Efficacy and Safety of Pramipexole Sustained Release versus Immediate Release Formulation for Nocturnal Symptoms in Chinese Patients with Advanced Parkinson’s Disease: A Pilot Study

Zhou, Haiyan; Li, Shuhua; Yu, Hongmei; Sun, Shenggang; Wan, Xinhua; Zhu, Xiaodong; Liu, Chun-Feng; Chen, Ling; Xiang, Wei; Sun, Yaqing; Chen, Haibo; Chen, Shengdi

doi:https://doi.org/10.1155/2021/8834950

Parkinson’s Disease

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Abstract Introduction Methods Results Discussion Conclusions Data Availability Conflicts of Interest Authors’ Contributions Acknowledgments Supplementary Materials References Copyright Related Articles

Research Article | Open Access

Volume 2021 | Article ID 8834950 | https://doi.org/10.1155/2021/8834950

Efficacy and Safety of Pramipexole Sustained Release versus Immediate Release Formulation for Nocturnal Symptoms in Chinese Patients with Advanced Parkinson’s Disease: A Pilot Study

Haiyan Zhou,¹Shuhua Li,^2,3Hongmei Yu,⁴Shenggang Sun,⁵Xinhua Wan,⁶Xiaodong Zhu,⁷Chun-Feng Liu,⁸Ling Chen,⁹Wei Xiang,¹⁰Yaqing Sun,¹⁰Haibo Chen,^2,3and Shengdi Chen¹

Academic Editor: Carlo Colosimo

Received23 Sept 2020

Revised24 Dec 2020

Accepted13 Jan 2021

Published03 Mar 2021

Abstract

Objective. To explore the efficacy and safety of pramipexole sustained release (SR) versus pramipexole immediate release (IR) in treating nocturnal symptoms in levodopa-treated Chinese patients with advanced Parkinson’s disease (PD) and sleep disturbances. Method. SUSTAIN was an open-label, randomised, active-controlled parallel group exploratory pilot study (NCT03521635). A total of 98 patients were randomly allocated (1 : 1) to either pramipexole SR (n = 49) or pramipexole IR (n = 49) groups. The primary endpoint was a change from baseline in PD Sleep Scale 2^nd version (PDSS-2) total score at 18 weeks. A reduction in score represents improvement. Secondary endpoints included Nocturnal Hypokinesia Questionnaire, Scales for Outcomes in PD Sleep Scale, Early Morning Off (EMO), Epworth Sleepiness Scale, PD Questionnaire-8, and responder rates as measured by PDSS-2 total score (<18), EMO scores (≥1 point change), Clinical Global Impression Improvement scale, and Patient Global Impression-Improvement scale. Other endpoints included motor complications (MDS-UPDRS part IV) score. Adverse events were evaluated for each group. Results. The mean pramipexole dose for both groups was 1.5 mg/day at week 18, and the mean changes in PDSS-2 total score for pramipexole SR and IR were –13.7 (95% CI –16.0 to –11.4) and –14.4 (–16.8 to –12.0) (difference of 0.7; ). Change from baseline for both groups achieved the minimal clinical important difference threshold (MCID = –3.44). No significant difference was observed in change from baseline for other measures of sleep-related disturbances or responder rates. For motor complications, a greater improvement in MDS-UPDRS part IV score was observed in pramipexole SR over IR (–3.4 vs –2.3; treatment group difference: –1.1; ). Both groups had comparable safety profiles. Conclusion. In Chinese patients with advanced PD and sleep disturbances, pramipexole SR and IR have similar benefits in the treatment of nocturnal symptoms and safety, and an improvement from baseline in nocturnal symptoms was observed regardless of pramipexole formulation.

1. Introduction

1.1. Background

Parkinson’s disease (PD) is a chronic, irreversible, degenerative disorder of the central nervous system, with slowly progressive degeneration of the nigrostriatal dopaminergic systems [1]. The management of PD in advanced stages aims to reduce and/or control functional disability and improve quality of life [2, 3]. Sleep disturbances occur in 40% to 98% of PD patients [4–6] and can adversely affect both patients and caregivers [7].

