The use of a laser micrometer system to determine the cross-sectional shape and area of ligaments:​ a comparative study with two existing methods

Woo, Savio L-Y.<sup>1,2</sup>; Danto, Michael I.<sup>1,2</sup>; Ohland, Karen J.<sup>1,2</sup>; Lee, Thay Q.<sup>3</sup>; Newton, Peter O.<sup>2</sup>

Affiliations

¹Connective Tissue and Muscoloskeletal Research Laboratories, Department of Orthopaedic Surgery, University of Pittsburgh, Pittsburgh, PA 15261

²Orthopaedic Bioengineering Laboratory, San Diego Veterans Administration Medical Center and University of California, San Diego, LaJolla, CA 92093

³STAMP Program, Long Beach Veterans Medical Center and Department of Orthopaedics, University of California, Irvine, Orange, CA 92668

Abstract

Determination of the tensile stresses in ligaments and tendons during uniaxial loading depends on accurate measurement of the cross-sectional area. In this study, a laser micrometer system was employed to evaluate the cross-sectional shape and area of the medial collateral ligament (MCL) at three locations and anterior cruciate ligament (ACL). In a New Zealand White (NZW) rabbit, morphologic sections of the ligaments were made to verify the cross-sectional shape reconstructed by the laser micrometer system. The areas obtained by the laser micrometer system from ten additional NZW rabbits were compared with those obtained by two other methods commonly used to measure the cross-sectional area of ligaments and tendons: one method uses digital calipers and the other a constant pressure (0.12 MPa) area micrometer. For the MCL, the digital calipers yielded results very similar to those of the laser micrometer, but the constant pressure area micrometer yielded values 20 percent lower. The area measured at the proximal site of the MCL was 13 percent greater than the area measured at the joint line and distal line. For the A CL, the values obtained by the digital calipers and constant pressure area micrometer were 16 and 20 percent lower, respectively. Because of the irregular shape exhibited by the rabbit ACL, the digital calipers could not accurately measure the crosssectional area. The constant pressure area micrometer yielded lower values for the cross-sectional area of both the MCL and ACL, presumably due to the applied pressure which caused changes in both the cross-sectional shape and area.

Links

DOI: 10.1115/1.2891206

PubMed: 2273869

WoS: A1990EL16300009

History

Received: 1989-11-01

Revised: 1990-04-20

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Cited By (29)

