Abstract
Introduction
In Prader–Willi syndrome (PWS) adult patients, sleep-breathing disorders, especially obstructive sleep apnoea syndrome (OSAS), are very common, whose missed or delayed diagnosis can contribute to further increase cardiovascular morbidity and mortality.
Purpose
The aim of this cross-sectional study was to evaluate differences in sleep-breathing parameters obtained by overnight cardiorespiratory polygraphy in 13 adult PWS patients and 13 individuals with non-syndromic obesity as controls matched by age, sex, and BMI.
Methods
In all subjects’ anthropometric parameters, body composition using bioimpedance analysis and overnight cardiorespiratory monitoring parameters were obtained.
Results
Ten (76.9%) PWS patients were diagnosed with OSAS, most notably nine (69.2%) and one PWS (7.7%) with mild and severe OSAS, respectively. Compared with the control group, PWS patients had evidence of higher apnoea–hypopnea index (AHI) (p = 0.04) and oxyhaemoglobin desaturation index (ODI) (p = 0.009). However, no differences were found between the two groups regarding OSAS categories or diagnosis of nocturnal respiratory failure. In the PWS group, there were no significant correlations among AHI, ODI and hypoxemia index (T90) and anthropometric measurements, fat mass (FM), and FM percentage (%). Conversely, in the control group, the sleep-related respiratory indices evaluated correlated positively with BMI, waist circumference, FM and FM%.
Conclusions
This study confirmed that AHI and ODI indices were worse in PWS than in age, sex and BMI-matched controls. The lack of their significant association with the anthropometric parameters and FM supported the existence of PWS-related mechanisms in OSAS pathophysiology that are independent of visceral obesity and FM.
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Introduction
Prader–Willi syndrome (PWS) is a rare genetic disorder caused by the lack of expression of genes on the paternally inherited chromosome 15q11.2-q13, with an estimated prevalence that ranges between 1/10,000 and 1/30,000 [1]. At birth, typical clinical manifestations include muscular hypotonia, feeding difficulties, retarded psychomotor development, and slowed growth with short stature. During childhood and adulthood, PWS patients generally develop pathologic hyperphagia responsible for severe obesity and early metabolic alterations, associated to mild-to-moderate intellectual and learning disabilities, behavioural and psychiatric symptoms, including obsessive–compulsive and oppositional behaviours [1,2,3].
Hypothalamic dysfunction is also a common finding in PWS that has been implicated in several clinical manifestations of the syndrome, including temperature instability, high pain threshold, sleep-breathing disorders, and endocrine abnormalities, such as growth hormone (GH) deficiency, central adrenal insufficiency, hypogonadism, and hypothyroidism [4]. These hormonal abnormalities contributed to the typical body composition pattern observed in PWS, which is characterised by higher fat mass (FM) than fat-free mass (FFM) compared with individuals with non-syndromic obesity matched for age and gender [5], reduced FFM and increased FM/FFM ratio when compared with both normal weight and individuals with obesity [6, 7]. However, in line with a recent paper by Grugni et al., the institution of GH replacement therapy during childhood could account for persistent improvement of body composition in adulthood [8].
The sleep-breathing disorder most frequently encountered in PWS patients is obstructive sleep apnoea syndrome (OSAS) [9]. OSAS is characterised by recurrent apnoeic events with increased upper airway resistance in the presence of respiratory effort, which leads to intermittent hypoxia and sleep fragmentation [10]. Polysomnography is the gold standard for diagnosis of OSAS [11].
However, polysomnography is a costly procedure with technical difficulties, which requires to be performed in a sleep laboratory. In addition, due to the variable grade of intellectual disability that characterise PWS, these patients not always are compliant or easily tolerate the complex polysomnographic recording devices.
Home overnight cardiorespiratory polygraphy is a reliable alternative to overnight polysomnography for the diagnosis of sleep-breathing disorders [12, 13]. It is of great clinical relevance to investigate the concomitant presence of OSAS in PWS, as OSAS represents an independent risk factor for hypertension, insulin resistance, and type 2 diabetes mellitus (T2DM) [9], which worsen the metabolic and cardiovascular risk in these patients.
In the general population, OSAS has a prevalence of 17%, which reaches 40–70% in individuals with obesity, and 58–86% in individuals with type T2DM [9].
Gender is a known potential moderator of OSAS prevalence in general population [14, 15]. In particular, among adults, the prevalence of OSAS was higher in men (13–33%) than in women (6–19%). However, to date, a gender difference in the prevalence of OSAS in PWS has not been demonstrated [16], as well as there are no significant gender differences in apnoea–hypopnea index (AHI) [17], or significant correlations between the sleep variables and gender in PWS patients [18]. According to recent studies, in children with PWS, the prevalence of OSAS is about 80–93% [16, 19], which is significantly higher than that observed in the general paediatric population (1–4%) [20]. In the adult population with PWS, the prevalence of OSAS reaches 95%, with a prevalence of 21% of severe OSAS, defined as presence of more than 30 apnoea or hypopneas events per hour [21].
