Progress toward understanding the underlying mechanisms of pelvic organ prolapse (POP) is limited, in part, due to a lack of information on the biomechanical properties and microstructural composition of the vaginal wall. Compromised vaginal wall integrity is thought to contribute to pelvic floor disorders; however, normal structure–function relationships within the vaginal wall are not fully understood. In addition to the information produced from uniaxial testing, biaxial extension–inflation tests performed over a range of physiological values could provide additional insights into vaginal wall mechanical behavior (i.e., axial coupling and anisotropy), while preserving in vivo tissue geometry. Thus, we present experimental methods of assessing murine vaginal wall biaxial mechanical properties using extension–inflation protocols. Geometrically intact vaginal samples taken from 16 female C57BL/6 mice underwent pressure–diameter and force–length preconditioning and testing within a pressure-myograph device. A bilinear curve fit was applied to the local stress–stretch data to quantify the transition stress and stretch as well as the toe- and linear-region moduli. The murine vaginal wall demonstrated a nonlinear response resembling that of other soft tissues, and evaluation of bilinear curve fits suggests that the vagina exhibits pseudoelasticity, axial coupling, and anisotropy. The protocols developed herein permit quantification of biaxial tissue properties. These methods can be utilized in future studies in order to assess evolving structure–function relationships with respect to aging, the onset of prolapse, and response to potential clinical interventions.
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October 2017
Technical Briefs
Biaxial Mechanical Assessment of the Murine Vaginal Wall Using Extension–Inflation Testing
Kathryn M. Robison,
Kathryn M. Robison
Mem. ASME
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: krobison@tulane.edu
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: krobison@tulane.edu
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Cassandra K. Conway,
Cassandra K. Conway
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: cconway2@tulane.edu
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: cconway2@tulane.edu
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Laurephile Desrosiers,
Laurephile Desrosiers
Department of Female Pelvic Medicine
& Reconstructive Surgery,
Ochsner Clinical School,
1514 Jefferson Highway,
New Orleans, LA 70121
e-mail: laurephile.desrosiers@ochsner.org
& Reconstructive Surgery,
Ochsner Clinical School,
1514 Jefferson Highway,
New Orleans, LA 70121
e-mail: laurephile.desrosiers@ochsner.org
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Leise R. Knoepp,
Leise R. Knoepp
Department of Female Pelvic Medicine
& Reconstructive Surgery,
Ochsner Clinical School,
1514 Jefferson Highway,
New Orleans, LA 70121
e-mail: lknoepp@ochsner.org
& Reconstructive Surgery,
Ochsner Clinical School,
1514 Jefferson Highway,
New Orleans, LA 70121
e-mail: lknoepp@ochsner.org
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Kristin S. Miller
Kristin S. Miller
Mem. ASME
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: kmille11@tulane.edu
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: kmille11@tulane.edu
Search for other works by this author on:
Kathryn M. Robison
Mem. ASME
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: krobison@tulane.edu
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: krobison@tulane.edu
Cassandra K. Conway
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: cconway2@tulane.edu
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: cconway2@tulane.edu
Laurephile Desrosiers
Department of Female Pelvic Medicine
& Reconstructive Surgery,
Ochsner Clinical School,
1514 Jefferson Highway,
New Orleans, LA 70121
e-mail: laurephile.desrosiers@ochsner.org
& Reconstructive Surgery,
Ochsner Clinical School,
1514 Jefferson Highway,
New Orleans, LA 70121
e-mail: laurephile.desrosiers@ochsner.org
Leise R. Knoepp
Department of Female Pelvic Medicine
& Reconstructive Surgery,
Ochsner Clinical School,
1514 Jefferson Highway,
New Orleans, LA 70121
e-mail: lknoepp@ochsner.org
& Reconstructive Surgery,
Ochsner Clinical School,
1514 Jefferson Highway,
New Orleans, LA 70121
e-mail: lknoepp@ochsner.org
Kristin S. Miller
Mem. ASME
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: kmille11@tulane.edu
Department of Biomedical Engineering,
Tulane University,
6823 St. Charles Avenue,
New Orleans, LA 70118
e-mail: kmille11@tulane.edu
1Corresponding author.
Manuscript received February 8, 2017; final manuscript received August 1, 2017; published online August 24, 2017. Assoc. Editor: Jonathan Vande Geest.
J Biomech Eng. Oct 2017, 139(10): 104504 (8 pages)
Published Online: August 24, 2017
Article history
Received:
February 8, 2017
Revised:
August 1, 2017
Citation
Robison, K. M., Conway, C. K., Desrosiers, L., Knoepp, L. R., and Miller, K. S. (August 24, 2017). "Biaxial Mechanical Assessment of the Murine Vaginal Wall Using Extension–Inflation Testing." ASME. J Biomech Eng. October 2017; 139(10): 104504. https://doi.org/10.1115/1.4037559
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