Changes In Kinematics Research Articles

Biomechanical coordination and variability alters following repetitive movement fatigue in overhead athletes with painful shoulder

Most sports and leisure activities involve repetitive movements in the upper limb, which are typically linked to pain and discomfort in the neck and shoulder area. Movement variability is generally expressed by changes in movement parameters from one movement to another and is a time-dependent feature of repetitive activities. The purpose of this study was to examine the effect of repeated movement-induced fatigue on biomechanical coordination and variability in athletes with and without chronic shoulder pain (CSP). In this controlled laboratory study, 24 overhead athletes in two groups of athletes with (N = 12) and without (N = 12) CSP were recruited. Biomechanical and Electromyographical data were recorded while the athletes were asked to perform repeating reaching tasks (RRT). Kinematic data was recorded every 30 s of the minutes of the repetitive pointing task (RPT). The kinematic and electromyography data were recorded at the first 30 s of “Fatigue-Terminal” (FT) and the last 30 s of “No-Fatigue” (NF) in the repetitive pointing task (RPT). Raw data was analyzed by using MATLAB code to extract the relevant coordination and movement variability data. Different fatigue conditions led to significant kinematic changes during the repetitive pointing task. In the CSP group, trunk lateral flexion decreased after fatigue, while it increased in the CON group (p < 0.013). Trunk rotation and shoulder elevation angles were smaller before fatigue than after in both groups (p < 0.001). Variability in joint angles, including trunk lateral flexion and elbow flexion, increased after fatigue, indicating less stability in movement patterns (p < 0.001). The coordination between trunk movement and shoulder elevation was altered post-fatigue, with significant changes in EMG variability for muscles like the Lower Trapezius and Long Head of the Biceps (p < 0.001). Results of our study indicate that both groups were able to accomplish fatigue, but they employed different movement strategies. The CSP group primarily focused on controlling the shoulder joint, while the CON group utilized both the shoulder and elbow joints in their strategy. This difference suggests that individuals in the CSP group who experienced chronic pain may have developed a strategy to minimize pain and fatigue during the task. Specifically, the CSP group’s approach appeared to involve adjustments in movement patterns to manage the task despite fatigue. This adaptation contrasts with the CON group’s more complex movement strategy, which involved greater variability and adjustments in both the shoulder and elbow joints.

The Spine Lengthens During Walking in Healthy Participants, with Age-Related Changes in Kinematic Parameters.

Background: While the importance of the upper and lower limbs in locomotion is well understood, the kinematics of the trunk during walking remains largely unexplored. Two decades ago, a casual observation was reported indicating spine lengthening in a small sample of mostly children during walking, but this observation was never replicated. Objectives: This study aims to verify the preliminary observation that spine lengthening occurs during walking and to explore changes in spine kinematics across three different age groups. Methods: A convenience sample of 45 healthy participants was divided into three groups of 15 individuals each: children (ages 5 to 13), young adults (ages 18 to 30), and older adults (ages 50 to 70). The spinal length, defined as the distance between C7 and the coccyx, and other kinematic parameters were analyzed using a motion analysis system while participants stood and walked standing and walking at their natural cadence. Results: In all groups, the length of the spine increased while walking compared to standing. This change was primarily due to a reduction in the inferior spinal angle, which is associated with lumbar lordosis, rather than a change in the superior spinal angle, which is related to thoracic kyphosis. The average change in spinal length during the walking cycle was approximately 7% in children, while it was only about 1% in adults. We also found a reduction in the range of motion for almost all the variables in adults. Conclusions: The increase in the spinal length during walking is related to a reduction in the physiological spine curve. This occurs due to muscle contractions which are needed to stabilize the locomotor system. As people age, the reduction in spinal length changes is associated with decreased spinal mobility and to a natural tendency toward anterior trunk flexion.

