Correlation of Kinematics and Kinetics of Changing Sagittal Plane Body Position during Landing and the Risk of Non-Contact Anterior Cruciate Ligament Injury

Mahgolzahra Kamari; Randeep Rakwal; Takuya Yoshida; Satoru Tanigawa; Seita Kuki

doi:10.3390/app11177773

Kamari, Mahgolzahra;Rakwal, Randeep;Yoshida, Takuya;Tanigawa, Satoru;Kuki, Seita

2021-08-24 00:00:00

applied sciences Article Correlation of Kinematics and Kinetics of Changing Sagittal Plane Body Position during Landing and the Risk of Non-Contact Anterior Cruciate Ligament Injury 1 , , † 2 , † 2 2 3 Mahgolzahra Kamari * , Randeep Rakwal , Takuya Yoshida , Satoru Tanigawa and Seita Kuki Graduate School of Comprehensive Human Sciences, Tsukuba International Academy for Sport Studies (TIAS), Tsukuba 305-8574, Japan Faculty of Health and Sport Sciences, University of Tsukuba, Tsukuba 305-8574, Japan; plantproteomics@gmail.com (R.R.); yoshida.takuya.gm@u.tsukuba.ac.jp (T.Y.); tanigawa.satoru.gb@u.tsukuba.ac.jp (S.T.) Faculty of Human Sciences, University of Economics, Higashiyodogawa-ku, Osaka 533-8533, Japan; kukiseita0607@gmail.com * Correspondence: zahra.kamari67@gmail.com † Joint ﬁrst authors. Abstract: Anterior cruciate ligament (ACL) injury is one of the most common knee injuries that negatively affect athletes’ future performance and return to play. The purpose of this study was to examine the correlation of kinematics and kinetics of changing sagittal plane body position during landing and the risk of non-contact ACL injury. Seven university female (age 19.57 0.79 y, height 164.21 8.11 m, weight 60.43 5.99 kg) athletes playing soccer and handball, and with two years Citation: Kamari, M.; Rakwal, R.; of training volunteered for this research. Three trunk positions: Lean Forward Landing (LFL), Self- Yoshida, T.; Tanigawa, S.; Kuki, S. selected Landing (SSL), and Upright Landing (URL)—via double/single-leg landing—were captured Correlation of Kinematics and by a high-speed VICON motion capture system. A 3 2 two-way within-subjects ANOVA and Kinetics of Changing Sagittal Plane Multiple Bonferroni corrected pairwise were used to test for condition (LFL, SSL, URL) and task Body Position during Landing and (single/double-leg) effects (p 0.05). The ﬁndings indicated that landing with a deeper knee ﬂexion the Risk of Non-Contact Anterior Cruciate Ligament Injury. Appl. Sci. angle (LFL) would lead to smaller impact forces when compared to upright landing. 2021, 11, 7773. https://doi.org/ 10.3390/app11177773 Keywords: ACL injuries; landing trunk positions; non-contact; sagittal plane; women athlete Academic Editors: Hanatsu Nagano and Cheng-Kung Cheng 1. Introduction Received: 17 June 2021 Surveying the research literature, sports-related websites and the news conﬁrm that Accepted: 20 August 2021 knee injuries are common among athletes and the active population. It can be considered Published: 24 August 2021 to be one of the biggest contributors among all sport injuries, accounting for around 15–50 percent [1]. Further, women have a more pronounced risk of sustaining a knee injury Publisher’s Note: MDPI stays neutral compared to males [1,2]. Research efforts over the years have found that a majority of with regard to jurisdictional claims in the injuries among female athletes were found particularly in lower extremities such as published maps and institutional afﬁl- the ankle and the knee [3,4]. The Anterior Cruciate Ligament (ACL) is the site of the iations. most serious and common knee injuries, and has been studied in many different ways, especially over the past few years, due to the increased number of participating athletes in research studies [5]. The knee joint is the common site of injury only second to the ankle [6], and in terms of severity, the rupture of the ACL can often cause critical loss of maximum Copyright: © 2021 by the authors. performance for athletes [6–8]. Licensee MDPI, Basel, Switzerland. Previous studies [9–11] have investigated a range of biomechanical motions that are This article is an open access article concerned with the risks of ACL injuries. In addition to the lower limb adaptations at distributed under the terms and the ankle and knee, the upper body trunk motion has been considered to contribute to conditions of the Creative Commons impact dissipation of the ACL. Studies have shown that the upright trunk position [4,8] Attribution (CC BY) license (https:// while landing [12] and inability to control the frontal plane trunk position [8,12] are often creativecommons.org/licenses/by/ associated with ACL injuries. Therefore, it is important to assess how trunk control affects 4.0/). Appl. Sci. 2021, 11, 7773. https://doi.org/10.3390/app11177773 https://www.mdpi.com/journal/applsci Appl. Sci. 2021, 11, 7773 2 of 8 lower extremity biomechanical parameters that may be associated with reducing the ACL injuries. Trunk stability is related to the ability of the hip to control the trunk in response to forces generated from distal body segments and unexpected perturbations. Greater trunk ﬂexion during landing may contribute to lower ACL loading and associated injury risk if this joint motion was effective in reducing ground reaction forces (GRF) [13,14]. Therefore, the purpose of this study was to determine the effect of trunk posture on key biomechanical variables that indicate ACL injury risk such as drop landing forces. It was hypothesized that the most ACL-protective biomechanical parameters would be associated with leaning forward landings (LFL) and the most harmful with upright landings (URL). Single- and double-leg stop-jump techniques are frequently executed in the compet- itive sports such as basketball, handball and soccer. Yu et al. (2006) [15] indicated that the landing phase of stop-jump tasks presents a signiﬁcant risk of injury to the lower extremities in general, particularly to the ACL. A number of reports have shown that most sports-related ACL injuries occur during non-contact situations that are characterized by landing, rapid deceleration, and sudden changes of direction [16,17]. In a single-leg drop landing task, larger GRF, an increased knee valgus, and decreased knee ﬂexion were identiﬁed at initial contact compared to double-leg drop landing [18,19]. This incidence rate for non-contact ACL injuries is two to eight times higher for female athletes compared to males in the same sport [20,21]. It is, therefore, interesting to investigate types of trunk motion that can improve landing mechanics in both single-leg and double-leg landing. This current research is focused on: (1) evaluating the effect of trunk body position on leaning forward landing (LFL), self-selected landing (SSL) and upright landing (URL) during a single/double-leg drop landing for ACL injuries risk reduction in university female players, and (2) investigating the risk of non-contact ACL injury in maximum strength jump-landing during landing position. An in-depth study on trunk body position during drop landing can possibly have implications to reduce the ACL injury risk among elite female players. 2. Materials and Methods A quantitative laboratory study with sagittal plane knee, hip, and trunk kinematics and kinetics in female athletes was performed. 2.1. Participants Seven female university-level athletes (age 19.57 0.79 y, height 164.21 8.11 m, weight 60.43 5.99 kg) playing soccer and handball, with 2 years of training volunteered in this investigation. Every subject was provided with an explanation about the experi- mental protocol. Each participant signed the informed consent prior to participation in the research, which was granted and mandated by the University of Tsukuba Research Ethics Committee. Inclusion criteria for participation were as follows: female, aged 18–25 and an active player on a university sports team involved in regular physical activity at least three days per week with each session longer than 45 min. Prospective participants were excluded if any of the following exclusion criteria were identiﬁed: known history of ACL injury or reconstruction; known history of a surgical procedure involving the lower extremity; previous lower extremity musculoskeletal injury in the last six weeks that required medical attention. 2.2. Protocols Drop-jumps were conducted to characterize landing mechanics in biomechanical testing environments including the two force plates (Kistler 9287C, 60 cm 40 cm) to collect the GRFs at 1000 Hz and 10 high-speed motion capture cameras (Vicon motion analyzer MX, type of T20 and T20S) were used to sample whole body kinematics at 250 Hz. For drop-jumps, a box with a height of 30 cm was placed 10 cm away from the force plate, and prior to their jump participants would stand 1 cm from the edge of the box. This box Appl. Sci. 2021, 11, x FOR PEER REVIEW 3 of 9 lect the GRFs at 1000 Hz and 10 high-speed motion capture cameras (Vicon motion ana- lyzer MX, type of T20 and T20S) were used to sample whole body kinematics at 250 Hz. For drop-jumps, a box with a height of 30 cm was placed 10 cm away from the force plate, and prior