The multifactorial and multidimensional nature of sleep disturbances precludes the use of a single instrument to measure sleep; specific and validated scales are needed to capture the complexity of the disease. Parkinson’s Disease Sleep Scale (PDSS) 2^nd version (PDSS-2) has been shown to be a reliable, valid, and promising tool to measure treatment response for nocturnal disabilities and sleep disorders in PD [8]; a total PDSS-2 score of ≥18 indicates severe sleep disturbances [9]. Various other tools to capture night sleep and day-time sleepiness have been used and reviewed [10–13].

Pramipexole is a nonergot dopamine agonist approved as monotherapy in early PD as well as adjunct therapy to levodopa in advanced PD [14]. Pramipexole sustained release (SR) is a new once-daily formulation of pramipexole, which has shown similar efficacy, safety, and tolerability to those of immediate release (IR) pramipexole taken three times daily. Compared with the IR formulation, a continuous delivery of treatment through pramipexole SR over an extended period [15] especially at night may be beneficial in treating nocturnal symptoms associated with PD.

The main objective of the study was to explore the efficacy between pramipexole SR versus pramipexole IR on nocturnal symptoms (as measured by the change from baseline to 18 weeks in PDSS-2 score) in levodopa-treated patients with advanced PD.

2. Methods

2.1. Study Design

The SUSTAIN (Sustained and immediate-release pramipexole on the noctUrnal Symptoms of paTients with Advanced ParkInsoN’s disease) was a phase IV, multicentre, open-label, randomised, active-controlled parallel group exploratory pilot study. Patients were recruited from 12 sites (with screened subjects) across China between 17 August 2018 and 2 September 2019.

Patients were randomly allocated (1 : 1) to receive either pramipexole SR or pramipexole IR, available as 0.375 mg or 0.75 mg tablets for the SR formulation and 0.25 mg or 1.0 mg for the IR formulation. The randomisation was performed by Boehringer Ingelheim Pharma GmbH & Co. KG, Germany, and the randomisation list was generated using a validated system and verified by a trial-independent statistician. An external vendor implemented the assignment based on the randomisation list. According to the summary of product characteristics for pramipexole SR and IR [16, 17], the treatment dose was uptitrated over 7 weeks, based on efficacy (Patient Global Impression-Improvement (PGI-I) scale) and tolerability of study medication, until optimal daily dose was reached (according to investigator judgement). The dose of study medication should be up titrated in all patients who are not at least “a little better” on the PGI-I and reduced to previous dose in case of dopaminergic side effects. Patients then entered a maintenance phase of 11 weeks at optimised dosage. The dose reduction phase after completion of maintenance phase lasted up to 7 days unless treatment was to be continued, as judged by investigators. During the 18-week active treatment phase, the timing of administration as well as the doses of these treatments will remain consistent for each patient.

The study was conducted in accordance with the principles of the Declaration of Helsinki and the Harmonized Tripartite Guideline for Good Clinical Practice from the International Council for Harmonization and was approved by local authorities and ethics committees at each participating site. The study is registered with ClinicalTrials.gov (NCT03521635). All patients provided written informed consent.

2.2. Patients

Patients included were male or female of ≥30 years old, diagnosed with advanced PD with at least 2 years of disease history and disease stages II–IV at on-time based on the modified Hoehn & Yahr scale confirmed by at least bradykinesia and one of the following signs: resting tremor and/or rigidity. The patients were also required to present with motor fluctuations, have clinically relevant sleep disturbances as measured by PDSS-2 (total score of ≥18) and sleep-related difficulties at night (scoring ≥2 on the PDSS-2 question 9) or morning (i.e., the frequency of “feeling like bodily movements are poor when you wake up?” was at least 2 to 3 days during the past week), and were receiving levodopa treatment. Continuing use of other anti-Parkinsonian agents was allowed, provided the dosage was unchanged during the prior 4 weeks and remained unchanged during study treatment phase. Patients were excluded if any of the following were reported: atypical Parkinsonian syndromes, any type of dementia (assessed by the Mini-Mental State Examination using a cut-off of 24) or psychiatric disorder, any history of deep brain stimulation, psychiatric or non-PD medical disorders capable of impeding trial participation, clinically significant hypotension or electrocardiographic abnormalities (>2 ULN levels on liver blood tests, or creatinine clearance <50 mL/min), any use of night-time SR dopaminergic (anti-PD) drug, hypnotic, neuroleptics, atypical antipsychotic, or stimulants within the prior 4 weeks, use of flunarizine within 3 months prior to randomisation visit, or serious sleep apnea hypopnea syndrome (scoring ≥3 on the PDSS-2 question 15). Details of the inclusion and exclusion criteria are available in Supplementary Table S1.

