AD, there remains no cure, and current treatments focus on symptom management rather than addressing the root causes of the disease [3,6,7].
The prodromal stage of AD is characterized by the presence of Mild Cognitive Impairment (MCI), which consists in cognitive decline that does not interfere significantly with daily life activities [8,9]. This is a critical period for early intervention, as it represents the initial stage before onset of dementia [7,8,9]. Individuals with MCI have annual conversion rates to AD ranging from 10-15% [4].
One of the most significant recent advances in neurobiology has been the discovery of the glymphatic system, a brain-wide network responsible for clearing metabolic waste products from the central nervous system (CNS), including Aβ [3,10,11]. This process is crucial for preventing the accumulation of Aβ and other toxic proteins that are implicated in the pathogenesis of AD [12,13]. The glymphatic system is highly dependent on the sleep-wake cycle, with its activity probably being most pronounced during slow-wave sleep (SWS) phase of non-rapid eye movement sleep (NREM) characterized by low-frequency, high-amplitude delta waves [12,13]. Studies have shown that the efficacy of the glymphatic system declines with age, which, coupled with sleep disturbances common in older adults, may contribute to the increased risk of AD and accelerate its progression observed in the aging population [11,12].
Sleep plays a fundamental role in cognitive health, with disturbances in sleep being increasingly recognized as both a symptom and a contributing factor to neurodegenerative diseases like AD [2,10,14]. Sleep disturbances, including insomnia, fragmented sleep, and Obstructive Sleep Apnea (OSA), are prevalent among older adults and particularly in individuals with AD [14]. OSA is one of the sleep alterations with higher prevalence in AD, affecting between 43% and 91% of patients [14,15]. It is characterized by repeated episodes of partial or complete obstruction of the upper airway during sleep [14,16]. OSA leads to intermittent hypoxia, hypercapnia, frequent arousals, and significant fragmentation of sleep, particularly reducing the duration and quality of SWS [14,15,16]. OSA is also a potential cause of cognitive impairment, likely due to multiple potential mechanisms, including oxidative stress, increased inflammation, and the presence of cerebral small-vessel lesions [17]. This underscores the current significance of medical treatments.
Continuous positive airway pressure (CPAP) therapy is the gold standard treatment for OSA and has been proven to be effective in improving sleep quality by preventing airway collapse during sleep [15,16,18]. It increases the duration and quality of SWS, potentially enhancing the glymphatic system’s function and reducing the risk of Aβ accumulation in the brain [15,18]. Several studies have demonstrated that CPAP adherence in patients with OSA and MCI/AD can normalize sleep breathing and possibly lead to better cognition, which specific cognitive domains still need to be determined [15]. Other studies have also reported that CPAP could increase cerebrospinal fluid (CSF) flow rate in anaesthetised rats, suggesting a possible therapeutic enhancement of glymphatic function [18].
Given the significant overlap between the prevalence of sleep disturbances in AD, as well as the potential for CPAP therapy to mitigate cognitive decline, this study aimed to explore the intricate relationship between OSA and MCI progression. We found that patients diagnosed with MCI and OSA with good CPAP adherence had improved sleep parameters and cognitive decline outcomes at 12-month follow-up, compared to those that did not use CPAP devices.

Methods

Study Design and Participants Inclusion

The current study consists of a sub-analysis of a prospective interventional and longitudinal pilot study. We included participants with MCI referred to the Cognition and Behaviour Unit at the Department of Neurology, Hospital Universitari MútuaTerrassa (HUMT) in Terrassa, Barcelona, Spain. Ethical approval from the Drug Research Ethics Committee of Fundació Assistencial Mútua Terrassa (approval code: P/21-132) was obtained on 17/11/2021. Participants also provided signed informed consent.
Participants with a diagnosis of MCI (confirmed by a Delayed Memory Index (DMI) below 85 on the Repeatable Battery for the Assessment of Neuropsychological Status (RBANS), a Mini-Mental State Examination (MMSE) score below 27, or a Clinical Dementia Rating (CDR) score of at least 0.5) and sufficient reading and writing skills to complete cognitive tests were included. AD pathology was confirmed by positive CSF AD biomarkers or positive 18F Flutemetamol PET/CT. AD biomarkers in CSF were measured by Catlab according to the established local cut-off values. Patients were considered positive for AD biomarkers when Aβ1-42/Aβ1-40 was < 0.068 pg/mL plus two more of the following: t-tau (> 404 pg/mL), p-tau 181 (> 52.1 pg/mL), Aβ1-42 (< 638pg/mL), t-tau/ Aβ1-42 (> 0.784). For the current study, all the patients were required to have a sleep registry with overnight video-polysomnography (V-PSG).
Exclusion criteria included a prior diagnosis of other neurocognitive disorders, a history of affective disorders or psychosis, current participation in cognitive training programs, or the use of psychotropic medications affecting cognition. Those with a history of cerebrovascular accidents, transient ischemic attacks, or traumatic brain injury, as well as individuals with conditions likely to interfere with the study procedures, were also excluded.