to their jump participants would stand 1 cm from the edge of the box. This box was placed directly between two adjacent force platforms, where the box was positioned 15 cm away from the edge of the platforms (Figure 1). Appl. Sci. 2021, 11, x FOR PEER REVIEW 3 of 9 lect the GRFs at 1000 Hz and 10 high-speed motion capture cameras (Vicon motion ana- Appl. Sci. 2021, 11, 7773 3 of 8 lyzer MX, type of T20 and T20S) were used to sample whole body kinematics at 250 Hz. For drop-jumps, a box with a height of 30 cm was placed 10 cm away from the force plate, and prior to their jump participants would stand 1 cm from the edge of the box. This box was placed directly between two adjacent force platforms, where the box was positioned was placed directly between two adjacent force platforms, where the box was positioned 15 cm away from the edge of the platforms (Figure 1). 15 cm away from the edge of the platforms (Figure 1). Figure 1. Global coordinate system and force plate orientation (Kistler 9287C). One hour before the experiment was initiated examiners set the VICON cameras, force plate, retroreflectors, computers, and recorders setting and prepared the clothes for the subjects. Every subject was provided general information about the experimental pro- tocol. Appropriate clothing consisted of own running shoes, tight-fitting top and high-cut Figure 1. Global coordinate system and force plate orientation (Kistler 9287C). Figure 1. Global coordinate system and force plate orientation (Kistler 9287C). running shorts. The warm-up consisted of a 10 min jog followed by light stretching. Par- ticipant One hour be s comp fore the leted exper a 5 mi iment w n warm as init-up iated exa and 5 miners min set the self-dir VICON ca ected st mera re s, tching, prior to data One hour before the experiment was initiated examiners set the VICON cameras, force plate, force plate, re retroreﬂectors, troreflector computers, s, computers, and recor and ders recorder setting s setting and p and preparr ed epared the c the clothes lothes for for the collection. General anthropometric measures (height, and weight) were taken for each subjects. the subjects. Every subject was Every subject was provided provide general d gener information al information about the about the experimental experime pr ntal otocol. pro- participant by the same researcher. As a specific warm-up, all the participants practiced tocol Appr . opriate clothing consisted of own running shoes, tight-ﬁtting top and high-cut five landing tasks to become accustomed to the movements before data collection. running Appropriate shorts. The clothing consisted of own warm-up consisted ofrunni a 10 ng min shoes, ti jog followed ght-fitting top a by light n str d hi etching. gh-cut Participants running short completed s. The waa rm-up consisted 5 min warm-upof a 10 and 5 m min in jo self-dir g followed ected str by etching, light stret prior ching. P to data ar- Forty-seven retro-reflective markers were applied bilaterally on specific body land- collection. General anthropometric measures (height, and weight) were taken for each ticipants completed a 5 min warm-up and 5 min self-directed stretching, prior to data marks over the right hand, right wrist lateral side, right wrist medial side, right elbow participant by the same researcher. As a speciﬁc warm-up, all the participants practiced collection. General anthropometric measures (height, and weight) were taken for each lateral side, right elbow medial side, right shoulder front side, right shoulder back side, ﬁve landing tasks to become accustomed to the movements before data collection. participant by the same researcher. As a specific warm-up, all the participants practiced Forty-seven retro-reﬂective markers were applied bilaterally on speciﬁc body land- five landing tasks to become accustomed to the movements before data collection. right acromial, left hand, left wrist lateral side, left wrist medial side, left elbow lateral marks over the right hand, right wrist lateral side, right wrist medial side, right elbow Forty-seven retro-reflective markers were applied bilaterally on specific body land- side, left elbow medial side, left shoulder front side, left shoulder back side, left acromial, lateral side, right elbow medial side, right shoulder front side, right shoulder back side, marks over the right hand, right wrist lateral side, right wrist medial side, right elbow right toe, right ball lateral side, right ball medial side, right heel, right ankle lateral side, right acromial, left