Running Shoes Research Articles

Running shoes and running injuries: mythbusting and a proposal for two new paradigms: ‘preferred movement path’ and ‘comfort filter’

In the past 100 years, running shoes experienced dramatic changes. The question then arises whether or not running shoes (or sport shoes in general) influence the frequency of running injuries...

Variation in Foot Strike Patterns among Habitually Barefoot and Shod Runners in Kenya.

Runners are often categorized as forefoot, midfoot or rearfoot strikers, but how much and why do individuals vary in foot strike patterns when running on level terrain? This study used general linear mixed-effects models to explore both intra- and inter-individual variations in foot strike pattern among 48 Kalenjin-speaking participants from Kenya who varied in age, sex, body mass, height, running history, and habitual use of footwear. High speed video was used to measure lower extremity kinematics at ground contact in the sagittal plane while participants ran down 13 meter-long tracks with three variables independently controlled: speed, track stiffness, and step frequency. 72% of the habitually barefoot and 32% of the habitually shod participants used multiple strike types, with significantly higher levels of foot strike variation among individuals who ran less frequently and who used lower step frequencies. There was no effect of sex, age, height or weight on foot strike angle, but individuals were more likely to midfoot or forefoot strike when they ran on a stiff surface, had a high preferred stride frequency, were habitually barefoot, and had more experience running. It is hypothesized that strike type variation during running, including a more frequent use of forefoot and midfoot strikes, used to be greater before the introduction of cushioned shoes and paved surfaces.

A New View of Responses to First-Time Barefoot Running

We examined acute alterations in gait and oxygen cost from shod-to-barefoot running in habitually-shod well-trained runners with no prior experience of running barefoot. Thirteen runners completed six-minute treadmill runs shod and barefoot on separate days at a mean speed of 12.5 km·h-1. Steady-state oxygen cost in the final minute was recorded. Kinematic data were captured from 30-consecutive strides. Mean differences between conditions were estimated with 90% confidence intervals. When barefoot, stride length and ground-contact time decreased while stride rate increased. Leg-and vertical stiffness and ankle-mid-stance dorsi-flexion angle increased when barefoot while horizontal distance between point of contact and the hip decreased. Mean oxygen cost decreased in barefoot compared to shod running (90% CI -11% to -3%) and was related to change in ankle angle and point-of-contact distance, though individual variability was high (-19% to +8%). The results suggest that removal of shoes produces an alteration in running gait and a potentially-practically-beneficial reduction in mean oxygen cost of running in trained-habitually-shod runners new to running barefoot. However, high variability suggests an element of skill in adapting to the novel task and that caution be exercised in assuming the mean response applies to all runners.

Multi-segmental foot modelling during shod activity: study of running shoe integrity

