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DOI: 10.1055/s-0030-1255064
© Georg Thieme Verlag KG Stuttgart · New York
Relationship Between Ventilatory Thresholds and Systolic Blood Pressure Variability
Publikationsverlauf
accepted after revision April 30, 2010
Publikationsdatum:
29. Juni 2010 (online)
Abstract
During exercise, an increase in respiratory rate amplifies the blood pressure oscillations. This phenomenon is usually intensified when exercise rate exceeds the ventilatory thresholds (VTs). The present study examined whether VTs assessment was possible from systolic blood pressure variability (SBPV) analysis to give blood pressure ventilatory thresholds (BPVTs). Blood pressure, ECG, and Ventilatory equivalents (VE/VO2, VE/VCO2) were collected from 15 well-trained subjects during an incremental exhaustive test performed on a cycloergometer. The “Short-Time Fourier Transform” was applied to SBP series to compute the instantaneous high frequency SBPV power (HF-SBPV). BPVTs were determined in all but 3 subjects. For the 12 remaining subjects, visual examination of ventilatory equivalents and HF-SBPV power revealed 2 thresholds for both methods. There was no difference between the first (VT1 235±60 vs. BPVT1 226±55 W, p=0.063) and second (VT2 293±67 vs. BPVT2 301±66 W, p=0.063) thresholds. However, BPVT1 was slightly underestimated compared to VT1 (9.9±15.4 W) given lower limit of agreement (LOA) at −19.9 W and higher at 40.4 W. BPVT2 was over-estimated compared to VT2 (−8.8±11.2 W) given lower LOA at −30.9 W and higher at 13.4 W. Thus, BPVTs determination appears useful in conditioning programs with sedentary or pathological subjects but probably not with trained subjects.
Key words
heavy exercise - cardio-respiratory interactions - hyperpnea - blood pressure variability - time frequency analysis - short time Fourier transform
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Correspondence
Dr. Francois Cottin
Unité de Biologie Intégrative
des Adaptations á I'Exercice
(UBIAE), Institut National de
la Santé et de la Recherche
Médicale (INSERM) 902/EA
3872, Genopole
Boulevard F. Mitterrand
91025 Evry cedex
France
Telefon: +33/169/644 881
Fax: +33/169/644 895
eMail: francois.cottin@univ-evry.fr