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Journal Articles
Journal:
Journal of Biomechanical Engineering
Publisher: ASME
Article Type: Research-Article
J Biomech Eng. February 2025, 147(2): 021001.
Paper No: BIO-24-1005
Published Online: November 27, 2024
Journal Articles
Journal:
Journal of Biomechanical Engineering
Publisher: ASME
Article Type: Research-Article
J Biomech Eng. February 2025, 147(2): 021003.
Paper No: BIO-24-1173
Published Online: November 27, 2024
Topics:
Kinematics,
Knee,
Materials handling,
Modeling,
Musculoskeletal system,
Performance,
Shear (Mechanics),
Stress,
Compression,
Risk assessment
Includes: Supplementary data
Journal Articles
Journal:
Journal of Biomechanical Engineering
Publisher: ASME
Article Type: Research-Article
J Biomech Eng. February 2025, 147(2): 021002.
Paper No: BIO-24-1054
Published Online: November 27, 2024
Journal Articles
Andrew Seamone, Jeremy N. Shapiro, Zhenyang Zhao, Vinay K. Aakalu, Anthony M. Waas, Christine Nelson
Journal:
Journal of Biomechanical Engineering
Publisher: ASME
Article Type: Technical Briefs
J Biomech Eng. January 2025, 147(1): 014503.
Paper No: BIO-24-1078
Published Online: November 27, 2024
Journal Articles
Journal:
Journal of Biomechanical Engineering
Publisher: ASME
Article Type: Research-Article
J Biomech Eng. January 2025, 147(1): 011010.
Paper No: BIO-23-1401
Published Online: November 27, 2024
Image
in Electro-Osmotic Mechanism of Ellis Fluid With Joule Heating, Viscous Dissipation, and Magnetic Field Effects in a Pumping Microtube
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 1 Flow regime More about this image found in Flow regime
Image
in Electro-Osmotic Mechanism of Ellis Fluid With Joule Heating, Viscous Dissipation, and Magnetic Field Effects in a Pumping Microtube
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 2 Comparison of nondimensional axial velocity field u of Goud et al. [ 31 ] with the present numerical analysis More about this image found in Comparison of nondimensional axial velocity field u of Goud et al. [ ...
Image
in Electro-Osmotic Mechanism of Ellis Fluid With Joule Heating, Viscous Dissipation, and Magnetic Field Effects in a Pumping Microtube
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 3 Effects of ( a ) m e , ( b ) H a , ( c ) β e , and ( d ) α , on velocity distribution u More about this image found in Effects of ( a ) m e , ( b ) H a , (...
Image
in Electro-Osmotic Mechanism of Ellis Fluid With Joule Heating, Viscous Dissipation, and Magnetic Field Effects in a Pumping Microtube
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 4 Effects of ( a ) m e , ( b ) H a , ( c ) β e , ( d ) α , ( e ) γ , and ( f ) Br , on temperature field θ More about this image found in Effects of ( a ) m e , ( b ) H a , (...
Image
in Electro-Osmotic Mechanism of Ellis Fluid With Joule Heating, Viscous Dissipation, and Magnetic Field Effects in a Pumping Microtube
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 5 Effects of ( a ) m e , ( b ) H a , ( c ) β e , ( d ) α , ( e ) γ , and ( f ) Br , on heat transfer coefficient Z t More about this image found in Effects of ( a ) m e , ( b ) H a , (...
Image
in Electro-Osmotic Mechanism of Ellis Fluid With Joule Heating, Viscous Dissipation, and Magnetic Field Effects in a Pumping Microtube
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 6 Effects of ( a ) m e , ( b ) H a , ( c ) β e , and ( d ) α , on skin friction coefficient C F More about this image found in Effects of ( a ) m e , ( b ) H a , (...
Image
in Electro-Osmotic Mechanism of Ellis Fluid With Joule Heating, Viscous Dissipation, and Magnetic Field Effects in a Pumping Microtube
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 7 Streamline distribution for ( a ) m e → 0.0 , ( b ) m e = 2 , and ( c ) m e = 5 at x = π , α = 0.1 , β e = 1 , Ha = 1.2 More about this image found in Streamline distribution for ( a ) m e → 0.0 , ...
Image
in Eyelid Motion Tracking During Blinking Using High-Speed Imaging and Digital Image Correlation
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 1 Schematic of the experimental setup: ( a ) top view schematic of the test setup, ( b ) side view schematic of the test setup, and ( c ) calibration image containing reference scale More about this image found in Schematic of the experimental setup: ( a ) top view schematic of the test s...
Image
in Eyelid Motion Tracking During Blinking Using High-Speed Imaging and Digital Image Correlation
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 2 Representative images of DIC facet tracking during eyelid closure at: ( a ) eye open ( t = 0.000 s), ( b ) eye closing ( t = 0.020 s), ( c ) eye closing ( t = 0.040 s), ( d ) eye closing ( t = 0.060 s), ( e ) eye closing (t = 0.080 s), and ( f ) eye closed ( t = 0.100 s) More about this image found in Representative images of DIC facet tracking during eyelid closure at: ( a )...
Image
in Eyelid Motion Tracking During Blinking Using High-Speed Imaging and Digital Image Correlation
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 3 Representative displacement and velocity data from one participant for one spontaneous and one reflex blink. Three facets are displayed in each subplot. Dashed lines represent time before and after the blink, the solid portion represents the time during the blink. ( a ) Spontaneous blink, v... More about this image found in Representative displacement and velocity data from one participant for one ...
Image
in Eyelid Motion Tracking During Blinking Using High-Speed Imaging and Digital Image Correlation
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 4 Horizontal and vertical displacements for spontaneous and reflex blinks. The dashed lines indicate the mean displacement for each type of blink. The error bars represent one standard deviation based on the four measurements for each participant. ( a ) Horizontal displacements and ( b ) vert... More about this image found in Horizontal and vertical displacements for spontaneous and reflex blinks. Th...
Image
in Eyelid Motion Tracking During Blinking Using High-Speed Imaging and Digital Image Correlation
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 5 Spontaneous and reflex blink duration for each participant. The dashed lines indicate the mean blink duration for each type of blink. The error bars represent one standard deviation based on the four measurements for each participant. More about this image found in Spontaneous and reflex blink duration for each participant. The dashed line...
Image
in Eyelid Motion Tracking During Blinking Using High-Speed Imaging and Digital Image Correlation
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 6 Maximum horizontal and vertical velocities for both blink types. The dashed lines indicate the mean blink duration for each type of blink. The error bars represent one standard deviation based on the four measurements for each participant. ( a ) Peak horizontal (X) velocity during eyelid cl... More about this image found in Maximum horizontal and vertical velocities for both blink types. The dashed...
Image
in Eyelid Motion Tracking During Blinking Using High-Speed Imaging and Digital Image Correlation
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 7 Facet path for three representative spontaneous and reflex blinks. The solid lines represent facet movement during eyelid closure and the dashed lines represent the facet movement returning to its initial position. Blue-toned lines represent spontaneous blinks for one participant and pink-t... More about this image found in Facet path for three representative spontaneous and reflex blinks. The soli...
Image
in Estimation of Joint Kinetics During Manual Material Handling Using Inertial Motion Capture: A Follow-Up Study
> Journal of Biomechanical Engineering
Published Online: November 27, 2024
Fig. 1 Illustration of the musculoskeletal models based on inertial motion capture with predicted ground reaction forces (top) and optical motion capture with measured ground reaction forces (bottom) More about this image found in Illustration of the musculoskeletal models based on inertial motion capture...
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