Hip Abductor Muscle Strength in Patients After Total Knee Arthroplasty: A Systematic Review and Meta-analysis

IntroductionImpaired hip abductor muscle strength indirectly leads to changes in knee kinematics and may cause pain or functional limitations after total knee arthroplasty (TKA). This study aimed to evaluate and quantify hip abductor muscle strength deficits after TKA and investigate external factors influencing hip abductor muscle strength after TKA. MethodsA comprehensive literature search was performed, and clinical studies reporting hip abductor muscle strength after primary TKA were included. We performed meta-analyses to assess the relative hip muscle strength of the operated leg compared to the contralateral limb and the change from preoperative to postoperative values across multiple time points. We also assessed the pooled absolute hip muscle strength across the following time points: preoperatively, up to two months, two to six months, and more than six months postoperatively. ResultsThere were 15 studies involving 823 patients that met our inclusion criteria. Compared with preoperative values, patients had a mean strength deficit of 18.0% (95% confidence interval (CI) [-30.8 to -5.2] at up to two months postoperatively, a non-significant deficit of 11.3% (CI [-32.7 to 10.2]) at two to six months postoperatively and an increase of 18.4% (CI [2.7 to 34.1]) at ≥ six months postoperatively. Compared with the contralateral side, patients had a mean abductor strength deficit of 11.5% (CI [-16.2 to -6.9]) preoperatively, 23.2% (CI [-27.6 to -18.8]) at up to two months postoperatively, a non-significant deficit of 10.8% (CI [-23.2 to 1.6]) at two to six months postoperatively and no difference (0.6% (CI [-4.2 to 5.4]) more than six months postoperatively. The study quality was low to moderate. ConclusionHip abductor muscle strength is reduced preoperatively in patients undergoing TKA, continues to decrease in the immediate postoperative period, but fully recovers within six to 12 months. Although these data can be used to guide patient education and rehabilitation planning, they should be interpreted with caution due to the heterogeneous and limited high-quality evidence.

In vivo shoulder kinematic changes and rotator cuff healing after surgical repair of large-to-massive rotator cuff tears

BackgroundFew studies have investigated the correlation between shoulder kinematics and clinical outcomes in patients undergoing rotator cuff repair using dynamic analysis. This study assessed shoulder kinematics before and after surgical repair in patients with rotator cuff tears (RCTs) and determined the relationship among shoulder kinematics and between shoulder kinematics and clinical outcomes.MethodsTen patients with large-to-massive RCTs and 10 control participants were included. In vivo shoulder kinematics during scapular plane abduction were measured preoperatively and 1 year postoperatively using validated image-registration techniques and compared among the control, preoperative, and postoperative groups. Mixed models were used to compare the effects of the groups on shoulder kinematics, followed by Tukey’s honest significant difference test. Pearson’s correlation coefficient was used to identify the correlations among shoulder kinematics and between each kinematic and clinical outcome.ResultsThe scapula, tilted more anteriorly preoperatively, was not different from the control group postoperatively. Additionally, the change in scapular posterior tilt (PT) throughout dynamic abduction was 18.17° ± 3.59° in the postoperative group, greater than that in the control group (11.54° ± 2.29°; p = 0.0037). The postoperative change in PT significantly correlated with acromiohumeral distance (AHD) and rotator cuff integrity (Sugaya classification) (AHD: r = 0.71, p = 0.023; Sugaya classification: r = − 0.75, p = 0.013), but not preoperative change in PT. Functional score improved from preoperative to postoperative (p < 0.0001). Abduction angle and functional score significantly correlated with Sugaya classification (abduction angle: r = − 0.67, p = 0.034; functional score: r = − 0.70, p = 0.025) but not with shoulder kinematics. Mean superior translation of the humeral head and AHD throughout abduction changed from 1.77 ± 1.34 to 0.61 ± 1.37 and 1.44 ± 1.59 to 2.71 ± 2.27 mm, respectively, from preoperative to postoperative (both p < 0.0001).ConclusionsAfter the surgical repair of large-to-massive RCTs, glenohumeral stability normalized, and the more anteriorly tilted orientation of the scapula improved. Additionally, the preoperative increased scapular motion throughout dynamic abduction was further enhanced postoperatively. Interestingly, in postoperative patients, scapular motion toward PT during dynamic abduction correlated with minimum AHD and cuff healing.

