Reliability of an In-Shoe Pressure Measurement System During Treadmill Walking

1996 ◽  
Vol 17 (4) ◽  
pp. 204-209 ◽  
Author(s):  
T. W. Kernozek ◽  
E. E. LaMott ◽  
M. J. Dancisak
Keyword(s):  
Measurement System ◽  
Pressure Measurement ◽  
Peak Pressure ◽  
Measurement Techniques ◽  
Peak Force ◽  
Foot Pressure ◽  
Time Integral ◽  
Pressure Time ◽  
Force Time ◽  
Pressure Measurement System

We examined the reliability of in-shoe foot pressure measurement using the Pedar in-shoe pressure measurement system for 25 participants walking at treadmill speeds of 0.89, 1.12, and 1.34 meters/sec. The measurement system uses EMED insoles, which consist of 99 capacitive sensors, sampled at 50 Hz. Data were collected for 20 seconds at two separate times while participants walked at each gait speed. Differences in some of the loading variables across speed relative to the total foot and across the different anatomical regions were detected. Different anatomical regions of the foot were loaded differently with variations in walking speed. The results indicated the need to control speed when evaluating loading parameters using in-shoe pressure measurement techniques. Coefficients of reliability were calculated. Variables such as peak force for the total foot required two steps to achieve a coefficient of reliability of 0.98. To achieve excellent reliability (>0.90) in the peak force, force time integral, peak pressure, and pressure time integral across the total foot and the seven regions, a maximum of eight steps was needed. In general, timing variables, such as the instant of peak force and the instant of peak pressure, tended to be the least reliable measures.

The Plantar Loading Variations to Uphill and Downhill Gradients During Treadmill Walking

2000 ◽  
Vol 21 (3) ◽  
pp. 227-231 ◽  
Author(s):  
John Grampp ◽  
John Willson ◽  
Thomas Kernozek
Keyword(s):  
Measurement System ◽  
Pressure Measurement ◽  
Peak Pressure ◽  
Treadmill Walking ◽  
Peak Force ◽  
Capacitive Sensors ◽  
Gradient Condition ◽  
Pressure Measurement System

The purpose of the study was to examine the plantar loading changes during 5 gradient conditions on a treadmill (−15%, −8.5%, Level, 8.5%, 15%) for 20 participants using the Pedar® in-shoe pressure measurement system. The measurement system uses EMED insoles, each consisting of 99 capacitive sensors, sampled at 50 Hz. Data was collected from the last 20 seconds at each gradient condition while participants walked. As the treadmill gradient increased, loading (peak pressure [PP] and peak force [PF]) increased in the hallux and 1st metatarsal regions and decreased in the heel region. With negative gradients, loading (PP and PF) increased in the heel region and decreased in the 4th and 5th metatarsal regions.

The effects of increasing heel height on forefoot peak pressure

1999 ◽  
Vol 89 (2) ◽  
pp. 75-80 ◽  
Author(s):  
MG Mandato ◽  
E Nester
Keyword(s):  
Measurement System ◽  
Pressure Measurement ◽  
Peak Pressure ◽  
First Metatarsal ◽  
Heel Height ◽  
Peak Pressures ◽  
Pressure Measurement System

The purpose of this study was to determine the effect of increasing heel height on peak forefoot pressure. Thirty-five women were examined while wearing sneakers and shoes with 2-inch and 3-inch heels. An in-shoe pressure-measurement system was used to document the magnitude and location of plantar peak pressures. Pressure under the forefoot was found to increase significantly with increasing heel height. As the heel height increased, the peak pressure shifted toward the first metatarsal and the hallux. The reproducibility of data obtained with the in-shoe pressure-measurement system was tested in five subjects; the data were found to be reproducible to within approximately 3% of measured pressures.

scholarly journals Lower limb kinetic comparisons between the chasse step and one step footwork during stroke play in table tennis

