Knowledge of mitral valve (MV) mechanics is essential for the understanding of normal MV function, and the design and evaluation of new surgical repair procedures. In the present study, we extended our investigation of MV dynamic strain behavior to quantify the dynamic strain on the central region of the posterior leaflet. Native porcine MVs were mounted in an in-vitro physiologic flow loop. The papillary muscle (PM) positions were set to the normal, taut, and slack states to simulate physiological and pathological PM positions. Leaflet deformation was measured by tracking the displacements of 16 small markers placed in the central region of the posterior leaflet. Local leaflet tissue strain and strain rates were calculated from the measured displacements under dynamic loading conditions. A total of 18 mitral valves were studied. Our findings indicated the following: (1) There was a rapid rise in posterior leaflet strain during valve closure followed by a plateau where no additional strain (i.e., no creep) occurred. (2) The strain field was highly anisotropic with larger stretches and stretch rates in the radial direction. There were negligible stretches, or even compression (stretch<1) in the circumferential direction at the beginning of valve closure. (3) The areal strain curves were similar to the stretches in the trends. The posterior leaflet showed no significant differences in either peak stretches or stretch rates during valve closure between the normal, taut, and slack PM positions. (4) As compared with the anterior leaflet, the posterior leaflet demonstrated overall lower stretch rates in the normal PM position. However, the slack and taut PM positions did not demonstrate the significant difference in the stretch rates and areal strain rates between the posterior leaflet and the anterior leaflet. The MV posterior leaflet exhibited pronounced mechanically anisotropic behavior. Loading rates of the MV posterior leaflet were very high. The PM positions influenced neither peak stretch nor stretch rates in the central area of the posterior leaflet. The stretch rates and areal strain rates were significantly lower in the posterior leaflet than those measured in the anterior leaflet in the normal PM position. However, the slack and taut PM positions did not demonstrate the significant differences between the posterior leaflet and the anterior leaflet. We conclude that PM positions may influence the posterior strain in a different way as compared to the anterior leaflet.

1.
Kalmanson
,
D.
, 1974,
The Mitral Valve—A Pluridisciplinary Approach
,
Publishing Sciences Group, Inc.
, Acton, p.
3
.
2.
Jimenez
,
J. H.
,
He
,
S.
,
Seorensen
,
D. D.
,
He
,
Z. M.
, and
Yoganathan
,
A. P.
, 2003, “
Effects of a Saddle Shaped Mitral Annulus on Regurgitation and Chordal Force Distribution: An In Vitro Study
,”
Ann. Biomed. Eng.
0090-6964,
31
, pp.
1171
1181
.
3.
May-Newman
,
K.
, and
Yin
,
F. C.
, 1995, “
Biaxial Mechanical Behavior of Excised Porcine Mitral Valve Leaflets
,”
Am. J. Phys.
0002-9505,
269
, pp.
H1319
1327
.
4.
Billiar
,
K. L.
, and
Sacks
,
M. S.
, 2000, “
Biaxial Mechanical Properties of the Natural and Glutaraldehyde Treated Aortic Valve Cusp: Part I—Experimental Results
,”
J. Biomech. Eng.
0148-0731,
122
, pp.
23
30
.
5.
Billiar
,
K. L.
, and
Sacks
,
M. S.
, 2000, “
Biaxial Mechanical Properties of the Native and Glutaraldehyde-Treated Aortic Valve Cusp: Part II—A Structural Constitutive Model
,”
J. Biomech. Eng.
0148-0731,
122
, pp.
327
335
.
6.
Chen
L.
,
Yin
F. C. P.
, and
May-Newman
K.
, 2004, “
The Structure and Mechanical Properties of the Mitral Valve Leaflet-Strut Chordae Transition Zone
,”
J. Biomech. Eng.
0148-0731,
126
, pp.
244
-
251
.
7.
Kunzelman
,
K. S.
,
Cochran
,
R. P.
,
Chuong
,
C.
,
Ring
,
W. S.
,
Verrier
,
E. D.
, and
Eberhart
,
R. D.
, 1993, “
Finite Element Analysis of the Mitral Valve
,”
J. Heart Valve Dis.
0966-8519,
2
, pp.
326
340
.
8.
Kunzelman
,
K. S.
,
Quick
,
D. W.
, and
Cochran
,
R. P.
, 1998, “
Altered Collagen Concentration in Mitral Valve Leaflets: Biochemical and Finite Element Analysis
,”
Ann. Thorac. Surg.
0003-4975,
66
, pp.