Cognitive Assessment

Baseline cognitive assessments with CDR, MMSE, and RBANS tests were conducted, followed by a re-evaluation after 12 months.
CDR assesses the following areas: Memory, Orientation, Judgement and Problem Solving, Community Affairs, Home and Hobbies, and Personal Care. It generates a semi-quantitative and categorical score that classifies different levels of cognitive impairment, with higher scores indicating more severe impairment.
MMSE consists of five parts: Orientation, Registration, Attention, Calculation, Recall and Language. Each section contains questions that contribute to determining the cognitive impairment score.
RBANS is composed of five indexes, which are Immediate Memory Index (IMI), Visuospatial Index (VSPI), Language Index (LNGI), Attention Index (ATI), and Delayed Memory Index (DMI). To determine the value of each index, different subtests are also considered. IMI: List Learning (LL) and Story Memory (SM); VSPI: Figure Copy (FC) and Line Orientation (LO); LNGI: Picture Naming (PN) and Semantic Fluency (SF); ATI: Direct Digit Span (DDS), Indirect Digit Span (IDS) and Coding (C); DMI: List Recall (LR), List Recognition (LRe), Story Recall (SR) and Figure Recall (FR). To minimize learning effects, a parallel version of the same cognitive battery was used (version A at baseline and version B at follow-up). In both the MMSE and RBANS, lower scores indicate more severe cognitive impairment.

Video-Polysomnography (V-PSG) and Sleep Architecture

Participants underwent overnight V-PSG at Adsalutem sleep unit, where one sleep night was recorded using a comprehensive setup including synchronized audiovisual recording, electroencephalography (EEG; F3, F4, C3, C4, O1, and O2, referred to the combined ears), electrooculography (EOG), electrocardiography, surface electromyogram (EMG) of the right and left anterior tibialis in the lower limbs. Nasal cannula, nasal and oral thermistors, thoracic and abdominal strain gauges, and finger pulse oximeter were used to measure the respiratory variables. Sleep stages and respiratory events were scored according to the American Academy of Sleep Medicine’s Manual for Scoring of Sleep and Associated Events, Version 3. All participants from the current sub-study were diagnosed with OSA. The OSA’s severity was established from the Apnea-Hypopnea Index (AHI), extracted from the V-PSG, considering the following limits: Mild OSA (AHI: 5-15 events/hour), Moderate OSA (AHI: 15-30 events/hour) and Severe OSA (AHI: > 30 events/hour) [19].
From V-PSG, we obtained the following sleep parameters: Duration of sleep stages, composed of non-rapid eye movement (NREM), sleep stages N1, N2 and N3; and duration of rapid eye movement (REM) sleep, total time in bed (total amount of time spent in bed including both sleep and wake periods), total sleep time (amount of time spent sleeping), sleep efficiency (ratio of the total sleep time to the time in bed, that could be affected by sleep disruptions) and wakefulness (amount of time spent awake while in bed), sleep position, including supine prone, right and left-side times. All these variables are measured in minutes, except sleep efficiency, which is indicated in percentage (%).
Patients diagnosed with moderate or severe OSA were prescribed CPAP based on standard medical criteria.

