Using the Portapres<sup>®</sup>
 for the measurement of toe arterial blood pressure during movement: is it valid and reliable?

Goreham, Joshua A.; Kimmerly, Derek S.; Ladouceur, Michel

doi:10.14814/phy2.13369

Cited by 5 publications

(2 citation statements)

References 19 publications

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“…If such correction was not possible, a cubic spline interpolation was used to correct for isolated artefacts and ectopic beats. Maximal blood pressure values after the R‐wave peaks were classified as SBP (Goreham, Kimmerly, & Ladouceur, 2017). The RE signal was derived from the ECG signal by analysing the distortion of the R‐wave peak attribugtable to induced respiratory thoracic motion (Moody, Mark, Zoccola, & Mantero, 1985).…”

Section: Methodsmentioning

confidence: 99%

Causal analyses to study autonomic regulation during acute head‐out water immersion, head‐down tilt and supine position

Corbier

Chouchou²,

Roche

et al. 2020

Experimental Physiology

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Thermoneutral head-out water immersion (WI) and 6 deg head-down tilt (HDT) are used to simulate SCUBA diving, swimming and microgravity, because these models induce an increase in central blood volume. Standard methods to analyse autonomic regulation have demonstrated an increase in parasympathetic activity and baroreflex sensitivity during these experimental conditions. However, such methods are not adapted to quantify all closed-loop interactions involved in respiratory and cardiovascular regulation. To overcome this limitation, we used Granger causality analysis between R-R intervals (RR), systolic blood pressure (SBP) and respiration (RE) in eight young, healthy subjects, recorded during 30 min periods in the supine position, WI and HDT. For all experimental conditions, we found a bidirectional causal relationship between RE and RR and between RR and SBP, with a dominant direction from RR to SBP, and a unidirectional causality from RE to SBP. These causal relationships remained unchanged for the three experimental tests. Interestingly, there was a lower causal relationship from RR to RE during WI compared with HDT. This causal link from RR to RE could be modulated by peripheral resistances. These results highlight differences in cardiovascular regulation during WI and HDT and confirm that Granger causality might reveal physiological mechanisms not accessible with standard methods.

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Section: Methodsmentioning

confidence: 99%

Causal analyses to study autonomic regulation during acute head‐out water immersion, head‐down tilt and supine position

Corbier

Chouchou²,

Roche

et al. 2020

Experimental Physiology

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“…First, R peaks are detected from the ECG signal using a laboratory developed algorithm (Pichot et al, 2016). Then maximum and minimum BP values between RR are classified as systolic and diastolic BP, respectively (Goreham et al, 2017). The MBP value is also calculated as the mean of the blood pressure curve taken between the successive diastoles.…”

Section: Causal Direction (Classic) [Gaussian] Fixedmentioning

confidence: 99%

CVRanalysis: a free software for analyzing cardiac, vascular and respiratory interactions

Pichot,

Corbier,

Chouchou

et al. 2024

Front. Physiol.

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Introduction: Simultaneous beat-to-beat R-R intervals, blood pressure and respiration signals are routinely analyzed for the evaluation of autonomic cardiovascular and cardiorespiratory regulations for research or clinical purposes. The more recognized analyses are i) heart rate variability and cardiac coherence, which provides an evaluation of autonomic nervous system activity and more particularly parasympathetic and sympathetic autonomic arms; ii) blood pressure variability which is mainly linked to sympathetic modulation and myogenic vascular function; iii) baroreflex sensitivity; iv) time-frequency analyses to identify fast modifications of autonomic activity; and more recently, v) time and frequency domain Granger causality analyses were introduced for assessing bidirectional causal links between each considered signal, thus allowing the scrutiny of many physiological regulatory mechanisms.Methods: These analyses are commonly applied in various populations and conditions, including mortality and morbidity predictions, cardiac and respiratory rehabilitation, training and overtraining, diabetes, autonomic status of newborns, anesthesia, or neurophysiological studies.Results: We developed CVRanalysis, a free software to analyze cardiac, vascular and respiratory interactions, with a friendly graphical interface designed to meet laboratory requirements. The main strength of CVRanalysis resides in its wide scope of applications: recordings can arise from beat-to-beat preprocessed data (R-R, systolic, diastolic and mean blood pressure, respiration) or raw data (ECG, continuous blood pressure and respiratory waveforms). It has several tools for beat detection and correction, as well as setting of specific areas or events. In addition to the wide possibility of analyses cited above, the interface is also designed for easy study of large cohorts, including batch mode signal processing to avoid running repetitive operations. Results are displayed as figures or saved in text files that are easily employable in statistical softwares.Conclusion:CVRanalysis is freely available at this website: anslabtools.univ-st-etienne.fr. It has been developed using MATLAB® and works on Windows 64-bit operating systems. The software is a standalone application avoiding to have programming skills and to install MATLAB. The aims of this paper area are to describe the physiological, research and clinical contexts of CVRanalysis, to introduce the methodological approach of the different techniques used, and to show an overview of the software with the aid of screenshots.

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Autonomic cardiovascular adaptations to acute head-out water immersion, head-down tilt and supine position

et al. 2019

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Using the Portapres^® for the measurement of toe arterial blood pressure during movement: is it valid and reliable?

Cited by 5 publications

References 19 publications

Causal analyses to study autonomic regulation during acute head‐out water immersion, head‐down tilt and supine position

Causal analyses to study autonomic regulation during acute head‐out water immersion, head‐down tilt and supine position

CVRanalysis: a free software for analyzing cardiac, vascular and respiratory interactions

Autonomic cardiovascular adaptations to acute head-out water immersion, head-down tilt and supine position

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Using the Portapres® for the measurement of toe arterial blood pressure during movement: is it valid and reliable?

Cited by 5 publications

References 19 publications

Causal analyses to study autonomic regulation during acute head‐out water immersion, head‐down tilt and supine position

Causal analyses to study autonomic regulation during acute head‐out water immersion, head‐down tilt and supine position

CVRanalysis: a free software for analyzing cardiac, vascular and respiratory interactions

Autonomic cardiovascular adaptations to acute head-out water immersion, head-down tilt and supine position

Contact Info

Product

Resources

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Using the Portapres^® for the measurement of toe arterial blood pressure during movement: is it valid and reliable?