Introduction Multi-segmental foot modelling (MSFM) during shod activity has the potential to enhance our understanding of how footwear influences foot motion. Recent work by Bishop et al. (2015) and Shultz & Jenkyn (2012) has validated the incision parameters to accommodate surface mounted markers for two alternative MSFMs, requiring 7 and 5 incisions respectively, within the shoe. These MSFMs have been sparsely used in contrast to 3DFoot model (Leardini et al. 2007) which would require 10 incisions and has not been used previously to assess in-shoe foot motion. Purpose of the study To determine the influence of incisions to accommodate Jenkyn and Nicol (JN) and 3DFoot MSFMs upon the structural integrity of neutral running shoes. Methods Two procedures were applied to assess shoe deformation. A) Eight males (30±8yrs, 1.78±0.05m, 84±7kg) completed 2 testing sessions. Participants ran at a self-selected pace (3±0.5m.s-1) in standard ASICS running shoes. Baseline shoe deformation data was collected during the first session. Prior to session 2, 25mm incisions were made to accommodate MSFMs: 3DFoot (left shoe) and JN (right shoe). Kinematic data were recorded using a 3D motion analysis system (VICON, Oxford, England) at 200Hz. Three retro-reflective markers (Figure 1) were used to measure as shoe distance and shoe angle at initial contact (IC), heel rise (HR) and toe off (TO). Shoe deformation measures were compared using paired t-tests. B) Material strain of the shoe upper was assessed in 1 male participant (26yrs, 1.80m, 80kgs) using ARAMIS optical system. Material strain patterns were compared between intact and cut conditions using Trend symmetry (TS) analysis (Crenshaw & Richards, 2006). Here Figure 1. Results No significant differences (p > 0.05) in shoe distance were recorded between intact and cut conditions but significant differences (p < 0.05) were reported in shoe angle at all three events of running gait (Table 1). Material strain assessment showed lower TS scores for the lateral aspect of the shoe (TS = 0.81 ± 0.11) than the medial aspect (TS = 0.89 ± 0.12). Symmetry was greater between the intact and JN shoe (TS= 0.88 ± 0.10) than the intact and 3DFoot shoe (TS = 0.82 ± 0.13). Here Table 1. Discussion and Conclusion Analysis of kinematic shoe deformation measures revealed individual responses to incisions made within the upper of a running shoe to accommodate MSFMs. Significant (p < 0.05) changes in shoe angles were noted between the intact and cut conditions at IC and TO for the JN incisions and HR for the 3DFoot incisions. However, while the changes in shoe angle were significant, the mean difference was small (≤ 5°). This value is lower than the minimal important difference proposed by Nester et al. (2007) for comparison of gait kinematics. Thus, it may be argued that the differences in shoes angles between intact and cut conditions were negligible and the results support the use of either MSFM to assess shod foot motion. While the use of kinematic measures to infer the shoes structural integrity have been used previously (Shultz and Jenkyn, 2012), no validation of these measure has been undertaken. The small and non-systematic findings reported in both this study and that of Shultz and Jenkyn (2012), particularly for shoe distance measures; question the sensitivity of kinematic shoe deformation measures to detect changes in structural integrity. Material strain analysis was used to further explore area specific alterations in the running shoes structural integrity from the different incision sets. The material strain analysis supported the use of the JN foot model to assess in-shoe foot kinematics, due to higher symmetry scores and smaller mean differences between the intact and JN shoes. Further exploration of additional means of assessing the influence of incisions to accommodate MSFM upon the shoes structural integrity is warranted. References Bishop, C. et al. (2015). Gait Posture, 41 (1), 295-299. Crenshaw, S. and Richards, J. (2006) Gait Posture, 24 (4), 515-521. Jenkyn, T. and Nicol, A. (2007). J Biomech, 40 (14), 3271-3278. Leardini, A. et al. (2007). Gait Posture, 25 (3), 453-462. Nester, C. et al. (2007). J Biomech, 40 (15), 3412-3423. Shultz, R. and Jenkyn, T. (2012). Med Eng Phys, 34 (1), 118-122.

Influence of barefoot and shod running on limb and joint stiffness characteristics during running

Influence of barefoot and shod running on limb and joint stiffness characteristics during running Jonathan Sinclair, Stephen Atkins & Paul John Taylor a University of Central Lancashire, Centre for Applied Sport and Exercise Science, Preston, United Kingdom b University of Central Lancashire, Centre for Applied Sport and Exercise Science, Preston, United Kingdom c University of Central Lancashire, School of Psychology, Preston, United Kingdom Published online: 18 Jun 2015.

Plantar pressure and foot roll-off timing during walking barefoot, in a minimal shoe, and in conventional footwear

The effect on gait dynamics of barefoot versus shod running has been well established, and differences in foot strike and kinetics as an effect of barefoot vs. shod running, and of running with dif...

Patellofemoral kinetics during running in heelless and conventional running shoes

Recreational running is a popular recreational activity often used to improve health and well-being of the participants. Sustaining injuries that stop people from running can therefore be detrimental. One of the most prevalent overuse injuries in recreational running populations (Chang et al., 2012; Ellapen et al., 2013) has been reported as patellofemoral pain which is a result of the pressure experienced between the posterior surface of the patella and the anterior distal aspect of the femur. Footwear designers have attempted to develop shoes to reduce rate of injuries in populations. One such design is a heelless shoe that appears to adjust the footstrike pattern of the participant during running (Sinclair et al., 2014). Such adaptation to movement may influence knee joint kinetics and kinematics altering the pressure between the patella and the femur.