Statistical Analysis

Participants were classified into two groups: those who used CPAP (due to prescription and tolerance of the device) and those who did not (because of lack of prescription in mild OSA or lower tolerance). The median, minimum, and maximum were calculated for the demographic data of each group, while the mean and standard deviation were calculated for neuropsychological test’s parameters. Differences in neuropsychological test scores were assessed by subtracting baseline values from follow-up scores (e.g., Δ MMSE = 12 Months MMSE – Baseline MMSE).
The normality of the data was assessed with Shapiro-Wilk test. Demographic features were compared between CPAP and non-CPAP groups using T-tests and Fisher’s exact tests, as appropriate, based on the normality. Longitudinal changes in CDR were assessed using Stuart-Maxwell test. Longitudinal changes in the other neurocognitive scores were analyzed using both Spearman and Pearson correlation tests for the full sample. The effect of CPAP treatment in the cognitive progression between the baseline and 12-month follow-up (Δ CDR, Δ MMSE, Δ RBANS Total and Δ RBANS sub-domains) was assessed using Generalized Linear Models (GLM) with baseline cognitive outcomes and AHI as covariates. Using GLM, the association among PSG variables and the cognitive variables was also evaluated, with the baseline results of the neuropsychological tests and CPAP as covariates. All statistical analyses were conducted in RStudio (version 4.4.2). The results were considered statistically significant when the p-value was lower than 0.05 and the correlation coefficient (r) was higher than 0.3.

Results

Demographic Description of the CPAP and Non-CPAP Groups

A total of 21 patients with MCI were included in this study. The median age of the sample was 77 years (60-81), and 71% (n = 15) were female. All patients were diagnosed with some OSA degree and accordingly, they were prescribed CPAP. 57% (n = 12) of patients were compliant in CPAP use ( ≥ 4h/night on, at least, 70% of nights). No statistically significant differences were found in sex and education between CPAP users and non-users (Table 1), but statistically significant differences were identified in age (p-value = 0.010), the CPAP group being younger than the non-CPAP group (Figure 1).

CPAP Results

Longitudinal Cognitive Status

When focusing on the full cohort included in the current study, statistically significant decline in neurocognitive performance at the 12-month follow-up compared with the baseline assessment were identified in CDR (p = 0.223), MMSE (p = < 0.001), RBANS Total (p = < 0.001), RBANS IMI (p = < 0.001), RBANS LL (p = < 0.001), RBANS SM (p = 0.001), RBANS SF (p = < 0.001), RBANS ATI (p = < 0.001), RBANS DDS (p = 0.005), RBANS C (p = < 0.001), RBANS DMI (p = 0.003), RBANS SR (p = 0.002) and RBANS FR (p = 0.003). On the other hand, RBANS LO (p = 0.031), RBANS LNGI (p = < 0.001), RBANS PN (p = 0.016), and RBANS LR (p = 0.003) presented better performance at the 12-month follow-up compared with the baseline (Table 2).
When comparing the difference between 12-month follow-up and baseline results in the CPAP and non-CPAP groups, a statistically significant difference was found in Δ MMSE, with lower cognitive decline in the CPAP group (p = 0.016). Statistically significant differences were also identified in Δ RBANS Total (p = 0.028), Δ RBANS FC (p = 0.010), and Δ RBANS SF (p = 0.045), with cognitive improvement in the CPAP group (Table 3).

Effect of Sleep in Cognitive Progression

The association between sleep parameters measured at baseline and cognitive progression was evaluated. Only cognitive variables that changed between baseline and 12-month follow-up (Table 2) were evaluated. To ensure that the results were not influenced by the use of CPAP, the use of this device was considered as a covariate for those analyses where a cognitive variable in a previous analysis without covariates was associated with CPAP.
From the different sleep stages (Table 4), N2 duration showed a significant negative correlation with Δ MMSE, while N3 had a significant positive correlation with Δ MMSE and Δ RBANS FR. REM duration was associated with better cognitive progression measured with Δ RBANS IMI and Δ RBANS LL. From the other sleep parameters, total sleep time showed a significant positive correlation with Δ RBANS IMI, Δ RBANS LL, Δ RBANS SM, Δ RBANS SF, Δ RBANS C, and Δ RBANS SR. Sleep efficiency was positively correlated with Δ RBANS LL, Δ RBANS SF, and RBANS C, while wakefulness had a significant negative correlation with Δ RBANS LL, Δ RBANS SF, and Δ RBANS C. About the sleep position variables, supine time had a significant negative correlation with Δ MMSE, Δ RBANS LO, and Δ RBANS DDS, and right-side time had a significant positive correlation with Δ MMSE and Δ RBANS LO. All these results were independent from the use of CPAP.

