The effect of anterior cruciate ligament graft rotation on knee laxity and graft tension

An in vitro biomechanical analysis

Sharon L. Hame, Keith L. Markolf, Arash J. Gabayan, David M Hunter, Brent Davis, Matthew S. Shapiro

Research output: Contribution to journalArticle

6 Citations (Scopus)

Abstract

Purpose: The purpose of this study was to determine the effects of rotating a bone-patellar tendonbone allograft during anterior cruciate ligament reconstruction on anteroposterior (AP) knee laxity and forces developed within the graft. Type of Study: In vitro biomechanical study using human cadaveric knees. Methods: Thirteen fresh-frozen knee specimens received bone-patella tendonbone allografts that were pretensioned at 30° of flexion to restore AP laxity to that of the intact knee. AP laxity was then measured at 0°, 30°, and 90° of knee flexion with the graft in neutral rotation and in 90° and 180° of internal and external rotation. Five specimens received allografts that were rotated to 90° internally and externally and then tensioned. Two knee specimens were used to measure the effects of graft rotation on graft force at full extension; 1 received 7 separate allografts and the other received 10 allografts. During testing, the potted end of the allograft that was connected to a tibial load cell was rotated. Results: In specimens tensioned and then rotated, AP laxity at 30° of knee flexion decreased an average of 0.9 mm with 90° of graft rotation in either direction. At 180° of external rotation, the mean decrease in laxity of 1.8 mm was significantly greater than that for 180° of internal rotation (P < .05). When significant, all mean laxity reductions at 0° and 90° of flexion were less than those at 30° of flexion. In specimens where the graft was rotated and then tensioned, rotation had no significant effect on laxity. With the exception of 90° of external rotation, rotation of the graft increased graft tension at full extension; 90° of internal rotation increased mean graft force by 11 N (P < .05). Rotating the graft 180° in either direction increased mean graft force at full extension by 25 N (P < .05). Conclusions: Although minor, rotating the graft had significant effects on knee laxity and graft tension. In general, AP laxity decreased and graft tension increased with increasing rotation of the graft. The direction of rotation did not seem to be important. As a result, clinicians who choose to rotate their patellar tendon grafts can expect that the biomechanical changes in the graft with rotation will have little clinical importance.

Original languageEnglish (US)
Pages (from-to)55-60
Number of pages6
JournalArthroscopy
Volume18
Issue number1
DOIs
StatePublished - Jan 1 2002
Externally publishedYes

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Anterior Cruciate Ligament
Knee
Transplants
Allografts
In Vitro Techniques
Bone and Bones
Patellar Ligament
Anterior Cruciate Ligament Reconstruction
Patella

Keywords

  • Anterior cruciate ligament
  • Biomechanics
  • Graft rotation
  • Laxity

ASJC Scopus subject areas

  • Orthopedics and Sports Medicine

Cite this

The effect of anterior cruciate ligament graft rotation on knee laxity and graft tension : An in vitro biomechanical analysis. / Hame, Sharon L.; Markolf, Keith L.; Gabayan, Arash J.; Hunter, David M; Davis, Brent; Shapiro, Matthew S.

In: Arthroscopy, Vol. 18, No. 1, 01.01.2002, p. 55-60.

Research output: Contribution to journalArticle

Hame, Sharon L. ; Markolf, Keith L. ; Gabayan, Arash J. ; Hunter, David M ; Davis, Brent ; Shapiro, Matthew S. / The effect of anterior cruciate ligament graft rotation on knee laxity and graft tension : An in vitro biomechanical analysis. In: Arthroscopy. 2002 ; Vol. 18, No. 1. pp. 55-60.
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abstract = "Purpose: The purpose of this study was to determine the effects of rotating a bone-patellar tendonbone allograft during anterior cruciate ligament reconstruction on anteroposterior (AP) knee laxity and forces developed within the graft. Type of Study: In vitro biomechanical study using human cadaveric knees. Methods: Thirteen fresh-frozen knee specimens received bone-patella tendonbone allografts that were pretensioned at 30° of flexion to restore AP laxity to that of the intact knee. AP laxity was then measured at 0°, 30°, and 90° of knee flexion with the graft in neutral rotation and in 90° and 180° of internal and external rotation. Five specimens received allografts that were rotated to 90° internally and externally and then tensioned. Two knee specimens were used to measure the effects of graft rotation on graft force at full extension; 1 received 7 separate allografts and the other received 10 allografts. During testing, the potted end of the allograft that was connected to a tibial load cell was rotated. Results: In specimens tensioned and then rotated, AP laxity at 30° of knee flexion decreased an average of 0.9 mm with 90° of graft rotation in either direction. At 180° of external rotation, the mean decrease in laxity of 1.8 mm was significantly greater than that for 180° of internal rotation (P < .05). When significant, all mean laxity reductions at 0° and 90° of flexion were less than those at 30° of flexion. In specimens where the graft was rotated and then tensioned, rotation had no significant effect on laxity. With the exception of 90° of external rotation, rotation of the graft increased graft tension at full extension; 90° of internal rotation increased mean graft force by 11 N (P < .05). Rotating the graft 180° in either direction increased mean graft force at full extension by 25 N (P < .05). Conclusions: Although minor, rotating the graft had significant effects on knee laxity and graft tension. In general, AP laxity decreased and graft tension increased with increasing rotation of the graft. The direction of rotation did not seem to be important. As a result, clinicians who choose to rotate their patellar tendon grafts can expect that the biomechanical changes in the graft with rotation will have little clinical importance.",
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AU - Hame, Sharon L.

AU - Markolf, Keith L.

AU - Gabayan, Arash J.

AU - Hunter, David M

AU - Davis, Brent

AU - Shapiro, Matthew S.

PY - 2002/1/1

Y1 - 2002/1/1

N2 - Purpose: The purpose of this study was to determine the effects of rotating a bone-patellar tendonbone allograft during anterior cruciate ligament reconstruction on anteroposterior (AP) knee laxity and forces developed within the graft. Type of Study: In vitro biomechanical study using human cadaveric knees. Methods: Thirteen fresh-frozen knee specimens received bone-patella tendonbone allografts that were pretensioned at 30° of flexion to restore AP laxity to that of the intact knee. AP laxity was then measured at 0°, 30°, and 90° of knee flexion with the graft in neutral rotation and in 90° and 180° of internal and external rotation. Five specimens received allografts that were rotated to 90° internally and externally and then tensioned. Two knee specimens were used to measure the effects of graft rotation on graft force at full extension; 1 received 7 separate allografts and the other received 10 allografts. During testing, the potted end of the allograft that was connected to a tibial load cell was rotated. Results: In specimens tensioned and then rotated, AP laxity at 30° of knee flexion decreased an average of 0.9 mm with 90° of graft rotation in either direction. At 180° of external rotation, the mean decrease in laxity of 1.8 mm was significantly greater than that for 180° of internal rotation (P < .05). When significant, all mean laxity reductions at 0° and 90° of flexion were less than those at 30° of flexion. In specimens where the graft was rotated and then tensioned, rotation had no significant effect on laxity. With the exception of 90° of external rotation, rotation of the graft increased graft tension at full extension; 90° of internal rotation increased mean graft force by 11 N (P < .05). Rotating the graft 180° in either direction increased mean graft force at full extension by 25 N (P < .05). Conclusions: Although minor, rotating the graft had significant effects on knee laxity and graft tension. In general, AP laxity decreased and graft tension increased with increasing rotation of the graft. The direction of rotation did not seem to be important. As a result, clinicians who choose to rotate their patellar tendon grafts can expect that the biomechanical changes in the graft with rotation will have little clinical importance.

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