A Direct Comparison of Biplanar Videoradiography and Optical Motion Capture for Foot and Ankle Kinematics

Kessler, Sarah; Rainbow, Michael J.; Lichtwark, Glen A.; Cresswell, Adrian Ben; D’Andrea, Susan E.; Konow, Nicolai; Kelly, Luke A.

doi:10.3389/fbioe.2019.00199

Cited by 75 publications

(83 citation statements)

References 32 publications

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“…The experimental protocol was approved by The University of Queensland and the Providence VA Medical Center Ethics Committee and conducted according to the Declaration of Helsinki. This data set has been used in a previous publication, see Kessler et al (2019).…”

Section: Methodsmentioning

confidence: 99%

“…The position and orientation of each bone was determined via scientific rotoscoping using the open source software package, Autoscoper (Brainerd et al, 2010) (Autoscoper V2, Brown University, Providence, RI, United States), as previously detailed in Kessler et al (2019). In brief, for each frame, the partial volume of the bone of interest is used to create a digitally reconstructed radiograph (DRR) that is projected onto the two calibrated x-ray images.…”

Section: Data Processingmentioning

confidence: 99%

“…Biplanar videoradiography has provided valuable insights into the function of the wrist (Akhbari et al, 2019), shoulder (Bey et al, 2006(Bey et al, , 2008, hip (Dimitriou et al, 2015), and knee (Akbarshahi et al, 2010;Miranda et al, 2013) during dynamic tasks. Recently, it has also been shown to accurately capture 3D skeletal motion of the bones in the foot (Ito, 2015;Wang et al, 2015) and subsequently used to calculate their foot kinematics (Roach et al, 2016(Roach et al, , 2017Kessler et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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The Reliability of Foot and Ankle Bone and Joint Kinematics Measured With Biplanar Videoradiography and Manual Scientific Rotoscoping

Maharaj

Kessler

Rainbow

et al. 2020

Front. Bioeng. Biotechnol.

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The intricate motion of the small bones of the feet are critical for its diverse function. Accurately measuring the 3-dimensional (3D) motion of these bones has attracted much attention over the years and until recently, was limited to invasive techniques or quantification of functional segments using multi-segment foot models. Biplanar videoradiography and model-based scientific rotoscoping offers an exciting alternative that allows us to focus on the intricate motion of individual bones in the foot. However, scientific rotoscoping, the process of rotating and translating a 3D bone model so that it aligns with the captured x-ray images, is either semi-or completely manual and it is unknown how much human error affects tracking results. Thus, the aim of this study was to quantify the inter-and intra-operator reliability of manually rotoscoping in vivo bone motion of the tibia, talus, and calcaneus during running. Three-dimensional CT bone volumes and high-speed biplanar videoradiography images of the foot were acquired on six participants. The six-degree-of-freedom motions of the tibia, talus, and calcaneus were determined using a manual markerless registration algorithm. Two operators performed the tracking, and additionally, the first operator re-tracked all bones, to test for intra-operator effects. Mean RMS errors were 1.86 mm and 1.90 • for intra-operator comparisons and 2.30 mm and 2.60 • for inter-operator comparisons across all bones and planes. The moderate to strong similarity values indicate that tracking bones and joint kinematics between sessions and operators is reliable for running. These errors are likely acceptable for defining gross joint angles. However, this magnitude of error may limit the capacity to perform advanced analyses of joint interactions, particularly those that require precise (sub-millimeter) estimates of bone position and orientation. Optimizing the view and image quality of the biplanar videoradiography system as well as the automated tracking algorithms for rotoscoping bones in the foot are required to reduce these errors and the time burden associated with the manual processing.

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Section: Methodsmentioning

confidence: 99%

Section: Data Processingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Reliability of Foot and Ankle Bone and Joint Kinematics Measured With Biplanar Videoradiography and Manual Scientific Rotoscoping

Maharaj

Kessler

Rainbow

et al. 2020

Front. Bioeng. Biotechnol.