Discussion

In this study, we reported a positive clinical effect of CPAP on cognitive progression in specific cognitive domains. Furthermore, we show an association between baseline sleep patterns, including N2 and N3 time, supine and right-side time, with cognitive progression at 12-month follow-up.

Cognitive Progression in the Full Cohort

The full cohort showed a decline in almost all significant cognitive variables, which is expected in patients with MCI or AD and OSA. Participants improved their scores in RBANS LO, RBANS LNGI, RBANS PN, and RBANS LR. RBANS LO and RBANS LR variables show a cognitive improvement in the CPAP group, while a worsening in non-CPAP group, indicating that this may be attributed to the positive effects of CPAP therapy. For the other two improved variables, RBANS LNGI and RBANS PN, improved scores were greatest in the CPAP group, but the cognition scores for both CPAP and non-CPAP groups improved. This is not consistent with the current literature and with what we expected (cognitive decline in the non-CPAP group, at least) [20]. Potential reasons for unexpected outcomes, such as improved cognitive scores, could be associated with the small size of the full cohort (n = 21).

Impact of the CPAP on Cognitive Progression

The positive effect of CPAP on cognitive progression was reported in previous studies. CPAP use was linked with a significant t-tau and t-tau/Aβ42 ratio reduction in plasma of OSA patients in a 3-month follow-up [21]. This was translated with an Aβ increase in CSF, which has also been correlated with a decreased brain deposition [22] in a 1-year study with a patient with OSA and subjective cognitive impairment, obtaining the normalization of the cerebral Aβ dynamics and t-tau/Aβ42 and Aβ42/Aβ40 ratios [23]. Previous studies characterized one of the main features of OSA, intermittent hypoxia during sleep, as one of the causes of cognitive decline before AD symptomatology [24,25,26]. During sleep, the dysfunction of the glymphatic system has been implicated as a mechanism for accumulation of Aβ in the brain [27]. This could be related to the cognitive worsening that was obtained in MMSE scores in patients with OSA [28], as well as in other domains (memory, attention, visuospatial, language, etc.) [29]. Other studies also observed slow cognitive decline or cognitive improvement in patients with OSA and AD when treated with CPAP [30,31,32].
Our results are consistent with these studies, obtaining that CPAP use was significantly associated with slower decline in Δ MMSE and an improvement in Δ RBANS Total, as well as an improvement in Δ RBANS FC and Δ RBANS SF sub-domains in a 12-month follow-up study in patients with OSA and MCI due to AD. These results are due to CPAP impact on sleep quality improvement, as well as an increase in oxygenation and a reduction in neuroinflammation [33]. Consequently, a better concentration and memory make these two sub-domains to be significantly improved [34].