2.3. Study Assessments/Outcomes

Efficacy endpoints were evaluated by calculating the change from baseline at week 18 in the following outcome measures and then comparing the difference between the pramipexole SR and IR groups. The primary endpoint evaluated was sleep disturbance, assessed using the PDSS-2 total score. The difference in change from baseline for primary endpoint was assessed with a prespecified minimal clinically important difference (MCID = –3.44) [9]. Subgroup analyses for the primary endpoint were done for age (<65, ≥65 years), pramipexole final dose (low/0.375–1.5 mg/day, medium/2.25–3.0 mg/day, high/3.75–4.5 mg/day), Hoehn & Yahr stage (on-phase: 2, 2.5, 3, 4), activities of daily living severity at baseline (MDS-UPDRS part II: high/>12 points, low/≤12 points), complication severity at baseline (MDS-UPDRS IV: high/>4 points, low/≤4 points), disease severity at baseline (off-time according to patient diary: high/≥4 hours, low/<4 hours), baseline levodopa dose (≤400 mg, >400 mg), and baseline equivalent levodopa dose (≤400 mg, >400 mg).

The secondary efficacy endpoints included other measures of night- and day-time disturbances related to sleep, including the Nocturnal Hypokinesia Questionnaire (NHQ), Scales for Outcomes in Parkinson’s Disease-Sleep Scale (SCOPA-S), Early Morning Off (EMO), and Epworth Sleepiness Scale (ESS). Quality of life in patients with PD as measured by the Parkinson’s Disease Questionnaire-8 (PDQ-8) and responder rates of patients showing improvement in PDSS-2 total score (<18 points), EMO scores (≥1 point change), Clinical Global Impression-Improvement (CGI-I) scale, and PGI-I scale were also assessed.

Further efficacy endpoints were impact on motor experiences of daily living and motor complications as measured by the Movement Disorder Society-Sponsored Revision of the Unified Parkinson’s Disease Rating Scale (MDS-UPDRS) part II and part IV; other measures of psychological health and quality of life included the General Geriatric Depression Scale- (GDS-) 15 score and EQ-5D-5L, healthcare resource utilization (HCRU) and costs (including direct/indirect medical and direct non-medical costs) incurred by patients during the course of study, and also Caregiver Burden Inventory (CBI).

A detailed description of the efficacy outcome measures is given in Table 1 for the primary and secondary endpoints and Supplementary Table S2 for further endpoints. Safety was assessed based on the physical examination, weight, vital signs, 12-lead electrocardiogram, laboratory tests, adverse events (AEs), serious AEs, and the Modified Minnesota Impulsive Disorders Interview (MMIDI).

2.4. Statistical Analyses

As a pilot study, the total eligible sample size of 80 was determined based on trial feasibility instead of statistical power for hypothesis testing. The randomised sample size of 86 considered a drop-out rate of 5%.

