Clinical characteristics of a large cohort of patients with narcolepsy candidate for pitolisant: a cross-sectional study from the Italian PASS Wakix® Cohort

The PASS-pitolisant study is an international, multicenter, observational, prospective, open-label long-term post-authorization safety study, currently ongoing in sleep centers with expertise in the management of narcolepsy. The enrollment period started in December 2016, in Italy in April 2017, and ended in June 2019, except for the UK, where the enrollment period was extended until 31 October 2019. In this paper, we present a cross-sectional study based on data from the inclusion visits performed in 14 Italian sleep centers that were included in the third interim report of the study updated as of January 2, 2020; therefore, none of patients was under pitolisant at the time of data analysis. Sleep centers participating in the study with the number of patients enrolled for each center are reported in Fig. 1.

The decision to initiate treatment with pitolisant was taken by the physician, according to routine clinical practice for a patient/symptom-centered approach, and independently of the decision to enroll the patient into the study. The research protocol was approved in each site by the local ethics committee.

Eligible patients were aged ≥ 18 years with NT1 or NT2 narcolepsy and suitable to be prescribed with pitolisant by specialists, according to clinical judgment and following the prescribing information of the drug’s summary of product characteristics, consistent with the real-world disease management. The exclusion criteria were (1) known contraindication to pitolisant (hypersensitivity to the active substance or to any of the excipients, severe hepatic insufficiency, breastfeeding, and pregnancy) and (2) patients who had received pitolisant during the 12 months preceding the inclusion. Before enrollment, patients signed informed consent to participate in the study. Study visits and/or questionnaire-based re-assessments were scheduled after patients’ inclusion, according to each sleep center’s routine practice, with the minimum requirement of one yearly visit over the course of treatment (in line with the clinical need to confirm drug prescription in Italy). Data collection was performed both with an e-CRF completed by the investigators and a self-administered paper questionnaire answered by patients at each visit. Data were collected locally, while data analysis was performed centrally by a dedicated contract research organization. In the current research, only data from the baseline visit were analyzed. The study protocol provided for annual meetings during which the investigators shared the patients’ treatment strategies.

The following data were recorded for each patient: demographics (age and sex), vital signs (heart rate, blood pressure, weight, height, and BMI), and comorbidities including cardiovascular diseases (coronary or cardiac insufficiency, arrhythmia, hypertension, and other cardiac/vascular disorders), hypercolesterolemia, neurological and psychiatric diseases (depression, anxiety, and other neurological or psychiatric conditions), obstructive sleep apnea, renal impairment, hepatic impairment, diabetes, obesity, autoimmune diseases, and other types of comorbidities. For each patient, we collected the diagnosis (NT1 or NT2), age at diagnosis, disease duration, diagnostic methodology (polysomnography plus multiple sleep latency test; CSF orexin deficiency), and the presence of symptoms (i.e., cataplexy, sleep paralysis, hallucinations, automatic behaviors, and disrupted nocturnal sleep). Daytime sleepiness at study inclusion was evaluated by the Epworth Sleepiness Scale (ESS) [22], and a score > 10 is consistent with the presence/persistence of EDS. To investigate the prevalence and impact of depressive symptoms, each patient completed the short version of the Beck Depression Inventory (BDI-13) [23], a self-administered form consisting of 13 items, scored from 0 to 3, and evaluating the main components of depression (affective, somatic, and cognitive), with a score > 4 suggestive of the presence of depressive symptoms (5–7: mild depressive symptoms; 8–15: moderate depressive symptoms; ≥16 severe depressive symptoms). Quality of life was investigated by EQ-5D-5L [24], a brief health status measure with five questions with Likert response options and a visual analog scale (EQ-VAS) where the patients are asked to rate their own health from 0 to 100 (the worst and best imaginable health, respectively). The descriptive part of the test evaluated 5 dimensions of health (mobility, self-care, usual activities, pain or discomfort, and anxiety or depression), ranking them into five levels of severity (no problems, slight problems, moderate problems, severe problems, and unable to perform or extreme problems). The burden of sleepiness-related impairment on the ability to conduct daily and recreational activities was evaluated by means of the short version of the Functional Outcomes of Sleep Questionnaire (FOSQ-10) [25], a brief and validated self-administered questionnaire consisting of 10 items with a 4-point Likert response format, which investigates the impact of sleepiness on five main domains (general productivity, activity level, vigilance, social outcomes, and intimate and sexual relationships), with higher scores representing better status. The severity of EDS and cataplexy were also evaluated by means of the Clinical Global Impression severity scale (CGI-S) [ 26], a 7-point scale (ranging from “normal” to “among the most extremely ill patients”) that requires the clinician to score the severity of the patient’s illness at the time of assessment.