Effect of Sleep Parameters on Cognitive Progression

The relationship between sleep variables, CPAP therapy, and cognition has been investigated in multiple studies in patients with OSA. However, examining it in patients with OSA and MCI could provide important insights into its appropriate use in patients with cognitive decline.
NREM N2, N3, and REM sleep are critical for cognitive health. N2 was longer in OSA patients and shorter in control and OSA-CPAP groups [35,36]. NREM N3 sleep is the main stage in which the glymphatic system is effective [37]. The impact of this enhancement is an improved clearance of metabolic products in the brain, including Aβ, generating less deposition of this protein and improved cognition when this stage is prolonged. Shorter REM is associated with lower performance in neuropsychological tests [38,39]. The results obtained in our study are consistent with this literature for NREM N2, in which longer stages have been associated with cognitive worsening in Δ MMSE, as well as for NREM N3, with longer stages correlated with cognitive improvement in Δ MMSE and Δ RBANS FR, and REM sleep, with longer duration associated with better cognition in Δ RBANS IMI and Δ RBANS LL.
Total sleep time and sleep efficiency also play significant roles in maintaining cognitive health. Studies have demonstrated that higher total sleep time would facilitate the repetition of sleep cycles, allowing NREM N3 to be longer [40]. Other studies have also described that sleep duration shorter or longer than certain limits, generally described as < 5h and > 9h in 70-year-old participants, would be associated with worsening cognition with a quadratic trend that can not be well-established with linear models [41]. There are disruptions too, like wakefulness that can affect sleep efficiency, which in turn can further fragment sleep when it is longer, generating poor cognition [42]. This information supports our results for total sleep time, sleep efficiency, and wakefulness as longer total sleep time was associated with better cognition in Δ RBANS IMI, Δ RBANS LL, Δ RBANS SM, Δ RBANS SF, Δ RBANS C, and Δ RBANS SR, higher sleep efficiency was correlated with cognitive improvement in Δ RBANS LL, Δ RBANS SF, and Δ RBANS C, and longer wakefulness with cognition worsening in Δ RBANS LL, Δ RBANS SF, and Δ RBANS C.
Right-side time and supine time are essential to understanding the sleep position importance that have been studied by other research groups. In humans, the “Starling resistor” mechanism in normal conditions prevents the overdrainage of cranial venous blood in supine sleeping position. In OSA, this mechanism is altered because a pressure airway drops below a critical value, generating the collapse of the upper airway [43,44]. This collapse activates a defense mechanism based on a choking feeling that may disrupt sleep in patients, affecting their cognition in chronic events [45]. Lower CPAP pressure can maintain the upper airway open easier in lateral than in supine position, helping to prevent this aforementioned collapse [46]. A possible reason for this could be that the collapse is easier in the supine position than in the lateral position, due to the gravitational effect. This collapse is associated with an increase in apneas and respiratory disruptions when sleeping [47], worsening cognition. These studies are consistent with the result obtained for supine time, in which longer time is associated with cognitive decline in Δ MMSE, Δ RBANS LO, and Δ RBANS DDS.
When sleeping in lateral position, it was observed that right position generates an increase in vagal tone and a reduction in sympathetic tone stronger than in left position [48]. It leads to the highest vagal modulation [49], where fibers provide parasympathetic innervation to the atria and sinoatrial node, while the left vagal nerve just innervates the ventricles [50]. Vagus Nerve Stimulation (VNS), an FDA-approved treatment for epilepsy and depression among others, has been associated with increased penetration of CSF into the brain, increasing brain waste clearance in mice [51]. This information could be the reason why longer right-side time is associated with cognitive improvement in Δ MMSE and Δ RBANS LO in our study, thus, sleeping in a right-side position would cause a stronger activation of parasympathetic tone in heart and affect CSF penetrance.
In the overall literature, it has been described that sleep deprivation evidences a decrease in comprehension, attention, language, and memory [52,53,54,55]. This could explain why we have obtained these results, affecting longer sleep time and greater sleep efficiency in MMSE and some attention, language, and memory RBANS sub-domains. Regarding the sleep position, it has been observed in our results that these positions could also have consequences. Thus, supine position had a negative effect on MMSE and RBANS sub-domains related to attention and memory, while right-side position showed cognitive improvement in MMSE and a memory RBANS sub-domain.

Study Limitations

This study has some limitations. Although prospective, it is a pilot study with a reduced sample size and an unequal distribution of participants between the CPAP (n = 12) and non-CPAP (n = 9) groups. The CPAP compliance in AD patients is more difficult when they are in more advanced stages of the disease. The V-PSG data were derived from a single-night study, which may not fully capture chronic sleep patterns. For future studies, long-term monitoring methods such as actigraphy could provide more robust insights [56]. Despite these limitations, we have identified significant results that are consistent with previous literature.

Conclusion

Our findings underscore the potential of CPAP to reduce the rate of cognitive decline in patients with OSA and MCI, demonstrating better cognitive outcomes in CPAP group after a 12-month follow-up. The associations between sleep and cognitive progression highlight the significance of sleep duration and position in maintaining cognitive health. Future studies with larger cohorts and extended monitoring are warranted to validate these findings and explore the role of CPAP in mitigating dementia progression in OSA patients. Additionally, follow-up at 24 months is important to further investigate the differences between groups, as well as to learn how to improve CPAP adherence in AD patients.