Demographic and safety data were analysed descriptively on all patients who received at least one dose of either pramipexole SR or IR (treated set, TS). The efficacy was analysed on all randomised patients who received pramipexole SR or IR with a baseline and at least one PDSS-2 total score measurement in maintenance period (full analysis set, FAS). For the primary endpoint, mean changes from baseline were analysed using a mixed model with repeated measures (MMRM) with treatment, visit in the maintenance period, and treatment-by-visit interaction, and analysis for primary endpoint was performed including visits in both titration and maintenance periods. Secondary and further endpoints were analysed as per primary endpoint, with respective baseline as covariate. For responder rates, logistic regression analyses were performed with treatment and baseline (if baseline was measured) as the independent variables. Additional post hoc analyses were performed to investigate: change from baseline in MDS UPDRS-IV by items (4.1–4.6) and by subgroups (age, PD duration, L-Dopa equivalent dose at baseline, degree of time spent with dyskinesia and in off state), and change from baseline in CBI subscales (details in supplementary materials). Given the exploratory nature of this study, no adjustments were made for multiplicity for all comparisons and overall false positive risk might be inflated. The data were analysed using Statistical Analysis System (SAS) for Windows version 9.4.

3. Results

3.1. Patient Disposition and Baseline Characteristics

A total of 98 patients were enrolled and equally assigned to pramipexole SR (n = 49) or IR (n = 49) groups, respectively (Figure 1). Of these, four patients in the SR group and six patients in the IR group prematurely discontinued during the titration/maintenance phase. For each of the treatment group, two patients discontinued due to “refused to continue taking trial medication” and one patient due to AEs. One patient in the IR group was lost to follow-up. A total of three patients (one in IR group, two in SR group) discontinued due to other reasons. Both groups had similar baseline clinical and demographic characteristics (mean age, 61.0 ± 9.8 years; Hoehn & Yahr stages II-III; duration of disease, 5.0 ± 3.4 years; mean total PDSS-2, 28.5 ± 7.6 points) (Table 2).

3.2. Efficacy

The adjusted mean changes from baseline at week 18 in PDSS-2 total score for pramipexole SR and IR were –13.7 (95% CI –16.0 to –11.4) and –14.4 (95% CI –16.8 to –12.0), respectively (Table 3). The difference between treatment groups was not statistically significant for PDSS-2 total score (treatment group difference: 0.7, 95% CI –2.7 to 4.0; ) and subscales (Table 3). The magnitude of treatment difference did not achieve the prespecified MCID (≤–3.44), but the change from baseline was <–3.44 for both pramipexole SR and IR; this was contributed by mean reductions from baseline in all PDSS-2 total score subgroups (disturbed sleep, motor symptoms at night, PD symptoms at night; Table 3). The adjusted mean changed from baseline in PDSS-2 total score over the titration/maintenance period (Figure 2). The result for changes in PDSS-2 total score at week 18 from baseline by predefined subgroups is available in Supplementary Table S3. It was noted that the change at week 18 in PDSS-2 total score from baseline was numerically larger in patient subgroups with higher baseline Hoehn & Yahr stage on phase and higher complication severity.

Figure 2

Adjusted mean changes from baseline in PDSS-2 over time in titration/maintenance period (FAS). Adjusted with factors treatment, titration/maintenance period, and covariate baseline. The current trend is consistent with the planned primary analysis for mean changes from baseline in PDSS-2 over time, which adjusted with factors treatment, maintenance phase and covariate baseline. Unstructured covariance matrix, Kenward–Roger approximation for denominator degrees of freedom. FAS, full analysis set; IR, immediate release; PDSS-2, Parkinson’s Disease Sleep Scale 2^nd version; PPX, pramipexole; SE, standard error; SR, sustained release.

No significant treatment differences were observed for adjusted mean change from baseline at week 18 in all secondary endpoints, that is, NHQ (SR versus IR: –1.9 versus –1.7), SCOPA-S night-time sleep (–3.8 versus –3.2), SCOPA-S day-time sleepiness (–1.4 versus –0.9), EMO (–1.8 versus –1.5), and ESS (–2.4 versus –2.6). There were a similar proportion of patients in both the pramipexole SR and IR groups that showed improvements in responder rates analyses (PDSS-2, EMO, CGI-I, and PGI-I) (Figure 3) and quality of life PDQ-8.

