TPress

@article{Darter2023,

title = {Changes in frontal plane kinematics over 12-months in individuals with the Percutaneous Osseointegrated Prosthesis (POP)},

author = {B. J. Darter and E. D. Syrett and K. B. Foreman and E. Kubiak and S. Sinclair},

url = {https://www.embase.com/search/results?subaction=viewrecord&id=L2023020092&from=export},

doi = {10.1371/journal.pone.0281339},

issn = {1932-6203},

year  = {2023},

date = {2023-01-01},

journal = {PLoS ONE},

volume = {18},

number = {2 February},

address = {B.J. Darter, Department of Physical Therapy, Virginia Commonwealth University, Richmond, VA, United States},

abstract = {Background A bone-anchored prosthesis (BAP) eliminates the need for a conventional socket by attaching a prosthesis directly to the user's skeleton. Currently, limited research addresses changes in gait mechanics post BAP implantation. Objective Examine changes in frontal plane movement patterns after BAP implantation. Methods Participants were individuals with unilateral transfemoral amputation (TFA) enrolled in the US Food and Drug Administration (FDA) Early Feasibility Study examining the Percutaneous Osseointegrated Prosthesis (POP). The participants completed overground gait assessments using their conventional socket and at 6-weeks, 12-weeks, 6-months, and 12- months following POP implantation. Statistical parameter mapping techniques were used in examining changes in frontal plane kinematics over the 12-months and differences with reference values for individuals without limb loss. Results Statistically significant deviations were found pre-implantation compared to reference values for hip and trunk angles during prosthetic limb stance phase, and for pelvis and trunk relative to the pelvis angles during prosthetic limb swing. At 6-weeks post-implantation, only the trunk angle demonstrated a statistically significant reduction in the percent of gait cycle with deviations relative to reference values. At 12-months post-implantation, results revealed frontal plane movements were no longer statistically different across the gait cycle for the trunk angle compared to reference values, and less of the gait cycle was statistically different compared to reference values for all other frontal plane patterns analyzed. No statistically significant within-participant differences were found for frontal plane movement patterns between pre-implantation and 6-weeks or 12-months post-implantation. Conclusions Deviations from reference values displayed prior to device implantation were reduced or eliminated 12-months post-implantation in all frontal plane patterns analyzed, while withinparticipant changes over the 12-month period did not reach statistical significance. Overall, the results suggest the transition to a BAP aided in normalizing gait patterns in a sample of relatively high functioning individuals with TFA.},

keywords = {adult, amputation, article, Axtion, biomechanics, bone plate, cane, clinical article, frontal plane, gait, hip, hip adduction angle, hip angle, human, kinematics, limb prosthesis, male, middle aged, motion analysis system, Ossur Rheo, Ottobock C-Leg, Ottobock Genium, Ottobock X3, pelvic angle, pelvis lab angle, Pro-Flex Pivo, prosthesis implantation, radiographic parameter, Renegade XL, Rush Low Profile, Rush Renegade, software agent, torque, Triton, Triton Low Profile, trunk, trunk flexion angle, trunk lab angle, trunk pelvis angle, tyloxapol, unilateral transfemoral amputation, walker, walking speed, Wave Sport},

pubstate = {published},

tppubtype = {article}

}

@article{Ernst2020,

title = {Characterizing adaptations of prosthetic feet in the frontal plane},

author = {M. Ernst and B. Altenburg and T. Schmalz},

url = {https://www.embase.com/search/results?subaction=viewrecord&id=L2005154580&from=export},

doi = {10.1177/0309364620917838},

issn = {0309-3646},

year  = {2020},

date = {2020-01-01},

journal = {Prosthet. Orthot. Int.},

volume = {44},

number = {4},

pages = {225–233},

address = {M. Ernst, Research Biomechanics, Clinical Research and Services, Ottobock SE Co. KGaA, Göttingen, Germany},

abstract = {Background: Energy-storage and return feet incorporate various design features including split toes. As a potential improvement, an energy-storage and return foot with a dedicated ankle joint was recently introduced allowing for easily accessible inversion/eversion movement. However, the adaptability of energy-storage and return feet to uneven ground and the effects on biomechanical and clinical parameters have not been investigated in detail. Objectives: To investigate the design-related ability of prosthetic feet to adapt to cross slopes and derive a theoretical model. Study design: Mechanical testing and characterization. Methods: Mechanical adaptation to cross slopes was investigated for six prosthetic feet measured by a motion capture system. A theoretical model linking the measured data with adaptations is proposed. Results: The type and degree of adaptation depends on the foot design, for example, stiffness, split toe or continuous carbon forefoot, and additional ankle joint. The model used shows high correlations with the measured data for all feet. Conclusions: The ability of prosthetic feet to adapt to uneven ground is design-dependent. The split-toe feet adapted better to cross slopes than those with continuous carbon forefeet. Joints enhance this further by allowing for additional inversion and eversion. The influence on biomechanical and clinical parameters should be assessed in future studies. Clinical relevance: Knowing foot-specific ability to adapt to uneven ground may help in selecting an appropriate prosthetic foot for persons with a lower limb amputation. Faster and more comprehensive adaptations to uneven ground may lower the need for compensations and therefore increase user safety.},

keywords = {arm prosthesis, arthrodesis, article, Axtion, biomechanics, bone conduction, finite element analysis, forefoot, histology, human, joint function, mathematical model, motion analysis system, osteoarthritis, Pacifica LP, Pro Flex LP, Prototype ESRJ, subtalar joint, theoretical model, Triton LP},

