Effect of Shoe Stiffness on Injury Produced Under External Rotation of the Foot in Human Cadavers

2013 ◽  
Author(s):  
Keith D. Button ◽  
Mark A. Davison ◽  
Jerrod E. Braman ◽  
Maureen C. Schaefer ◽  
Roger C. Haut
Keyword(s):  
Ankle Sprain ◽  
External Rotation ◽  
Ankle Injuries ◽  
Upper Body ◽  
Deltoid Ligament ◽  
Ankle Sprains ◽  
Interosseous Ligament ◽  
Lateral Ankle ◽  
Human Cadavers ◽  
Anterior Deltoid

Ankle sprain is a common occurrence in sports, accounting for 10–30% of injuries 9. Injury to the lateral ligamentous complex occurs under excessive foot inversion and is known as a “lateral ankle sprain” 1. Injury to the anterior deltoid ligament (ADL), which consists of the tibionavicular ligament (TiNL) and the anterior tibiotalar ligament (ATiTL), is known as a “medial ankle sprain” 13. High ankle sprains occur in the distal tibiofibular syndesmosis, which is comprised of the anterior and posterior tibiofibular ligaments (ATiFL and PTiFL) and the interosseous ligament (IOL) 2. While approximately 85% of ankle sprains are lateral ankle injuries, syndesmotic (high) and medial injuries typically result in more time off the field. The mechanism of both high and medial ankle sprain is commonly ascribed to excessive internal rotation of the upper body, while the foot is planted on the playing surface.

Determination of In Situ Ankle Ligament Strains in Cases of High and Medial Ankle Sprains

2012 ◽  
Author(s):  
Keith D. Button ◽  
Feng Wei ◽  
Eric G. Meyer ◽  
Kathleen Fitzsimons ◽  
Roger C. Haut
Keyword(s):  
Ankle Sprain ◽  
Ankle Injury ◽  
Ankle Injuries ◽  
Deltoid Ligament ◽  
Generic Model ◽  
Ankle Sprains ◽  
Ligament Injuries ◽  
Lateral Ankle Sprain ◽  
Lateral Ankle ◽  
Tibiofibular Ligament

Ankle sprain is a common occurrence in sports, accounting for 10–30% of injuries [1]. While approximately 85% of ankle sprains are lateral ankle injuries, syndesmotic (high) and medial injuries typically result in more time off the field. In order to help limit or mitigate ankle injuries, it is important to understand the mechanisms of injury. While numerous biomechanical studies have been conducted to investigate ankle injuries, most of them are designed to study ankle fractures rather than sprains. Ankle sprains have been graded in the clinical literature and associated with the degree of damage to a ligament resulting from excessive strains [2]. Recently, there have been studies of lateral ankle sprain in laboratory settings [3,4] and based on investigation of game films [5], providing considerable insight into the mechanism of lateral ankle sprain. On the other hand, few biomechanical studies have been conducted on high and medial ankle sprains. A more recent study from our laboratory used human cadaver limbs to investigate such injuries [6]. The study showed that the type of ankle injury, whether medial or high, under excessive levels of external foot rotation depends on the extent of foot eversion [6]. Everted limbs showed isolated anterior tibiofibular ligament injuries (high ankle sprain) only, while neutral limbs mostly demonstrated deltoid ligament failures (medial ankle sprain). Additionally, the study documented grade II (partial tears) and grade III (ruptures) ligament injuries. While a computational ankle model has also been developed and validated to help understand the mechanisms of injury [7], it is a generic model. The objective of the current study was to develop computational, subject-specific models from those cadaver limbs and determine the levels of ligament strain generated in the medial and high ankle injury cases, as well as correlate the grades of injury with ligament strains from the computational model.

Mechanism of Injury in a High Ankle Sprain: A Simulation Study

2011 ◽  
Author(s):  
Feng Wei ◽  
Jerrod E. Braman ◽  
Eric G. Meyer ◽  
John W. Powell ◽  
Roger C. Haut
Keyword(s):  
Ankle Sprain ◽  
Simulation Study ◽  
External Rotation ◽  
Recovery Period ◽  
Cadaver Study ◽  
Ankle Sprains ◽  
Mechanism Of Injury ◽  
Tibiofibular Syndesmosis ◽  
Lateral Ankle ◽  
High Ankle Sprain

Injury to the tibiofibular syndesmosis ligaments, which bind together the distal ends of the tibia and fibula, is commonly referred to as a high ankle sprain [8]. While lateral ankle sprains are the most common injury, high ankle sprains represent a more disabling problem and require a longer recovery period [1] and different treatment [4]. The mechanism associated with a high ankle sprain is primarily thought to involve external rotation of the foot [1,7]. However, both a cadaver study [6] and a simulation study [5] show that tibiofibular syndesmosis ligaments are not stretched the most during an excessive, pure external foot rotation.

