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Literature DB >> 19189147

Wave intensity analysis and the development of the reservoir-wave approach.

John V Tyberg¹, Justin E Davies, Zhibin Wang, William A Whitelaw, Jacqueline A Flewitt, Nigel G Shrive, Darryl P Francis, Alun D Hughes, Kim H Parker, Jiun-Jr Wang.

Abstract

The parameters of wave intensity analysis are calculated from incremental changes in pressure and velocity. While it is clear that forward- and backward-traveling waves induce incremental changes in pressure, not all incremental changes in pressure are due to waves; changes in pressure may also be due to changes in the volume of a compliant structure. When the left ventricular ejects blood rapidly into the aorta, aortic pressure increases, in part, because of the increase in aortic volume: aortic inflow is momentarily greater than aortic outflow. Therefore, to properly quantify the effects of forward or backward waves on arterial pressure and velocity (flow), the component of the incremental change in arterial pressure that is due only to this increase in arterial volume--and not, fundamentally, due to waves--first must be excluded. This component is the pressure generated by the filling and emptying of the reservoir, Otto Frank's Windkessel.

Mesh：

Year: 2009 PMID： 19189147 DOI： 10.1007/s11517-008-0430-z

Source DB: PubMed Journal: Med Biol Eng Comput ISSN： 0140-0118 Impact factor: 2.602

22 in total

1. Method for the calculation of velocity, rate of flow and viscous drag in arteries when the pressure gradient is known.

Authors: J R WOMERSLEY
Journal: J Physiol Date: 1955-03-28 Impact factor: 5.182

2. Forward and backward running waves in the arteries: analysis using the method of characteristics.

Authors: K H Parker; C J Jones
Journal: J Biomech Eng Date: 1990-08 Impact factor: 2.097

3. Systemic venous circulation. Waves propagating on a windkessel: relation of arterial and venous windkessels to systemic vascular resistance.

Authors: Jiun-Jr Wang; Jacqueline A Flewitt; Nigel G Shrive; Kim H Parker; John V Tyberg
Journal: Am J Physiol Heart Circ Physiol Date: 2005-08-19 Impact factor: 4.733

4. Wave intensity analysis of left ventricular filling: application of windkessel theory.

Authors: Jacqueline A Flewitt; Tracy N Hobson; Jiun Wang; Clifton R Johnston; Nigel G Shrive; Israel Belenkie; Kim H Parker; John V Tyberg
Journal: Am J Physiol Heart Circ Physiol Date: 2007-02-02 Impact factor: 4.733

5. Translation of Otto Frank's paper "Die Grundform des Arteriellen Pulses" Zeitschrift für Biologie 37: 483-526 (1899).

Authors: K Sagawa; R K Lie; J Schaefer
Journal: J Mol Cell Cardiol Date: 1990-03 Impact factor: 5.000

6. Determination of wave speed and wave separation in the arteries.

Authors: A W Khir; A O'Brien; J S Gibbs; K H Parker
Journal: J Biomech Date: 2001-09 Impact factor: 2.712

7. Wave-intensity analysis: a new approach to coronary hemodynamics.

Authors: Y H Sun; T J Anderson; K H Parker; J V Tyberg
Journal: J Appl Physiol (1985) Date: 2000-10

8. Evidence of a dominant backward-propagating "suction" wave responsible for diastolic coronary filling in humans, attenuated in left ventricular hypertrophy.

Authors: Justin E Davies; Zachary I Whinnett; Darrel P Francis; Charlotte H Manisty; Jazmin Aguado-Sierra; Keith Willson; Rodney A Foale; Iqbal S Malik; Alun D Hughes; Kim H Parker; Jamil Mayet
Journal: Circulation Date: 2006-04-03 Impact factor: 29.690

9. Propagation velocity and reflection of pressure waves in the canine coronary artery.

Authors: T Arts; R T Kruger; W van Gerven; J A Lambregts; R S Reneman
Journal: Am J Physiol Date: 1979-10

Review 10. An introduction to wave intensity analysis.

Authors: Kim H Parker
Journal: Med Biol Eng Comput Date: 2009-02-11 Impact factor: 2.602

28 in total

1. Arterial reservoir-excess pressure and ventricular work.

Authors: Kim H Parker; Jordi Alastruey; Guy-Bart Stan
Journal: Med Biol Eng Comput Date: 2012-02-26 Impact factor: 2.602

Review 2. Meta-analysis of the comparative effects of different classes of antihypertensive agents on brachial and central systolic blood pressure, and augmentation index.

Authors: Charlotte H Manisty; Alun D Hughes
Journal: Br J Clin Pharmacol Date: 2013-01 Impact factor: 4.335

Wave intensity analysis and the development of the reservoir-wave approach.

1. Method for the calculation of velocity, rate of flow and viscous drag in arteries when the pressure gradient is known.

2. Forward and backward running waves in the arteries: analysis using the method of characteristics.

3. Systemic venous circulation. Waves propagating on a windkessel: relation of arterial and venous windkessels to systemic vascular resistance.

4. Wave intensity analysis of left ventricular filling: application of windkessel theory.

5. Translation of Otto Frank's paper "Die Grundform des Arteriellen Pulses" Zeitschrift für Biologie 37: 483-526 (1899).

6. Determination of wave speed and wave separation in the arteries.

7. Wave-intensity analysis: a new approach to coronary hemodynamics.

8. Evidence of a dominant backward-propagating "suction" wave responsible for diastolic coronary filling in humans, attenuated in left ventricular hypertrophy.

9. Propagation velocity and reflection of pressure waves in the canine coronary artery.

Review 10. An introduction to wave intensity analysis.

1. Arterial reservoir-excess pressure and ventricular work.

Review 2. Meta-analysis of the comparative effects of different classes of antihypertensive agents on brachial and central systolic blood pressure, and augmentation index.

3. Arterial hemodynamics and wave analysis in the frequency and time domains: an evaluation of the paradigms.

4. Increasing pulse wave velocity in a realistic cardiovascular model does not increase pulse pressure with age.

5. CrossTalk opposing view: Forward and backward pressure waves in the arterial system do not represent reality.

6. The paradox of hypoxic pulmonary hypertension (2013 Grover Conference series).

7. Function of circle of Willis.

8. Wave reflections in the pulmonary arteries analysed with the reservoir-wave model.

9. A mathematical model of pressure and flow waveforms in the aortic root.

10. Living Without a Pulse: The Vascular Implications of Continuous-Flow Left Ventricular Assist Devices.