Mancini SL, Dickin C, Hankemeier DA, Rolston L, Wang H. Risk of Anterior Cruciate
Ligament Injury in Female Soccer Athletes: A Review. J Orthopedics & Orthopedic
Surg. 2021;2(1):13-21
Journal of Orthopedics and Orthopedic Surgery
Page 20 of 21
49.
anterior cruciate ligament injury mechanisms: a systematic review.
Sports Medicine. 2010; 40(9): 729-46.
50.
ligament rupture causes concomitant loading and damage of the
anterior cruciate ligament. J Knee Surg. 2003; 16(3): 148-151.
51. Shin CS, Chaudhari AM, Andriacchi TP. The effect of isolated valgus
moments on ACL strain during single-leg landing: A simulation study.
Journal of Biomechanics. 2009; 42(3): 280-285.
52. . Mechanisms for noncontact
anterior cruciate ligament injuries: knee joint kinematics in 10 injury
situations from female team handball and basketball. Am J Sports
Med. 2010; 38(11): 2218-2225.
53. Shin CS, Chaudhari AM, Andriacchi TP. Valgus Plus Internal Rotation
Moments Increase Anterior Cruciate Ligament Strain More Than
54.
during landing is associated with increased frontal plane knee motion
and moments. Clin Biomech (Bristol, Avon). 2010; 25(2): 142-6.
55.
extremity kinematics, kinetics and energy absorption during landing.
Clin Biomech (Bristol, Avon). 2003; 18(7): 662-9.
56. Leppänen M, Pasanen K, Krosshaug T, et al. Sagittal Plane Hip, Knee,
and Ankle Biomechanics and the Risk of Anterior Cruciate Ligament
Injury: A Prospective Study. Orthop J Sports Med. 2017; 5(12):
2325967117745487.
57.
ACL injuries: A stochastic biomechanical modeling study. Journal of
Sport and Health Science. 2012; 1(1): 36-42.
58.
behavior and slackness of the anterior cruciate ligament at multiple
215.
59. Miyasaka T, Matsumoto H, Suda Y, et al. Coordination of the anterior
and posterior cruciate ligaments in constraining the varus-valgus
and internal-external rotatory instability of the knee. Journal of
Orthopaedic Science. 2002; 7(3): 348-53.
60. Fleming BC, Renstrom PA, Beynnon BD, et al. The effect of
weightbearing and external loading on anterior cruciate ligament
strain. J Biomech. 2001; 34(2): 163-170.
61.
forces during landing from a jump. J Sci Med Sport. 1999; 2(1): 86-88.
62. Sell TC, Ferris CM, Abt JP, et al. Predictors of proximal tibia anterior
shear force during a vertical stop-jump. Journal of Orthopaedic
Research. 2007; 25(12): 1589-1597.
63.
108-115.
64.
soccer: Loading mechanisms, risk factors, and prevention programs.
Journal of Sport and Health Science. 2014; 3: 299-306.
65.
forces, knee moments and muscle co-contraction during an impact-
like deceleration landing: Implications for the non-contact mechanism
of ACL injury. Knee. 2010; 17(4): 291-5.
66. .
Absorption and Biomechanics During Landing, Part I: Sagittal-Plane
67. .
Absorption and Biomechanics During Landing, Part II: Frontal-Plane
48(6): 757-763.
68.
on the biomechanics of the knee. Am J Sports Med. 2004; 32(2): 376-
382.
69. .
contact ACL Injury as Determined from Bone Bruise Location. Am J
Sports Med. 2015; 43(10): 2515-2521.
70.
loading can induce noncontact anterior cruciate ligament injury. Am J
Sports Med. 2004; 32(2): 477-483.
71. Chappell JD, Yu B, Kirkendall DT, et al. A comparison of knee kinetics
between male and female recreational athletes in stop-jump tasks.
Am J Sports Med. 2002; 30(2): 261-267.
72.
electromyography of landing preparation in vertical stop-jump: risks
for noncontact anterior cruciate ligament injury. Am J Sports Med.
2007; 35(2): 235-241.
73. . Measurement of in vivo
anterior cruciate ligament strain during dynamic jump landing. J
Biomech. 2011; 44(3): 365-371.
74.
Ligament Injury. Sports Med. 2006; 36(5): 411-428.
75. Bencke J, Aagaard P, Zebis MK. Muscle Activation During ACL Injury
Physiol. 2018; 9: 445.
76.
as Predictors of Knee Biomechanics During a Drop Jump Task. Med Sci
77.
Landing Biomechanics Linked to Anterior Cruciate Ligament Loading.
J Athl Train. 2013; 48(6): 764-772.
78. .
during a drop-jump task reduces tibiofemoral shear and compressive
forces: implications for ACL injury prevention training. J Sports Sci.
2017; 35(24): 2405-2411.
79.
Activation and Knee Flexion During a Jump-Landing Task. J Athl Train.
2012; 47(4): 406-413.
80. Stearns KM, Powers CM. Improvements in hip muscle performance
result in increased use of the hip extensors and abductors during a
landing task. Am J Sports Med. 2014; 42(3): 602-609.
81.
Quadriceps and Hamstrings Cocontraction Patterns With Knee Joint
Loading. Journal of Athletic Training. 2009; 44(3), 256-263.
82.
Program on the Kinetics and Kinematics of Jumping Tasks. Am J
Sports Med. 2008; 36(6): 1081-1086.
83. Lephart SM, Abt JP, Ferris CM, et al.
characteristic changes in high school athletes: a plyometric versus
basic resistance program. British Journal of Sports Medicine. 2005;
39(12): 932-938.
84.
single-limb stability in young female athletes. J Orthop Sports Phys
Ther. 2004; 34(6): 305-316.
85. . Making football safer for
women: a systematic review and meta-analysis of injury prevention
programmes in 11 773 female football (soccer) players. Br J Sports
Med. 2020; 54: 1089-1098.