A comparison of kinematic and kinetic characteristics of intrinsic flexor muscles of the foot exercises: Effect on the medial longitudinal arch of the foot

Background Standing toe curl (STC) has an immediate effect on muscle activity, but the kinematics of the exercise and its effect on the medial longitudinal arch of the foot are unknown. Objective The purpose of this study was to examine the differences in kinematic and kinetic changes during toe flexion while performing towel curl (TC) in a standing position and STC. Methods Ten healthy adults with normal feet (18 limbs) participated in this study. Using a three-dimensional motion analysis system, we calculated the toe flexion angle, medial longitudinal arch (MLA) angle, MLA height, MLA length, ankle joint angle, center of foot pressure, and center position of the hip joint during toe flexion using TC and STC exercises. Results The TC exercise resulted in a decrease in the MLA due to the backward shift in the center of pressure and ankle dorsiflexion. On the other hand, STC did not demonstrate any significant difference in the position of the center of pressure or ankle joint angle, allowing the toes to flex while maintaining a standing posture and resulting in an increase in the MLA. Conclusions STC was suggested to be effective in maintaining MLA for weight support.

Time-dependent changes in medial meniscus kinematics and attachment strength after anterior root injury and repair in a large animal model.

This study investigated joint kinematics and attachment tensile mechanics following resection of the medial meniscus anterior attachment. A secondary objective investigated the repair of the attachment. Yucatan minipigs underwent unilateral surgery for either Injury (en bloc) resection of the anterior attachment of the insertional ligament, (a portion of the cranial medial meniscotibial ligament) or Repair (immediate repair with a suture anchor), with the contralateral knee as Intact control. Evaluation at 6 weeks and 6 months included joint kinematics measured from MRI acquired under knee compression and tensile testing of the attachment. Injury resulted in large levels of meniscus extrusion, despite the development of a fibrovascular scar. At 6 weeks, the meniscus extruded 1.95 mm more than Intact; at 6 months, this extrusion was reduced to 0.77 mm. Under an applied 1× body weight load, the meniscus further extruded and was not different with treatment or time. During attachment tensile testing, elongation was 0.6 mm for Intact, following Injury, elongation was 2.7 mm at 6 weeks and was partially restored to 1.5 mm at 6 months. Despite this, the cartilage wear worsened over time. Repair was inadequate to avoid the extrusion or cartilage wear seen in the injury group at 6 weeks, so it was not continued for the 6-month group. This study demonstrates that while meniscus injury is useful to study cartilage degeneration, a holistic consideration of the role of the meniscus itself, including its changing material properties and its impact on joint mechanics during injury, repair, and rehabilitation, are key factors contributing to overall joint health.

“Acute responses to barefoot running are related to changes in kinematics, mechanical load, and inflammatory profile”

This study investigated the acute effects of barefoot (BF) running on biomechanical parameters and cytokine concentrations. Seventy-one habitually shod runners had biomechanical parameters evaluated during running shod (SH) and BF, while a sub-group of 19 runners had their inflammatory profile analyzed before and after a running session, using their habitual shoes or barefoot. Running BF changed spatiotemporal and joint kinematics, including the stride frequency (increased) and length (decreased), and foot strike pattern (more plantarflexed ankle at initial contact). An increased impact force was observed (p < 0.05), while joint moment, power, and work were also affected by BF running: a shift of joint load from the knee and hip to the ankle occurred (p < 0.05). In cytokine levels, maintenance (all cytokines, except Eotaxin, IL-12p40, IL-2, IL5, and MIP-1 beta) or reductions (IL-12p40, IL-2, and IL5) were observed as an acute response to BF running, what means to keep or reduce the levels of pro-inflammatory cytokines and immunological/chemoattraction proteins when compared to SH. Summarily, a single session of BF running may not represent enough stress to induce changes in the inflammatory profile. Besides the increased impact force, the joint load was reduced during short-term BF running. Nevertheless, short-term BF running should be cautiously applied due to the shift of joint load from the knee and hip to the ankle.