PeerJ ◽  
2021 ◽  
Vol 9 ◽  
pp. e12481
Author(s):  
Yuqi He ◽  
Dong Sun ◽  
Xiaoyi Yang ◽  
Gusztáv Fekete ◽  
Julien S. Baker ◽  
...  
Keyword(s):  
Lower Limb ◽  
Peak Pressure ◽  
Table Tennis ◽  
Time Integral ◽  
Pressure Time ◽  
One Step ◽  
Force Time ◽  
The One ◽  
Plantar Force ◽  
Force Time Integral

Background Biomechanical footwork research during table tennis performance has been the subject of much interest players and exercise scientists. The purpose of this study was to investigate the lower limb kinetic characteristics of the chasse step and one step footwork during stroke play using traditional discrete analysis and one-dimensional statistical parameter mapping. Methods Twelve national level 1 table tennis players (Height: 172 ± 3.80 cm, Weight: 69 ± 6.22 kg, Age: 22 ± 1.66 years, Experience: 11 ± 1.71 year) from Ningbo University volunteered to participate in the study. The kinetic data of the dominant leg during the chasse step and one step backward phase (BP) and forward phase (FP) was recorded by instrumented insole systems and a force platform. Paired sample T tests were used to analyze maximum plantar force, peak pressure of each plantar region, the force time integral and the pressure time integral. For SPM analysis, the plantar force time series curves were marked as a 100% process. A paired-samples T-test in MATLAB was used to analyze differences in plantar force. Results One step produced a greater plantar force than the chasse step during 6.92–11.22% BP (P = 0.039). The chasse step produced a greater plantar force than one step during 53.47–99.01% BP (P < 0.001). During the FP, the chasse step showed a greater plantar force than the one step in 21.06–84.06% (P < 0.001). The one step produced a higher maximum plantar force in the BP (P = 0.032) and a lower maximum plantar force in the FP (P = 0) compared with the chasse step. The one step produced greater peak pressure in the medial rearfoot (P = 0) , lateral rearfoot (P = 0) and lateral forefoot (P = 0.042) regions than the chasse step during BP. In FP, the chasse step showed a greater peak pressure in the Toe (P = 0) than the one step. The one step had a lower force time integral (P = 0) and greater pressure time integral (P = 0) than the chasse step in BP, and the chasse step produced a greater force time integral (P = 0) and pressure time integral (P = 0.001) than the one step in the FP. Conclusion The findings indicate that athletes can enhance plantarflexion function resulting in greater weight transfer, facilitating a greater momentum during the 21.06–84.06% of FP. This is in addition to reducing the load on the dominant leg during landing by utilizing a buffering strategy. Further to this, consideration is needed to enhance the cushioning capacity of the sole heel and the stiffness of the toe area.

Increased In-Shoe Lateral Plantar Pressures with Chronic Ankle Instability

2011 ◽  
Vol 32 (11) ◽  
pp. 1075-1080 ◽  
Author(s):  
Heather Schmidt ◽  
Lindsay D. Sauer ◽  
Sae Yong Lee ◽  
Susan Saliba ◽  
Jay Hertel
Keyword(s):  
Plantar Pressure ◽  
Peak Pressure ◽  
Ankle Instability ◽  
Chronic Ankle Instability ◽  
Maximum Force ◽  
Pressure System ◽  
Time To Peak ◽  
Time Integral ◽  
Pressure Time ◽  
Force Time

