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In vitro load transmission in the canine knee: The effect of medial meniscectomy and varus rotation (1993)

Anderson, D. R. ; Newman, A. P. ; Daniels, A. U.

Springer

Knee surgery, sports traumatology, arthroscopy 1 (1993), S. 44-50

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ISSN: 1433-7347

Keywords: Meniscus ; Meniscctomy ; Varus ; Biomechanics ; Knee

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine , Sports Science

Notes: Abstract The purpose of this study was to determine the in vitro load-transmission characteristics of the canine knee, paying particular attention to the positioning effect of the meniscus in the coronal plane. The intact joint was first loaded and then tested under two different loading conditions after a complete medial meniscectomy. The first set of test conditions attempted to simulate those used by previous investigators, by ignoring the spacer effect of the meniscus. The second set of tests were carried ouf following varus rotation of the joint (to account for the loss of the meniscal spacer) to assure initial contact in both tibiofemoral compartments at the start of test cycle. It is presumed that this varus realignment occurs during weight bearing following meniscectomy in vivo. As in previous studies, the joints experienced slightly larger displacements (although not statistically significant) and had lower stiffness values following medial meniscectomy than when intact. However, following varus realignment of the joint after meniscectomy, the displacement was markedly smaller (−35% to −40%;P〈0.01) and the structural stiffness was much greater (47–123%;P〈0.05) over the range of forces analyzed, compared with the intact joint. The ratio of dissipated to input energy was 42% for the intact joint, and increased following meniscectomy to 54% (P〈0.05) with realignment and 55% (P〈0.05) without realignment. Measured contact area decreased by 17% (P〈0.05) following meniscectomy alone, and by 12% (P〈0.05) following meniscectomy with realignment. Scince varus rotation of the joint following meniscectomy resulted in an increase in structural stiffness, it was concluded that the medial meniscus reduces the structural stiffness of the intact joint. In addition, the meniscus has a role in elastic energy storage and increasing contact area. A model is presented to explain both the decrease in stiffness after meniscectomy without varus rotation and the increase in stiffness after meniscectomy with varus rotation, employing linear springs of unequal length and different stiffnesses. After removal of the softer meniscal element and allowing joint approximation to occur, loading of the stiffer articular element results in an initially stiffer preparation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01552158

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The effect of medial meniscectomy and coronal plane angulation on in vitro load transmission in the canine stifle joint (1989)

Newman, Alan P. ; Anderson, D. Ron ; Daniels, A. U. ; [et al.]

Hoboken, NJ [u.a.] : Wiley-Blackwell

Journal of Orthopaedic Research 7 (1989), S. 281-291

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ISSN: 0736-0266

Keywords: Meniscus ; Meniscectomy ; Canine ; Mechanics ; In vitro ; Life and Medical Sciences

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Medicine

Notes: The purpose of this study was to determine the in vitro load transmission characteristics of the canine stifle joint, paying particular attention to the positioning effect of the meniscus in the coronal plane. The intact joint was first loaded, and then tested under two different loading conditions after a complete medial meniscectomy. The first set of test conditions attempted to simulate those used by previous investigators, by ignoring the spacer effect of the meniscus and not repositioning the joint after its removal. The second set of tests was carried out after the joint was repositioned in the coronal plane to allow initial contact to occur in both tibiofemoral compartments. It is presumed that this occurs subsequent to a meniscectomy in vivo, following the application of any weight-bearing load. As with previous investigators, it was found that after meniscectomy the joints produced slightly larger displacements and lower stiffnesses than when intact (no significant differences from intact). However, repositioning the meniscectomized joint produced markedly smaller displacements (35-49%, p 〈 0.01) and greater stiffnesses (47-123%, p 〈 0.05) over the range of forces analyzed, compared with the intact joint. The ratio of dissipated to input energy was 42% for the intact joint, and rose following meniscectomy to 54% (p 〈 0.05) with repositioning and 55% (p 〈 0.05) without repositioning. Measured contact area decreased by 17% (p 〈 0.05) following meniscectomy alone, and by 12% (p 〈 0.05) following meniscectomy with repositioning. Since repositioning of the joint subsequent to meniscectomy (accounting for the loss of the meniscal spacer) resulted in an increse in structural stiffness, it was concluded that the medial meniscus decreases the structural stiffness of the intact stifle joint. In addition, the meniscus has a role in elastic energy storage and increasing contact area. This study is intended to serve as a baseline comparison for future in vivo studies on meniscetomy, meniscal repair, and meniscal replacement, in addition to more fully elucidating the mechanism of load transmission. A model is presented to explain both the decrease in stiffness after meniscectomy without repositioning and the increase in stiffness after meniscectomy with repositioning, employing linear springs of unequal length and different stiffnesses. After removal of the softer meniscal element and allowing joint approximation to occur, loading of the stiffer articular element results in an initially stiffer preparation.

Additional Material: 7 Ill.