Pulse Pressure Amplification, Arterial Stiffness, and Peripheral Wave Reflection Determine Pulsatile Flow Waveform of the Femoral Artery

Hashimoto, Junichiro; Ito, Sadayoshi

doi:10.1161/hypertensionaha.110.159368

Cited by 87 publications

(76 citation statements)

References 36 publications

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“…This hypothesis is consistent with actual observations, although additional effects of arterial distensibility (reservoir function) and blood inertia must also be taken into account. Of particular note in this study is that, as the pulse pressure amplification decreases with aortic stiffening, the reverse flow also decreases proportionally (Hashimoto and Ito 2010). Bogren et al previously speculated that the reverse flow in the lower body may supply diastolic flow into internal abdominal organs such as the kidney (Bogren and Buonocore 1994).…”

Section: Central Hemodynamics and Brainmentioning

confidence: 58%

“…Due to this amplification, the blood pressure during late systole and early diastole is much higher in the peripheral than central arteries when measured simultaneously (Rowell et al 1968). The amplification ratio was reported to be approximately 130% between the central aorta and femoral artery in a hypertensive population (Hashimoto and Ito 2010).…”

Section: Central Hemodynamics and Brainmentioning

confidence: 99%

“…A recent investigation has revealed that the aorta-tofemoral pulse pressure amplification is positively correlated with the reverse flow in the femoral artery (Hashimoto and Ito 2010). This finding can be explained by the hypothetical mechanism that the aorta-to-femoral pressure difference is primarily responsible for the bidirectional (triphasic) Refer to the text for more details.…”

Section: Central Hemodynamics and Brainmentioning

confidence: 99%

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Central Hemodynamics and Target Organ Damage in Hypertension

Hashimoto

2014

Tohoku J. Exp. Med.

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Recent advances in technology have enabled the noninvasive evaluation of pulsatile hemodynamics in the central aorta; namely, central pressure and flow measurements. The central blood pressure represents the true load imposed on the heart, kidney and brain, and the central blood flow influences the local flow into these vital organs. An elevation of the central blood pressure has a direct, adverse impact on the target organ and, thus, the cardiovascular prognosis in patients with hypertension. A decrease in the central blood flow can cause organ dysfunction and failure. The central pressure and flow dynamics were conventionally regarded as unidirectional from the heart to the periphery. However, current evidence suggests that it should be recognized as a bidirectional interplay between the central and peripheral arteries. Specifically, the pressure pulse wave is not only transmitted forward to the periphery but also reflected backward to the central aorta. The flow pulse wave is also composed of the forward and reverse components. Aortic stiffening and arteriolar remodeling due to hypertension not only augment the central pressure by increasing the wave reflection but also may alter the central bidirectional flow, inducing hemodynamic damage/dysfunction in susceptible organs. Therefore, central hemodynamic monitoring has the potential to provide a diagnostic and therapeutic basis for preventing systemic target organ damage and for offering personalized therapy suitable for the arterial properties in each patient with hypertension. This brief review will summarize hypothetical mechanisms for the association between the central hemodynamics and hypertensive organ damage in the heart, kidney and brain.

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Section: Central Hemodynamics and Brainmentioning

confidence: 58%

Section: Central Hemodynamics and Brainmentioning

confidence: 99%

Section: Central Hemodynamics and Brainmentioning

confidence: 99%

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Central Hemodynamics and Target Organ Damage in Hypertension

Hashimoto

2014

Tohoku J. Exp. Med.

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“…23,24 In brief, after the brachial blood pressure measurement, pulsatile pressure signals were recorded with applanation tonometry from the radial, carotid, and femoral arteries. These pulse waveforms were used to determine various pressure and stiffness parameters, including the aortic systolic and pulse pressures, incident pressure wave height (P 1h ), augmented pressure, augmentation index (AIx, corrected for heart rate of 75 bpm), the aorta-to-radial and aorta-to-femoral pulse pressure amplifications, and the carotidfemoral and carotid-radial pulse wave velocities (PWV C-F and PWV C-R ).…”

