TY - JOUR
T1 - Inaccuracy of mitral pressure half-time immediately after percutaneous mitral valvotomy
T2 - Dependence on transmitral gradient and left atrial and ventricular compliance
AU - Thomas, J. D.
AU - Wilkins, G. T.
AU - Choong, C. Y.P.
AU - Abascal, V. M.
AU - Palacios, I. F.
AU - Block, P. C.
AU - Weyman, A. E.
PY - 1988
Y1 - 1988
N2 - Mitral pressure half-time (T( 1/2 )) is widely used as an independent measure of mitral valve area in patients undergoing percutaneous mitral valvotomy. However, fluid dynamics theory predicts T( 1/2 ) to be strongly dependent on chamber compliance and the peak transmitral gradient, which are variables that change dramatically with valvotomy. These theoretical predictions were tested in an in vitro model of the left heart where valve area, chamber compliance, and initial gradient were independently adjusted. Measured T( 1/2 ) was observed to vary inversely with orifice area and directly with net chamber compliance and the square foot of the initial pressure gradient. Theoretical predictions of T( 1/2 ) agreed with observed values with r = 0.998. To test this theory in vivo, the hemodynamic tracings of 18 patients undergoing mitral valvotomy were reviewed. Predictions were made for T( 1/2 ) assuming dependence only on valve area; these showed some correlations before valvotomy (r = 0.48-0.64, p < 0.05) but none after valvotomy (r = 0.05-0.28, p = NS). Predictions for T( 1/2 ) based on the theoretical derivation (and thus including compliance and pressure in their calculation) were much better: before valvotomy, r = 0.93-0.96, p < 0.0001; after valvotomy, r = 0.52-0.66, p < 0.05. These data indicate that T( 1/2 ) is not an independent inverse measure of mitral valve area but is also directly proportional to net chamber compliance and the square root of the initial transmitral gradient. These other factors render T( 1/2 ) an unreliable measure of mitral valve area in the setting of acute mitral valvotomy.
AB - Mitral pressure half-time (T( 1/2 )) is widely used as an independent measure of mitral valve area in patients undergoing percutaneous mitral valvotomy. However, fluid dynamics theory predicts T( 1/2 ) to be strongly dependent on chamber compliance and the peak transmitral gradient, which are variables that change dramatically with valvotomy. These theoretical predictions were tested in an in vitro model of the left heart where valve area, chamber compliance, and initial gradient were independently adjusted. Measured T( 1/2 ) was observed to vary inversely with orifice area and directly with net chamber compliance and the square foot of the initial pressure gradient. Theoretical predictions of T( 1/2 ) agreed with observed values with r = 0.998. To test this theory in vivo, the hemodynamic tracings of 18 patients undergoing mitral valvotomy were reviewed. Predictions were made for T( 1/2 ) assuming dependence only on valve area; these showed some correlations before valvotomy (r = 0.48-0.64, p < 0.05) but none after valvotomy (r = 0.05-0.28, p = NS). Predictions for T( 1/2 ) based on the theoretical derivation (and thus including compliance and pressure in their calculation) were much better: before valvotomy, r = 0.93-0.96, p < 0.0001; after valvotomy, r = 0.52-0.66, p < 0.05. These data indicate that T( 1/2 ) is not an independent inverse measure of mitral valve area but is also directly proportional to net chamber compliance and the square root of the initial transmitral gradient. These other factors render T( 1/2 ) an unreliable measure of mitral valve area in the setting of acute mitral valvotomy.
UR - http://www.scopus.com/inward/record.url?scp=0023753489&partnerID=8YFLogxK
U2 - 10.1161/01.CIR.78.4.980
DO - 10.1161/01.CIR.78.4.980
M3 - Article
C2 - 3168200
AN - SCOPUS:0023753489
SN - 0009-7322
VL - 78
SP - 980
EP - 993
JO - Circulation
JF - Circulation
IS - 4 I
ER -