S198
205
.
9.
Kunzelman
,
K. S.
,
Reimink
,
M. S.
, and
Cochran
,
R. P.
, 1998, “
Flexible Versus Rigid Ring Annuloplasty For Mitral Valve Annular Dilatation: A Finite Element Model
,”
J. Heart Valve Dis.
0966-8519,
7
, pp.
108
116
.
10.
Cochran
,
R. P.
, and
Kunzelman
,
K. S.
, 1998, “
Effect of Papillary Muscle Position on Mitral Valve Function: Relationship to Homografts
,”
Ann. Thorac. Surg.
0003-4975,
66
, pp.
S155
161
.
11.
Sacks
,
M. S.
,
He
,
Z. M.
,
Baijens
,
L.
,
Wanant
,
S.
,
Shah
,
P.
,
Sugimoto
,
H.
, and
Yoganathan
,
A. P.
, 2002, “
Surface Strains in the Anterior Leaflet of the Functioning Mitral Valve
,”
Ann. Biomed. Eng.
0090-6964,
30
, pp.
1281
1290
.
12.
He
,
Z. M.
,
Sacks
,
M. S.
,
Baijens
,
L.
,
Wanant
,
S.
,
Shah
,
P.
, and
Yoganathan
,
A.
, 2003, “
Effects of Papillary Muscle Position on the In Vitro Dynamic Strain on the Porcine Mitral Valve
,”
J. Heart Valve Dis.
0966-8519,
12
, pp.
488
494
13.
Sacks
,
M. S.
,
Grashow
,
J.
, and
Yoganathan
,
A. P.
, 2003, “
High Strain Rate Behavior of Heart Valve Tissues
,”
Proceedings of the Annual BMES Fall Meeting, Nashville, TN, 1–4 October
.
14.
Jensen
,
M.
,
Lemmon
,
J.
,
Gessaghi
,
V. C.
,
Conrad
,
C.
,
Levine
,
R. A.
, and
Yoganathan
,
A. P.
, 2001, “
Harvested Porcine Mitral Xenograft Fixation: Impact on Fluid Dynamic Performance
,”
J. Heart Valve Dis.
0966-8519,
10
, pp.
111
124
.
15.
Iyengar
,
A.
,
Sugimoto
,
H.
,
Smith
,
D. B.
, and
Sacksm
M. S.
, 2001, “
Dynamic In Vitro Quantification of Bioprosthetic Heart Valve Leaflet Motion Using Structured Light Projection
,”
Am. Mineral.
0003-004X,
29
, pp.
963
973
.
16.
Sacks
,
M. S.
,
Smith
,
D. B.
, and
Hiesterm
E D.
,
, 1997, “
A Small Angle Light Scattering Device For Planar Connective Tissue Microstructural Analysis
,”
Ann. Biomed. Eng.
0090-6964,
25
, pp.
678
689
.
17.
Adamczyk
M. M.
, and
Vesely
I.
, 2002, “
Characteristics of Compressive Strains in Porcine Aortic Valves Cusps
,”
J. Heart Valve Dis.
0966-8519,
11
, pp.
75
83
.
18.
Chester
A. H.
Misfeld
M.
, and
Yacoub
M. H
, 2000, “
Receptor-Mediated Contraction of Aortic Valve Leaflets
,”
J. Heart Valve Dis.
0966-8519,
9
, pp.
250
255
.
19.
Kershaw
J. D.
,
Chester
A. H.
, and
Yacoub
M. H.
, 2004, “
Heart Valve Cusps Exhibit Differential Contractile Capacities in Response to Receptor and Non-Receptor Operated-Mechanisms
,”
9th Biennial Meeting of International Society For Applied Cardiovascular Biology, 10–13 March, 2004, Savannah, GA
, p.
53
.
20.
Curtis
M. B.
, and
Priola
D. V.
, 1992,
Mechanical Properties of the Canine Mitral Valve: Effects of Autonomic Stimulation
,”
Am. J. Physiol.
0002-9513,
262
, pp.
H56
H62
.
21.
Kunzelman
,
K. S.
,
Cochran
,
R. P.
,
Murphree
,
S. S.
,
Ring
,
W. S.
,
Verrier
,
E. D.
, and
Eberhart
,
R. C.
, 1993, “
Differential Collagen Distribution in the Mitral Valve and its Influence on Biomechanical Behavior
,”
J. Heart Valve Dis.
0966-8519,
2
, pp.
236
244
.
You do not currently have access to this content.