A dynamic energy storage and return foot prosthesis is a type of prosthesis designed to mimic and restore the functionality and natural movement of the limb that has been amputated. This type of prosthesis is designed to allow patients to perform daily activities, even very dynamic ones, with greater ease and efficiency. The distinguishing feature of a dynamic energy storage and return prosthesis is the presence of a system that accumulates mechanical energy during the support phase on the ground and returns it during the push phase, increasing the amount of push itself. In foot prostheses, it is common to use carbon fiber blades or springs that deform during the support of the foot and then restore themselves, returning elastic energy during the subsequent push. This helps reduce the effort required to walk and allows for more fluid and natural movements. Additive Manufacturing (AM) technology is ideal for highly customized and high-value production. Orthoses/prostheses are particularly suited to exploit the potential of this technology. However, the lack of functional materials that meet different design needs, such as structure and comfort of the devices, has limited the use of AM mainly in orthoses. AM is promising for orthoses due to its customization capability and reduced production costs compared to traditional solutions. In particular, it has been shown how continuous filament carbon printing can lead to the creation of prostheses that have dynamic and energy return characteristics similar to or even superior to commercial ones. The present pilot clinical investigation aims to provide indications regarding the safety and performance of the 3D printed prosthesis - named PROFIL - in a real-world scenario. The state of the art has not yet defined the performance and safety of 3D printed prostheses with thermoplastic materials and continuous carbon fiber. Since greater comfort and the possibility of performing physical activity more easily with the use of these devices is expected, it is considered of interest for clinical practice to evaluate these prostheses. The primary objective of the study is therefore to evaluate the safety and performance of the device during walking on flat surfaces and more demanding tasks. The secondary objectives aims at evaluate usability and deformation of the 3D printed prosthesis under different loading conditions (slow and fast walking, ascending and descending ramps or steps) by mean of fiber-glass sensors integrated in the prosthesis foot.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
3
Energy storage and restoration 3D printed prosthesis foot
Energy storage and restitution prosthesis foot made in carbon fibers blades
Centro Protesi Inail
Vigorso Di Budrio, Bologna, Italy
Number of Adverse Events Occurred During Use of the Intervention Prosthesis Foot
Adverse events may be: falling, stumbling, lower back pain as consequence of the prosthesis foot use, stump pain as consequence of the prosthesis foot use, breakage of the prosthesis foot
Time frame: Day 1 and Day 2
Change From Comparator of Lower Limb Joint Angles Measured With Inertial Measurements Units (IMUs)
The IMUs record joints kinematics while subjects perform a series of motor tasks, i.e. walk of flat surfaces at a self-selected speed and ascend/descend stairs and ramps. In particular, the following variables are measured: range of motion of ankle joint (prosthetic ankle), knee joint, and hip joint of the impaired lower limb. The measured angles are normalized on a gait cycle (0% = heel strike, 100% = toe off). The outocome variable is computed as mean difference between the normalized measured angles and the normalized reference value taken from the literature.
Time frame: Day 1 and Day 2
Change From Comparator of Lower Limb Joint Angles Measured With an Optoelectronic System
The optoelectronic system records joints kinematics while subjects walk of a flat surfaces at a self-selected speed. In particular, the following variables are measured: range of motion of ankle joint (prosthetic ankle), knee joint, and hip joint of the impaired lower limb. The measured angles are normalized on a gait cycle (0% = heel strike, 100% = toe off). The outocome variable is computed as mean difference between the normalized measured angles and the normalized reference value taken from the literature.
Time frame: Day 1 and Day 2
Change From Comparator of Gait Quality Wihile Ascending Ramps With Hill Assessment Index (HAI)
Hill Assessment Index (HAI) is a 12-points ordinal scale used to evaluate ramp ascending quality; the higher the score the better the gait quality while ascending ramps (0 = cannot do/refuse to do, 11 = even step, without assistive device) .
Time frame: Day 1 and Day 2
Change From Comparator of Gait Quality While Ascending Stairs With Stair Ascending Index (SAI)
Stair Ascending Index (SAI) is 14-points ordinal scale used to quantify stair ascending qualty; the higher the score the better the gait quality while ascending stairs (0 = cannot do/refuse to do, 13 = Without rail or assistive device, step-over-step pattern)
Time frame: Day 1 and Day 2
Change From Comparator of Equilibrium in Orthostatism by Mean of Force Plates
The subject is asked to stand still on a force plate for 30 seconds. The sway path of the Centre of Pressure (COP) is recorded. The higher the valure the sway path, the lower the equilibrium in orthostatism. This outcome measure is performed with the eyes open and closed
Time frame: Day 1 and Day 2
Change From Comparator of Load Simmetry While Standing up/Sitting Down From/on a Chiar by Mean of Force Plates
The subject is asked to sit on a chair with both the feets (sound foot and prosthesis foot) on different force plates. At the "Start" signal, the subject stands up, stands still for 5 seconds and sits down. The weigth distribution on the lower limbs is recorded during the entire task. The symmetry index is computed as the ratio between: the difference between the load peak of the ground reaction force (GRF) measured in the sound side and the load peak of the ground reaction force (GRF) measured in the impaired side ON the sum between the load peak of the ground reaction force (GRF) measured in the sound side and the load peak of the ground reaction force (GRF) measured in the impaired side. Asymmetry index = \[(peak GRF sound - peak GRF impaired) / (peak GRF sound + peak GRF impaired)\]\*100%
Time frame: Day 1 and Day 2
Change From Comparator of Amputee Mobility Predictor (AMP-PRO)
AMP is a 21-item objectve measure in which static and dynamic sitting and standing activities, as well as transfer and gait skills of progressing difficulty are performed. Score range is 0-47. Higher scores indicate better mobility. Based on the final score, 4 groups are defined (K1 = 15-26, K2 = 27-36, K3 = 37-42, K4 = 43-47).
Time frame: Day 1 and Day 2
Change From Comparator of Functional Mobility Measured With the L-test
The subject starts from a sitting position. At the "Start" signal, the subject stands up from the chair, walks in a closed 10-meters L-shaped path, and sits down on the same chair. The time necessary to complete the path is measured with a stopwatch. The lower the time to complete the path, the higher the functional mobility.
Time frame: Day 1 and Day 2
Change From Comparator of Usability of the Prosthesis Foot
Usability is measured with an ad hoc custom-made 6-items questionnaire. Each item ranges 1 to 5. To compute the final score, each item is summed up (total range: 6-30). The higher the score, the better the usability.
Time frame: Day 1 and Day 2
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