Figure 3

Responder rates in patients (FAS). The responder rates for each outcome measure: PDSS-2, total score <18; EMO, patient improved at least 1 comparing to his/her baseline condition; CGI-I, clinician rated of any improvement (1 = very much better, 2 = much better, or 3 = a little better); PGI-I, patient rated of any improvement (1 = very much better, 2 = much better, or 3 = a little better). CGI-I, Clinical Global Impression of Improvement; CI, confidence interval; EMO, Early Morning Off; FAS, full analysis set; IR, immediate release; PDSS-2, Parkinson’s Disease Sleep Scale-2; PGI-I, Patient Global Impression of Improvement; SR, sustained release.

No significant treatment differences in adjusted mean change from baseline at week 18 were observed for further endpoints MDS-UPDRS II, GDS-15, EQ-5D-5L, and CBI (Supplementary Table S4). Both treatment groups reported improvements in MDS-UPDRS part IV (SR versus IR: –3.4 [95% CI –4.1 to –2.7] versus –2.3 [95% CI –3.0 to –1.6]), with greater improvements observed with pramipexole SR (treatment group difference: –1.1, ). Additional post hoc analyses showed a generally consistent trend in favor of pramipexole SR for MDS-UPDRS part IV items and selected subgroups (Supplementary Table S5 and S6). Within the CBI subscales, the difference between caregivers of patients who received pramipexole SR (n = 13) versus IR (n = 11) was greatest for physical burden (–3.7 versus –1.0) (Supplementary Table S5). The median (Q1-Q3) hours spent by caregivers during day-time and night-time were 0 (0–4) hours versus 0 (0–8) hours and 0 (0–1.5) versus 0 (0–0) hours for pramipexole SR and IR groups, respectively. No pattern of differences between treatment groups were observed for HCRU and costs.

3.3. Study Drug

The mean exposure to the study drug in the pramipexole SR and IR treatment groups was similar (121.2 versus 115.8 days); at 18 weeks, mean pramipexole dose for SR and IR groups was 1.5 mg/day and mean cumulative dose was 162.1 mg and 161.0 mg, respectively. Both treatment groups achieved good overall compliance (80%–120% compliance: 100% for pramipexole SR and 95.9% for pramipexole IR).

3.4. Safety Outcomes

The proportion of AEs for both groups were similar, with almost half of the patients in each group reporting at least one AE (Table 4). Most of the AEs were of mild or moderate intensity. One patient who received pramipexole IR reported a serious AE; none were reported for the pramipexole SR group. This patient with a serious AE experienced mechanical ileus, cholecystitis, cholelithiasis, and femoral neck fracture; these were assessed by the investigator as not related. Treatment-related AEs were reported in 32.7% and 38.8% of the SR and IR group, respectively. Of impulse control related AEs, two patients reported compulsive sexual behaviour and one experienced visual hallucinations (SR group); one patient reported compulsive shopping and one reported gambling (IR group). Overall, both formulations of pramipexole were generally well tolerated with similar safety profiles.

4. Discussion

SUSTAIN is the first open-label, randomised, active-controlled study to compare the efficacy, and safety of pramipexole SR versus pramipexole IR in treating nocturnal symptoms in patients with advanced PD receiving levodopa. After 18 weeks, both treatment groups demonstrated similar benefits for the primary endpoint, that is, change from baseline in PDSS-2 total score, and secondary endpoints which include other measures of night- and day-time disturbances related to sleep. Based on the suggested and prespecified MCID for PDSS-2 [9], the observed changes from baseline in both pramipexole SR and IR suggest clinical effects of improvement in nocturnal symptoms regardless of formulations.

Sleep disturbance is a common nonmotor symptom in PD [18, 19] and may worsen with increased disease duration [20]. Nocturnal akinesia and other motoric disorders of sleep contribute to motor-related sleep disturbances in Parkinson’s disease [18]. Altogether, patients with poor sleep, interacting with motor dysfunction and mood disorders, are at risk of reduced quality of life [21–23]. The dopaminergic system is associated with both sleep and wakefulness; therefore, PD treatment (i.e., levodopa and/or dopamine agonist) which influences the dopaminergic system could potentially have an effect on sleep [20]. Existing studies of dopaminergic medications suggest benefits of pharmacological treatment on sleep disturbances, including those of extended-release formulation [8, 24, 25]. This is supported by the Chinese consensus for the management of sleep disturbances in patients with PD, which recommend the use of dopamine agonists for treatment of insomnia [6].