LATERAL ANKLE SPRAIN — AN UPDATE

2013 ◽  
Vol 16 (04) ◽  
pp. 1330003
Author(s):  
Shibli Nuhmani ◽  
Moazzam Hussain Khan
Keyword(s):  
Ankle Sprain ◽  
Bone Fractures ◽  
Sports Injury ◽  
Ankle Injuries ◽  
Anterior Talofibular Ligament ◽  
Ankle Sprains ◽  
Calcaneofibular Ligament ◽  
Lateral Ankle ◽  
Major Loss ◽  
Sporting Activities

Ankle sprain injuries are the most common injury sustained during sporting activities. One-sixth of all sports injury loss time is from ankle sprains. Each year, an estimated 1 million people present to physicians with acute ankle injuries. Three-quarters of ankle injuries involve the lateral ligamentous complex, comprised of the anterior talofibular ligament (ATFL), the calcaneofibular ligament (CFL) and the posterior talofibular ligament (PTFL). Lateral ankle sprains typically occur when the rearfoot undergoes excessive supination on an externally rotated lower leg. The diagnosis of a sprain relies on the medical history including symptoms, as well as making a differential diagnosis mainly in distinguishing it from strains or bone fractures. Despite their prevalence in society, ankle sprains still remain a difficult diagnostic and therapeutic challenge in the athlete, as well as in society in general. The high incidence of ligamentous ankle injuries requires clearly defined acute care and a broad knowledge of new methods in rehabilitation. In addition to rapid pain relief, the main objective of treatment is to quickly restore the range of motion of the ankle without any major loss of proprioception, thereby restoring full activity as soon as possible. The purpose of this article is to review the anatomy, pathomechanics, investigation, diagnosis and management of lateral ankle sprains.

scholarly journals Predictive Factors of Recovery after an Acute Lateral Ankle Sprain: A Longitudinal Study

Sports ◽  
2021 ◽  
Vol 9 (3) ◽  
pp. 41
Author(s):  
Philippe Terrier ◽  
Sébastien Piotton ◽  
Ilona M. Punt ◽  
Jean-Luc Ziltener ◽  
Lara Allet
Keyword(s):  
Ankle Sprain ◽  
Strength Function ◽  
Selection Procedure ◽  
Ankle Sprains ◽  
Lateral Ankle Sprain ◽  
Lateral Ankle ◽  
Functional Scores ◽  
Logistic Regressions ◽  
Poor Outcomes ◽  
Clinical Measures

A prominent feature of ankle sprains is their variable clinical course. The difficulty of providing a reliable early prognosis may be responsible for the substantial rate of poor outcomes after an ankle sprain. The aim of the present study was to evaluate the prognostic value of objective clinical measures, pain, and functional scores for ankle sprain recovery. Fifty-two participants suffering from lateral ankle sprain were included. Sprain status was assessed four weeks following injury and included evaluations of ankle range of motion, strength, function, and pain. Seven months following injury, a second assessment classified the patients into recovered and non-recovered groups using ankle ability measures. Following a predictor pre-selection procedure, logistic regressions evaluated the association between the four-week predictors and the seven-month recovery status. Twenty-seven participants (52%) fully recovered and 25 did not (48%). The results of the logistic regressions showed that walking pain was negatively associated with the probability of recovering at seven months (odds ratio: 0.71, 95% CI: 0.53–0.95). Pain four weeks after ankle sprain had relevant predictive value for long-term recovery. Special attention should be paid to patients reporting persistent pain while walking four weeks following sprain to reduce the risk of chronicity.

scholarly journals Role of magnetic resonance imaging in ankle sprains

2021 ◽  
Vol 25 (1) ◽  
pp. 438-445
Author(s):  
Nawroz Othman ◽  
Salwa AL-Najjar
Keyword(s):  
Magnetic Resonance Imaging ◽  
Magnetic Resonance ◽  
Clinical Evaluation ◽  
Ankle Sprain ◽  
Soft Tissues ◽  
Ankle Injuries ◽  
Bone Lesions ◽  
Ankle Sprains ◽  
Resonance Imaging ◽  
Imaging Results