In particular, obesity, altered ventilatory control, airway hypotonia, micrognathia, narrowing of the upper airway, and respiratory muscle weakness, are all common conditions in PWS that contribute to make these patients highly vulnerable to developing sleep-breathing disorders [22].
However, due to the psychomotor retardation that affects PWS patients, the symptoms of OSAS can be difficult to detect. Caregivers often report snoring, nocturnal breathing difficulties, and restless sleep, as well as marked daytime sleepiness [23]. However, if PWS patients are not carefully assisted by a multidisciplinary team, the diagnosis of OSAS can escape. The missed diagnosis of OSAS can have repercussions on both sleep and life quality, which contribute to further increase cardiovascular morbidity and mortality in PWS patients [24]. There is also evidence of sudden and unexplained death during sleep in patients with PWS, which may be secondary to respiratory pathology [25].
So far, studies analysing the differences between adult patients with PWS and non-syndromic obesity are limited. In particular, Yee et al. previously reported that in a sample cohort of adult and adolescent PWS patients compared with a control group matched on the basis of age, sex, and body mass index (BMI), PWS patients had more evidence of nocturnal hypoxemia, with lower saturations of oxyhaemoglobin and higher percentages of sleep time at less than 80% oxyhaemoglobin saturation [21].
The aim of this study was to investigate the differences in sleep-breathing parameters, in particular AHI, oxyhaemoglobin desaturation index (ODI) and hypoxemia index (T90), evaluated by overnight cardiorespiratory polygraphy, in a sample of adult PWS patients compared with age, sex and BMI-matched controls, and their possible association with body composition.
Materials and methods
We carried out a cross-sectional observational study at the Department of Clinical Medicine and Surgery, Unit of Endocrinology, University Federico II, Naples (Italy). The study protocol, approved by the Ethical Committee of the University of Naples Federico II Medical School (n. 173/16), was carried according to the Code of Ethics of the World Medical Association (Declaration of Helsinki) for experiments involving humans and patients were widely informed before signing their consent. For the PWS group, subject consent was acquired through the primary caregiver or guardian.
Thirteen adult PWS patients with genetically confirmed diagnoses (via positive methylation testing) attending the Outpatient Clinic of the Unit of Endocrinology were consecutively recruited from October 2016 to January 2020 regardless of symptoms of OSAS. Ten patients received GH replacement therapy during childhood, while only three patients were diagnosed in adulthood and were not treated. GH therapy was withdrawn at least 10 years before being selected for this study.
Thirteen Caucasian age, sex and BMI-matched control subjects with obesity were consecutively recruited from the same geographical area around Naples metropolitan area, Italy, among subjects referred to the pneumology unit for snoring or other clinical features of OSAS, as daytime sleepiness, difficulty concentrating, and diurnal somnolence. None of them had previously diagnosed with OSAS or was treated with continuous positive airway pressure (CPAP). Subjects were excluded if they had any known lung disease or uncontrolled metabolic or cardiovascular diseases. Subjects were also excluded if they were on anti-obesity treatments, ketogenic diet, stimulant medications, medications that would affect sleep and breathing (e.g. opiates, benzodiazepines), or had significant alcohol intake. Since the study protocol included the assessment of body composition by bioimpedance analysis (BIA), we excluded subjects with pacemakers or defibrillators that could potentially interfere with BIA assessment, or patients suffering from chronic diseases that could interfere with fluid homeostasis, such as liver or chronic renal diseases, cancer, and acute or chronic inflammatory diseases.
All the anthropometric parameters were measured in the morning between 8:00 a.m. and 12:00 p.m. after an overnight fast, by an expert Nutritionist according to the International Society for the Advancement of Kinanthropometry of 2006 (ISAK 2006), with patients wearing light clothes and without shoes [26, 27]. The height was measured with a wall-mounted stadiometer (Seca 711; Seca, Hamburg, Germany), while weight was assessed by a calibrated balance beam scale (Seca 711; Seca, Hamburg, Germany). A no stretchable measuring tape was used to assess waist circumference (WC) by the same Nutritionist: tape was placed around the bare abdomen just above the hip bone and parallel to the floor and measurement was taken to the nearest centimetre at the midpoint between the bottom of the rib cage and above the top of the iliac crest during minimal respiration [28]. BMI was calculated using the following formula: weight (kg) divided by height squared (m2), and BMI was used to divide the subjects into obesity classes as established by World Health Organization’s criteria: grade I obesity (BMI: 30.0–34.9 kg/m2), grade II obesity (BMI: 35.0–39.9 kg/m2), and grade III obesity (BMI ≥ 40.0 kg/m2) [29].