In a retrospective exploratory analysis of advanced PD patients with sleep disturbances while on stable levodopa, a numerical benefit in sleep was observed with pramipexole SR over pramipexole IR [26]. Using an open-label, randomised parallel group design, this 18-week study did not demonstrate significant differences between pramipexole formulations on PDSS-2 total score and subscales. Given the long terminal phase half-life of pramipexole IR (8–12 hours) [27], the multiple dosing might result in steady-state concentration including night-time and contributed to the obvious improvement of nocturnal motor disturbances. Therefore, even if the SR formulation can improve the 24 h fluctuations of drug plasma concentrations [28], both formulations might have reached a similar ceiling effect for the efficacy of nocturnal symptoms. In terms of change from baseline in PDSS-2 total score, both pramipexole SR and IR treatment still achieved the MCID threshold of –3.44 [29]; while lacking a placebo control group, these improvements in sleep were consistent with that observed in the previous study of pramipexole versus placebo [25]. Similarly in a randomised controlled study of rotigotine, the mean PDSS-2 total score decreased by –5.9 points with 24-h rotigotine (baseline, 19.3) and by –1.9 points with placebo (baseline, 20.5) after 4 weeks of treatment [30].

Long-term therapy with levodopa is associated with the development of motor fluctuations and dyskinesia [31]; dopamine agonists such as pramipexole that have longer half-lives have demonstrated a reduction in rate of development of dyskinesia than levodopa [32]. It was noted that both treatment groups in this pramipexole study reported clinical improvements in motor complications compared with baseline (MCID = –0.9) [33] after 18 weeks, with greater improvements observed in pramipexole SR; the same numerical trend was observed for all the individual UPDRS IV items, particularly in terms of time spent with dyskinesia. Nonetheless, these analyses are post hoc without adjustment on multiplicity and hence should be interpreted with caution. These results are consistent with the pramipexole IR long-term outcome study in advanced PD [34]. Meanwhile, depression is also commonly associated with poor sleep [22, 35]. Sleep disturbance and depression may overlap and arise from common neurobiological networks, yet both may differentially contribute to quality of life [36].

While the pilot data presented suggests no difference in sleep outcomes between pramipexole SR or IR, the practical approach of a once-daily therapy may still offer greater convenience benefit and facilitate better treatment adherence [37]. Noncompliance in PD treatment management has costly effects on patients’ health and healthcare systems [38], especially among the elderly with other medical comorbidities and complex medication regimes [39]. Caregivers can play an important role in the regular care and treatment adherence [40], and poor quality of sleep in PD patients has been associated with depression and increased burden in caregivers [41, 42]. Therefore, the engagement and support for the well-being of caregivers should be a necessary part of the PD treatment system.

The AE data during the study for both groups were comparable. Few patients who were treated with either pramipexole formulations experienced dizziness (6.1%) or nausea (4.1%) in this study; these were lower compared with the AE profile in a similar study of rotigotine (10% and 21%) [30]. Serious AEs and AEs leading to discontinuation were minimal in both pramipexole groups, suggesting that the AEs and titration of treatment were well-managed and patients continued to show improvements in motor complications.

Interpretation of the findings in SUSTAIN is limited by its sample size, open-label design, and lack of placebo arm to demonstrate treatment effectiveness. Self-reported data are inherently vulnerable to response bias [43] and objective measures of sleep. For example, polysomnography (gold standard) or triaxial accelerometer was not used in this study as these measures require time and cost and are labour-intensive. Nevertheless, this is the first study to evaluate difference in the efficacy of the SR versus IR formulation in nocturnal symptoms for PD. The study applied a formal cut-off of ≥18 points on the PDSS-2 total score identifying those with existing sleep disturbances and allocated patients to different treatment arms in a randomised manner. PDSS-2 is a validated measure of sleep disturbances in PD [8]; however, given the complex and multidimensional aspect of poor sleep, a comprehensive battery of self-report measures of day- and night-time sleep disturbances was applied, including independent measures of patient’s night-time symptoms captured by caregivers (NHQ by caregivers), which patients’ themselves might not be aware of.