Ground reaction forces in forefoot strike runners wearing minimalist shoes during hill running

Forefoot strike (FFS) running is primarily seen when wearing minimalist running shoes or running barefoot. One of the distinct characteristics in FFS is an absent impact transient in the ground rea...

Individual-specific determinants of successful adaptation to minimal and maximal running shoes

Minimalist shoes have been touted as a panacea for preventing running-related injuries, although evidence is inconclusive (Ryan, Elashi, Newsham-West, & Taunton, 2014). Maximalist shoes, with great...

Effects of footwear designed to boost energy return on running economy compared to traditional running shoes

Running economy is considered as a principal determining factor of running performance. Athletic footwear has been advocated as a mechanism by which running economy can be enhanced (Frederick, Howl...

Effects of minimalist and traditional running shoes on injury rates: a pilot randomised controlled trial

Despite recent advances in running shoe conception, injuries represent a major concern in the running community. The objective of this study was to gather the pilot data for a larger randomised controlled trial regarding the effects of traditional and minimalist shoes on the incidence of running-related injuries (RRI), as well as the rate of adherence to a running programme. Twenty-six recreational runners were recruited. They were randomly assigned to minimalist (MS) or traditional (TS) shoes and participated in a 16-week training programme. The information on previously reported risk factors for RRI was gathered. Participants reported pain and compliance using an online tool. Main outcome measures included the rates of recruitment, adherence to the programme and programme completion, RRI and the missed training days secondary to the running-related pain. The recruited runners represented 72.2% of potential participants, among which 20 (76.9%) completed the programme. Two subjects dropped out before randomisation, plus three in MS and one in TS during the programme. Rate of adherence was 82.4% in MS and 86.2% in TS. Three runners per group sustained an RRI (25%, 95% C.I. = 9.8%–46.7%). Results support the feasibility of a larger scale study. A total of 116 runners would be needed to detect a clinically significant difference of 20% in injury incidence between MS and TS.

Eight weeks gait retraining in minimalist footwear has no effect on running economy

PurposeTo evaluate the effects of an eight week combined minimalist footwear (MFW) and gait-retraining intervention on running economy (RE) and kinematics in conventional footwear runners. MethodsTwenty-three trained male runners (age: 43±10years, stature: 177.2±9.2cm, body mass: 72.8±10.2kg, V̇O2max: 56.5±7.0mLmin−1kg−1) were recruited. Participants were assigned to either an intervention group (n=13) who gradually increased exposure to MFW and also implemented gait-retraining over an eight week period. RE and kinematics were measured in both MFW and conventional running shoes (CRS) at pre-tests and eight weeks, in a random order. In contrast the control group (n=10) had no MFW exposure or gait retraining and were only tested in CRS. ResultsThe MFW and gait re-training intervention had no effect on RE (p<.001). However, RE was significantly better in MFW (mean difference 2.72%; p=.002) at both pre and post-tests compared to CRS. Step frequency increased as a result of the intervention (+5.7 steps per minute [spm]; p<.001), and was also significantly higher in MFW vs. CRS (+7.5spm; p<.001). ConclusionWhilst a better RE in MFW was observed when compared to CRS due to shoe mass, familiarization to MFW with gait-retraining was not found to influence RE.

Comparison of minimalist footwear strategies for simulating barefoot running: a randomized crossover study.

