Parkinson's Disease Clinical Trial
Official title:
Circadian & Homeostatic Synchronization Effect on Waking Mobility in Parkinson's Disease: a Feasibility Study
Sleep benefit (SB) consists of a spontaneous, transient and inconsistent improvement of the
mobility occurring on morning awakening in approximately 40% of Parkinson's disease (PD)
patients, before taking the first morning dose of dopaminergic drugs.
The SB could represent a pathway for the development of new therapeutic strategies for motor
symptoms in PD.
Being a seemingly unpredictable phenomenon and a great variability daily, inter- and
intra-subject, the SB study requires multiple and repeated assessments of mobility for
several days. An experimental home setting would be optimal for this purpose in terms of
cost-effectiveness and patient acceptability.
In addition, since the extent and nature of SB have not been well characterized so far, and
the magnitude of its variability is unknown, a reliable assessment method, independent of
observers and situation, the SB is a requirement of further research in this area.
A recently developed technique combining machine learning algorithms with wireless portable
sensors (accelerometers and gyroscopes) and software applications could be particularly
promising for characterizing the complexity and multiplicity of SBs in. With this technique,
repeated and multiple assessments of mobility can be performed in the homes of patients
without the constant presence of a researcher.
This approach offers several advantages in terms of cost-effectiveness, feasibility and
acceptability of study protocols by patients. It also improves the ecological validity of
subjective and objective estimates of mobility in these patients.
The investigators chose to conduct this preliminary study on patients with PD rather than on
healthy subjects, because SB is a phenomenon that has been described so far only in this
population. Investigators also consider that the feasibility of the study will depend mainly
on the patients' ability to move and the context of their own illness.
SB is a phenomenon induced by sleep. The propensity and timing of sleep depend on the
coordinated interaction of the duration of the previous awakening (homeostatic process) and a
circadian signal (circadian process). In order to better understand SB, it is necessary to
study the reciprocal influences of the circadian and homeostatic process.
Investigators have devised a new paradigm to "shift" the circadian process phase around the
homeostatic process, maintained under constant conditions, in order to observe the effect of
the synchronism or desynchronization of these two processes on the awakening mobility of
patients with an MP. This experimental approach was approved by Professor Aleksandar
Videnovic (Harvard University School of Medicine, USA), opinion leader on circadian
rhythmicity in the MP and scientific collaborator of this study.
As a first step, the investigators plan to implement a technology-assisted home-based
methodology, to validate it in PD patients and to verify the logistic feasibility of this
method-assisted approach in a small group of patients, in order to to be able to apply this
paradigm in larger scientific projects.
Parkinson's disease is a common neurodegenerative disorder touching 1.5% of the general
population over 60 year-old and featuring impaired mobility with high impact on daily living
and quality of life of the patients and their caregivers. Fourty percent of the patients with
Parkinson's disease (PD) report inconstant, prominent, spontaneous, transitory improvement in
mobility occurring on morning awakening, before taking their first morning dose of
dopaminergic medications. This apparently unpredictable, highly variable, sleep-related
phenomenon has been named "Sleep Benefit" (SB) by the scientists.
SB is a promising track to follow to develop novel therapeutic strategies for motor symptoms
in PD. An innovative approach could be to induce modifications of mobility by influencing
sleep regulation in PD patients in experimental settings.
Sleep propensity and timing depend on the coordinated interaction of the duration of
preceding wakefulness (homeostatic component) and on a circadian signal (circadian
component). Reciprocal interactions between homeostatic and circadian processes preside to
internal synchrony of many physiological processes. We hypothesize SB to depend on
serendipitous optimal synchronization between circadian and homeostatic process on morning
awakening. As SB shows high day-to-day, inter- and intra-subject variability, studying SB
requires multiple, repeated assessment of mobility during several days. A home-based
experimental setting would be optimal for this purpose in terms of cost-effectiveness and
acceptability by the patients. Moreover, considering that the range and nature of SB has not
been well characterized so far, and that the amplitude of its variability is unknown, a
reliable, observer- and situation-independent, reproducible assessment method of SB is a
pivotal requirement for further research in this area.
A recently developed technique associating machine-learning algorithms with wireless wearable
sensors (accelerometers and gyroscopes) and software applications might be particularly
promising to characterize the complexity and multiplicity of SB in PD. Thanks to this
technique, repeated, multiple assessments of mobility can be performed at patients' home
without the constant presence of an investigator.
The working hypothesis of this study is that motor performance in PD patients improves on
morning awakening when optimal synchrony between circadian and homeostatic regulation of
sleep occurs. As first step, we envision to set up a home-based and technology-assisted
methodology and to verify its scientific, technological and logistic feasibility.
The study will involve four work packages, for each of which specific endpoints are defined:
WP1: Definition of the logistics, setting, practices of the study procedures for home
assessment;
WP2: Technological setup of:
- IMU wearable sensors
- SleepFit software application development
- light therapy (included sham light therapy)
- home polysomnography
- chronobiological assessments (distal-proximal skin body temperature gradient; Dim Light
Melatonin Onset (DLMO) from salivary specimens;
Two work packages (3 and 4) will require patients inclusion and interventions on patients:
WP3: Validation of mobility assessment by wearable sensors: accuracy of machine learning
algorithm to predict patients' motor status based on the MDS-UPDRS-III total score and on the
3.14 item (global clinical impression of mobility);
WP4: Testing in real-life conditions at patients' home in a small group of subjects.
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