On the same day, immediately after the measurement of the anthropometric parameters and, therefore, still in a fasting condition, body composition was assessed using a BIA phase-sensitive system by experienced observers (an 800-µA current at a frequency single-frequency of 50 kHz BIA 101 RJL, Akern Bioresearch, Florence, Italy). The exam was performed as suggested by the European Society of Parental and Enteral Nutrition (ESPEN) [30]. The electrodes were placed on the hand and the ipsilateral foot, according to Kushner [31]. The fat mass was obtained using the prediction equation for adult male PWS patients developed by Gray et al. [32] and for female PWS patients developed by Bedogni et al. [33], as already used in other works [34, 35]. The same operator and the same device obtained BIA determinations under strictly standardised conditions to avoid interobserver and inter-device variability. The BIA was routinely checked with resistors and capacitors of known values.
Overnight cardiorespiratory monitoring in ambient air was performed through the polygraph (Vital Night, Vitalaire, Rangendingen, Germany) with assessment of airflow through nasal cannula, respiratory effort by thoraco-abdominal bands and oxygen saturation and heart rate with pulse oximetry [36]. Cardiorespiratory monitoring measures apnoea events, that are defined as episodes of cessation of breathing of at least 10 s with or without oxygen desaturation, and hypopnea events characterised by a reduction of respiration of at least 10 s with a reduction of at least 30% of the nasal pressure signal. The number of apnoea and hypopnea events per hour of sleep was used to calculate the AHI. According to international guidelines, diagnosis of OSAS was made if there were an AHI ≥ 5/h. This index was also used to stratify the disease severity: mild with AHI ranging between 5 and 14/h, moderate with AHI between 15 and 29/h and severe with AHI ≥ 30/h [37]. ODI corresponds to the number of desaturations ≥ 4% per hour of recording and an ODI value > 10 raises the suspicion of OSAS. T90 was also evaluated, i.e. the percentage of time spent with oxygen saturation < 90%. If the T90 is > 30% of the recording time, nocturnal respiratory failure is diagnosed [36].
Statistical analysis
Data of the study participants were expressed as means and standard deviations (SD) for normally distributed continuous variables and relative frequencies for categorical variables. The data normal distribution was evaluated by a Kolmogorov–Smirnov test, and the abnormal data were normalised by a logarithm. Skewed variables were back transformed for presentation in tables and figures.
Differences between adults PSW and control group were analysed by Student’s paired t-test. Chi square (χ2) test was used to determine the significance of differences in the variable frequency distribution across OSAS and ODI categories, and between nocturnal respiratory insufficiency (Y/N). The correlations between sleep-related respiratory indices and age, anthropometric parameters, and FM were assessed with Pearson r correlation coefficient. The level of significance was taken as p < 0.05. Data were analysed using the SPSS Software (PASW Version 21.0, SPSS Inc., Chicago, IL, USA) and MedCalc® package (Version 12.3.0 1993- 2012 MedCalc Software bvba—MedCalc Software, Mariakerke, Belgium.
Results
The study population consisted of 26 participants: 13 adult PWS patients and 13 controls matched by age, sex, and BMI. Age, anthropometric characteristics, including WC as a surrogate measure of visceral adiposity, FM and FM percentage (FM%) of the study population are summarised in Table 1. There were no significant differences in anthropometric parameters or FM between PWS adults and controls.
Ten (76.9%) PWS patients were diagnosed with OSAS, nine (69.2%) and one PWS (7.7%) with mild and severe OSAS, respectively. OSAS prevalence did not differ significantly between PWS and control group (10/13 vs 6/13: χ2 2.6, p = 0.11). Compared with the control group, PWS patients had evidence of higher AHI (p = 0.04) and ODI (p = 0.009). As reported in Table 2, no differences were found between the two groups regarding OSAS categories (mild, moderate, severe), diagnosis of nocturnal respiratory failure based on T90 and suspicion of OSAS based on ODI > 10.
Correlation study
In the PWS group, there was no significant correlation in the sleep-related respiratory indices included in the study and anthropometric measurements, FM and FM% (Table 3). Conversely, in the control group, AHI correlated positively with BMI (r = 0.88; p = 0.001), WC (r = 0.73; p = 0.005), FM (r = 0.85; p = 0.001) and FM% (r = 0.76; p = 0.002); ODI correlated positively with BMI (r = 0.95; p = 0.001), WC (r = 0.84; p = 0.001), FM (r = 0.93; p = 0.001) and FM% (r = 0.82: p = 0.001); T90 correlated positively with BMI (r = 0.94; p = 0.001), WC (r = 0.96; p = 0.001), FM (r = 0.95; p = 0.001) and FM% (r = 0.86; p = 0.001).
Discussion
In line with the current literature [21], in our study, we found a high prevalence of OSAS in adult PWS patients, although without significant differences compared with a well-matched obese control population. As novel finding, we showed that there were significant differences in sleep-related respiratory indices obtained by the home overnight cardiorespiratory polygraphy between PWS patients and controls. In particular, PWS patients had a higher AHI and more frequent episodes of oxygen nocturnal desaturation compared with controls. Of interest, while in controls, the sleep-related respiratory indices were positively associated with anthropometric parameters, including WC as a surrogate measure of visceral adiposity, and fat mass, these correlations were not evident in PWS patients.