hand, left wrist lateral side, left wrist medial side, left elbow lateral lateral side, right elbow medial side, right shoulder front side, right shoulder back side, side, left elbow medial side, left shoulder front side, left shoulder back side, left acromial, right right acromi ankle m al, leedial ft handsid , left e wr , rig ist h lat t knee later eral side, left a l side, wrist med right k ial side n, ee medial side, r left elbow lateral ight trochanterion, right toe, right ball lateral side, right ball medial side, right heel, right ankle lateral side, side, left elbow medial side, left shoulder front side, left shoulder back side, left acromial, left toe, left ball lateral side, left ball medial side, left heel, left ankle lateral side, left ankle right ankle medial side, right knee lateral side, right knee medial side, right trochanterion, right toe, right ball lateral side, right ball medial side, right heel, right ankle lateral side, medial side, left knee lateral side, left knee medial side, left trochanterion, top of head, left toe, left ball lateral side, left ball medial side, left heel, left ankle lateral side, left ankle right ankle medial side, right knee lateral side, right knee medial side, right trochanterion, medial side, left knee lateral side, left knee medial side, left trochanterion, top of head, right right ear, left ear, suprasternal front, suprasternal back, right rib, left rib, xiphoid, xiphoid left toe, left ball lateral side, left ball medial side, left heel, left ankle lateral side, left ankle ear, left ear, suprasternal front, suprasternal back, right rib, left rib, xiphoid, xiphoid back, medial side, left knee lateral side, left knee medial side, left trochanterion, top of head, back, right anterior-superior iliac spine, left anterior-superior iliac spine, right posterior- right anterior-superior iliac spine, left anterior-superior iliac spine, right posterior-superior right ear, left ear, suprasternal front, suprasternal back, right rib, left rib, xiphoid, xiphoid superior iliac spine, and left posterior-superior iliac spine (Figure 2). iliac spine, and left posterior-superior iliac spine (Figure 2). back, right anterior-superior iliac spine, left anterior-superior iliac spine, right posterior- superior iliac spine, and left posterior-superior iliac spine (Figure 2). Figure 2. A total of 47 reflective markers were placed on each subject. Figure Figure 2. 2. A total A to ofta 47l o reﬂective f 47 remarkers flective wer ma e placed rkers on we each re place subject. d on each subject. Appl. Sci. 2021, 11, x FOR PEER REVIEW 4 of 9 Appl. Sci. 2021, 11, 7773 4 of 8 Seven participants were required to partake in two different landing techniques and Seven participants were required to partake in two different landing techniques and were permitted three practice trials for each technique. Five successful trials, verified by were permitted three practice trials for each technique. Five successful trials, veriﬁed by video, were collected for each trunk posture. If participants did not place the dominant video, were collected for each trunk posture. If participants did not place the dominant foot (which was determined at the beginning of experiment by asking each participant; foot (which was determined at the beginning of experiment by asking each participant; all of them were aware of their dominant foot) on the force plate, or lost balance and did all of them were aware of their dominant foot) on the force plate, or lost balance and not execute the task with the appropriate landing technique or did not perform the appro- did not execute the task with the appropriate landing technique or did not perform the priate task based on the cue generated by the software, the trial was not successful and appropriate task based on the cue generated by the software, the trial was not successful discarded from analysis. Participants were initially instructed to stand on the edge of the and discarded from analysis. Participants were initially instructed to stand on the edge of box with feet 35 cm apart. They stood on the step on their dominant leg with the knee of the box with feet 35 cm apart. They stood on the step on their dominant leg with the knee the other leg bent at approximately 90°, with neutral hip rotation, arms crossed/with their of the other leg bent at approximately 90 , with neutral hip rotation, arms crossed/with hands on their hips. Subjects for single-leg landing stood on the opposite foot with their their hands on their hips. Subjects