Author Contributions

Conceptualization, Carmen L. Frias, Natalia Cullell and Jerzy Krupinski; Data curation, Carmen L. Frias and Cristina Artero; Formal analysis, Carmen L. Frias; Funding acquisition, Natalia Cullell and Jerzy Krupinski; Investigation, Carmen L. Frias, Marta Almeria, Judith Castejon, Cristina Artero, Giovanni Caruana, Andrea Elias and Karol Uscamaita; Methodology, Carmen L. Frias; Project administration, Natalia Cullell and Jerzy Krupinski; Resources, Marta Almeria, Judith Castejon, Cristina Artero and Karol Uscamaita; Software, Carmen L. Frias; Supervision, Natalia Cullell and Jerzy Krupinski; Validation, Marta Almeria and Judith Castejon; Visualization, Carmen L. Frias; Writing – original draft, Carmen L. Frias; Writing – review & editing, Marta Almeria, Judith Castejon, Giovanni Caruana, Andrea Elias, Karol Uscamaita, Virginia Hawkins, Nicola J. Ray, Mariateresa Buongiorno, Natalia Cullell and Jerzy Krupinski.

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Preprints 168392 g001
Figure 1. OSA severity in the full cohort and within the CPAP and non-CPAP groups. Representation of the quantity (n) and percentage (%) of participants with Mild, Moderate, and Severe OSA. OSA, Obstructive Sleep Apnea.
Figure 1. OSA severity in the full cohort and within the CPAP and non-CPAP groups. Representation of the quantity (n) and percentage (%) of participants with Mild, Moderate, and Severe OSA. OSA, Obstructive Sleep Apnea.
Preprints 168392 g001
Table 1. CPAP and non-CPAP Demographic Data.
Table 1. CPAP and non-CPAP Demographic Data.
Features Non-CPAP (n = 9) CPAP (n = 12) P-value
Age, yrs 79 (72-81) 74 (60-78) 0.010
Sex

