TY - JOUR
T1 - Static rotational and sagittal knee laxity measurements after reconstruction of the anterior cruciate ligament
AU - Lorbach, O.
AU - Kieb, M.
AU - Brogard, P.
AU - Maas, S.
AU - Pape, D.
AU - Seil, R.
PY - 2012/5
Y1 - 2012/5
N2 - Purpose: The goal of the present study was to evaluate static anteroposterior and rotational knee laxity after ACL reconstructions with two noninvasive measurement devices by comparing the measured results of the operated with the contralateral healthy knees of the patients. Methods: Fifty-two consecutive patients were reviewed after isolated single-bundle transtibial ACL reconstruction using a BPTB graft. At a mean follow-up of 27 months, sagittal AP laxity was tested using a noninvasive knee measurement system (Genourob) with an applied pressure of 67 N, 89 N and 134 N. Rotational laxity was measured using a noninvasive rotational knee laxity device (Rotameter) with an applied torque of 5, 8 and 10 Nm. The results were compared with the measurements of the patients' healthy contralateral knees. Tegner, Lysholm and IKDC score were used in order to evaluate the clinical outcome. Results: Pivot shift was negative (33) or glide (16) in 49 patients with 12 of 16 (75%) patients having also a pivot glide on the healthy contralateral side; Lachman tests were negative in 50 cases. Subjective assessment of the IKDC score was classified according to category A in 44 patients, B in 5 patients and C in 3 patients. Mean Lysholm score was 94.5 ± 9.5, median Tegner score was 7 (3-9) preoperative and 6 (3-9) at follow-up (n. s.). Anteroposterior knee laxity measurements revealed mean side-to-side differences of 0.6-1.3 mm (P < 0.0001). Rotational laxity measurements revealed no statistical significant differences between the operated and the contralateral knee (n. s.). The measured differences in the entire rotational range varied from 0.2° to 1° depending on the applied torque. In those 3 patients with a positive pivot shift, differences in the entire rotational range of 4.5° at 5 N, 4.6° at 8 N and 4.1° at 10 N were found. Conclusion: Static knee laxity was quantified after ACL surgery using the introduced noninvasive measurement systems by comparing the measured results of the operated with the contralateral healthy knees. Significant differences were found in AP laxity although they were defined as clinically successful according to the IKDC classification. No significant differences were found in rotational knee laxity measurements. Therefore, the used noninvasive masurement devices might offer a high potential for objective quality control in knee ligament injuries and their treatment. Level of evidence: Retrospective case series, Level IV.
AB - Purpose: The goal of the present study was to evaluate static anteroposterior and rotational knee laxity after ACL reconstructions with two noninvasive measurement devices by comparing the measured results of the operated with the contralateral healthy knees of the patients. Methods: Fifty-two consecutive patients were reviewed after isolated single-bundle transtibial ACL reconstruction using a BPTB graft. At a mean follow-up of 27 months, sagittal AP laxity was tested using a noninvasive knee measurement system (Genourob) with an applied pressure of 67 N, 89 N and 134 N. Rotational laxity was measured using a noninvasive rotational knee laxity device (Rotameter) with an applied torque of 5, 8 and 10 Nm. The results were compared with the measurements of the patients' healthy contralateral knees. Tegner, Lysholm and IKDC score were used in order to evaluate the clinical outcome. Results: Pivot shift was negative (33) or glide (16) in 49 patients with 12 of 16 (75%) patients having also a pivot glide on the healthy contralateral side; Lachman tests were negative in 50 cases. Subjective assessment of the IKDC score was classified according to category A in 44 patients, B in 5 patients and C in 3 patients. Mean Lysholm score was 94.5 ± 9.5, median Tegner score was 7 (3-9) preoperative and 6 (3-9) at follow-up (n. s.). Anteroposterior knee laxity measurements revealed mean side-to-side differences of 0.6-1.3 mm (P < 0.0001). Rotational laxity measurements revealed no statistical significant differences between the operated and the contralateral knee (n. s.). The measured differences in the entire rotational range varied from 0.2° to 1° depending on the applied torque. In those 3 patients with a positive pivot shift, differences in the entire rotational range of 4.5° at 5 N, 4.6° at 8 N and 4.1° at 10 N were found. Conclusion: Static knee laxity was quantified after ACL surgery using the introduced noninvasive measurement systems by comparing the measured results of the operated with the contralateral healthy knees. Significant differences were found in AP laxity although they were defined as clinically successful according to the IKDC classification. No significant differences were found in rotational knee laxity measurements. Therefore, the used noninvasive masurement devices might offer a high potential for objective quality control in knee ligament injuries and their treatment. Level of evidence: Retrospective case series, Level IV.
KW - ACL
KW - Knee-laxity
KW - Measurement device
KW - Single-bundle
KW - Tibiofemoral rotation
UR - http://www.scopus.com/inward/record.url?scp=84860129516&partnerID=8YFLogxK
U2 - 10.1007/s00167-011-1635-5
DO - 10.1007/s00167-011-1635-5
M3 - Review article
C2 - 21811853
AN - SCOPUS:84860129516
SN - 0942-2056
VL - 20
SP - 844
EP - 850
JO - Knee Surgery, Sports Traumatology, Arthroscopy
JF - Knee Surgery, Sports Traumatology, Arthroscopy
IS - 5
ER -