Our findings are in line with those of Marzullo et al., who demonstrated a significantly higher number of apnoea–hypopnea episodes and greater nocturnal desaturation in PWS patients than controls with non-syndromic obesity [38]. Moreover, our data confirm that the prevalence of OSAS is high among adult PWS patients, albeit not different compared to controls. However, while PWS patients performed the nocturnal respiratory monitoring without specific symptom of OSAS as part of the screening protocol provided by the PWS management guidelines, controls were recruited by the pneumology unit for suspected symptoms of OSAS.
In addition, we also observed a major impairment of sleep-related respiratory indices in PWS patients compared with controls. The major impairment of sleep-related respiratory indices in PWS patients let us to speculate that, in addition to the known risk factors for OSAS shared by PWS and non-syndromic obesity, such as excess weight, visceral obesity, and pulmonary restriction, there are PWS-related factors not normally present in subjects with non-syndromic obesity, such typical body composition pattern [5], respiratory muscle weakness, chest wall deformities, severe scoliosis, and craniofacial abnormalities, which could contribute to worsen the respiratory function in PWS patients and that therefore deserve to be investigated with ad hoc studies [22].
The independent relationship of the major impairment of sleep-related respiratory indices and obesity in PWS patients is in line with the similar independent relationship of ventilatory control responses to hypoxemia and hypercapnia and obesity in these patients. In particular, when breathing air with a reduced percentage of oxygen compared to the ambient air, 35% of PWS patients did not exhibit a hypoxic ventilatory response, while the remaining patients had a significantly blunted response compared to healthy controls [39]. Similarly, PWS patients had a blunted hypercapnic ventilatory response compared to non-obese PWS patients and BMI-matched obese controls, as further impediment in maintaining normoxia and normocapnia in an efficient manner [39]. Therefore, the ventilatory response to both hypoxia and hypercapnia appears to be reduced in PWS patients regardless of BMI, and the response to hypercapnia appears to be altered even during sleep [39], thus suggesting that abnormal arousal response or different thresholds to hypoxia and hypercapnia may be another contributing factor to OSAS in PWS.
In this complex scenario, it is tempting to speculate that the higher nocturnal desaturation in our sample of adult PWS patients compared with BMI-matched controls could unravel abnormalities in the brain centres that regulate sleep and breathing in PWS. In particular, genes identified at the neuronal level in animal models, including Necdin and Necdin-related MAGE, and involved in the control of respiration, are imprinted genes, whose paternal expression is absent in PWS [40]. In fact, it has been observed that Necdin deficiency alters the serotonergic metabolism, the morphology of serotonin vesicles in medullary serotonergic neurons, and that Necdin deficiency in mice induces central respiratory deficits reminiscent of PWS (irregular rhythm, frequent apnoeas, and blunted respiratory regulations) [40]. This experimental evidence suggested that the lack of Necdin could affect maturation and function of the respiratory network in PWS.
Furthermore, a dysfunction of the orexin system seems to be present both in animal models [41] and in PWS patients [42], which might be involved in the sleep-breathing disorders in PWS. Orexin is a neuropeptide exclusively produced in the perifornical area and the lateral and posterior hypothalamic area of the brain. Orexin neurons project throughout the central nervous system to nuclei involved in the control of sleep–wakefulness, feeding, neuroendocrine homeostasis, and autonomic regulation [43]. Recent evidence showed moderately decreased cerebrospinal fluid orexin levels in PWS patients [44], although the number of orexin neurons in the hypothalamus was not reduced in patients with PWS [45]. Therefore, the orexin deficiency in PWS appears to be more related to the disruption in the connecting pathway between the hypothalamus, the cerebral cortex, and the brainstem [45], rather than to the reduction in the number of orexin neurons. Interestingly, experimental studies on mouse models with orexin deficiency [46, 47] reported both a modulatory effect of the hypothalamic orexin system on respiratory activity [48], and an increase in spontaneous sleep apnoeas, especially in REM sleep [49], thus suggesting that the orexin dysfunction found in PWS may partly contribute to the pathophysiology of sleep-breathing disorders, commonly present in this syndrome.
Several studies have shown a relationship between increased BMI and both severity of OSAS and greater AHI in general population [16, 50]. As above mentioned, and in agreement with previous observations [19, 51], our findings confirmed that in our group of PWS patients there were no correlations between AHI and BMI or other anthropometric parameters included in the study. However, considering that BMI is a rather inaccurate measure of adiposity that does not allow to discriminate between fat mass and free fat mass, we included the assessment of fat mass obtained using BIA, and demonstrated that in PWS patients AHI and the other saturation parameters did not correlate with fat mass. Indeed, we found that there was a trend in the differences in FM% between PWS patients and controls, with a lower FM% in PWS patients. In line with the current literature [8], this finding lets us to hypothesise that the institution of the GH therapy during childhood in the vast majority of PWS patients included in our study group could account for the persistent improvement of body composition in adulthood in comparison with age and BMI-matched controls.