1.000
   Females 6 (66.67%) 9 (75.00%)
   Males 3 (33.33%) 3 (25.00%)
Education, yrs 12 (5-18) 9 (2-20) 0.327
Abbreviation: Yrs, Years.
Table 2. Neurocognitive Performance of all Subjects at Baseline and 12 Months Follow-Up.
Table 2. Neurocognitive Performance of all Subjects at Baseline and 12 Months Follow-Up.
Neurocognitive Test / Assessment Score T0 (Baseline)
(mean ± SD)		 Score T1 (12 Months)
(mean ± SD)		 P-value
CDR 0.64 ± 0.36 0.71 ± 0.37 0.223
MMSE 22.67 ± 5.35 20.71 ± 5.51 < 0.001
RBANS Total 66.24 ± 14.77 64.24 ± 15.48 < 0.001
RBANS IMI 65.05 ± 15.50 61.29 ± 15.25 < 0.001
RBANS LL 17.90 ± 5.51 16.50 ± 6.07 < 0.001
RBANS SM 7.24 ± 4.33 6.33 ± 4.82 0.001
RBANS VSPI 85.89 ± 19.38 87.95 ± 17.08 0.056
RBANS FC 16.65 ± 2.66 17.10 ± 1.92 0.365
RBANS LO 13.00 ± 4.24 13.05 ± 4.05 0.031
RBANS LNGI 74.21 ± 19.12 77.68 ± 16.45 < 0.001
RBANS PN 7.84 ± 2.14 8.58 ± 1.71 0.016
RBANS SF 11.71 ± 5.58 11.38 ± 5.16 < 0.001
RBANS ATI 69.42 ± 18.14 69.11 ± 18.59 < 0.001
RBANS DDS 4.86 ± 1.28 4.48 ± 1.33 0.005
RBANS IDS 2.82 ± 2.83 4.47 ± 1.55 0.768
RBANS C 21.00 ± 14.15 20.00 ± 14.86 < 0.001
RBANS DMI 64.75 ± 19.35 57.30 ± 19.49 0.003
RBANS LR 1.10 ± 1.67 1.33 ± 2.20 0.003
RBANS LRe 14.90 ± 4.38 14.50 ± 2.70 0.349
RBANS SR 2.57 ± 2.77 1.86 ± 2.41 0.002
RBANS FR 5.86 ± 5.08 5.48 ± 5.71 0.003
Abbreviations: SD, Standard Deviation; MMSE, Mini-Mental State Examination; RBANS, Repeatable Battery for the Assessment of Neuropsychological Status; LL, List Learning; SM, Story Memory; IMI, Immediate Memory Index; FC, Figure Copy; LO, Line Orientation; VSPI, Visuospatial Index; PN, Picture Naming; SF, Semantic Fluency; LNGI, Language Index; DDS, Direct Digit Span; IDS, Indirect Digit Span; C, Coding; ATI, Attention Index; LR, List Recall; LRe, List Recognition; SR, Story Recall; FR, Figure Recall; DMI, Delayed Memory Index.
Table 3. Groups’ Neurocognitive Performance Differences at 12 Months Follow-Up Regarding Basal Diagnosis.
Table 3. Groups’ Neurocognitive Performance Differences at 12 Months Follow-Up Regarding Basal Diagnosis.
Neuropsychological Test / Assessment Non-CPAP (n = 9) CPAP (n = 12) P-value
T1 (12 Months) – T0 (Baseline)(mean ± SD) T1 (12 Months) – T0 (Baseline)(mean ± SD)
CDR 0.06 ± 0.17 0.08 ± 0.19 0.838
MMSE -3.78 ± 2.54 -0.58 ± 3.42 0.016
RBANS Total -6.38 ± 7.73 1.89 ± 9.09 0.028
RBANS IMI -4.78 ± 9.96 -3.00 ± 14.52 0.229
RBANS LL -2.56 ± 4.10 -0.45 ± 4.91 0.589
RBANS SM -0.78 ± 2.91 -1.00 ± 4.59 0.495
RBANS VSPI -6.11 ± 14.83 9.40 ± 20.59 0.119
RBANS FC -1.11 ± 2.09 1.73 ± 2.97 0.010
RBANS LO -0.33 ± 2.74 0.40 ± 4.81 0.988
RBANS LNGI 2.44 ± 12.27 4.40 ± 15.68 0.177
RBANS PN 0.67 ± 1.41 0.80 ± 1.99 0.643
RBANS SF -1.67 ± 2.69 0.67 ± 4.10 0.045
RBANS ATI -1.38 ± 6.80 0.45 ± 8.49 0.834
RBANS DDS -0.33 ± 0.87 -0.42 ± 0.79 0.961
RBANS IDS 2.00 ± 3.16 1.33 ± 4.27 0.151
RBANS C -3.38 ±6.07 0.73 ± 6.31 0.135
RBANS DMI -18.00 ± 13.87 1.18 ± 15.52 0.064
RBANS LR -0.44 ± 0.88 0.75 ± 2.18 0.326
RBANS LRe -2.67 ± 3.43 1.45 ± 4.95 0.145
RBANS SR -0.78 ± 1.09 -0.67 ± 1.87 0.211
RBANS FR -0.67 ± 4.09 -0.17 ± 4.93 0.802