for single-leg landing stood on the opposite foot with hands on their hips and landed with the foot in the center of the force plate. Then, drop- their hands on their hips and landed with the foot in the center of the force plate. Then, landings were performed in three trunk positions (LFL, URL, and SSL) randomly. For drop-landings were performed in three trunk positions (LFL, URL, and SSL) randomly. For double doubleleg leglandings, landings, p participants articipants wer were e instr inst ucted ructed to to dr drop off the b op off the box,owith x, wiboth th both feet feet landing land- simultaneously ing simultaneousl and y entir and ent elyion rely the on t for hce e fo platforms rce platforms (one (one pl platform atform per leg) per l to eg) complete to complet ﬁvee trials five tr as ialanded. ls as landed After . A landing fter landin (single-leg/double-leg) g (single-leg/double-on leg) the on t for hce e for plate ce plat with e wit theh dominant the dom- leg, inant participants leg, participant weresr wer equir e req ed to uir hold ed to this hold t position his pos for ition for three seconds. three seconds. Upon the completion of the test, the reﬂective markers were removed. This research Upon the completion of the test, the reflective markers were removed. This research deﬁned an action cycle as landing and keeping balance on the ground. The moment of foot defined an action cycle as landing and keeping balance on the ground. The moment of initial contact to the ground is the time when force value is greater than zero in the ﬁrst foot initial contact to the ground is the time when force value is greater than zero in the frame data that appears from the force platform. The action process of the single/double first frame data that appears from the force platform. The action process of the single/dou- footstep and immediate stop stage is from the ﬁrst touchdown of the foot to the knee ﬂexion ble footstep and immediate stop stage is from the first touchdown of the foot to the knee angle reaching the maximum. The biomechanical parameter extraction in two stages of flexion angle reaching the maximum. The biomechanical parameter extraction in two this research included: (1) joint angle and angular velocity of the trunk, hip, knee and stages of this research included: (1) joint angle and angular velocity of the trunk, hip, knee ankle during the initial touchdown of feet; (2) maximum ﬂexion angle of the hip and knee; and ankle during the initial touchdown of feet; (2) maximum flexion angle of the hip and (3) the peak of GRF in the horizontal plane on single/double footstep and immediate stop knee; (3) the peak of GRF in the horizontal plane on single/double footstep and immediate stage and (4) the peak of GRF in the vertical plane on single/double footstep stage. Only stop stage and (4) the peak of GRF in the vertical plane on single/double footstep stage. successful drop landings (initial landing) of the trials were analyzed (Figure 3). Only successful drop landings (initial landing) of the trials were analyzed (Figure 3). Figure 3. Sequence progression of the landing; (A) Single-leg LFL, (B) Single- leg SSL, (C) Single leg Figure 3. Sequence progression of the landing; (A) Single-leg LFL, (B) Single- leg SSL, (C) Single leg UPL, (D) Double-leg LFL, (E) Double-leg SSL, (F) Double-leg UPL. UPL, (D) Double-leg LFL, (E) Double-leg SSL, (F) Double-leg UPL. 2.3. 2.3. Parame Parameters ters Kinematic and kinetics of joint angle and torque moment of the lower limb (hip, knee, Kinematic and kinetics of joint angle and torque moment of the lower limb (hip, knee, and ankle) during three trunk positions (Lean forward, Self-selected, Upright landing) and ankle) during three trunk positions (Lean forward, Self-selected, Upright landing) from single-leg and double-leg landings were completed. from single-leg and double-leg landings were completed. 2.3.1. Upright Landing (URL) 2.3.1. Upright Landing (URL) Initial contact during landing is on the heel with the body as upright as possible. Initial contact during landing is on the heel with the body as upright as possible. Appl. Sci. 2021, 11, 7773 5 of 8 2.3.2. Lean Forward Landing (LFL) Initial contact during landing is on the ball of the feet with the trunk leaning forward. 2.3.3. Self-Selected Landing (SSL) Subject lands on the mid-foot with upright right trunk position. Participants were informed how to land self-selected prior to the start of the experiment. 