Background and objective: Musculoskeletal injuries frequently occur in the ankle in both the athletic and general population. Ankle sprains are among the most frequent types of ankle injuries, which are conventionally diagnosed through clinical examinations. However, magnetic resonance imaging can provide a more precise diagnosis, leading to better injury management and prevention of consequent chronic complications. The present study aimed to examine the significance of magnetic resonance imaging in detecting and assessing changes that occur in ligaments and soft tissues in patients with ankle sprains. Methods: In a prospective study, 50 patients with ankle sprain referred to Rizgary and Erbil Teaching hospitals in Erbil city, Iraqi Kurdistan Region, from March 2018 to April 2019, were included in the study. They underwent clinical evaluation and MRI (GE general electric 1.5 Tesla). Two expert radiologists analyzed the magnetic resonance imaging images, and the results were compared. The collected data were analyzed using SPSS version 23 through descriptive statistics. Results: Most patients (64%) belonged to the age groups of 30-49 years old. Most of them (64%) were males. Most events of ankle sprain (66%) were because of sports and accidents. The clinical evaluation proved 82% of the ankle sprains. Regarding the laterality of the lesions, 60% were spotted in the right ankles and 40% in the left. According to magnetic resonance imaging results, both radiologists diagnosed that the ankle sprains included bone lesions, ligament injury, tendon injury, and effusion. There was an agreement of ≥ 96% between the two radiologists in this regard. The two radiologists were not significantly different in terms of diagnosing the ligament side. As reported by the radiologists based on the magnetic resonance imaging images, the anterior, lateral, and medial tendons were normal in most cases. Conclusion: Magnetic resonance imaging is a vitally important tool that can be utilized reliably and accurately to diagnose and evaluate changes in ligaments and soft tissues in patients with ankle sprains. Keywords: Magnetic resonance imaging (MRI); Ankle sprain; Ligaments; Injuries.

Evaluation of the Sports Ankle Rating System in Young, Athletic Individuals with Acute Lateral Ankle Sprains

2003 ◽  
Vol 24 (3) ◽  
pp. 274-282 ◽  
Author(s):  
Glenn N. Williams ◽  
Joseph M. Molloy ◽  
Thomas M. DeBerardino ◽  
Robert A. Arciero ◽  
Dean C. Taylor
Keyword(s):  
Ankle Injuries ◽  
Rating System ◽  
Ankle Sprains ◽  
Rating Score ◽  
Lateral Ankle ◽  
Life Measure ◽  
Initial Validation ◽  
Unique System ◽  
The Impact

The purpose of this paper is to introduce the Sports Ankle Rating System and provide the initial validation for its use. As its name implies, this outcomes measurement system is intended for use in assessing the functional outcomes of athletes with ankle injuries. This unique system consists of three distinct instruments: the Quality of Life Measure, the Clinical Rating Score, and the Single Assessment Numeric Evaluation. We began the validation process of the Sports Ankle Rating System with subjects who had sustained lateral ankle sprains because this is the most common injury in sports. The results of this study indicate that the Sports Ankle Rating System is: effective at assessing the impact that an ankle sprain has on an athlete's functional and psychosocial status responsive to changes in an athlete's ankle-related health status, and valid and reliable as tested.

scholarly journals Stress vs. Non-Stress Radiographs in Subtle Syndesmotic Injuries

2018 ◽  
Vol 3 (3) ◽  
pp. 2473011418S0029
Author(s):  
Nicola Krähenbühl ◽  
Travis Bailey ◽  
Nathan Davidson ◽  
Heath Henninger ◽  
Charles Saltzman ◽  
...  
Keyword(s):  
Ankle Instability ◽  
External Rotation ◽  
Paired Comparison ◽  
Weight Bearing ◽  
Deltoid Ligament ◽  
Ankle Sprains ◽  
X Rays ◽  
Syndesmotic Injury ◽  
Stress Radiographs ◽  
Clear Space

