Breathing is a complex process, which can be controlled through voluntary command or neural control. Parkinson's disease (PD) is a progressive neurological disorder. Many individuals with PD experience respiratory problems, such as coughing difficulties or shortness of breath. Changes in neural control of breathing could be part of the reason of these respiratory problems. This study will measure whether neural control of breathing is impaired in individuals with PD compared to healthy individuals.
Rationale: Parkinson's disease (PD) is a progressive neurological disorder, characterised by loss of dopaminergic neurons. Respiratory dysfunction is common in patients with PD and can lead to pneumonia, which is a common cause of death in PD. However, the exact mechanism of respiratory dysfunction in PD is unknown. The complex process of neural control of breathing may be involved, but this is understudied. This is partly caused by methodological limitations to quantify neural control of breathing. In this study, we will use respiratory neurophysiological methods to determine whether neural control of breathing is impaired in Parkinson's disease. These techniques are hypercapnic ventilatory response, respiratory related evoked potentials and transcranial magnetic stimulation. This study will test the hypothesis that the neural control of breathing is impaired in individuals with PD compared to healthy subjects. Objective: Primary Objective: To identify disease (Parkinson's disease) specific alterations in neural control of breathing by using respiratory neurophysiological techniques. Study design: Exploratory cross-sectional study. Study population: Healthy subjects (n=15) and patients with Parkinson's disease (n=15) \>18 years old. Main study parameters/endpoints: * Hypercapnic ventilatory response curve (HCVR): HCVR will be determined using the CO2-rebreathing technique. * Respiratory related evoked potential (RREP): RREP is a measure of cerebral cortical activity elicited by a short inspiratory occlusion. * Transcranial magnetic stimulation (TMS) diaphragm: TMS is an established tool for investigating the cortical excitability related to breathing. Nature and extent of the burden and risks associated with participation, benefit and group relatedness: The risk of this study for the participants is negligible. Subjects do not directly benefit from participating in this study. The scientific benefit of this study is to achieve a better understanding of the neural control of breathing in Parkinson's disease. The outcomes of this study may give rise to future new treatments in Parkinson's disease. The burden of the separate study procedures is relatively small: there are no invasive procedures and patients continue their medication as usual. However, the total time of the visit and the collective burden of the experiments may be perceived as strenuous. Therefore, subjects will be explicitly informed about this aspect of the study, and enough breaks will be scheduled in the program.
Control of breathing is predominantly regulated by feedback of the central chemoreceptors. All chemoreceptors are sensitive to changes in partial pressure of carbon dioxide and via acid-base reactions to hydrogen concentration. The hypercapnic ventilatory response test shows the relationship between end-tidal PCO2 and the resulting minute ventilation.
The RREP is a measure of cerebral cortical activity elicited by short inspiratory occlusion or breathing against inspiratory resistive loads and quantifies the initial arrival and further processing of sensory afferent respiratory information in the cortex.
Radboudumc
Nijmegen, Gelderland, Netherlands
RECRUITINGHypercapnic ventilatory response curve
Sensitivity slope of the ventilation increase per unit increase in PetCO2, as measured with a rebreathing technique.
Time frame: baseline - during the test
Respiratory related evoked potential
A measure of cerebral cortical activity elicited by a short inspiratory occlusion, expressed in the presence, latency and amplitude of components Nf, P1, N1, P2 and P3.
Time frame: baseline - during the test
Transcranial magnetic stimulation
Interstimulus interval curves, using a conditioning stimulus at 80% and a test stimulus at 125%.
Time frame: baseline - during the test
FVC
Forced vital capacity.
Time frame: baseline - during the test
FEV1
Forced expiratory volume in 1 second.
Time frame: baseline - during the test
MIP
Maximal inspiratory pressure.
Time frame: baseline - during the test
MEP
Maximal expiratory pressure.
Time frame: baseline - during the test
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Study Type
OBSERVATIONAL
Enrollment
30
Transcranial magnetic stimulation of the diaphragm is an established tool for investigating the cortical excitability related to breathing. TMS will be delivered over the vertex using a magnetic stimulator and a 110mm double cone coil.