2.4. Data Processing The kinetics and kinematic data were processed with a low-pass fourth-order zero-lag digital Butterworth ﬁlter at 40 and 12 Hz, respectively. The position and orientation data were synchronized with the GRF data. The joint angles were calculated as previously reported by Shultz and Schmitz [22]. To compare trunk inclination across the landing conditions, sagittal plane angles of the thorax and sacrum were calculated relative to the vertical axis of the global coordinate system and were deﬁned as the thoracic and sacral in- clination angles, respectively. The participants may have modiﬁed their sacral and thoracic inclination angles differently while landing due to different vertebral articulations in the lumbar spine. Therefore, both the sacral and thoracic inclination angles were examined to determine how the participants modiﬁed their trunk positions during single/double-leg landings. The thoracic and sacral inclination angles as well as the ankle dorsi/plantar ﬂexion angles at initial foot contact were extracted to ensure that the participants success- fully modiﬁed their landing styles across the three conditions. To test hypotheses of the current study, the peak vertical GRFs and peak plantar ﬂexor moments as well as the times to these peaks were extracted. The peak knee extensor moment, sagittal plane hip and ankle moments, and knee ﬂexion angles at the instant of peak knee extensor moment were subsequently extracted. 2.5. Statistical Methods Fifteen female subjects (university-level competitive athletes) volunteered to partici- pate in this study; however, ﬁve did not meet study eligibility criteria due to the previous history of ACL injury. This left a total of 10 subjects who consented and participated in the study; however, three of them had to be excluded due to inadequate three-dimensional marker tracking during the landing phase of the landing trials. Landing biomechanics related to ACL injury were assessed during a double-leg/single-leg stop-landing maneu- ver, using a video-based motion analysis system. A repeated measure two-way ANOVA (p 0.05) was used to test the within-subject differences of landing biomechanical charac- teristics between conditions (LFL, SSL, URL) and task (double and single leg). Regarding the ANOVA test, if the Mauchly’s p-value was signiﬁcant (p 0.05), Greenhouse–Geisser correction results were taken from the tables, but, if the Mauchly’s test p-value were found not signiﬁcant (p > 0.05) sphericity-assumed results were used. Bonferroni design was used to prevent data from incorrectly appearing to be statistically signiﬁcant. 3. Results 3.1. Demographic Results Table 1 shows the descriptive statistics of the three professional handball players and four professional soccer players who were eligible for complete inclusion in the study. Table 1. Subject’s demographic distribution (n = 7). Min Max Mean SD Age 19 21 19.57 0.787 Height (cm) 153 177 164.21 8.113 Weight (kg) 53 68 60.43 5.987 Appl. Sci. 2021, 11, 7773 6 of 8 3.2. Torque Analyses This part will show the analyses of torque for the ankle (dorsiﬂexion), knee (ﬂexion) and hip (ﬂexion) in the three trunk positions while landing. Table 2 shows the descriptive statistics and the results of ANOVA. p-values from ANOVA * denote statistically signiﬁcant difference (p 0.05). Table 2. Descriptive statistics and results of 2-way repeated measure ANOVAs (Mean SD) compar- isons of sagittal plan trunk angles (LFL, SSL and URL) and hip, knee and ankle ﬂexion angles during double/single-leg landing. LFL SSL URL Double Leg Single Leg Double Leg Single Leg Double Leg Single Leg Hip 49 12.8 51.7 22.3 43.3 13.7 * 63.9 23.1 * 44.2 13.1 * 59.2 21.9 Knee 44.8 13.6 61.2 22 44.9 12.7 64.9 29.5 46.7 16.6 * 59.2 26.1 Ankle * 46 8 * 48 13 45 11 40 6 58 30 66 34 * Signiﬁcant main effect at a level of less than 0.05. Negative directions indicate hip and knee ﬂexion, positive direc- tions indicates ankle dorsiﬂexion. LFL leaning forward landing, SSL self-selected landing, URL upright landing. Table 2 shows that the ankle dorsiﬂexion was signiﬁcant during single/double-leg landing in the LFL trunk position (p 0.05). The data in Table 2 also demonstrate signiﬁcant difference levels of single-leg land- ing during URL for the knee and signiﬁcant difference levels of URL position during single/double-leg landing for the hip. Moreover, result shows SSL was notably different for the hip during single-leg landing (p 0.05). 