Year	Entry
2003	Woo SL-Y, Abramowitch SD, Loh JC, Musahl V, Wang JH-C. Ligament healing: present status and the future of functional tissue engineering. In: Guilak F, Butler DL, Goldstein SA, Mooney DJ, eds. Functional Tissue Engineering. New York, NY: Inc., Springer-Verlag; 2003:17-34.
2003	Kerrigan JR, Ivarsson BJ, Bose D, Madeley NJ, Millington SA, Bhalla KS, Crandall JR. Rate-sensitive constitutive and failure properties of human collateral knee ligaments. In: Proceedings of the 2003 International IRCOBI Conference on the Biomechanics of Impact. September 25, 2003; Lisbon, Portugal.177-190.
1995	Myers BS, Van Ee CA, Camacho DLA, Woolley CT, Best TM. On the structural and material properties of mammalian skeletal muscle and its relevance to human cervical impact dynamics. In: Proceedings of the 39th Stapp Car Crash Conference. November 8-10, 1995; San Diego, CA. Warrendale, PA: Society of Automotive Engineers:203-214. SAE 952723.
2015	Lievers WB, Frimenko RE, McCullough KA, Crandall JR, Kent RW. Etiology and biomechanics of midfoot (Lisfranc) injuries in athletes. Crit Rev Biomed Eng. 2015;43(2-3):213-238.
1994	Derwin KA, Soslowsky LJ, Green WDK, Elder SH. A new optical system for the determination of deformations and strains: calibration characteristics and experimental results. J Biomech. October 1994;27(10):1277-1285.
1996	Race A, Amis AA. Cross-sectional area measurement of soft tissue: a new casting method. J Biomech. September 1996;29(9):1207-1212.
1996	Bowman SM, Zeind J, Gibson LJ, Hayes WC, McMahon TA. The tensile behavior of demineralized bovine cortical bone. J Biomech. November 1996;29(11):1497-1501.
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2005	Hashemi J, Chandrashekar N, Cowden C, Slauterbeck J. An alternative method of anthropometry of anterior cruciate ligament through 3-D digital image reconstruction. J Biomech. May 2005;38(3):551-555.
2004	Abramowitch SD, Woo SL-Y. An improved method to analyze the stress relaxation of ligaments following a finite ramp time based on the quasi-linear viscoelastic theory. J Biomech Eng. February 2004;126(1):92-97.
2010	Schmidt KH, Ledoux WR. Quantifying ligament cross-sectional area via molding and casting. J Biomech Eng. September 2010;132(9):091012.
1993	Danto MI, Woo SL. The mechanical properties of skeletally mature rabbit anterior cruciate ligament and patellar tendon over a range of strain rates. J Orthop Res. January 1993;11(1):58-67.
1996	Przybylski GJ, Carlin GJ, Patel PR, Woo SL-Y. Human anterior and posterior cervical longitudinal ligaments possess similar tensile properties. J Orthop Res. 1996;14(6):1005-1008.
2005	Mkandawire C, Ledoux WR, Sangeorzan BJ, Ching RP. Foot and ankle ligament morphometry. J Rehab Res Dev. November–December 2005;42(6):809-819.
1997	Pioletti DP. Viscoelastic Properties of Soft Tissues Application to Knee Ligaments and Tendons [PhD thesis]. Swiss Federal Institute of Technology Lausanne; 1997.
1997	Bowman SM. Creep of Trabecular Bone [PhD thesis]. Cambridge, MA: Harvard University; May 1997.
1999	Bull AMJ. Measurement and Computer Simulation of Knee Kinematics [PhD thesis]. Imperial College London; 1999.
1997	Debski RE. A Combined Experimental and Computational Approach to Examine the Function of the Capsuloligamentous Structures At the Glenohumeral Joint [PhD thesis]. University of Pittsburgh; 1997.
1998	Pfaeffle HJ. Role of the Interosseous Ligament in Forearm Compressive Load Transfer [PhD thesis]. University of Pittsburgh; 1998.
2004	Abramowitch SD. An Evaluation of the Non-Linear Viscoelastic Properties of the Healing Medial Collateral Ligament [PhD thesis]. University of Pittsburgh; 2004.
2006	Moore SM. Glenohumeral Capsule Should be Evaluated as a Sheet of Fibrous Tissue: A Study in Functional Anatomy [PhD thesis]. University of Pittsburgh; 2006.
2007	Papas NP. Potential of a Bioscaffold to Enhance the Healing of the MCL Following a Mop-End Tear: An Animal Model Study [Master's thesis]. University of Pittsburgh; 2007.
2011	Feola AJ. Impact of Vaginal Synthetic Prolapse Meshes on the Mechanics of the Host Tissue Response [PhD thesis]. University of Pittsburgh; 2011.
2014	Kim KE. The Development of Biodegradable Metallic Screws and Suture Anchors for Soft Tissue Fixation in Orthopaedic Surgery [PhD thesis]. University of Pittsburgh; 2014.
2015	Farraro KF. Regeneration of the Anterior Cruciate Ligament Using Resorbable Metallic and Extracellular Matrix Bioscaffolds [PhD thesis]. University of Pittsburgh; 2015.
2005	Chandrashekar NK. Sex-Based Difference in the Morphology, Tensile Properties and Ultrastructure of the Human Anterior Cruciate Ligament and Patellar Tendon [PhD thesis]. Lubboch, TX: Texas Tech University; December 2005.
1998	Derwin KA. A Quantitative Investigation of Structure-Function Relationships in a Tendon Fascicle Model [PhD thesis]. University of Michigan; 1998.
2008	Pokhai GG. The Development of a Laser Reflectance System to Measure the Cross-Sectional Area of Soft Tissues [Master's thesis]. University of Guelph; June 2008.
2002	Mkandawire C. The Relationship Between Viscoelastic Relaxation and Ligament Morphometry [PhD thesis]. Seattle, WA: University of Washington; 2002.