Increased kinematic changes in ascending compared with descending biplanar cut in open wedge high tibial osteotomy—a multibody simulation

BackgroundThe ascending or descending extended biplanar tibial cut in open wedge high tibial osteotomy (owHTO) not only changes the lower limb anatomy in the coronal plane but also leads to different three-dimensional (3D) changes in the patellofemoral joint. This study aimed to perform a comprehensive analysis of the dynamic biomechanical changes in the knee joint using a multibody simulation model.MethodsThirteen 3D computer models derived from lower limb computer tomography scans were used for owHTO. Osteotomies with ascending or descending biplanar cut were simulated for each wedge height from 6 to 12 mm (in 1-mm intervals). Multibody simulation was used to analyze differences in patellar shift, patellar tilt, mediolateral patellar rotation, and tibiofemoral rotation during a squat simulation from 5° to 100° knee flexion.ResultsThe main effects of an ascending compared with a descending extended biplanar cut in owHTO were characterized by an increase in lateralization of the patella and rotation, along with reduced tilt. Linear mixed models revealed statistically significant effects of both wedge height and cut variant on knee kinematics at 100° knee flexion, with the influence of the cut variant (ascending/descending) being higher on all analyzed kinematic parameters.ConclusionsSignificant differences in the changes in patellofemoral shift, tilt, rotation, and tibiofemoral rotation were observed when performing owHTO with an ascending versus a descending biplanar cut. Apart from tibiofemoral rotation, the resulting kinematic changes were greater with an ascending cut.

Meniscus Injury Induces Patellofemoral Osteoarthritis Development Mediated by Synovitis and Gait Kinematics: A Preclinical Study.

To investigate whether meniscal injury leads to the development of patellofemoral (PF) osteoarthritis (PFOA) and to explore how synovitis and gait kinematics mediate this relationship. Fifty-four male Wistar rats (12 weeks old) were randomly assigned to the control, sham, or destabilized medial meniscus (DMM) groups. The rats were subjected to gait analysis to assess the kinematic changes at 2, 4, and 8 weeks postoperatively. Subsequently, the rats were euthanized, and their right knees were harvested for histological analysis. The Osteoarthritis Research Society International (OARSI) and modified Mankin (MM) scores in the DMM group were significantly higher than those in the control and sham groups at week 2 and significantly higher than those in the control group at week 4. The OARSI and MM scores in the sham group were significantly higher than those in the control group at weeks 2 and 4. The association between the DMM and OARSI scores was significantly mediated by the synovitis score and knee flexion angle at foot contact (proportion mediated: 58% and 10%, respectively). The association between the sham and OARSI scores was significantly mediated by the synovitis score and knee flexion angle (proportion mediated: 24% and 24%, respectively). DMM surgery induced articular cartilage damage in the PF joint. Synovitis and the knee flexion angle significantly mediated the association between DMM or sham surgery and PFOA development.

Risk factors and treatment strategies for adjacent segment disease following spinal fusion (Review).