Abbreviations: SD, Standard Deviation; MMSE, Mini-Mental State Examination; RBANS, Repeatable Battery for the Assessment of Neuropsychological Status; LL, List Learning; SM, Story Memory; IMI, Immediate Memory Index; FC, Figure Copy; LO, Line Orientation; VSPI, Visuospatial Index; PN, Picture Naming; SF, Semantic Fluency; LNGI, Language Index; DDS, Direct Digit Span; IDS, Indirect Digit Span; C, Coding; ATI, Attention Index; LR, List Recall; LRe, List Recognition; SR, Story Recall; FR, Figure Recall; DMI, Delayed Memory Index.
Table 4. Relationships Between Baseline V-PSG and Cognitive Progression.
Table 4. Relationships Between Baseline V-PSG and Cognitive Progression.
Sleep Stages Sleep Quality Sleep Position
N2 N3 REM TST SE W ST RST
Δ MMSE p-value 0.038 0.022 0.879 0.856 0.673 0.655 0.023 0.011
r -0.41 0.51 0.14 0.01 0.01 -0.02 -0.44 0.56
Δ RBANS Total p-value 0.415 0.299 0.766 0.055 0.090 0.094 0.549 0.076
r 0.19 0.21 0.03 0.35 0.29 -0.29 -0.10 0.35
Δ RBANS IMI p-value 0.106 0.977 0.044 0.014 0.038 0.048 0.420 0.966
r 0.32 -0.17 0.42 0.38 0.29 -0.27 0.25 -0.12
Δ RBANS LL p-value 0.393 0.628 0.015 0.024 0.036 0.041 0.705 0.866
r 0.18 0.01 0.53 0.40 0.36 -0.35 0.12 -0.02
Δ RBANS SM p-value 0.106 0.865 0.294 0.038 0.118 0.148 0.329 0.877
r 0.35 -0.17 0.20 0.39 0.26 -0.23 0.28 -0.07
Δ RBANS LO p-value 0.928 0.249 0.985 0.214 0.294 0.360 0.041 0.002
r -0.08 0.28 -0.13 0.10 0.07 -0.06 -0.43 0.54
Δ RBANS LNGI p-value 0.280 0.509 0.682 0.098 0.183 0.194 0.579 0.679
r 0.42 -0.04 -0.27 0.31 0.27 -0.26 0.26 -0.03
Δ RBANS PN p-value 0.216 0.683 0.893 0.235 0.379 0.390 0.153 0.410
r 0.49 -0.32 -0.19 0.25 0.21 -0.21 0.46 -0.30
Δ RBANS SF p-value 0.191 0.281 0.266 0.032 0.018 0.016 0.882 0.656
r 0.37 0.09 0.11 0.33 0.39 -0.41 0.12 -0.02
Δ RBANS ATI p-value 0.291 0.625 0.955 0.278 0.456 0.465 0.855 0.615
r 0.24 0.13 -0.02 0.22 0.15 -0.14 -0.04 0.10
Δ RBANS DDS p-value 0.178 0.154 0.781 0.242 0.328 0.344 0.014 0.058
r -0.33 0.36 -0.12 -0.30 -0.25 0.24 -0.53 0.39
Δ RBANS C p-value 0.064 0.348 0.993 0.020 0.016 0.014 0.445 0.937
r 0.42 0.21 -0.02 0.47 0.49 -0.50 0.19 -0.03
Δ RBANS DMI p-value 0.227 0.536 0.759 0.427 0.317 0.300 0.632 0.639
r 0.32 0.03 0.09 0.24 0.29 -0.31 -0.04 0.04
Δ RBANS LR p-value 0.196 0.515 0.769 0.191 0.121 0.109 0.084 0.271
r 0.32 0.06 0.09 0.29 0.35 -0.36 0.43 -0.30
Δ RBANS SR p-value 0.181 0.360 0.079 0.019 0.055 0.073 0.776 0.216
r 0.40 -0.10 0.45 0.51 0.40 -0.37 0.24 0.05
Δ RBANS FR p-value 0.328 0.035 0.473 0.549 0.253 0.196 0.273 0.207
r 0.25 0.46 -0.11 0.13 0.25 -0.28 -0.24 0.30
Abbreviations: MMSE, Mini-Mental State Examination; RBANS, Repeatable Battery for the Assessment of Neuropsychological Status; LL, List Learning; SM, Story Memory; IMI, Immediate Memory Index; FC, Figure Copy; LO, Line Orientation; VSPI, Visuospatial Index; PN, Picture Naming; SF, Semantic Fluency; LNGI, Language Index; DDS, Direct Digit Span; IDS, Indirect Digit Span; C, Coding; ATI, Attention Index; LR, List Recall; LRe, List Recognition; SR, Story Recall; FR, Figure Recall; DMI, Delayed Memory Index; N2: NREM Stage 2 (min); N3: NREM Stage 3 (min), REM: Rapid-Eye Movement (min); TST: Total Sleep Time (min); SE: Sleep Efficiency (%); W: Wakefulness (min); ST: Supine Time (min); RST: Right-Side Time (min).
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