Regarding mortality in PWS patients, excluding the condition of sudden death with unknown cause, respiratory failure was the most common cause accounting for 31% of all deaths, followed by cardiac disease/failure (16%) [52]. These data suggest a possible reciprocal pathophysiological influence between the two systems in PWS patients, thus supporting the need for a complete cardiorespiratory evaluation. In particular, OSAS could be a potential contributor to cardiovascular alterations in PWS. In the general population, OSAS is an independent risk factor for arrhythmias, sympathetic hyperactivity, hypertension, diastolic and systolic dysfunction, pulmonary congestion, and cardiac hypertrophy [53]. In PWS patients sleep apnoea-related hypoxia is acknowledged as a cause of cor pulmonale [25, 54]. In addition, PWS patients have a lower left ventricle mass compared to subjects with non-syndromic obesity, and this aspect seems to be only partially dependent on GH deficiency, responsible for a hypotrophic hypokinetic syndrome. In particular, both Insulin-like growth factor-I levels and nocturnal oxygen desaturation were main significant predictors of left ventricle mass and heart rate in PWS patients [38]. To further underline the bidirectional link between OSAS and cardiovascular disease in PWS, it is reported in the literature that the use of adaptive servoventilation can improve the prognosis in case of heart failure in PWS secondary to sleep-disordered breathing [55]. These data supported to include the diagnosis and therapy of OSAS in the prevention of cardiovascular risk in PWS.
In non-syndromic obesity, there is also consolidated evidence regarding the effect of CPAP not only on the improvement of sleep-breathing parameters, but also of metabolic and cardiovascular risk factors [9]. CPAP treatment is also recommended in PWS patients with OSAS [56]. In a small cohort of PWS patients and in some case reports, CPAP was effective in improving OSAS-related symptoms, particularly excessive daytime sleepiness [51, 57,58,59]. However, the cardiometabolic effects of CPAP treatment in PWS patients have not yet been studied.
There are some limitations to this study. First, the cross-sectional nature of this study did not allow any statements on the causal relationships between OSAS and adiposity in PWS. Second, the sample size was relatively small, and this is because PWS is a rare disease. Nevertheless, we have calculated the sample size using 95% power to enrol the appropriate number of patients for each group, matching also controls for gender, age, and BMI. Third, we performed the overnight cardiorespiratory monitoring and did not the polysomnographic recording, so we are not able to determine accurately sleep stage and hypopneas linked to arousal. As a final limitation of the study, BIA is not the most accurate method for assessing body composition, although it is a commonly used and validated method in the clinical practice, with a high agreement with Dual X-ray Absorptiometry, also among patients with severe obesity [60]. However, the main strength of this study was the use of a control group age, sex and BMI-matched that allowed us to assess whether PWS per se was associated with worse sleep-related respiratory indices regardless of the obesity condition.
Conclusion
In conclusion, we reported there were significant differences in sleep-related respiratory indices obtained by the home overnight cardiorespiratory polygraphy between PWS patients and a well-matched obese control population. Of interest, the alterations in sleep-related respiratory indices were not associated with anthropometric parameters, including WC, as a surrogate measure of visceral adiposity, and fat mass, thus supporting the existence of PWS-related OSAS pathophysiological mechanisms independent of visceral obesity and fat mass. Further studies with polysomnographic recording are mandatory to confirm this hypothesis.
Data availability
The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.
Code availability
Not applicable.
