An Anterior Cruciate Ligament In Vitro Rupture Model Based on Clinical Imaging.
ACL reconstruction
anterior cruciate ligament
injury mechanism
Journal
The American journal of sports medicine
ISSN: 1552-3365
Titre abrégé: Am J Sports Med
Pays: United States
ID NLM: 7609541
Informations de publication
Date de publication:
07 2021
07 2021
Historique:
pubmed:
12
6
2021
medline:
10
8
2021
entrez:
11
6
2021
Statut:
ppublish
Résumé
Biomechanical studies on anterior cruciate ligament (ACL) injuries and reconstructions are based on ACL transection instead of realistic injury trauma. To replicate an ACL injury in vitro and compare the laxity that occurs with that after an isolated ACL transection injury before and after ACL reconstruction. Controlled laboratory study. Nine paired knees were ACL injured or ACL transected. For ACL injury, knees were mounted in a rig that imposed tibial anterior translation at 1000 mm/min to rupture the ACL at 22.5° of flexion, 5° of internal rotation, and 710 N of joint compressive force, replicating data published on clinical bone bruise locations. In contralateral knees, the ACL was transected arthroscopically at midsubstance. Both groups had ACL reconstruction with bone-patellar tendon-bone graft. Native, ACL-deficient, and reconstructed knee laxities were measured in a kinematics rig from 0° to 100° of flexion with optical tracking: anterior tibial translation (ATT), internal rotation (IR), anterolateral (ATT + IR), and pivot shift (IR + valgus). The ACL ruptured at 26 ± 5 mm of ATT and 1550 ± 620 N of force (mean ± SD) with an audible spring-back tibiofemoral impact with 5 This study developed an ACL injury model in vitro that replicated clinical ACL injury as evidenced by bone bruise patterns. ACL injury caused larger increases of laxity than ACL transection, likely because of damage to adjacent tissues; these differences often persisted after ACL reconstruction. This in vitro model created more realistic ACL injuries than surgical transection, facilitating future evaluation of ACL reconstruction techniques.
Sections du résumé
BACKGROUND
Biomechanical studies on anterior cruciate ligament (ACL) injuries and reconstructions are based on ACL transection instead of realistic injury trauma.
PURPOSE
To replicate an ACL injury in vitro and compare the laxity that occurs with that after an isolated ACL transection injury before and after ACL reconstruction.
STUDY DESIGN
Controlled laboratory study.
METHODS
Nine paired knees were ACL injured or ACL transected. For ACL injury, knees were mounted in a rig that imposed tibial anterior translation at 1000 mm/min to rupture the ACL at 22.5° of flexion, 5° of internal rotation, and 710 N of joint compressive force, replicating data published on clinical bone bruise locations. In contralateral knees, the ACL was transected arthroscopically at midsubstance. Both groups had ACL reconstruction with bone-patellar tendon-bone graft. Native, ACL-deficient, and reconstructed knee laxities were measured in a kinematics rig from 0° to 100° of flexion with optical tracking: anterior tibial translation (ATT), internal rotation (IR), anterolateral (ATT + IR), and pivot shift (IR + valgus).
RESULTS
The ACL ruptured at 26 ± 5 mm of ATT and 1550 ± 620 N of force (mean ± SD) with an audible spring-back tibiofemoral impact with 5
CONCLUSION
This study developed an ACL injury model in vitro that replicated clinical ACL injury as evidenced by bone bruise patterns. ACL injury caused larger increases of laxity than ACL transection, likely because of damage to adjacent tissues; these differences often persisted after ACL reconstruction.
CLINICAL RELEVANCE
This in vitro model created more realistic ACL injuries than surgical transection, facilitating future evaluation of ACL reconstruction techniques.