Adjacent segment disease (ASD) is a significant clinical complication following cervical and lumbar spinal fusion surgery, characterized by the degeneration of spinal segments adjacent to the fused area. The present literature review aimed to elucidate the risk factors contributing to ASD and to evaluate current and emerging treatment strategies. Epidemiological data indicate that patient‑related factors such as age, pre‑existing spinal degeneration and comorbidities, along with surgical factors including the type of fusion, instrumentation and alignment correction, play pivotal roles in ASD development. Biomechanical alterations post‑fusion further exacerbate the risk. The underlying mechanisms of ASD involve changes in spinal kinematics and disc degeneration, driven by inflammatory and degenerative processes. Diagnostic modalities, such as magnetic resonance imaging and computed tomography scans, are essential for early detection and accurate diagnosis. Preventive strategies emphasize meticulous preoperative planning, advanced surgical techniques and postoperative rehabilitation. Treatment approaches range from conservative methods such as physical therapy and pharmacological interventions to surgical solutions, including revision surgeries and the use of motion‑preserving technologies. Emerging therapies, particularly in regenerative medicine, show promise in mitigating ASD. The present review underscored the necessity of a multidisciplinary approach to optimize patient outcomes and highlighted the need for ongoing research to address gaps in the current understanding of ASD in both cervical and lumbar regions.

Evaluating tibial rotation in recurrent patellar dislocation with four-dimensional computed tomography.

This study is to investigate the three-dimensional (3D) kinematic changes in the knee joint in patients with recurrent patellar dislocation using four-dimensional computed tomography (4DCT) imaging and the 3D-3D surface registration technique. Ten knees from nine patients with recurrent patellar dislocation and seven knees from seven controls (unaffected side of patients with unilateral anterior cruciate ligament injury) were analyzed using 4DCT. The patients were asked to extend their knees from 60° of flexion to full extension for 10s in the CT gantry. We used the 3D-3D registration technique, and the 3D angles of the patella and tibia relative to the femur were evaluated. In the dislocation group, the patellar lateral tilt increased as the knee extended. Significant differences were found between the two groups at 0°-20° of knee flexion. The tibia rotated externally as the knee extended in the dislocation group. Significant differences between the two groups were found at 0°-10° of knee flexion. This study demonstrated significant differences in the timing and magnitude of tibial external rotation between patients with recurrent patellar dislocation and controls. Specifically, the tibia began to externally rotate during the early phase of knee extension in the dislocation group. These findings provide new insights into knee kinematics that may inform future treatment strategies for patellar dislocation.

Effect duration of a self-applied talocrural joint mobilization on restricted dorsiflexion: a repeated measures design

ABSTRACT Objectives We aimed to determine the effect duration of a talocrural mobilization on individuals with restricted dorsiflexion during a static weight bearing lunge test (WBLT) and dynamic 3D motion capture-based peak ankle dorsiflexion during a forward step down (FSD) task. Secondarily, we aimed to correlate any immediate changes in ankle mobility with concurrent changes in proximal joint kinematics during the FSD post-mobilization. Methods Seventy-six individuals were screened for dorsiflexion restriction, of which 26 (15 females, 22.3 ± 2.2 years old, body mass index 25.2 ± 2.9 kg/m2) qualified with a WBLT of ≤ 35° on at least one limb. A baseline WBLT measure and 3D motion capture of 5 consecutive FSD repetitions on a 6-inch box were obtained. Participants then viewed an instructional video of a talocrural joint self-mobilization using a resistance band. WBLT and FSD were collected again immediately post-mobilization and at 5-min intervals for 60 min or until the WBLT returned to baseline for 2 consecutive measures. Results WBLT dorsiflexion showed a mean increase of 6.5 degrees (p < 0.001) post-mobilization. The effect faded over time and no longer differed from baseline 25 min post-mobilization (p = 0.964). Dynamic peak ankle dorsiflexion did not change post-mobilization at any time point (p ≥ 0.546). No 3D kinematic time-course changes were observed at the hip or knee. However, immediate raw alterations in dorsiflexion correlated with alterations for hip and knee flexion. Discussion/Conclusion A talocrural joint mobilization increased static dorsiflexion per the WBLT for a 20–25-min period with regression to baseline. However, increased dynamic ankle dorsiflexion was not observed during the FSD task. Improved mobility alone does not appear to change movement patterns. Clinicians should be aware of both effect duration and the potential need for task-specific training to better facilitate dynamic utilization of increased mobility.