Abbreviations
- PWS:
-
Prader–Willi syndrome
- GH:
-
Growth hormone
- FM:
-
Fat Mass
- FFM:
-
Fat-Free Mass
- OSAS:
-
Obstructive sleep apnoea syndrome
- T2DM:
-
Type 2 diabetes mellitus
- BMI:
-
Body mass index
- BIA:
-
Bioimpedance analysis
- WC:
-
Waist circumference
- AHI:
-
Apnoea–hypopnea index
- ODI:
-
Oxyhaemoglobin desaturation index
- T90:
-
Hypoxemia index
- CPAP:
-
Continuous positive airway pressure
- IL-1β:
-
Interleukin-1β
- TNFα:
-
Tumour necrosis factor-α
References
Cassidy SB, Schwartz S, Miller JL, Driscoll DJ (2012) Prader-Willi syndrome. Genet Med 14:10–26
Kayadjanian N, Schwartz L, Farrar E, Comtois KA, Strong TV (2018) High levels of caregiver burden in Prader-Willi syndrome. PLoS ONE 13:e0194655
Muscogiuri G, Barrea L, Faggiano F, Maiorino MI, Parrillo M, Pugliese G, Ruggeri RM, Scarano E, Savastano S, Colao A et al (2021) Obesity in Prader-Willi syndrome: physiopathological mechanisms, nutritional and pharmacological approaches. J Endocrinol Invest 44:2057–2070
Muscogiuri G, Formoso G, Pugliese G, Ruggeri RM, Scarano E, Colao A, Restare, (2019) Prader-Willi syndrome: an uptodate on endocrine and metabolic complications. Rev Endocr Metab Disord 20:239–250
Theodoro MF, Talebizadeh Z, Butler MG (2006) Body composition and fatness patterns in Prader-Willi syndrome: comparison with simple obesity. Obesity (Silver Spring) 14:1685–1690
Bedogni G, Grugni G, Tringali G, Agosti F, Sartorio A (2015) Assessment of fat-free mass from bioelectrical impedance analysis in obese women with Prader-Willi syndrome. Ann Hum Biol 42:538–542
Cimolin V, Cau N, Galli M, Pau M, Parisio C, Saezza A, Grugni G, Capodaglio P (2021) Gait strategy and body composition in patients with Prader-Willi syndrome. Eat Weight Disord 26:115–124
Grugni G, Marzullo P, Delvecchio M, Iughetti L, Licenziati MR, Osimani S, Ragusa L, Salvatoni A, Sartorio A, Stagi S et al (2021) Stimulated GH levels during the transition phase in Prader-Willi syndrome. J Endocrinol Invest 44:1465–1474
Pugliese G, Barrea L, Laudisio D, Salzano C, Aprano S, Colao A, Savastano S, Muscogiuri G (2020) Sleep Apnea, obesity, and disturbed glucose homeostasis: epidemiologic evidence, biologic insights, and therapeutic strategies. Curr Obes Rep 9:30–38
Eckert DJ, White DP, Jordan AS, Malhotra A, Wellman A (2013) Defining phenotypic causes of obstructive sleep apnea. identification of novel therapeutic targets. Am J Respir Crit Care Med 188:996–1004
Sateia MJ (2014) International classification of sleep disorders-third edition: highlights and modifications. Chest 146:1387–1394
Laratta CR, Ayas NT, Povitz M, Pendharkar SR (2017) Diagnosis and treatment of obstructive sleep apnea in adults. CMAJ 189:E1481–E1488
Masa JF, Corral J, Pereira R, Duran-Cantolla J, Cabello M, Hernandez-Blasco L, Monasterio C, Alonso A, Chiner E, Rubio M et al (2011) Effectiveness of home respiratory polygraphy for the diagnosis of sleep apnoea and hypopnoea syndrome. Thorax 66:567–573
Heinzer R, Vat S, Marques-Vidal P, Marti-Soler H, Andries D, Tobback N, Mooser V, Preisig M, Malhotra A, Waeber G et al (2015) Prevalence of sleep-disordered breathing in the general population: the HypnoLaus study. Lancet Respir Med 3:310–318
Senaratna CV, Perret JL, Lodge CJ, Lowe AJ, Campbell BE, Matheson MC, Hamilton GS, Dharmage SC (2017) Prevalence of obstructive sleep apnea in the general population: a systematic review. Sleep Med Rev 34:70–81
Sedky K, Bennett DS, Pumariega A (2014) Prader Willi syndrome and obstructive sleep apnea: co-occurrence in the pediatric population. J Clin Sleep Med 10:403–409
Hertz G, Cataletto M, Feinsilver SH, Angulo M (1993) Sleep and breathing patterns in patients with Prader Willi syndrome (PWS): effects of age and gender. Sleep 16:366–371
Lin HY, Lin SP, Lin CC, Tsai LP, Chen MR, Chuang CK, Huang CY (2007) Polysomnographic characteristics in patients with Prader-Willi syndrome. Pediatr Pulmonol 42:881–887
Canora A, Franzese A, Mozzillo E, Fattorusso V, Bocchino M, Sanduzzi A (2018) Severe obstructive sleep disorders in Prader-Willi syndrome patients in southern Italy. Eur J Pediatr 177:1367–1370
Lumeng JC, Chervin RD (2008) Epidemiology of pediatric obstructive sleep apnea. Proc Am Thorac Soc 5:242–252
Yee BJ, Buchanan PR, Mahadev S, Banerjee D, Liu PY, Phillips C, Loughnan G, Steinbeck K, Grunstein RR (2007) Assessment of sleep and breathing in adults with Prader-Willi syndrome: a case control series. J Clin Sleep Med 3:713–718
