Movement of skin markers with respect to their underlying bone (i.e. soft tissue artifacts (STAs)) might corrupt the accuracy of marker-based movement analyses. This study aims to quantify STAs in 3D for foot markers and their effect on multi-segment foot kinematics as calculated by the Oxford and Rizzoli Foot Models (OFM, RFM). Fifteen subjects with asymptomatic feet were seated on a custom-made loading device on a computed tomography (CT) table, with a combined OFM and RFM marker set on their right foot. One unloaded reference CT-scan with neutral foot position was performed, followed by 9 loaded CT-scans at different foot positions. The 3D-displacement (i.e. STA) of each marker in the underlying bone coordinate system between the referen...
Musculoskeletal models used in gait analysis require coordinate systems to be identified for the bod...
Accurately measuring of intrinsic foot kinematics using skin mounted markers is difficult, limited i...
When using optoelectronic stereophotogrammetry, skin deformation and displacement causes marker move...
Movement of skin markers with respect to their underlying bone (i.e. soft tissue artifacts (STAs)) m...
Segment poses and joint kinematics estimated from skin markers are highly affected by soft tissue ar...
Background and Rationale: Multi-segment foot models allow measurement of the movement (kinematics) o...
The soft-tissue interface between skin-mounted markers and the underlying bones poses a major limita...
The human feet are essential for our unique way of bipedal locomotion. A dysfunctional foot limits o...
Background: Foot and ankle joint kinematics are measured during clinical gait analyses with marker-b...
The estimation of joint kinematics from skin markers is hindered by the soft tissue artefact (STA), ...
Soft tissue artifact (STA) is the main source of error in kinematic estimation of human movements ba...
Understanding the effect of individual marker misplacements is important to improve the repeatabilit...
Soft tissue artifact (STA) has been identified as the most critical source of error in clinical gait...
Accurate measurement of underlying bone positions is important for the understanding of normal movem...
Musculoskeletal models used in gait analysis require coordinate systems to be identified for the bod...
Accurately measuring of intrinsic foot kinematics using skin mounted markers is difficult, limited i...
When using optoelectronic stereophotogrammetry, skin deformation and displacement causes marker move...
Movement of skin markers with respect to their underlying bone (i.e. soft tissue artifacts (STAs)) m...
Segment poses and joint kinematics estimated from skin markers are highly affected by soft tissue ar...
Background and Rationale: Multi-segment foot models allow measurement of the movement (kinematics) o...
The soft-tissue interface between skin-mounted markers and the underlying bones poses a major limita...
The human feet are essential for our unique way of bipedal locomotion. A dysfunctional foot limits o...
Background: Foot and ankle joint kinematics are measured during clinical gait analyses with marker-b...
The estimation of joint kinematics from skin markers is hindered by the soft tissue artefact (STA), ...
Soft tissue artifact (STA) is the main source of error in kinematic estimation of human movements ba...
Understanding the effect of individual marker misplacements is important to improve the repeatabilit...
Soft tissue artifact (STA) has been identified as the most critical source of error in clinical gait...
Accurate measurement of underlying bone positions is important for the understanding of normal movem...
Musculoskeletal models used in gait analysis require coordinate systems to be identified for the bod...
Accurately measuring of intrinsic foot kinematics using skin mounted markers is difficult, limited i...
When using optoelectronic stereophotogrammetry, skin deformation and displacement causes marker move...