Concomitant medications were recorded for each patient, with particular regard for specific treatment of EDS (modafinil, sodium oxybate, and methylphenidate) and cataplexy (sodium oxybate, antidepressants). None of the patients included in the current study was under treatment with solriamfetol as long, as at the time of study enrollment, the drug was not yet available (EMA’s authorization on January 2020).

Continuous variables are presented as means and standard deviation and as median and interquartile range, as appropriate; categorical variables are presented as absolute frequencies and percentages. Statistical analysis was performed in multiple steps. First, the study cohort was divided into three subgroups, according to the modality of prescription of pitolisant: patients who still were not under anti-narcoleptic medication at the inclusion visit and in whom pitolisant was prescribed as the first-choice treatment (“naive group”), patients that stopped their prior narcoleptic medication while starting pitolisant therapy after the inclusion visit (“switched group”), and patients that continued at least one prior treatment together with pitolisant (“add-on group”). A univariate comparison for categorical variables was performed on these data using the χ² test; Fisher’s exact test was used for post hoc analysis. Continuous variables were compared by one-way ANOVA, and post hoc comparisons were carried out by means of Tukey’s test. Appropriate multiple comparison corrections were applied to take family-wise type-I errors into account.

Subsequently, to adjust for the effects of potential confounders, multivariate multinominal logistic regression was used to model the probabilities of the different modalities of prescription of pitolisant. Backward selection was used to identify significant clinical baseline dependent variables, among clinically relevant variables with p ≤ 0.25 with univariate analysis (NT1, ESS>10, BDI, VAS, QoL, FOSQ-10), adjusted for age and sex. The level of significance was set at p < 0.05. Statistical analyses were carried out with SAS software (version 9.4, SAS Institute, North Carolina, USA).

A total of 191 narcoleptic patients (52.4% males; mean age: 42.5±16.1 years) were enrolled by the 14 Italian sleep centers participating in the PASS-pitolisant study (see Fig. 1).

Most of the patients (146/191, 76.4%) were affected by NT1. The mean age at narcolepsy diagnosis was 35.5±15.8 years (range 7.8–80.4) and the mean disease duration was 7.1±6.7 years (range 0–31.9).

EDS (ESS > 10) was the commonest reported symptom (164/191, 85.9%; median ESS score: 15; IQR: 12–19; range: 4–24). EDS was classified as severe (ESS > 15) in almost half of the patients (91/191, 47.6%). Cataplexy was reported in 74.3% of cases. Notably, a relatively small number of patients (27/191, 14.1%) reported an ESS score of ≤ 10. In these cases, pitolisant was prescribed in order to improve cataplexy.

Results of nocturnal polysomnography plus multiple sleep latency test were available for 187/191 (97.9%) patients, and in 167/191 (87.4%), the latter showed a mean sleep latency ≤ 8 min and at least two SOREMPs. In the remaining cases, the diagnosis was established according to the presence of EDS and CSF orexin-A concentration below the cut-off value of 110 pg/mL.

Orexin-A levels were measured in 97 out of 191 (50.8%) patients, and 59 out of 97 (60.8%) had CSF orexin-A concentration below the cut-off value of 110 pg/mL, consistent with a diagnosis of NT1, including a patient without clinical history of cataplexy.

The commonest associated narcoleptic symptoms were disrupted nocturnal sleep (69.1%), sleep hallucinations (64.4%), sleep paralysis (60.2%), and automatic behaviors (37.7%).

According to the BDI scores, 52.2% presented depressive symptoms (16.0%, 27.7%, and 8.5% of mild, moderate, and severe intensity, respectively).

Results of EQ-5D-5L showed that most patients did not complain of problems in mobility, self-care, or pain/discomfort dimensions; conversely, around half of the patients’ reported problems in pursuing their usual activities and/or reported anxiety/depressive mood. The mean EQ-VAS value was 64.7 ± 20.7 (range 10.0–100.0); the mean FOSQ-10 score was 13.7 ± 3.8 (range 5.0–20.0).

The main demographic and clinical characteristics are summarized in Table 1.

Regarding EDS, the CGI-S showed that most included subjects were described as moderately ill (29.8%), markedly ill (34.6%), severely ill (15.7%), or among the most extremely ill patients (0.5%). The remaining 19.4% of patients were deemed by the sleep specialists as normal, borderline ill, or mildly ill. With regard the cataplexy CGI-S, patients were categorized as borderline ill or mildly ill in around half of the cases (46.6%), with 24.7% being moderately ill, 15.1% markedly ill, 8.2% severely ill, and 0.7% of patients described as among the most extremely ill.