Identifiants
pubmed: 34115540
doi: 10.1177/03635465211017145
pmc: PMC8283191
doi:
Types de publication
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
2387-2395Références
Am J Sports Med. 2015 Oct;43(10):2515-21
pubmed: 26264770
Am J Sports Med. 2018 Jun;46(7):1559-1565
pubmed: 29667852
Am J Sports Med. 2007 Mar;35(3):359-67
pubmed: 17092928
Arthroscopy. 2018 Aug;34(8):2398-2406
pubmed: 29730210
Am J Sports Med. 2015 Apr;43(4):905-11
pubmed: 25589386
Am J Sports Med. 2016 Feb;44(2):345-54
pubmed: 26657572
Am J Sports Med. 2010 Apr;38(4):721-7
pubmed: 20200323
Am J Sports Med. 2010 Aug;38(8):1591-7
pubmed: 20530720
J Biomech. 2008 Dec 5;41(16):3377-83
pubmed: 19007932
J Bone Joint Surg Am. 1980 Mar;62(2):259-70
pubmed: 7358757
Am J Sports Med. 2008 Sep;36(9):1675-87
pubmed: 18490472
J Bone Joint Surg Am. 2008 Dec;90(12):2724-34
pubmed: 19047719
Am J Sports Med. 2016 Jan;44(1):126-32
pubmed: 26574601
Am J Sports Med. 2016 Feb;44(2):400-8
pubmed: 26657852
Am J Sports Med. 2017 Feb;45(2):347-354
pubmed: 28027653
Comput Aided Surg. 2000;5(2):98-107
pubmed: 10862132
Am J Sports Med. 2013 Jul;41(7):1595-604
pubmed: 23696212
Am J Sports Med. 2011 Feb;39(2):279-88
pubmed: 21239692
Am J Sports Med. 2010 Nov;38(11):2218-25
pubmed: 20595545
Am J Sports Med. 1991 May-Jun;19(3):217-25
pubmed: 1867330
Am J Sports Med. 2004 Mar;32(2):477-83
pubmed: 14977677
Am J Sports Med. 2019 Nov;47(13):3203-3211
pubmed: 31613650
Orthop J Sports Med. 2020 Apr 15;8(4):2325967120911162
pubmed: 32313810
Knee Surg Sports Traumatol Arthrosc. 2019 May;27(5):1587-1594
pubmed: 30094498
Knee Surg Sports Traumatol Arthrosc. 2020 Apr;28(4):1159-1168
pubmed: 31980844
Arthroscopy. 2012 Oct;28(10):1481-9
pubmed: 22796141
Am J Sports Med. 2014 Jun;42(6):1401-7
pubmed: 24668872
Am J Sports Med. 2019 Jul;47(9):2067-2076
pubmed: 31307223
Am J Sports Med. 2018 Jul;46(9):2113-2121
pubmed: 29864374
Am J Sports Med. 2009 Feb;37(2):252-9
pubmed: 19182110
Am J Sports Med. 2001 Nov-Dec;29(6):771-6
pubmed: 11734491
J Bone Joint Surg Br. 1993 Sep;75(5):812-7
pubmed: 8376447
Am J Sports Med. 2019 May;47(6):1376-1384
pubmed: 30986093
Am J Sports Med. 2016 Dec;44(12):3126-3131
pubmed: 27507843
Knee Surg Sports Traumatol Arthrosc. 2019 Feb;27(2):646-651
pubmed: 30310925
Am J Sports Med. 2007 Feb;35(2):223-7
pubmed: 17158275
Knee Surg Sports Traumatol Arthrosc. 2015 Jan;23(1):112-8
pubmed: 25502611
Arthroscopy. 2016 Nov;32(11):2331-2341
pubmed: 27177438
J Orthop Res. 1993 Jan;11(1):58-67
pubmed: 8423521
J Orthop Res. 2019 Aug;37(8):1730-1742
pubmed: 30977558
Sports Med. 2019 Mar;49(3):453-462
pubmed: 30689129
Br J Sports Med. 2009 Jun;43(6):417-22
pubmed: 19372088
J Biomech. 2018 May 17;73:153-160
pubmed: 29622481
J Bone Joint Surg Am. 2011 Aug 17;93(16):1510-8
pubmed: 22204006
Clin Orthop Relat Res. 2007 Apr;457:203-9
pubmed: 17195812