Changes of upper-limb kinematics during practice of a redundant motor task in patients with Parkinson’s disease

The ability to learn novel motor skills is essential for patients with Parkinson’s disease (PD) to regain activities of daily living. However, the underlying mechanisms of motor learning in PD remain unclear. To identify motor features that are distinctively manifested in PD during motor learning, we quantified a rich set of variables reflecting various aspects of the learning process in a virtual throwing task. While the performance outcome improved similarly over 3 days of practice for both PD patients and age-matched controls, further analysis revealed distinct learning processes between the two groups. PD patients initially performed with a slow release velocity and gradually increased it as practice progressed, whereas the control group began with an unnecessarily rapid release velocity, which they later stabilized at a lower value. Performance characteristics related to the timing of ball release and the inter-release interval did not show significant group differences, although they were modulated across practice in both groups. After one week, both groups retained the performance outcomes and underlying kinematics developed over practice. This study underscores the importance of analyzing the multi-faceted learning process to characterize motor skill learning in PD. The findings may provide insights into PD pathophysiology and inform rehabilitation strategies.

The influence of lightweight wearable resistance on whole body coordination during sprint acceleration among Australian Rules football players.

Rapid acceleration is an important quality for field-based sport athletes. Technical factors contribute to acceleration and these can be deliberately influenced by coaches through implementation of constraints, which afford particular coordinative states or induce variability generally. Lightweight wearable resistance is an emerging training tool, which can act as a constraint on acceleration. At present, however, the effects on whole body coordination resulting from wearable resistance application are unknown. To better understand these effects, five male Australian Rules football athletes performed a series of 20 m sprints with either relatively light or heavy wearable resistance applied to the anterior or posterior aspects of the thighs or shanks. Whole body coordination during early acceleration was examined across eight wearable resistance conditions and compared with baseline (unresisted) acceleration coordination using group- and individual-level hierarchical cluster analysis. Self-organising maps and a joint-level distance matrix were used to further investigate specific kinematic changes in conditions where coordination differed most from baseline. Across the group, relatively heavy wearable resistance applied to the thighs resulted in the greatest difference to whole body coordination compared with baseline acceleration. On average, heavy posterior thigh wearable resistance led to altered pelvic position and greater hip extension, while heavy anterior thigh wearable resistance led to accentuated movement at the shoulders in the transverse and sagittal planes. These findings offer a useful starting point for coaches seeking to use wearable resistance to promote adoption of greater hip extension or upper body contribution during acceleration. Importantly, individuals varied in how they responded to heavy thigh wearable resistance, which coaches should be mindful of.

Future Changes in the Vertical Structure of Severe Convective Storm Environments over the U.S. Central Great Plains

Abstract The effect of warming on severe convective storm potential is commonly explained in terms of changes in vertically integrated (“bulk”) environmental parameters, such as CAPE and 0–6-km shear. However, such events are known to depend on the details of the vertical structure of the thermodynamic and kinematic environment that can change independently of these bulk parameters. This work examines how warming may affect the complete vertical structure of these environments for fixed ranges of values of high CAPE and bulk shear, using data over the central Great Plains from two high-performing climate models (CNRM and MPI). To first order, projected changes in the vertical sounding structure are consistent between the two models: the environment warms approximately uniformly with height at constant relative humidity, and the shear profile remains relatively constant. The boundary layer becomes slightly drier (−2% to 6% relative humidity) while the free troposphere becomes slightly moister (+1% to 3%), with a slight increase in moist static energy deficit aloft with stronger magnitude in CNRM. CNRM indicates enhanced low-level shear and storm-relative helicity associated with stronger hodograph curvature in the lowest 2 km, whereas MPI shows near-zero change. Both models strongly underestimate shear below 1 km compared to ERA5, indicating large uncertainty in projecting subtle changes in the low-level flow structure in climate models. The evaluation of the net effect of these modest thermodynamic and kinematic changes on severe convective storm outcomes cannot be ascertained here but could be explored in simulation experiments. Significance Statement Severe thunderstorms and tornadoes cause substantial damage and loss of life each year, which raise concerns about how they may change as the world warms. We typically use a small number of common atmospheric parameters to understand how these localized events may change with climate change. However, climate change may alter the weather patterns that produce these events in ways not captured by these parameters. This work examines how climate change may alter the complete vertical structure of temperature, moisture, and wind and discusses the potential implications of these changes for future severe thunderstorms and tornadoes.