pubstate = {published},

tppubtype = {article}

}

@article{Darter2023,

title = {Changes in frontal plane kinematics over 12-months in individuals with the Percutaneous Osseointegrated Prosthesis (POP)},

author = {B. J. Darter and E. D. Syrett and K. B. Foreman and E. Kubiak and S. Sinclair},

url = {https://www.embase.com/search/results?subaction=viewrecord&id=L2023020092&from=export},

doi = {10.1371/journal.pone.0281339},

issn = {1932-6203},

year  = {2023},

date = {2023-01-01},

journal = {PLoS ONE},

volume = {18},

number = {2 February},

address = {B.J. Darter, Department of Physical Therapy, Virginia Commonwealth University, Richmond, VA, United States},

abstract = {Background A bone-anchored prosthesis (BAP) eliminates the need for a conventional socket by attaching a prosthesis directly to the user's skeleton. Currently, limited research addresses changes in gait mechanics post BAP implantation. Objective Examine changes in frontal plane movement patterns after BAP implantation. Methods Participants were individuals with unilateral transfemoral amputation (TFA) enrolled in the US Food and Drug Administration (FDA) Early Feasibility Study examining the Percutaneous Osseointegrated Prosthesis (POP). The participants completed overground gait assessments using their conventional socket and at 6-weeks, 12-weeks, 6-months, and 12- months following POP implantation. Statistical parameter mapping techniques were used in examining changes in frontal plane kinematics over the 12-months and differences with reference values for individuals without limb loss. Results Statistically significant deviations were found pre-implantation compared to reference values for hip and trunk angles during prosthetic limb stance phase, and for pelvis and trunk relative to the pelvis angles during prosthetic limb swing. At 6-weeks post-implantation, only the trunk angle demonstrated a statistically significant reduction in the percent of gait cycle with deviations relative to reference values. At 12-months post-implantation, results revealed frontal plane movements were no longer statistically different across the gait cycle for the trunk angle compared to reference values, and less of the gait cycle was statistically different compared to reference values for all other frontal plane patterns analyzed. No statistically significant within-participant differences were found for frontal plane movement patterns between pre-implantation and 6-weeks or 12-months post-implantation. Conclusions Deviations from reference values displayed prior to device implantation were reduced or eliminated 12-months post-implantation in all frontal plane patterns analyzed, while withinparticipant changes over the 12-month period did not reach statistical significance. Overall, the results suggest the transition to a BAP aided in normalizing gait patterns in a sample of relatively high functioning individuals with TFA.},

keywords = {adult, amputation, article, Axtion, biomechanics, bone plate, cane, clinical article, frontal plane, gait, hip, hip adduction angle, hip angle, human, kinematics, limb prosthesis, male, middle aged, motion analysis system, Ossur Rheo, Ottobock C-Leg, Ottobock Genium, Ottobock X3, pelvic angle, pelvis lab angle, Pro-Flex Pivo, prosthesis implantation, radiographic parameter, Renegade XL, Rush Low Profile, Rush Renegade, software agent, torque, Triton, Triton Low Profile, trunk, trunk flexion angle, trunk lab angle, trunk pelvis angle, tyloxapol, unilateral transfemoral amputation, walker, walking speed, Wave Sport},

pubstate = {published},

tppubtype = {article}

}

@article{Ernst2020,

title = {Characterizing adaptations of prosthetic feet in the frontal plane},

author = {M. Ernst and B. Altenburg and T. Schmalz},

url = {https://www.embase.com/search/results?subaction=viewrecord&id=L2005154580&from=export},

doi = {10.1177/0309364620917838},

issn = {0309-3646},

year  = {2020},

date = {2020-01-01},

journal = {Prosthet. Orthot. Int.},

volume = {44},

number = {4},

pages = {225–233},

address = {M. Ernst, Research Biomechanics, Clinical Research and Services, Ottobock SE Co. KGaA, Göttingen, Germany},

abstract = {Background: Energy-storage and return feet incorporate various design features including split toes. As a potential improvement, an energy-storage and return foot with a dedicated ankle joint was recently introduced allowing for easily accessible inversion/eversion movement. However, the adaptability of energy-storage and return feet to uneven ground and the effects on biomechanical and clinical parameters have not been investigated in detail. Objectives: To investigate the design-related ability of prosthetic feet to adapt to cross slopes and derive a theoretical model. Study design: Mechanical testing and characterization. Methods: Mechanical adaptation to cross slopes was investigated for six prosthetic feet measured by a motion capture system. A theoretical model linking the measured data with adaptations is proposed. Results: The type and degree of adaptation depends on the foot design, for example, stiffness, split toe or continuous carbon forefoot, and additional ankle joint. The model used shows high correlations with the measured data for all feet. Conclusions: The ability of prosthetic feet to adapt to uneven ground is design-dependent. The split-toe feet adapted better to cross slopes than those with continuous carbon forefeet. Joints enhance this further by allowing for additional inversion and eversion. The influence on biomechanical and clinical parameters should be assessed in future studies. Clinical relevance: Knowing foot-specific ability to adapt to uneven ground may help in selecting an appropriate prosthetic foot for persons with a lower limb amputation. Faster and more comprehensive adaptations to uneven ground may lower the need for compensations and therefore increase user safety.},

keywords = {arm prosthesis, arthrodesis, article, Axtion, biomechanics, bone conduction, finite element analysis, forefoot, histology, human, joint function, mathematical model, motion analysis system, osteoarthritis, Pacifica LP, Pro Flex LP, Prototype ESRJ, subtalar joint, theoretical model, Triton LP},

pubstate = {published},

tppubtype = {article}

}