Most of the patients (121/191, 63.4%) presented at least one comorbidity. The commonest comorbidity was obesity, affecting up to one-third of patients (62/191, 32.5%), followed by cardiovascular diseases (28.8%) and neurological-psychiatric disorders (24.1%). Among cardiovascular comorbidities, hypertension (16.2%) and arrhythmias (5.2%) were the most frequent. Details regarding other comorbidities are provided in Table 2.

Up to 84.8% of patients had received at least one prior treatment for narcolepsy. Treatment used for EDS included modafinil (79.6%), sodium oxybate (29.3%), and metylphenidate (1.0%). Medications to treat concomitant insomnia disorder were used in a minority of cases (1.6%) and included melatonin, lormetazepam, promethazine, zolpidem, and zopiclone. Medications adopted to treat cataplexy included sodium oxybate (29.3%), venlafaxine (29.3%), non-SSRIs (e.g., clomipramine, trimipramine) (2.6%), NRIs (1.6%), SSRI (1.0%), or other antidepressant therapies (3.1%). Detailed pharmacological treatment of the study cohort is reported in Table 3.

Pitolisant was most commonly prescribed as an add-on treatment (120/191, 62.8%; “add-on group”), rather than switched from other therapies (42/191, 22.0%, “switched group”) or as first treatment (29/191, 15.2%, “naïve group”).

The three groups presented a significant difference in the prevalence of NT1 (χ²= 9.125, p = 0.010) which, in the post hoc comparison, was significantly higher in the “add-on group” (99/120, 82.5%) compared to the “switched group” (25/42, 59.5%) (p = 0.005, Fisher’s exact test). Similarly, the prevalence of cataplexy (χ² = 9.222, p = 0.010) and of sleep paralysis (χ² = 8.507, p = 0.014) differs among groups; in particular, cataplexy was significantly more frequent in the “add-on group” (97/120, 80.8%) compared to the “switched group” (24/42, 57.1%) (p = 0.004, Fisher’s exact test), while sleep paralysis were more commonly observed in the “naive group” (22/29, 75.9%) compared to the “switched group” (18/42, 42.9%) (p = 0.008, Fisher’s exact test). Also, the distribution of cases with the presence/persistence of EDS (ESS > 10) showed significant differences among the three groups (χ² = 9.866, p = 0.007), being present in all patients of the “naive group” (29/29, 100%). The burden of sleepiness-related impairment on the ability to conduct daily and recreational activities, evaluated by means of FOSQ-10, significantly differs among groups (F_{2, 188} = 72.770, p = 0.001), with post hoc comparison in particular showing significantly lower values of FOSQ10, consistent with a lower status in the “naive group” compared to the “add-on group” (FOSQ10 in the “naive group”: 11.6 ± 4.0; FOSQ10 in the “add-on group”: 14.4 ± 3.4; p=0.001). The BDI scores also showed a difference among groups (F_{2, 188}=32.814, p=0.040) as a consequence of significantly higher values in the “naive group” than in the “add-on group” (“naive group”: 9.0±7.9, “add-on group”: 6.0±5.7; p=0.040) and a trend towards significance in the comparison between the “naive group” and the “switched group” (“naive group”: 9.0±7.9, “switched group”: 5.8±4.9; p=0.068). In particular, the prevalence of “severe depressive symptoms,” defined as a BDI score greater than 15, differs among the three groups (χ²= 6.900, p=0.032) as a result of a significantly higher prevalence in the “drug-naïve group” (6/29, 21.4%) compared to “add-on group” (8/120, 6.8%) (p=0.031, Fisher’s exact test). Finally, the three groups differed in time from diagnosis to inclusion (F_{2, 188} = 142.424, p < 0.001), which was significantly shorter in the “naive group” compared to the “add-on group” (“naive group”: 1.6±3.6 years, “add-on group”: 8.5±6.7 years; p < 0.001) and to the “switched group” (“naive group”: 1.6±3.6 years, “switched group”: 6.7±6.4 years; p = 0.003).

No other significant differences were observed in the comparison among the three subgroups. The most relevant significant results of post hoc comparisons are shown in Fig. 2. The results of the multivariate analysis substantially confirmed the findings of the univariate comparison. Further demographic and clinical details and comparison between groups are reported in Table 4.