Image Processing Reference
In-Depth Information
59.
Mancini, G., De Boe, S., Anselmo, E., Simon, S., Le Free, M., and Vogel, R.
(1987). Quantitative regional curvature analysis: an application of shape determi-
nation for the assessment of segmental left ventricular function in man.
Am. Heart.
J
. 113(2 Pt 1): 326-334.
60.
Mancini, G., DeBoe, S., McGillem, M., and Bates, E. (1988). Quantitative regional
curvature analysis: a prospective evaluation of ventricular shape and wall motion
measurements.
Am. Heart. J
. 116(6 Pt 1): 1611-1621.
61.
Kass, D., Traill, T., Keating, M., Altieri, P., and Maughan, W. (1988). Abnormal-
ities of dynamic ventricular shape change in patients with aortic and mitral valvular
regurgitation: assessment by Fourier shape analysis and global geometric indexes.
Circ. Res.
62(1): 127-38.
62.
Barletta, G., Baroni, M., del Bene, R., Toso, A., and Fantini, F. (1998). Regional
and temporal nonuniformity of shape and wall movement in the normal left
ventricle.
Cardiology,
90(3): 195-201.
63.
Kondo, C., Caputo, G., Smelka, R., Foster, E., Shimakawa, A., and Higgins, C.
(1991). Right and left ventricular stroke volume measurements with velocity-
encoded cine MR imaging:
in vitro
and
in vivo
validation.
Am. J. Roentgenol
.
157(1): 9-16.
64.
Hillis, L., Firth, B., and Winniford, M. (1986). Analysis of factors affecting the
variability of Fick vs. indicator dilution measurements of cardiac output.
Am. J.
Cardiol
. 56(12): 764-768.
65.
McEachen, J.C., Neohorai, A., and Duncan, J.S. (1994). A recursive filter for
temporal analysis of cardiac motion. in
Math. Meth. Biomed. Imag. Anal
. 124-133.
Seattle, USA.
66.
Potel, M., Rubin, J., MacKay, S., Aisen, A., Al-Sadir, J., and Sayre, R. (1983).
Methods for evaluating cardiac wall motion in three dimensions using bifurcation
points of the coronary arterial tree.
Inv. Rad
. 18(1): 47-57.
67.
Kim, H., Min, B., Lee, M., Seo, J., Lee, Y., and Han, M. (1985). Estimation of
local cardiac wall deformation and regional wall stress from biplane coronary
cineangiograms.
IEEE Trans. Biomed. Eng
. 32(7): 503-512.
68.
Chen, C. and Huang, T. (1990). Epicardial motion and deformation estimation
from coronary artery bifurcation points. in
Intl. Conf. Comput. Vision
. 456-459.
Osaka, Japan.
69.
Young, A., Hunter, P., and Smaill, B. (1992). Estimation of epicardial strain using
the motions of coronary bifurcations in biplane cineangiography.
IEEE Trans.
Biomed. Eng
. 39(5): 526-531.
70.
Harrison, D., Goldblatt, A., Braunwald, E., Glick, G., and Mason, D.T. (1963).
Studies on cardiac dimensions in intact unanesthetized man. I. description of
techniques and their validation.
Circ. Res
. 13: 448-455.
71.
Rankin, J., McHale, P., Artentzen, C., Ling, D., Greenfield, J., and Anderson, R.
(1976). The three-dimensional dynamic geometry of the left ventricle in the
conscious dog.
Circ. Res
. 39(3): 304-313.
72.
Brower, R., ten Katen, H., and Meester, G. (1978). Direct method for determining
regional myocardial shortening after bypass surgery from radiopaque markers in
man.
Am. J. Cardiol
. 41(7): 1222-1229.
73.
Ingels, N., Daughters, G., Stinson, E., Alderman, E. (1980). Evaluation of methods
for quantitating left ventricular segmental wall motion in man using myocardial
markers as a standard.
Circulation
. 61(5): 966-972.
Search WWH ::
Custom Search