Possible benefits of barefoot running have been widely discussed in recent years. Uncertainty exists about which footwear strategy adequately simulates barefoot running kinematics. The objective of this study was to investigate the effects of athletic footwear with different minimalist strategies on running kinematics. Thirty-five distance runners (22 males, 13 females, 27.9 ± 6.2 years, 179.2 ± 8.4 cm, 73.4 ± 12.1 kg, 24.9 ± 10.9 km.week-1) performed a treadmill protocol at three running velocities (2.22, 2.78 and 3.33 m.s-1) using four footwear conditions: barefoot, uncushioned minimalist shoes, cushioned minimalist shoes, and standard running shoes. 3D kinematic analysis was performed to determine ankle and knee angles at initial foot-ground contact, rate of rear-foot strikes, stride frequency and step length. Ankle angle at foot strike, step length and stride frequency were significantly influenced by footwear conditions (p<0.001) at all running velocities. Posthoc pairwise comparisons showed significant differences (p<0.001) between running barefoot and all shod situations as well as between the uncushioned minimalistic shoe and both cushioned shoe conditions. The rate of rear-foot strikes was lowest during barefoot running (58.6% at 3.33 m.s-1), followed by running with uncushioned minimalist shoes (62.9%), cushioned minimalist (88.6%) and standard shoes (94.3%). Aside from showing the influence of shod conditions on running kinematics, this study helps to elucidate differences between footwear marked as minimalist shoes and their ability to mimic barefoot running adequately. These findings have implications on the use of footwear applied in future research debating the topic of barefoot or minimalist shoe running.

The Effects of Barefoot and Shod Running on Limb and Joint Stiffness Characteristics in Recreational Runners

ABSTRACTThe authors aimed to determine the effects of barefoot (BF) and several commercially available barefoot-inspired (BFIS) footwear models on limb and joint stiffness characteristics compared with conventional footwear (CF). Fifteen male participants ran over a force platform at 4.0 m.s−1, in BF, BFIS, and CF conditions. Measures of limb and joint stiffness were calculated for each footwear. The results indicate that limb and knee stiffness were greater in BF and minimalist BFIS than in CF. CF and more structured BFIS were associated with a greater ankle stiffness compared with BF and minimalist BFIS. These findings serve to provide further insight into the susceptibility of runners to different injury mechanisms as a function of footwear.

The minimalist index is a valid and reliable tool for rating running shoes

Background:Minimalist running shoes is a popular topic among physical therapists with regards to biomechanics and injury prevention. Recently, an expert consensus created a new rating scale, the Minimalist Index (MI), which aims at scoring the degree of minimalism of a given shoe. The MI considers five subscales judged by the experts to be important to differentiate between levels of minimalism: (1) weight, (2) stack height, (3) heel to toe drop, (4) technologies, and (5) flexibility. Although such rating scale is needed to improve clinical recommendations, its validity and reliability need to be established. Purpose: To evaluate the validity, and the inter-rater and intra-rater reliability of the MI. Methods: Eighty-five researchers (health or sport sciences), physicians or allied health professionals or specialized running shoe retailers with a minimum of one-year experience in running shoe recommendations were recruited. They all took part in a testing session during which the evaluation of the validity and inter-rater reliability of the MI was assessed. Theywere randomly assigned tofive differentmodels of running shoes (for a total of 10different types of running shoes, 17 to 24 evaluators for each group). They first had to rank (0 to 5) their five assigned shoe models from the most minimalist to the least minimalist. Thereafter, they had to evaluate their five shoes models using the MI. Thirty of the recruited participants also tookpart in a second testing session (intra-rater reliability, test-retest interval of 2 to 14 days) during which they had to rate for a second time the same five shoes. Discriminative validity of the MI was evaluated using one-way ANOVA by comparing the mean scores on the MI according to their rank (1 to 5). Interand intra-rater reliability of the total score of the MI was determined for each type of running shoes using intraclass correlation coefficients (ICC), while Gwet’s AC1 indices with quadratic weighting were used to determine the reliability of the MI’s subscales. Results: One-way ANOVA analysis showed significant rank x score interaction (P< 0.001) with significant Bonferroni adjustments between all ranks (P< 0.001), showing that the MI can discriminate the shoe models according to their ranking. Excellent inter-rater reliability was found for total MI score for each shoe model (ICC= 0.99–1.00, P< 0.001) as well as for weight, stack height, heel to toe drop and flexibility subscales (AC1= 0.82–0.99, P< 0.001). Analyses yielded good inter-rater reliability for the technologies subscale (AC1= 0.73, P< 0.001). As for intra-rater, excellent reliability was found for total score (ICC= 0.99, P< 0.001) and for the five subscales (AC1= 0.88–0.99, P< 0.001). Conclusion(s):These results suggest that theMI is a valid and highly reliable tool to evaluate the degree of minimalism of running shoes. For both intra-rater and inter-rater, total score was found to have excellent reliability, with each subscale showing good to excellent reliability. Implications: The MI can be used by physical therapists to recommend adequate footwear to runners and proper transition time between different models in order to minimize injury risk.

