THE HYDRODYNAMIC FUNCTION AND LEAFLET DYNAMICS OF AORTIC AND PULMONARY ROOTS AND VALVES - AN INVITRO STUDY

被引：24

作者：

WEERASENA, N

LOCKIE, KJ

BUTTERFIELD, M

FISHER, J

KEARNEY, JN

DAVIES, GA

机构：

[1] UNIV LEEDS,DEPT MECH ENGN,LEEDS LS2 9JT,W YORKSHIRE,ENGLAND

[2] KILLINGBECK HOSP,CARDIAC RES UNIT,LEEDS,ENGLAND

来源：

EUROPEAN JOURNAL OF CARDIO-THORACIC SURGERY | 1992年 / 6卷 / 07期

关键词：

HOMOGRAFT; PULMONARY ROOT; AORTIC ROOT; FUNCTION;

D O I：

10.1016/1010-7940(92)90171-S

中图分类号：

R5 [内科学];

学科分类号：

1002 ; 100201 ;

摘要：

Fresh homograft aortic and pulmonary roots were tested in a pulsatile flow simulator to assess their hydrodynamic function and leaflet opening characteristics. Simultaneous flow and pressure measurements were obtained for a range of cardiac outputs. The effective orifice area and regurgitant volumes were calculated. The mean pressure difference across the pulmonary roots was obtained under both left and right side pressures. A video recording of valve leaflet function was also obtained for each valve. A comparison was made with four porcine bioprosthetic heart valves (21 and 23 mm). The mean pressure difference with respect to flow for the 21 mm Hancock II and Intact porcine bioprostheses was significantly higher than that for all aortic roots tested. The 24 mm aortic root showed significantly lower pressure drop compared to all porcine valves tested. The mean pressure difference across each pulmonary root at pulmonary pressures was significantly greater than at systemic pressures. At systemic pressures the fully open leaflets had a triangular orifice with low leaflet open bending strains at the commissures. At the lower internal pressures, with reduced dilation of the root, higher bending strains were noted. These were not as severe as seen in porcine valves.

引用

页码：350 / 356

页数：7

共 25 条

[1]

Barratt-Boyes B.G., Roche A.H.G., Brandt P.W.T., Smith J.C., Lowe J.B., Aortic homograft valve replacement. A long-term follow-up of an initial series of 101 patients, Circulation, 40, pp. 763-775, (1969)

[2]

Bernhard A., Mahmoodi M., Sievers H.H., Kraatz E.G., Maurer I., Heintzen P., A “semi-supported” porcine xenograft-de-scription and frist clinical use, Thorac Cardiovasc Surgeon, 37, pp. 313-315, (1989)

[3]

Brewer R.J., Deck J.D., Capati B., Nolan S.P., The dynamic aortic root: Its role in aortic valve function, J Thorac Cardiovasc Surg, 72, pp. 413-417, (1976)

[4]

Brewer R.J., Mentzer R.M., Deck J.D., Ritter R.C., Trefil J.S., Nolan S.P., An in vivo study of the dimensional changes of the aortic valve leaflets during the cardiac cycle, J Thorac Cardiovasc Surg, 74, pp. 645-650, (1977)

[5]

Butterfield M., Fisher J., Davis G.A., Kearney J.N., Leaflet geometry and function in porcine bioprostheses, Eur J Cardio-thorac Surg, 5, pp. 27-33, (1991)

[6]

Butterfield M., Fisher J., Davis G.A., Kearney J.N., Sureta F., Watson D.A., Fresh and glutaraldehyde preserved frame mounted homograft and porcine bioprosthetic heart valves: Leaflet geometry, dynamics and functions, Clinical implant materials advances in biomaterials, 9, (1990)

[7]

David T.E., Pollick C., Bos J., Aortic valve replacement with stentless porcine aortic bioprosthesis, J Thorac Cardiovasc Surg, 90, pp. 113-118, (1990)

[8]

Fisher J., Jackie G.R., Wheatley D.J., Design of a function test apparatus for prosthetic heart valves, Clin Phys Physiol Meas, 7, pp. 63-73, (1986)

[9]

Fisher J., Wheatley D.J., Hydrodynamic function of ten bioprosthetic heart valves in the aortic position, Clin Phys Physiol Meas, 9, pp. 307-317, (1988)

[10]

Gonzalez-Lavin L., Robles A., Graf D., Morbidity following the Ross operation, J Cardiac Surg, 3, pp. 305-308, (1988)

← 1 2 3 →