Category: Sports Introduction/Purpose: Between 1-18% of all ankle sprains and 23% of all ankle fractures involve injury to the distal tibio-fibular syndesmosis. Syndesmotic injuries can create a substantial diagnostic and therapeutic challenge for orthopaedic surgeons. While acute injuries can be assessed using conventional radiographs, subtle syndesmotic injuries may be misdiagnosed using X-rays. Misdiagnoses may result in chronic ankle instability, pain and post-traumatic osteoarthritis of the tibio-talar joint. The purpose of this study was to investigate whether syndesmotic injury was more easily diagnosed with stress vs. non-stress radiographs.radiographs.sed with stress vs. non-stress radiographs. Methods: Five pairs of cadavers (tibia plateau to toe-tip, mean 61 years, range 52-70 years) were scanned with weight-bearing CT (170 lb, w/ and w/o 10 Nm static external rotation torque). Digitally reconstructed radiographs (DRRs), which are comparable to conventional radiographs, were reconstructed from the 3D CT data. The following conditions were tested: First, intact ankles (Native) were tested. Second, one specimen from each pair underwent AITFL resection, while the contralateral underwent deltoid resection (Condition 1). Third, the remaining intact deltoid ligament or AITFL was resected in each ankle (Condition 2). Finally, the interosseous membrane (IOM) was resected in all ankles (Condition 3). Condition 3 was defined as acute syndesmotic injury. Using antero-posterior (AP) views, the tibio-fibular clear space (TFCS), tibiofibular overlap (TFO) and medial clear space (MCS) were assessed. Statistical analysis was performed using paired (comparison within groups) and unpaired (comparison between groups) t-test where p=0.05 was considered significant. Results: Regarding the TFCS, Native vs. Condition 3 in 10 Nm stress radiographs was significantly different in the deltoid group (p=0.021). Using TFO in stress and non-stressed radiographs, Native vs. Condition 2 and 3 was significantly different for the deltoid group (p=0.043), and Native vs. Condition 3 in the syndesmotic group (p=0.027). Regarding the MCS in non-stress radiographs, Native vs. Condition 3 was significantly different in the deltoid group (p=0.007), while in stress views, Native vs. Condition 2 was significant different in the syndesmotic (p=0.026) and Native vs. Condition 3 in the deltoid group (p=0.030). No differences were found comparing the conditions of the AITFL with the same conditions of the deltoid group. Conclusion: The TFCS cannot be used to assess subtle or acute syndesmotic injuries in stress and non-stress radiographs. The TFO can be used to assess a combined injury to the AITFL and deltoid ligament in stress and non-stress radiographs. The MCS can be used to assess acute syndesmotic injuries in stress and non-stress radiographs. Radiographs (stress or non-stress) cannot be used to distinguish between injuries to the AITFL or deltoid ligament. Therefore, stress and non-stress radiographs are not useful in assessment of subtle syndesmotic injuries. Stress-radiographs are not superior compared to non-stress radiographs in assessment of acute syndesmotic injuries.

scholarly journals Displacement of Sequential Syndesmotic Ankle Injuries Assessed by a 3D Weightbearing CT

2019 ◽  
Vol 4 (4) ◽  
pp. 2473011419S0012
Author(s):  
Arne Burssens ◽  
Nicola Krähenbühl ◽  
Hannes Vermue ◽  
Nathan Davidson ◽  
Maxwell Weinberg ◽  
...  
Keyword(s):  
External Rotation ◽  
Imaging Techniques ◽  
Pearson Correlation ◽  
Ankle Injuries ◽  
Deltoid Ligament ◽  
3D Analysis ◽  
Anatomical Landmarks ◽  
Posterior Translation ◽  
2D Imaging ◽  
Weightbearing Ct

Category: Ankle Introduction/Purpose: Syndesmotic ankle injuries are challenging to diagnose, since current 2D imaging techniques try to quantify a 3D displacement. Therefore, our aim was two-fold: to determine displacement of sequential syndesmotic ankle injuries under various amounts of load using a 3D weightbearing CT (WBCT) and to assess the relation with current 2D imaging. Methods: Seven paired male cadaver specimens were included (tibia plateau to toe-tip) and mounted into a custom-built frame. WBCT scans were obtained after different patterns of load (0 kg or 85 kg) were combined with torque (0 Nm or 10 Nm external rotation). These conditions were repeated after each ligament condition: intact ligaments, sequential sectioning of the anterior inferior tibiofibular ligament (AITFL), deltoid ligament (DL), and interosseous membrane (IOM). CT images were segmented to obtain 3D models. These allowed quantification of displacement based on the position of computed anatomical landmarks in reference to the intact position of the fibula. A correlation analysis was performed between the 2D and 3D measurements. Results: The effect of torque caused significant displacements in all directions (P<0.05), except for shortening of the fibula (P>0.05). Weight caused a significant lateral (mean=-1.4 mm, SD=1.5) and posterior translation (mean=-0.6 mm, SD=1.8). The highest displacement consisted of external rotation (mean=-9.4°, SD=6.5) and posterior translation (mean=6.1 mm, SD=2.3) after IOL sectioning combined with torque (Fig. 1). Pearson correlation coefficients were moderate (range 0.31-0.51, P<0.05). Conclusion: Torque demonstrated superiority over weight in detecting syndesmotic ankle instability after 3D analysis. The clinical relevance of these findings can improve diagnosis by incorporating rotatory platforms during imaging and treatment strategies by providing appropriate stabilization against rotation.