Gillett ES, Perez IA (2016) Disorders of sleep and ventilatory control in Prader-Willi syndrome. Diseases 4(4):23
Manni R, Politini L, Nobili L, Ferrillo F, Livieri C, Veneselli E, Biancheri R, Martinetti M, Tartara A (2001) Hypersomnia in the Prader Willi syndrome: clinical-electrophysiological features and underlying factors. Clin Neurophysiol 112:800–805
Yaggi HK, Concato J, Kernan WN, Lichtman JH, Brass LM, Mohsenin V (2005) Obstructive sleep apnea as a risk factor for stroke and death. N Engl J Med 353:2034–2041
Stevenson DA, Anaya TM, Clayton-Smith J, Hall BD, Van Allen MI, Zori RT, Zackai EH, Frank G, Clericuzio CL (2004) Unexpected death and critical illness in Prader-Willi syndrome: report of ten individuals. Am J Med Genet A 124A:158–164
Barrea L, Annunziata G, Muscogiuri G, Laudisio D, Di Somma C, Maisto M, Tenore GC, Colao A, Savastano S (2019) Trimethylamine N-oxide, Mediterranean diet, and nutrition in healthy, normal-weight adults: also a matter of sex? Nutrition 62:7–17
Barrea L, Muscogiuri G, Di Somma C, Tramontano G, De Luca V, Illario M, Colao A, Savastano S (2019) Association between Mediterranean diet and hand grip strength in older adult women. Clin Nutr 38:721–729
Nishida C, Ko GT, Kumanyika S (2010) Body fat distribution and noncommunicable diseases in populations: overview of the 2008 WHO Expert Consultation on Waist Circumference and Waist-Hip Ratio. Eur J Clin Nutr 64:2–5
https://www.who.int/health-topics/obesity. Accessed 12 Feb 2022
Rosato E, Gigante A, Gasperini ML, Proietti L, Muscaritoli M (2021) Assessing malnutrition in systemic sclerosis with global leadership initiative on malnutrition and European Society of Clinical Nutrition and Metabolism Criteria. JPEN J Parenter Enteral Nutr 45:618–624
Kushner RF (1992) Bioelectrical impedance analysis: a review of principles and applications. J Am Coll Nutr 11:199–209
Gray DS, Bray GA, Gemayel N, Kaplan K (1989) Effect of obesity on bioelectrical impedance. Am J Clin Nutr 50:255–260
Bedogni G, Grugni G, Tringali G, Tamini S, Marzullo P, Sartorio A (2019) Assessment of fat-free mass from bioelectrical impedance analysis in men and women with Prader-Willi syndrome: cross-sectional study. Int J Food Sci Nutr 70:645–649
Lazzer S, Grugni G, Tringali G, Sartorio A (2016) Prediction of basal metabolic rate in patients with Prader-Willi syndrome. Eur J Clin Nutr 70:494–498
Barrea L, Pugliese G, de Alteriis G, Colao A, Savastano S, Muscogiuri G (2020) Phase angle: could be an easy tool to detect low-grade systemic inflammation in adults affected by Prader-Willi syndrome? Nutrients 12:2065
Berry RB, Budhiraja R, Gottlieb DJ, Gozal D, Iber C, Kapur VK, Marcus CL, Mehra R, Parthasarathy S, Quan SF et al (2012) Rules for scoring respiratory events in sleep: update of the 2007 AASM manual for the scoring of sleep and associated events. Deliberations of the sleep apnea definitions task force of the American Academy of Sleep Medicine. J Clin Sleep Med 8:597–619
Kapur VK, Auckley DH, Chowdhuri S, Kuhlmann DC, Mehra R, Ramar K, Harrod CG (2017) Clinical practice guideline for diagnostic testing for adult obstructive sleep apnea: an American Academy of Sleep Medicine Clinical Practice Guideline. J Clin Sleep Med 13:479–504
Marzullo P, Marcassa C, Campini R, Eleuteri E, Minocci A, Priano L, Temporelli P, Sartorio A, Vettor R, Liuzzi A et al (2005) The impact of growth hormone/insulin-like growth factor-I axis and nocturnal breathing disorders on cardiovascular features of adult patients with Prader-Willi syndrome. J Clin Endocrinol Metab 90:5639–5646
Arens R, Gozal D, Omlin KJ, Livingston FR, Liu J, Keens TG, Ward SL (1994) Hypoxic and hypercapnic ventilatory responses in Prader-Willi syndrome. J Appl Physiol 1985(77):2224–2230
Zanella S, Watrin F, Mebarek S, Marly F, Roussel M, Gire C, Diene G, Tauber M, Muscatelli F, Hilaire G (2008) Necdin plays a role in the serotonergic modulation of the mouse respiratory network: implication for Prader-Willi syndrome. J Neurosci 28:1745–1755
Pace M, Colombi I, Falappa M, Freschi A, Bandarabadi M, Armirotti A, Encarnacion BM, Adamantidis AR, Amici R, Cerri M et al (2020) Loss of Snord116 alters cortical neuronal activity in mice: a preclinical investigation of Prader-Willi syndrome. Hum Mol Genet 29:2051–2064