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“…The development of three-dimensional (3D) multi-segment foot models partially tackled this major shortcoming of the established 3D lower limb models and showed their clinical value through the detection of intrinsic foot mobility impairments [1]. During the last decade, foot and ankle biomechanics were essentially described through the kinematics of the gait cycle as determined from cadaver, invasive bone pins, biplanar videoradiography and noninvasive surface marker studies, and plantar pressure measurements [2][3][4][5][6][7][8]. Recently, multi-segment kinetic foot models have received increasing attention in methodological and clinical studies providing new insights into how the intrinsic joints of the foot can have individual power distributions [9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Intrinsic foot joints adapt a stabilized‐resistive configuration during the stance phase

Chèze

Dumas

Besse

et al. 2020

Journal of Foot and Ankle Research

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Background: This study evaluated the 3D angle between the joint moment and the joint angular velocity vectors at the intrinsic foot joints, and investigated if these joints are predominantly driven or stabilized during gait. Methods: The participants were 20 asymptomatic subjects. A four-segment kinetic foot model was used to calculate and estimate intrinsic foot joint moments, powers and angular velocities during gait. 3D angles between the joint moment and the joint angular velocity vectors were calculated for the intrinsic foot joints defined as follows: ankle joint motion described between the foot and the shank for the one-segment foot model (hereafter referred as Ankle), and between the calcaneus and the shank for the multi-segment foot model (hereafter referred as Shank-Calcaneus); joint motion described between calcaneus and midfoot segments (hereafter referred as Chopart joint); joint motion described between midfoot and metatarsus segments (hereafter referred as Lisfranc joint); joint motion described between first phalanx and first metatarsal (hereafter referred as First Metatarso-Phalangeal joint). When the vectors were approximately aligned, the moment was considered to result in propulsion (3D angle <60 o) or resistance (3D angle >120 o) at the joint. When the vectors are approximately orthogonal (3D angle close to 90°), the moment was considered to stabilize the joint. Results: The results showed that the four intrinsic joints of the foot are never fully propelling, resisting or being stabilized, but are instead subject to a combination of stabilization with propulsion or resistance during the majority of the stance phase of gait. However, the results also show that during pre-swing all four the joints are subject to moments that result purely in propulsion. At heel off, the propulsive configuration appears for the Lisfranc joint first at terminal stance, then for the other foot joints at pre-swing in the following order: Ankle, Chopart joint and First Metatarso-Phalangeal joint. Conclusions: Intrinsic foot joints adopt a stabilized-resistive configuration during the majority of the stance phase, with the exception of pre-swing during which all joints were found to adopt a propulsive configuration. The notion of stabilization, resistance and propulsion should be further investigated in subjects with foot and ankle disorders.

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“…Previous studies conducted for the measurement of 3D kinematics of the foot bones during gait can be classi ed into four categories [1][2][3][4][5][6][7][8][9][10] , including skin marker-based motion capture system, uoroscopy study, in-vivo measurement with bone pins and measurement through cadaver gait simulators. However, some limitations are found in previous research methods.…”

Section: Introductionmentioning

confidence: 99%

In vitro study of foot bone kinematics via a custom-made cadaveric gait simulator

Zhu

Wang

Yuan

et al. 2020

Preprint

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Background: Quantifying detailed kinematics of the intrinsic foot bone during gait is crucial for understanding biomechanical functions of the foot complex musculoskeletal structure and making appropriate surgery decisions.Research question: The purpose of this experiment is to measure bones kinematic of the normal foot in a gait cycle via a custom-made cadaveric gait simulator.Methods：In this experiment, we used a custom-made 6 degrees of freedom (DOF) of robotic gait simulator simulating normal human gait to measure the 3-dimensional (3D) kinematics of tibia, calcaneus, cuboid, navicular, medial cuneiform, first metatarsal, and fifth metatarsal through six cadaveric feet.Results: The results showed that the kinematic of the intrinsic foot bones in the stance phase of the gait was successfully quantified using a custom-made robotic gait simulator. During walking stance, the joints in the medial column of foot had less movement than those in the lateral column. And during the later portion of stance, no rotational cease was observed in the movement between navicular and cuboid, calcaneocuboid joint, or cuneonavicular joint.Conclusion: This study described foot bone motion using a biomechanically near-physiological gait simulator with 6 DOF of the tibia. The kinematic data helps to clarify previous descriptions of several joints kinematics that are difficult to study in vivo. The methodology also provides a platform for researchers to explore more invasive foot biomechanics under dynamic and near-physiologic conditions.

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A Direct Comparison of Biplanar Videoradiography and Optical Motion Capture for Foot and Ankle Kinematics

Cited by 75 publications

References 32 publications

The Reliability of Foot and Ankle Bone and Joint Kinematics Measured With Biplanar Videoradiography and Manual Scientific Rotoscoping

The Reliability of Foot and Ankle Bone and Joint Kinematics Measured With Biplanar Videoradiography and Manual Scientific Rotoscoping

Intrinsic foot joints adapt a stabilized‐resistive configuration during the stance phase

In vitro study of foot bone kinematics via a custom-made cadaveric gait simulator

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