Effect of Highly Cushioned Shoes on Ground Reaction Forces during Running

In contrast to the recent trend of minimal footwear, highly cushioned running shoes have begun to emerge on the market. These shoes are designed with a very thick midsole, with claims that they reduce the impact of landing. However, the effect of these shoes on impacts has not been examined. PURPOSE: To compare the ground reaction forces during running in the highly cushioned (HC) and traditional (TR) running shoes. METHODS: 5 healthy male runners (age 33.7 ± 13.6), who run a minimum of 10 mpw in TR running shoes, have been recruited in this ongoing study. All subjects underwent an instrumented treadmill analysis, first with a neutral, TR shoe and then with a HC shoe. Subjects ran at a self-selected speed (range 2.46 - 2.91 m/s), which remained constant across conditions. Variables associated with impact were assessed to include, vertical impact peak (VIP), instantaneous (VILR) and average (VALR) load rate, peak lateral force (PLF) and peak medial force (PMF). Additionally, peak vertical force (PVF) was assessed. All force values were normalized to body weight. Mean and percent differences were calculated. A statistical analysis will be performed when all subjects have been recruited and tested. RESULTS: Rather than lower impact forces, running in highly cushioned shoes resulted in similar VIP and VILR, PMF and PVF. VALR was actually higher in the HC shoes and this variable has been linked with injuries. PLF was lower in the HC shoes, which may result in a reduction of the pronatory moment on the foot. CONCLUSION: Based on these very preliminary results, with the exception of PLF, ground reaction force variables were not lowered by running in a HC shoe. These results will be re-examined when additional subjects are added.Table: No title available.

Biomechanics of Running with a Commercially Available Non-Custom Athletic Footwear Insole

A commercially available non-custom athletic footwear (AF) insole has recently been developed and is claimed to help prevent and treat running injuries such as patellofemoral pain syndrome (PFPS), plantar faciitis (PF), and tibial stress syndrome (TSS); however, no data are available to support whether these insoles influence biomechanical variables associated with these injuries. PURPOSE: To determine if the AF insole alters biomechanical variables associated with PFPS, PF and TSS. METHODS: Fifteen uninjured participants completed 5 trials running at 4m/s along a 30m runway with each of two conditions: (1) their own running shoe, control (CON), and (2) #1 with the AF insole placed within the shoe. As participants ran, 3D trajectories of the participant’s right lower leg and foot, and 3D ground reaction force data were recorded. Kinetic and kinematic data were used to calculate the following biomechanical variables: (1) knee abduction angular impulse during stance phase (associated with PFPS), (2) peak foot eversion angle during stance phase (associated with PF and TSS), and (3) peak foot eversion velocity during stance (associated with TSS). Two-tailed paired-samples t-tests were used to compare the CON and AF insole conditions. RESULTS: No significant differences were observed between the CON and AF insole conditions for knee abduction angular impulses (CON: 10.3±5.4 Nms, AF insole: 9.6±4.7 Nms, p=0.26), peak foot eversion angles (CON: 11.1±4.5 deg, AF insole: 10.8±4.3 deg, p=0.64) or peak foot eversion velocities (CON: 378±108 deg/s, AF insole: 408±122 deg/s, p=0.06). However, individually, many participants (7/15 for knee abduction angular impulse, 11/15 for peak foot eversion and eversion velocity) experienced relevant biomechanical changes of ± 10% or more with the AF insole. CONCLUSIONS: AF insoles have an influence on biomechanical variables associated with PFPS, PF or TSS for individual runners; however, their influence is not systematic across participants. Consequently, the AF insoles may offer benefit to some runners, but be detrimental to others.