3.3. Joint Angle Analyses Table 3 shows the group means and standard deviations of the sagittal plane trunk angle (LFL, SSL, URL) during double leg and single leg landings among seven athletes (N). It was hypothesized that the dorsiﬂexion joint angle would be more signiﬁcant for ACL injury in the URL during the landing phase. Further, based on estimated marginal means, the p-values from ANOVA; * denote statistically signiﬁcant difference (16.7 21.2). Moreover, results show the knee joint angle was signiﬁcantly different during both landing phases in the URL trunk position (p 0.05). p-value from ANOVA * denotes statistically signiﬁcant differences for SSL and URL during single-leg landing (81.9 33.8 and 87.6 50.7, respectively). Table 3. Descriptive statistics and results of 2-way repeated measures ANOVA (Mean SD) compar- isons of sagittal plan trunk angles (LFL, SSL and URL) and hip, knee and ankle ﬂexion angles during double/single-leg landing. LFL SSL URL Double Leg Single Leg Double Leg Single Leg Double Leg Single Leg Hip 69.9 27.3 77.1 27.6 67.8 22.6 * 81.9 33.8 68.4 21 * 87.6 50.7 Knee 36 11.9 39.7 19.2 36.1 12.8 43.7 27.7 * 34.3 10.7 * 45.1 30.6 Ankle 39.7 6.2 41.2 6.9 37.8 6 38.4 4.7 * 23 18.6 * 16.7 21.2 * Signiﬁcant main effect at a level of less than 0.05. Negative directions indicate hip and knee ﬂexion, pos- itive directions indicates ankle dorsiﬂexion. LFL, leaning forward landing; SSL, self-selected landing; URL, upright landing. 4. Discussion The current study hypothesized that, compared to the double-leg landing, single-leg landing would have a smaller hip and knee ﬂexion angles at the time of initial foot contact with the ground, (2) have lower hip and knee ﬂexion angular velocities at the time of initial foot contact with the ground, (3) have a greater GRF during landing, (4) have a greater knee joint reaction force during landing, and (5) have a greater knee ﬂexion moment during landing. The present research has provided support through the obtained evidence Appl. Sci. 2021, 11, 7773 7 of 8 indicating signiﬁcant levels for the torque angle during dorsiﬂexion, hip ﬂexion and knee ﬂexion (p 0.05). The contention that the shock absorption of the ankle joint angle is lessened in URL was further supported in our study (16.7 21.2). This observation indicates that LFL allowed the participants sufﬁcient time to produce the peak ankle plantar ﬂexor moment before the peak GRF occurred, increasing the proportion of GRF absorption by the ankle. Corresponding to requiring less dorsiﬂexion during landing (more plantar ﬂexion), subjects showed signiﬁcant results for the ankle (Table 2). Conversely, during URL, the peak GRF occurred before the peak ankle plantar ﬂexor moment. Collectively, these results support previous suggestions that shock-attenuating capacity is higher in LFL than in URL [15]. Our results showed that the greatest peak knee extensor moment occurred during single-leg landing with the URL trunk position and the smallest peak knee extensor moment occurred during single-leg landing with the LFL trunk position. The hip extensor moments at the time of peak knee extensor moment were greater for URL than for LFL. Furthermore, the URL during single-leg landing is indicated as a position where the knee receives more external force and more extension; therefore, the chance of knee injury and consequently ACL injury will increase in sagittal plane trunk positions (Tables 2 and 3). These ﬁndings indicate that trunk ﬂexion potentially reduces a subsequent load placed on the ACL immediately after ground contact, which is when the ACL injury reportedly occurs. Trunk ﬂexion during landing produced greater knee and hip ﬂexion compared with a more erect or trunk-extended (URL) landing posture, placing the lower extremity in a position associated with decreased ACL injury risk [8]. As such, active trunk ﬂexion could be an integral component of ACL injury-prevention programs by virtue of its ability to simultaneously inﬂuence kinetic, kinematic, and neuromuscular variables that have been suggested as risk factors for ACL injury. 