3D printed orthotic leg brace with movement assist

Boolos, Maria; Corbin, Sabrina; Herrmann, Andy; Regez, Bradley

doi:10.1016/j.stlm.2022.100062

Cited by 7 publications

(6 citation statements)

References 7 publications

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“…The primary criterion guiding their selection was to guarantee the steadfast stability of the designated sample throughout the duration of the measurements. Figures [13][14][15] showcase photographic representations of the sample undergoing the bending test. The grips utilized in the testing apparatus for the orthosis pivotal assembly parts, crafted through 3D printing methodologies using rPET and PLA, are instrumental in upholding the stability of the designated sample throughout the testing procedures.…”

Section: Analisys Of the Lateral Thigh Pivotal Componentsmentioning

confidence: 99%

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Empowering Rehabilitation: Design and Structural Analysis of a Low-Cost 3D-Printed Smart Orthosis

Popișter,

Dragomir,

Ciudin

et al. 2024

Polymers

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Three-dimensional (3D) printing of polymer materials encompasses a wide range of applications and innovations. Polymer-based 3D printing, also known as additive manufacturing, has gained significant attention due to its versatility, cost-effectiveness, and potential to revolutionize various industries. The current paper focuses on obtaining a durable low-cost rehabilitation knee orthosis. Researchers propose that the entire structure should be obtained using modern equipment within the additive manufacturing domain—3D printing. The researchers focus on determining, through a 3D analysis of the entire 3D model assembly, which parts present a high degree of stress when a kinematic simulation is developed. The entire 3D model of the orthosis starts based on the result obtained from a 3D scanning of the knee joint of a patient, providing a precise fixation, and allowing for direct personalization. Based on the results and identification of the critical parts, there will be used different materials and a combination of 3D printing strategies to validate the physical model of the entire orthosis. For the manufacturing process, the researchers use two types of low-cost fused filament fabrication (FFF), which are easy to find on the worldwide market. The motivation for manufacturing the entire assembly using 3D printing techniques is the short time in which complex shapes can be obtained, which is relevant for the present study. The main purpose of the present research is to advance orthotic technology by developing an innovative knee brace made of 3D-printed polymers that are designed to be lightweight, easy-to-use, and provide comfort and functionality to patients during the rehabilitation process.

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Section: Analisys Of the Lateral Thigh Pivotal Componentsmentioning

confidence: 99%

“…Owing to the adaptability of 3D printing technology, these lightweight devices can include complex geometries and features. Material selection allows for the appropriate mechanical properties, while rapid prototyping enables quick iterations and modifications [13][14][15][16][17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

Empowering Rehabilitation: Design and Structural Analysis of a Low-Cost 3D-Printed Smart Orthosis

Popișter,

Dragomir,

Ciudin

et al. 2024

Polymers

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“…Most orthoses are parts with complex shapes, and for this reason, it is almost impossible and very expensive to personalize them for each patient in a conventional production way [ 189 ]. In Figure 32 , different complex 3D printed orthoses devices, for the lower and upper extremities, are presented [ 189 , 190 , 191 , 192 , 193 , 194 ].…”

Section: Complexity Of Additive Manufactured Partsmentioning

confidence: 99%

“… Orthosis devices for ( a ) neck [ 193 ], ( b ) finger [ 189 ], ( c ) hand [ 190 ], ( d ) knee [ 191 ], ( e ) ankle [ 194 ], and ( f ) foot [ 192 ]. …”

Section: Figurementioning

confidence: 99%

Influence of Process Parameters on the Characteristics of Additively Manufactured Parts Made from Advanced Biopolymers

et al. 2023

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Over the past few decades, additive manufacturing (AM) has become a reliable tool for prototyping and low-volume production. In recent years, the market share of such products has increased rapidly as these manufacturing concepts allow for greater part complexity compared to conventional manufacturing technologies. Furthermore, as recyclability and biocompatibility have become more important in material selection, biopolymers have also become widely used in AM. This article provides an overview of AM with advanced biopolymers in fields from medicine to food packaging. Various AM technologies are presented, focusing on the biopolymers used, selected part fabrication strategies, and influential parameters of the technologies presented. It should be emphasized that inkjet bioprinting, stereolithography, selective laser sintering, fused deposition modeling, extrusion-based bioprinting, and scaffold-free printing are the most commonly used AM technologies for the production of parts from advanced biopolymers. Achievable part complexity will be discussed with emphasis on manufacturable features, layer thickness, production accuracy, materials applied, and part strength in correlation with key AM technologies and their parameters crucial for producing representative examples, anatomical models, specialized medical instruments, medical implants, time-dependent prosthetic features, etc. Future trends of advanced biopolymers focused on establishing target-time-dependent part properties through 4D additive manufacturing are also discussed.

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“…3D printing technology allows for the creation of custom-fit, comfortable, and functional orthotic devices. Another major benefit of 3D printing is that it can greatly reduce the lead time and cost associated with traditional methods of manufacturing orthotic devices and at a fraction of the cost of traditional methods [ 15 , 16 ]. The development of a new 3D-printed collar will aim to be fully bespoke, incorporating patient’s anatomy captured via 3D scanning in the design process for each collar.…”

Section: Bespoke Collar For People Living With Mndmentioning

confidence: 99%

Neck Collar Assessment for People Living With Motor Neuron Disease: Are Current Outcome Measures Suitable?

Spears¹,

Abdulle²,

Korovilas³

et al. 2023

Interact J Med Res

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A majority of people living with motor neuron disease (MND) experience weakness of the neck and as a result, experience head drop. This exacerbates problems with everyday activities (eating, talking, breathing, etc). Neck collars are often used to support head drop; however, these are typically designed for prehospitalization settings to manage and brace the cervical region of the spine. As a result, it has been recorded that people living with MND often reject these collars for a variety of reasons but most notably because they are too restricting. The current standardized outcome measures (most notably restricting cervical range of motion) used for neck collars are summarized herein along with whether they are suitable for a bespoke neck collar specifically designed for people living with MND.

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3D printed orthotic leg brace with movement assist

Cited by 7 publications

References 7 publications

Empowering Rehabilitation: Design and Structural Analysis of a Low-Cost 3D-Printed Smart Orthosis

Empowering Rehabilitation: Design and Structural Analysis of a Low-Cost 3D-Printed Smart Orthosis

Influence of Process Parameters on the Characteristics of Additively Manufactured Parts Made from Advanced Biopolymers

Neck Collar Assessment for People Living With Motor Neuron Disease: Are Current Outcome Measures Suitable?

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