Parkinson's disease (PD) is a neurodegenerative movement disorder that provoke motors and non-motors symptoms causing further dependence and disability. Among non-motor issues, orthostatic hypotension (OH) is a severe manifestation of autonomic dysfunctions, occurring in approximately 30% of those with PD. The fall in blood pressure (BP) during orthostatic position (ORT) is normally compensated to maintain adequate cerebral blood flow (CBF) through autoregulation of cerebral vessels (AC). However, if AC is compromised, CBF may decrease and cause pre-syncope symptoms such as dizziness and loss of balance. Inspiratory muscle training (IMT) is a non-pharmacological strategy to improve respiratory muscle strength, cerebrovascular, cardiovascular control in several populations. However, the effects of IMT on cardiovascular autonomic control (i.e. baroreflex sensitivity-BRS), hemodynamic and AC during ORT in PD patients with and without orthostatic hypotension have not yet been studied. Our hypothesis is that IMT will increase inspiratory muscle strength and influence spontaneous breathing pattern, improving BRS. In addition, IMT will cause a smaller drop in BP and CBF during ORT. Furthermore, maintaining CBF will reduce postural instability during ORT. PD patients without and with OH (PD-OH) will participate in the study and will be randomly divided into two groups recruited at the Antônio Pedro University Hospital. The experimental group will perform 6-8 weeks of training at 30-75% of maximum inspiratory pressure (MIP), and the placebo group will perform the same training protocol at 5% of MIP (sham). The home-based protocol will be of 30 repetitions twice a day, five days a week. In active ORT test, BP, R-R intervals, stroke volume, cardiac output, respiratory rate, ventilatory variables and mean cerebral blood flow velocity (MCAv) will be continuously monitored for 10 minutes in the supine position (SUP), 10 minutes in the sitting position and then 6 minutes in the ORT position. Oscillations of the body's center of pressure (COP), through a force platform, and neuromuscular responses of the gastrocnemius and tibialis anterior muscles, through surface electromyography, will be recorded while maintaining the ORT position. The orthostatic test will be performed before and after the interventions (placebo and experimental). We believe that IMT will promote an improvement in BRS, AC, and postural control, presenting itself as a potential non-pharmacological countermeasure in autonomic dysfunctions and in the prevention of falls in Parkinson's disease.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
DOUBLE
Enrollment
30
The home-based inspiratory muscle training (IMT) protocol will use an inspiratory threshold loading device (PowerBreathe Wellness, Southam, United Kingdom). IMT for experimental group will start with a minimal load (\~9 cmH2O) during the first week, aiming for a familiarization process. During the second week, the IMT targeted a moderate load of 45% of maximal inspiratory pressure (MIP) previously defined, which will be gradually increased by 10% of MIP each week until reaching 75% of MIP in the final week.
The Sham group will performer the same training protocol that experimental group, but at 5% of MIP during all weeks. Therefore, the sham group will not increase the training load during the protocol.
Universidade Federal Fluminense
Niterói, Rio de Janeiro, Brazil
center of pressure of the body
The variables related to postural balance will be performed on a force platform (Accusway Dual Top, USA) in a bipedal position. The participants' feet will be positioned with the heels together and with a 30° gap between the feet. Throughout the test, the individual's center of pressure (COP) will be continuously recorded, determined as a neuromuscular response to the location of the center of gravity (COG). The starting point used for the assessment will be considered the moment when the individual reaches the orthostatic position, for which the highest value of the weight force (Fz) will be obtained. The elliptical area, the total distance and the displacement speed COPxy will be calculated as COP variables. The signals will be filtered at a frequency of 50 Hz as a Hamming window and a "low-pass" filter to reduce interference.
Time frame: Two measurements will be taken: one at baseline (second visit) and after 6 weeks of training (third visit)
cerebral blood flow
In order to estimate changes in cerebral perfusion, the blood flow velocity in the middle cerebral artery (MCAv) will be used, insonated using a pulsed transcranial ultrasound Doppler with 2-MHz waves. The transducer will be positioned over the right temporal window in all participants, fixed with an adjustable headband. The insonation depth will be 20 and 60 mm, depending on the anatomical positioning of the vessel, to ensure the best signal quality. The cerebral vascular conductance index (CVCi) will be calculated as the mean of the MCAv divided by the mean arterial pressure (MAP) obtained through photoplethysmography. This index will be used as a way to estimate changes in cerebrovascular conductance.Cerebral autoregulation will be dynamically assessed by the cerebral autoregulation index (RoR), calculated using the following formula: RoR = (ΔCVCi/ΔT)/ΔMAP. The first field of the formula consists of a linear regression between CVCi and time. The delta MAP will be obtained.
Time frame: Two measurements will be taken: one at baseline (second visit) and after 6 weeks of training (third visit)
Hemodynamic variables
Blood pressure will be recorded beat-to-beat using infrared photoplethysmography (FinometerPro; Finapres Medical Systems, Arnhem, The Netherlands), R-R intervals using electrocardiography (Equivital, ADinstruments, AUS), and stroke volume and cardiac output will be recorded noninvasively using transthoracic impedance (PhysioFlow, PF-05, Manatec Biomedical, Macheren, France). All variables will be recorded simultaneously at a sampling rate of 1 kHz and analyzed offline using a data acquisition system and data analysis software (PowerLab 16SP hardware and LabChart 8 PRO software; ADInstruments, Australia).
Time frame: Two measurements will be taken: one at baseline (second visit) and after 6 weeks of training (third visit)
Metabolic and Ventilatory Variables
Metabolic and ventilatory variables will be acquired by a metabolic gas analyzer (Ultima CPX; Medgraphics, St. Paul, MN, USA) and a medium-flow pneumotachograph (Medgraphics, St. Paul, MN, USA). The device will be calibrated at the beginning of each test using a 3-L cylinder. The variables recorded will be minute ventilation (VE), tidal volume (Vt), expired carbon dioxide pressure (PetCO2), expiratory time (Te), inspiratory time (Ti), the ratio between Ti and total respiratory time (Ti/Ttot) and between Vt and Ti (Vt/Ti).
Time frame: Two measurements will be taken: one at baseline (second visit) and after 6 weeks of training (third visit)
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