Human walking biomechanics on sand substrates of varying foot sinking depth.

Our current understanding of human gait is mostly based on studies using hard, level surfaces in a laboratory environment. However, humans navigate a wide range of different substrates every day, which incur varied demands on stability and efficiency. Several studies have shown that when walking on natural compliant substrates there is an increase in energy expenditure. However, these studies report variable changes to other aspects of gait such as muscle activity. Discrepancies between studies exist even within substrate types (e.g. sand), which suggests that relatively 'fine-scale' differences in substrate properties exert quantifiable influences on gait mechanics. In this study, we compared human walking mechanics on a range of sand substrates that vary in overall foot sinking depth. We demonstrated that variation in the overall sinking depth in sand was associated with statistically significant changes in joint angles and spatiotemporal variables in human walking but exerted relatively little influence on pendular energy recovery and muscle activations. Significant correlated changes between gait metrics were frequently recovered, suggesting a degree of coupled or mechanistic interaction in their variation within and across substrates. However, only walking speed (and its associated spatiotemporal variables) correlated frequently with absolute foot sinkage depth within individual sand substrates, but not across them. This suggests that a causative relationship between walking speed and foot sinkage depth within individual sand substates is not coupled with systematic changes in joint kinematics and muscle activity in the same way as is observed across sand substrates.

Lower limbs kinematic analysis during a jump landing task in soccer players with unilateral anterior cruciate ligament reconstruction

BackgroundFatigue leads to an acute decline in muscle strength, altered patterns of lower extremity muscle activation, changes in hip and knee kinematics. In terms of the effects of fatigue on knee joint kinematics during plyometric training, there is still a lack of knowledge regarding kinematic differences between athletes who passed the ACL reconstructions rehabilitation period and healthy athletes. Therefore, this study aimed to compare lower limb joint kinematic parameters between reconstructed cruciate ligament and healthy control soccer players during jump landing in a fatigued setting.MethodsLower limb kinematic parameters were recorded in 20 professional soccer players (age, 24.95 ± 2.92 years; body mass, 77.20 ± 12.88 kg; height, 1.77 ± 3.19 m) during jump landing task before and after the fatigue protocol. The control group consisted of healthy subjects and the experimental group consisted of subjects with ACL reconstruction by thigh transplantation. Kinematic data was recorded with 4 cameras to measure lower limb angles at first foot contact and maximum range of motion.ResultsThe results showed that before fatigue, there was only a significant difference between the two groups in the maximum range of motion of the non-involved hip joint (P = 0.022) and angle of the involved hip at first contact (P = 0.049). In other data on joint range of motion or initial contact angle, no significant difference was observed between the two groups (P > 0.05). After fatigue protocol, there was a significant difference in initial foot contact in non-involved (P = 0.030), and involved (P = 0.020) hip joint angles between the two groups. However, no significant difference in initial contact angle or range of motion of other joints was observed between the groups.ConclusionsThis study shows that plyometric fatigue does not contribute to numerous changes in contact angles and range of motion in lower extremity joints in healthy soccer players and those with a history of cruciate ligament repairs.