Background: Previous plantar pressure research found increased loads and slower loading response on the lateral aspect of the foot during gait with chronic ankle instability compared to healthy controls. The studies had subjects walking barefoot over a pressure mat and results have not been confirmed with an in-shoe plantar pressure system. Our purpose was to report in-shoe plantar pressure measures for chronic ankle instability subjects compared to healthy controls. Methods: Forty-nine subjects volunteered (25 healthy controls, 24 chronic ankle instability) for this case-control study. Subjects jogged continuously on a treadmill at 2.68 m/s (6.0 mph) while three trials of ten consecutive steps were recorded. Peak pressure, time-to-peak pressure, pressure-time integral, maximum force, time-to-maximum force, and force-time integral were assessed in nine regions of the foot with the Pedar-x in-shoe plantar pressure system (Novel, Munich, Germany). Results: Chronic ankle instability subjects demonstrated a slower loading response in the lateral rearfoot indicated by a longer time-to-peak pressure (16.5% ± 10.1, p = 0.001) and time-to-maximum force (16.8% ± 11.3, p = 0.001) compared to controls (6.5% ± 3.7 and 6.6% ± 5.5, respectively). In the lateral midfoot, ankle instability subjects demonstrated significantly greater maximum force (318.8 N ± 174.5, p = 0.008) and peak pressure (211.4 kPa ± 57.7, p = 0.008) compared to controls (191.6 N ± 74.5 and 161.3 kPa ± 54.7). Additionally, ankle instability subjects demonstrated significantly higher force-time integral (44.1 N/s ± 27.3, p = 0.005) and pressure-time integral (35.0 kPa/s ± 12.0, p = 0.005) compared to controls (23.3 N/s ± 10.9 and 24.5 kPa/s ± 9.5). In the lateral forefoot, ankle instability subjects demonstrated significantly greater maximum force (239.9N ± 81.2, p = 0.004), force-time integral (37.0 N/s ± 14.9, p = 0.003), and time-to-peak pressure (51.1% ± 10.9, p = 0.007) compared to controls (170.6 N ± 49.3, 24.3 N/s ± 7.2 and 43.8% ± 4.3). Conclusion: Using an in-shoe plantar pressure system, chronic ankle instability subjects had greater plantar pressures and forces in the lateral foot compared to controls during jogging. Clinical Relevance: These findings may have implications in the etiology and treatment of chronic ankle instability. Level of Evidence: III, Retrospective Case Control Study

scholarly journals Effects of walking speed and slope on foot pressure in young healthy adults

2018 ◽  
Vol 3 (3) ◽  
pp. 2473011418S0030
Author(s):  
Kyoung Min Lee ◽  
Byung-Cho Min ◽  
Seungbum Koo
Keyword(s):  
Walking Speed ◽  
Peak Pressure ◽  
Healthy Adults ◽  
Basic Sciences ◽  
Foot Pressure ◽  
Time Integral ◽  
Pressure Time ◽  
Downhill Walking ◽  
Walking Speeds ◽  
Uphill Walking

Category: Basic Sciences/Biologics Introduction/Purpose: Although pedobarographic measurement is increasingly used for clinical and research purposes, relatively few published studies have investigated regarding effects of walking speed and slope. This study examined pedobarographic findings in young healthy adults with regard to different walking speeds and slopes. Methods: Twenty young healthy adults (mean age 22.4 years, SD 1.2 years; 10 males and 10 females) were recruited. Dynamic pedobarographic data were obtained during treadmill walking with different walking speeds (3.2 km/hr, 4.3 km/hr, and 5.4 km/hr) and slopes (-8°, -4°, 0°, 4°, and 8°). Pedobarographic data including peak pressure and pressure-time integral were measured on five plantar segments: medial forefoot (MFF), lateral forefoot (LFF), medial midfoot (MMF), lateral midfoot (LMF), and heel. Distribution of foot pressure between medial and lateral sides, and between anterior and posterior aspects were calculated as varus/valgus index and forefoot/heel index, respectively. Walking speed of 4.3 km/hr on 0° of slope was considered as standard walking condition. Results: Varus/valgus index of peak pressure showed significant increase on the slope of 8° and the walking speed of 4.3 km/hr (p=0.036) and 5.4 km/hr (p=0.007). Forefoot/heel index of peak pressure significantly decreased on downhill walking. Varus/valgus index of pressure-time integral showed significant increase when uphill and downhill slope was greater and walking speed was faster compared with standard with walking condition. Forefoot/heel index of pressure-time integral showed significant increase in downhill walking while significant decrease was observed during uphill walking. Conclusion: Changes of walking speed and slope caused those of foot pressure distribution. Therefore, combination of walking speed and speed might be associated with pressure related symptoms and disorders of the foot.

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