Comparison of Self-Selected Pace and Heart Rate Response in Barefoot vs Shod Running

Interest in the fitness trend of barefoot (BF) running has increased in recent years. While it has been demonstrated that the oxygen cost of running increases about 1% for each 100 gram increase in running shoe weight, it is not yet known how this will affect the self-selected pace (SSP) and heart rate (HR) response of BF running during recreational activity of traditionally shod (SH) subjects. PURPOSE: To determine the SSP and HR response to BF vs SH running on a rubberized 200 meter indoor track in recreationally active young adults. METHODS: Seventy-three college age students (45% males) were asked to run for eight minutes at a SSP one time wearing and one time not wearing running shoes in a randomized order. Running time and HR were recorded at the completion of each 200 meter lap as well as the total distance covered in meters at the end of the eight minute runs. Polar HR monitors were used to measure HR. Running pace was calculated as total distance in meters divided by total time in minutes. RESULTS: The SSP chosen by subjects was identical in the BF and SH condition (172 meters/minute). There was a trend toward higher mean HR response in the BF (169.7 ± 1.7) vs S (167.1 ± 1.8) conditions (p=0.08) at the same SSP. CONCLUSION: Based on the previously reported reduction in oxygen cost associated with reduced running shoe weight and the established positive relationship HR and running speed have with the oxygen cost of activity, our hypothesis that either the SSP would increase or the HR at a similar pace would be attenuated in BF running was not supported. Possible explanations for this might include the novelty of BF running in our subjects, adjustments in running mechanics, and heightened sensory feedback.

The Effect of Footwear on Acute, Static and Dynamic Balance

It is common belief that Zero Drop (ZD) shoes and minimalist (MN) shoes provide users with better stability than do traditional (TR) shoes due to the attempt to mimic barefoot (BF). Testing the dynamic and static balance in each type of shoe, gives further insight into whether ZD and/or MN shoes provide additional balance during activities. Balance is very important in movement, being able to increase balance just by wearing the correct shoe could be advantageous. PURPOSE: To examine static and dynamic balance between the different types of running shoes. METHODS: Participants include 14 males and 13 females with and average age of 24.3 years old. They were recruited by word of mouth and volunteered for the study. Participants first completed a consent form and questionnaire approved by UVU-IRB then participated in the 8 trials. The 8 trials were performed on a BioDex SD Balancing System and consisted of performing two sets of static balancing for 20 seconds for the first trial, then repeated with a dynamic set of balancing. This was repeated using the following conditions; TR, ZD, MN, and BF performed in a randomized order. The two trials were averaged for the analysis. Repeated measures ANOVA (α=0.05) was used to analyze the data. RESULTS: Overall static balance was only significantly different between (TR and BF, p=.033), with anterior/posterior balance being significant between (TR and BF p=.042; TR and MN p=.017). During the dynamic condition there was no difference in the medial/lateral in all trials and conditions. There was no significant differences between any of the static trials. CONCLUSION: Due to the raised heel of traditional running shoes, the postural stability and balance is compromised. The thickness of the sole seems to be less of an important factor as the results from ZD and MN shoes showed no significant difference, however both shoes results in better balance than TN shoes, this trend would suggest that there is a move towards greater balance with the zero-drop philosophy. While this study recommends barefoot positioning provides better stability, more research is needed to address Zero Drop and minimalist shoes.

Kinetic Asymmetry Between New and Worn Running Shoes

Kinetic Asymmetry Between New and Worn Running Shoes