Section: Aortic Blood Pressure and Arterial Function Measurementsmentioning

confidence: 99%

“…Therefore, we sought to comprehensively assess the descending aortic and cerebral (carotid) flow pulse waveforms in patients with hypertension, using a noninvasive and quantitative method. 23,24 Our primary objectives were as follows: (1) to clarify the physiological determinants of the aortic flow reversal (with a particular focus on aortic stiffness and pressure), and (2) to investigate the potential association between aortic reverse flow and carotid antegrade flow. We hypothesized that aortic flow reversal would increase with aortic stiffening and consequently strengthen the pathological (hemodynamic) link between thoracic aorta and cerebral macrovasculature.…”

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confidence: 99%

Aortic Stiffness Determines Diastolic Blood Flow Reversal in the Descending Thoracic Aorta

2013

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Abstract-Aortic stiffening often precedes cardiovascular diseases, including stroke, but the underlying pathophysiological mechanisms remain obscure. We hypothesized that such abnormalities could be attributable to altered central blood flow dynamics. In 296 patients with uncomplicated hypertension, Doppler velocity pulse waveforms were recorded at the proximal descending aorta and carotid artery to calculate the reverse/forward flow ratio and diastolic/systolic flow index, respectively. Tonometric waveforms were recorded on the radial artery to estimate aortic pressure and characteristic impedance (Z 0 ) and to determine carotid-femoral (aortic) and carotid-radial (peripheral) pulse wave velocities. In all subjects, the aortic flow waveform was bidirectional, comprising systolic forward and diastolic reverse flows. The aortic reverse/forward flow ratio (35±10%) was positively associated with parameters of aortic stiffness (including pulse wave velocity, Z 0 , and aortic/peripheral pulse wave velocity ratio), independent of age, body mass index, aortic diameter, and aortic pressure. The carotid flow waveform was unidirectional and bimodal with systolic and diastolic maximal peaks. There was a positive relationship between the carotid diastolic/systolic flow index (28±9%) and aortic reverse/ forward flow ratio, which remained significant after adjustment for aortic stiffness and other related parameters. The Bland-Altman plots showed a close time correspondence between aortic reverse and carotid diastolic flow peaks. In conclusion, aortic stiffness determines the extent of flow reversal from the descending aorta to the aortic arch, which contributes to the diastolic antegrade flow into the carotid artery. This hemodynamic relationship constitutes a potential mechanism linking increased aortic stiffness, altered flow dynamics, and increased stroke risk in hypertension.

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Manipulation of arterial stiffness, wave reflections, and retrograde shear rate in the femoral artery using lower limb external compression

et al. 2013

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Exposure of the arterial wall to retrograde shear acutely leads to endothelial dysfunction and chronically contributes to a proatherogenic vascular phenotype. Arterial stiffness and increased pressure from wave reflections are known arbiters of blood flow in the systemic circulation and each related to atherosclerosis. Using distal external compression of the calf to increase upstream retrograde shear in the superficial femoral artery (SFA), we examined the hypothesis that changes in retrograde shear are correlated with changes in SFA stiffness and pressure from wave reflections. For this purpose, a pneumatic cuff was applied to the calf and inflated to 0, 35, and 70 mmHg (5 min compression, randomized order, separated by 5 min) in 16 healthy young men (23 ± 1 years of age). Doppler ultrasound and wave intensity analysis was used to measure SFA retrograde shear rate, reflected pressure wave intensity (negative area [NA]), elastic modulus (Ep), and a single-point pulse wave velocity (PWV) during acute cuff inflation. Cuff inflation resulted in stepwise increases in retrograde shear rate (P < 0.05 for main effect). There were also significant cuff pressure-dependent increases in NA, Ep, and PWV across conditions (P < 0.05 for main effects). Change in NA, but not Ep or PWV, was associated with change in retrograde shear rate across conditions (P < 0.05). In conclusion, external compression of the calf increases retrograde shear, arterial stiffness, and pressure from wave reflection in the upstream SFA in a dose-dependent manner. Wave reflection intensity, but not arterial stiffness, is correlated with changes in peripheral retrograde shear with this hemodynamic manipulation.

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Pulse Pressure Amplification, Arterial Stiffness, and Peripheral Wave Reflection Determine Pulsatile Flow Waveform of the Femoral Artery

Cited by 87 publications

References 36 publications

Central Hemodynamics and Target Organ Damage in Hypertension

Central Hemodynamics and Target Organ Damage in Hypertension

Aortic Stiffness Determines Diastolic Blood Flow Reversal in the Descending Thoracic Aorta

Manipulation of arterial stiffness, wave reflections, and retrograde shear rate in the femoral artery using lower limb external compression

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