Finite Element Analysis of Fixed Medial Malleolar Fractures

2013 ◽  
Author(s):  
Ruchi D. Chande ◽  
John R. Owen ◽  
Robert S. Adelaar ◽  
Jennifer S. Wayne
Keyword(s):  
Finite Element Analysis ◽  
Finite Element ◽  
Mechanical Performance ◽  
External Rotation ◽  
Weight Bearing ◽  
High Stress ◽  
Ankle Injuries ◽  
Deltoid Ligament ◽  
Medial Malleolus ◽  
Element Analysis

The ankle joint, comprised of the distal ends of the tibia and fibula as well as talus, is key in permitting movement of the foot and restricting excessive motion during weight-bearing activities. Medial ankle injury occurs as a result of pronation-abduction or pronation-external rotation loading scenarios in which avulsion of the medial malleolus or rupture of the deltoid ligament can result if the force is sufficient [1]. If left untreated, the joint may experience more severe conditions like osteoarthritis [2]. To avoid such consequences, medial ankle injuries — specifically bony injuries — are treated with open reduction and internal fixation via the use of plates, screws, wires, or some combination thereof [1, 3–4]. In this investigation, the mechanical performance of two such devices was compared by creating a 3-dimensional model of an earlier cadaveric study [5], validating the model against the cadaveric data via finite element analysis (FEA), and comparing regions of high stress to regions of experimental failure.

scholarly journals Characterization of Ankle Kinematics and Constraint Following Ligament Rupture in a Cadaveric Model

2019 ◽  
Vol 141 (11) ◽  
Author(s):  
Bardiya Akhbari ◽  
Matthew H. Dickinson ◽  
Ednah G. Louie ◽  
Sami Shalhoub ◽  
Lorin P. Maletsky
Keyword(s):  
Internal Rotation ◽  
External Rotation ◽  
Training Data ◽  
Ankle Injuries ◽  
Ankle Sprains ◽  
Ligament Rupture ◽  
Ankle Kinematics ◽  
Posterior Translation ◽  
Ankle Mobility ◽  
And Inversion

Ankle sprains are a common injury that may need reconstruction and extensive physical therapy. The purpose of this study was to provide a description of the biomechanics of the ankle joint complex (AJC) after anterior talofibular (ATFL) and calcaneofibular (CFL) ligament rupture to better understand severe ankle injuries. The envelope of motion of ten cadaveric ankles was examined by manual manipulations that served as training data for a radial basis function used to interpolate ankle mobility at flexion angles under load and torque combinations. Moreover, ankle kinematics were examined, while tendons were loaded to identify how their performance is altered by ligament rupture. The increased force required to plantarflex the ankle following ligament rupture was measured by calculating the load through the Achilles. Following ATFL injury, the largest changes were internal rotation (5 deg) in deep plantarflexion and anterior translation (1.5 mm) in early plantarflexion. The combined ATFL and CFL rupture changed the internal/external rotation (3 deg), anterior/posterior translation (1 mm), and inversion (5 deg) throughout flexion relative to the isolated ATFL rupture. Moreover, the Achilles' load increased by 24% after the rupture of ligaments indicating a reduction in its efficiency. This study suggests that if patients demonstrate primarily an increased laxity in internal rotation, the damage has solely occurred to the ATFL; however, if the constraint is reduced across multiple motions, there is likely damage to both ligaments. Higher loads in the Achilles suggest that it is overloaded after the injury; hence, targeting the calf muscles in rehabilitation exercises may reduce patients' pain.

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