Cataldi M, Arnaldi D, Tucci V, De Carli F, Patti G, Napoli F, Pace M, Maghnie M, Nobili L (2021) Sleep disorders in Prader-Willi syndrome, evidence from animal models and humans. Sleep Med Rev 57:101432
Willie JT, Chemelli RM, Sinton CM, Yanagisawa M (2001) To eat or to sleep? Orexin in the regulation of feeding and wakefulness. Annu Rev Neurosci 24:429–458
Omokawa M, Ayabe T, Nagai T, Imanishi A, Omokawa A, Nishino S, Sagawa Y, Shimizu T, Kanbayashi T (2016) Decline of CSF orexin (hypocretin) levels in Prader-Willi syndrome. Am J Med Genet A 170A:1181–1186
Fronczek R, Lammers GJ, Balesar R, Unmehopa UA, Swaab DF (2005) The number of hypothalamic hypocretin (orexin) neurons is not affected in Prader-Willi syndrome. J Clin Endocrinol Metab 90:5466–5470
Kuwaki T, Li A, Nattie E (2010) State-dependent central chemoreception: a role of orexin. Respir Physiol Neurobiol 173:223–229
Dergacheva O, Yamanaka A, Schwartz AR, Polotsky VY, Mendelowitz D (2016) Hypoxia and hypercapnia inhibit hypothalamic orexin neurons in rats. J Neurophysiol 116:2250–2259
Fukushi I, Yokota S, Okada Y (2019) The role of the hypothalamus in modulation of respiration. Respir Physiol Neurobiol 265:172–179
Kuwaki T (2008) Orexinergic modulation of breathing across vigilance states. Respir Physiol Neurobiol 164:204–212
Williams K, Scheimann A, Sutton V, Hayslett E, Glaze DG (2008) Sleepiness and sleep disordered breathing in Prader-Willi syndrome: relationship to genotype, growth hormone therapy, and body composition. J Clin Sleep Med 4:111–118
Pavone M, Caldarelli V, Khirani S, Colella M, Ramirez A, Aubertin G, Crino A, Brioude F, Gastaud F, Beydon N et al (2015) Sleep disordered breathing in patients with Prader-Willi syndrome: a multicenter study. Pediatr Pulmonol 50:1354–1359
Butler MG, Manzardo AM, Heinemann J, Loker C, Loker J (2017) Causes of death in Prader-Willi syndrome: Prader-Willi Syndrome Association (USA) 40-year mortality survey. Genet Med 19:635–642
Hamilton GS, Solin P, Naughton MT (2004) Obstructive sleep apnoea and cardiovascular disease. Intern Med J 34:420–426
Schrander-Stumpel CT, Curfs LM, Sastrowijoto P, Cassidy SB, Schrander JJ, Fryns JP (2004) Prader-Willi syndrome: causes of death in an international series of 27 cases. Am J Med Genet A 124A:333–338
Kawano H, Ikeda T, Shimazaki K, Arakawa S, Matsumoto Y, Hayano M, Maemura K (2013) Successful treatment of heart failure in an adult patient with Prader-Willi syndrome. Intern Med 52:771–776
Dodet P, Sanapo F, Leu-Semenescu S, Coupaye M, Bellicha A, Arnulf I, Poitou C, Redolfi S (2022) Sleep disorders in adults with Prader-Willi syndrome: review of the literature and clinical recommendations based on the experience of the French reference centre. J Clin Med 11:1986
Clift S, Dahlitz M, Parkes JD (1994) Sleep apnoea in the Prader-Willi syndrome. J Sleep Res 3:121–126
Doshi A, Udwadia Z (2001) Prader-Willi syndrome with sleep disordered breathing: effect of two years nocturnal CPAP. Indian J Chest Dis Allied Sci 43:51–53
Sforza E, Krieger J, Geisert J, Kurtz D (1991) Sleep and breathing abnormalities in a case of Prader-Willi syndrome. the effects of acute continuous positive airway pressure treatment. Acta Paediatr Scand 80:80–85
Savastano S, Belfiore A, Di Somma C, Mauriello C, Rossi A, Pizza G, De Rosa A, Prestieri G, Angrisani L, Colao A (2010) Validity of bioelectrical impedance analysis to estimate body composition changes after bariatric surgery in premenopausal morbidly women. Obes Surg 20:332–339
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Conceptualization, GP, LB and ASZ; methodology, GP and LB; software, GP and LB; validation, AC and S.S.; formal analysis, GP and LB; investigation, GP, LB and ASZ; resources, AC; data curation, GP, LB, GDA and SS; writing—original draft preparation, GP; writing—review and editing, SS; visualisation, AC; supervision, SS and AC; project administration, LB, GM and SS; all the authors have read and agreed to the published version of the manuscript.
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Pugliese, G., Barrea, L., Sanduzzi Zamparelli, A. et al. Body composition and obstructive sleep apnoea assessment in adult patients with Prader–Willi syndrome: a case control study. J Endocrinol Invest 45, 1967–1975 (2022). https://doi.org/10.1007/s40618-022-01831-5
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DOI: https://doi.org/10.1007/s40618-022-01831-5