5. Conclusions

In Chinese patients with advanced PD and sleep disturbances, pramipexole SR and IR have similar benefits in the treatment of nocturnal symptoms and safety; and an improvement from baseline in nocturnal symptoms was observed regardless of pramipexole formulation.

Data Availability

To ensure independent interpretation of clinical study results, Boehringer Ingelheim grants all external authors access to all relevant material, including participant-level clinical study data, and relevant material as needed by them to fulfill their role and obligations as authors under the ICMJE criteria. Furthermore, clinical study documents (e.g., study report, study protocol, and statistical analysis plan) and participant clinical study data are available to be shared after publication of the primary manuscript in a peer-reviewed journal and if regulatory activities are complete and other criteria met per the BI Policy on Transparency and Publication of Clinical Study Data: https://trials.boehringer-ingelheim.com/. Prior to providing access, documents will be examined, and, if necessary, redacted, and the data will be de-identified, to protect the personal data of study participants and personnel and to respect the boundaries of the informed consent of the study participants. Clinical study reports and related clinical documents can also be requested via the link https://trials.boehringer-ingelheim.com/. All requests will be governed by a Document Sharing Agreement. Bona fide, qualified scientific and medical researchers may request access to de-identified, analysable participant clinical study data with corresponding documentation describing the structure and content of the datasets. Upon approval, and governed by a Data Sharing Agreement, data are shared in a secured data-access system for a limited period of one year, which may be extended upon request. Researchers should use the https://trials.boehringer-ingelheim.com/link to request access to the study data.

Conflicts of Interest

Haiyan Zhou, Shuhua Li, Hongmei Yu, Shenggang Sun, Xinhua Wan, Xiaodong Zhu, Chun-Feng Liu, Ling Chen, Haibo Chen, and Shengdi Chen acted as investigators of the SUSTAIN study. Wei Xiang and Yaqing Sun are employees of Boehringer Ingelheim. This study was funded and supported by Boehringer Ingelheim.

Authors’ Contributions

Haiyan Zhou and Shuhua Li are co-first authors of this manuscript.

Acknowledgments

The authors acknowledge the study investigators of the SUSTAIN study group for their contributions to data acquisition for this study: Fudong Shi, Tianjin Medical University General Hospital; Qiumin Qu, First Affiliated Hospital of Xi’an Jiaotong University; Weiguo Liu, Brain Hospital Affiliated to Nanjing Medicine University; Huifang Shang, West China Hospital; Xiaoguang Luo, The First Hospital of Chinese Medical University; and Baorong Zhang, The Second Affiliated Hospital of Zhejiang University School of Medicine. The authors also thank the patients and staff who participated in this study, and the following employees of Boehringer Ingelheim for their contributions: Xiaodong Shi for the analysis programming, Zhaoxia Du for data management, Xiyan Li for statistical support of the study results, and Hui Chin Teoh for the writing and editorial assistance of the manuscript.

Supplementary Materials

The following tables are included in a supplementary file. Table S1: inclusion and exclusion criteria. Table S2: description of outcome measures for further efficacy endpoints. Table S3: adjusted mean changes in PDSS-2 total score at week 18 from baseline by subgroups (FAS). Table S4: adjusted mean changes in psychological health, quality of life, and caregiver burden at week 18 from baseline (FAS). Table S5: adjusted men changes in MDS-UPDRS IV items and CBI subscales at week 18 from baseline (FAS). Table S6: adjusted mean changes in MDS-UPDRS IV at week 18 from baseline by subgroups (FAS). (Supplementary Materials)

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Copyright © 2021 Haiyan Zhou et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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