An expository analysis of biomechanical and subjective impacts induced by shoe inserts in asymptomatic subjects: A systematic review on functionality and mechanisms of action

AbstractThis systematic review explores the biomechanical and subjective effects of shoe inserts, including foot orthotics (FOs) and insoles, in asymptomatic subjects. Aimed at understanding their implications, the review poses two key research questions: (i) the influence of shoe inserts on lower extremity biomechanics and subjective perception and (ii) the effects of different design characteristics on these aspects. Following Preferred Reporting of Systematic Reviews and Meta‐Analysis guidelines, a meticulous search of Scopus and PubMed from August 2022 to March 2023 yielded 34 articles, with 26 focusing on biomechanical effects and eight on comfort effects. The studies, conducted during static and dynamic activities, such as standing, walking, jogging, running, jumping, and cycling, reveal significant reductions in rearfoot eversion, knee joint forces, and lower extremity muscle forces through postings and wedging in FOs. Changes in stiffness impact rearfoot kinematics, plantar pressure distribution, and ankle–foot power distribution. Conversely, surface texture and arch variations demonstrate limited significance. FOs and shoe inserts, characterized by geometric, material, location, size, and fabrication features, effectively regulate forces and moments on the lower extremity. This control promotes uniform plantar pressure distribution and enhances comfort during various activities. These insights benefit manufacturers, clinicians, and stakeholders, providing a deeper understanding of the positive benefits of FOs and shoe inserts. However, further well‐designed studies on clinical populations are necessary to validate these findings and establish their clinical efficacy, as the current focus remains on healthy subjects.

Results of the rehabilitation program for patients after suting the meniscues according to the "all-inside" method

The menisci play an important role in the functioning of the knee joint. Ruptures of the menisci cause significant changes in joint kinematics, which is one of the prerequisites for the development of early osteoarthritis. Suturing a torn meniscus prevents this complication. The aim of the study was to study the results of the implemented program of physical rehabilitation of patients after suturing vertical tears of the meniscus of the knee joint using the "all-inside" technique. 43 patients who underwent suturing of a vertical meniscus tear using the "all-inside" technique took part in the study. Patients were divided into 2 groups. The first experimental group - 21 people who were given a rehabilitation program according to our method. The second group, the control group - 22 patients who underwent rehabilitation according to the existing program. In the process of rehabilitation measures, the intensity of pain in patients of the experimental group according to VAS significantly decreased (p &lt; 0,001). Bending of the knee joint in the experimental group reached 96,42% of the normal, in the control group 78,57%. During the rehabilitation process, there was an increase in muscle tone and amplitude of the quadriceps muscle among patients in the experimental group.

Kinematic Changes throughout Childhood in Youth with Cerebral Palsy: Influence of Age and Orthopaedic Surgery.

Abnormal gait kinematics are common in youth with cerebral palsy (CP), but prior studies have not analyzed their longitudinal change throughout childhood. This study examines how age and orthopaedic surgery influence gait kinematics throughout childhood in those with ambulatory CP. In this institutional review board-approved prospective cohort study, children with spastic CP (GMFCS I-III) were recruited at age 17-40 months. Instrumented gait analysis was performed at 3-year intervals from age 4 to 21 years, collecting longitudinal kinematic data in bare feet at a self-selected speed. The change in Gait Profile Score (ΔGPS) between each pair of gait analyses (intervals) was analyzed by age distribution (<10, 10-15, ≥15 years) and by presence/absence of orthopaedic surgery. The study included 31 children (GMFCS: I [13], II [14], III [4]). A baseline instrumented gait analysis was performed at age 5.8 ± 1.6 years with subsequent analysis at 2.5 ± 1.3-year intervals. Examining ΔGPS from baseline to final outcome, 87% of limbs were improved/unchanged; 298 intervals of ΔGPS were analyzed and classified as nonsurgical or surgical. Analysis revealed greater GPS improvement in intervals with surgery versus intervals without (p = 0.0004). Surgical intervals had significantly greater GPS improvement in the <10- vs. >15-year-old groups, p = 0.0063. Improvement in gait kinematics in children with CP is significantly influenced by age and timing of orthopaedic surgical intervention for gait correction, and was most pronounced for children <10 years old. Although surgery was associated with improved outcomes in all age groups, these improvements were significantly less for children >10 years old. These results reinforce the importance of considering the timing of orthopaedic surgery.