5. Conclusions This study suggests that leaning forward while landing (LFL) appears to protect the ACL by increasing the shock absorption capacity and knee ﬂexion angles and decreasing anterior shear force due to the knee joint compression force. Conversely, upright landing (URL) appears to be harmful to the ACL by increasing the post-impact force of landing while decreasing knee ﬂexion angles, all of which lead to a greater tibial anterior shear force and ACL loading. Based on the obtained data, we infer that a higher risk of ACL injury in the single-leg landing task could result from the fact that the single-leg landing exhibited greater peak proximal tibia anterior and lateral shear forces during the landing phase than the double-leg landed task (Tables 2 and 3). Further studies with a larger number of participants across sports (basketball, handball, soccer) would be required to provide new insights and support the data obtained in this present research. Finally, authors acknowledge the limitation of the present study that is its small sample size. Although the results showed the LFL to be the best position for preventing the ACL injury, it remains to be proven, and without further research it would be an overstatement believing that lean forward landing could be an integral part of injury prevention programs. Moreover, how a forward lean could also impact the kinematics of landings in some sports (e.g., cause back injury, change dynamics of tactical components/movements, etc.) needs to be investigated. Author Contributions: Methodology, M.K.; validation, T.Y., S.K. and S.T.; formal analysis, T.Y.; investigation, M.K.; data curation, T.Y.; writing—original draft preparation, M.K.; writing—review and editing, R.R.; supervision, R.R. All authors have read and agreed to the published version of the manuscript. Funding: This research received no external funding. Institutional Review Board Statement: The study was conducted according to the guidelines of the Declaration of Helsinki, and approved by the Institutional Review Board (or Ethics Committee) of UNIVERSITY OF TSUKUBA (protocol code tai30-123, 10 October 2019). Appl. Sci. 2021, 11, 7773 8 of 8 Informed Consent Statement: Informed consent was obtained from all subjects involved in the study. Data Availability Statement: The data are not publicly available due to ethical restrictions. Acknowledgments: The authors would like to thank all the participants (women athletes) and research assistants who supported this research. Conﬂicts of Interest: The authors declare no conﬂict of interest. References 1. De Loës, M.; Dahlstedt, L.J.; Thomée, R. A 7-year study on risks and costs of knee injuries in male and female youth participants in 12 sports. Scand. J. Med. Sci. Sports 2000, 10, 90–97. [CrossRef] 2. Aaron, M.G.; Zbgniew, G.; Jacques, G.B. 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Markolf, K.L.; Burchﬁeld, D.M.; Shapiro, M.M.; Shepard, M.F.; Finerman, G.A.; Slauterbeck, J.L. Combined knee loading states that generate high anterior cruciate ligament forces. J. Orthop. Res. 1995, 13, 930–935. [CrossRef] 8. Stevenson, H.; Webster, J.; Johnson, R.; Beynnon, B. Gender differences in knee injury epidemiology among competitive alpine ski racers. Lowa Orthop. J. 1998, 18, 64–66. 9. Fleming, B.C.; Renstrom, P.A.; Beynnon, B.D.; Engstrom, B.; Peura, G.D.; Badger, G.J.; Johnson, R.J. The effect of weightbearing and external loading on anterior cruciate ligament strain. J. Biomech. 2001, 34, 163–170. [CrossRef] 10. Donnelly, C.J.; Lloyd, D.G.; Elliott, B.C.; Reinbolt, J.A. Optimizing whole-body kinematics to minimize valgus knee loading during sidestepping: Implications for ACL injury risk. J. Biomech. 2012, 45, 1491–1497. [CrossRef] 11. Hewett, T.E.; Myer, G.D.; Ford, K.R. Anterior cruciate ligament injuries in female athletes: Part 1, mechanisms and risk factors. Am. J. 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Correlation of Kinematics and Kinetics of Changing Sagittal Plane Body Position during Landing and the Risk of Non-Contact Anterior Cruciate Ligament Injury

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Applied Sciences – Multidisciplinary Digital Publishing Institute

Published: Aug 24, 2021

Keywords: ACL injuries; landing trunk positions; non-contact; sagittal plane; women athlete

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Correlation of Kinematics and Kinetics of Changing Sagittal Plane Body Position during Landing and the Risk of Non-Contact Anterior Cruciate Ligament Injury

Correlation of Kinematics and Kinetics of Changing Sagittal Plane Body Position during Landing and the Risk of Non-Contact Anterior Cruciate Ligament Injury

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Correlation of Kinematics and Kinetics of Changing Sagittal Plane Body Position during Landing and the Risk of Non-Contact Anterior Cruciate Ligament Injury

Correlation of Kinematics and Kinetics of Changing Sagittal Plane Body Position during Landing and the Risk of Non-Contact Anterior Cruciate Ligament Injury

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