Polymer-Based Additive Manufacturing for Orthotic and Prosthetic Devices: Industry Outlook in Canada

Sakib-Uz-Zaman, Chowdhury; Khondoker, Mohammad Abu Hasan

doi:10.3390/polym15061506

Cited by 12 publications

(11 citation statements)

References 51 publications

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“…Also of note is the potential of porous media design for hydrate obtaining [ 35 ]. Three-dimensional printing of various materials is actively developing and allows for optimizing production processes [ 38 , 39 , 40 , 41 , 42 , 43 , 44 , 45 ]. In the case of gas hydrates, such an approach makes it possible to vary the medium’s parameters for obtaining hydrate in a wide range, allowing optimizing artificial materials for developing a particular hydrate-based technology.…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional-Printed Polymeric Cores for Methane Hydrate Enhanced Growth

et al. 2023

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Polymeric models of the core prepared with a Raise3D Pro2 3D printer were employed for methane hydrate formation. Polylactic acid (PLA), acrylonitrile butadiene styrene (ABS), carbon fiber reinforced (UltraX), thermoplastic polyurethane (PolyFlex), and polycarbonate (ePC) were used for printing. Each plastic core was rescanned using X-ray tomography to identify the effective porosity volumes. It was revealed that the polymer type matters in enhancing methane hydrate formation. All polymer cores except PolyFlex promoted the hydrate growth (up to complete water-to-hydrate conversion with PLA core). At the same time, changing the filling degree of the porous volume with water from partial to complete decreased the efficiency of hydrate growth by two times. Nevertheless, the polymer type variation allowed three main features: (1) managing the hydrate growth direction via water or gas preferential transfer through the effective porosity; (2) the blowing of hydrate crystals into the volume of water; and (3) the growth of hydrate arrays from the steel walls of the cell towards the polymer core due to defects in the hydrate crust, providing an additional contact between water and gas. These features are probably controlled by the hydrophobicity of the pore surface. The proper filament selection allows the hydrate formation mode to be set for specific process requirements.

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Section: Introductionmentioning

confidence: 99%

Three-Dimensional-Printed Polymeric Cores for Methane Hydrate Enhanced Growth

et al. 2023

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“…By integrating color, texture, and design elements reflecting the user's personality and style, prosthetists promote a sense of ownership and self-expression, fostering a positive body image and boosting self-confidence [89]. Overall, the customization and personalization of prosthetic devices contribute to enhanced comfort, functionality, and user satisfaction [90]. Leveraging advancements in biomimetics and additive manufacturing, prosthetists can now create prosthetic solutions that not only restore lost function but also empower users to lead active and fulfilling lives.…”

Section: Enhanced Comfort and Functionalitymentioning

confidence: 99%

Recent Advances in Biomimetics for the Development of Bio-Inspired Prosthetic Limbs

Varaganti,

Seo

2024

Biomimetics

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Recent advancements in biomimetics have spurred significant innovations in prosthetic limb development by leveraging the intricate designs and mechanisms found in nature. Biomimetics, also known as “nature-inspired engineering”, involves studying and emulating biological systems to address complex human challenges. This comprehensive review provides insights into the latest trends in biomimetic prosthetics, focusing on leveraging knowledge from natural biomechanics, sensory feedback mechanisms, and control systems to closely mimic biological appendages. Highlighted breakthroughs include the integration of cutting-edge materials and manufacturing techniques such as 3D printing, facilitating seamless anatomical integration of prosthetic limbs. Additionally, the incorporation of neural interfaces and sensory feedback systems enhances control and movement, while technologies like 3D scanning enable personalized customization, optimizing comfort and functionality for individual users. Ongoing research efforts in biomimetics hold promise for further advancements, offering enhanced mobility and integration for individuals with limb loss or impairment. This review illuminates the dynamic landscape of biomimetic prosthetic technology, emphasizing its transformative potential in rehabilitation and assistive technologies. It envisions a future where prosthetic solutions seamlessly integrate with the human body, augmenting both mobility and quality of life.

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“…Process improvements include adaptive process control for laser powder bed fusion [155] AM to optimize material usage, in situ monitoring using computer vision to minimize material consumption, and multi-material AM systems with extrusion-based approaches that facilitate the effective integration of sustainable materials [156]. Personalized orthotics and prosthetics made of recyclable and biocompatible materials, aerospace parts like rocket engines and aircraft parts made of lightweight, sustainable materials, and medical devices like implants and surgical guides that are made with biocompatibility and sustainability in mind are just a few of the numerous applications of additive manufacturing (AM) [157,158]. These developments highlight AM's revolutionary potential to promote a circular economy and advance environmentally friendly manufacturing techniques, opening the door for more ground-breaking discoveries in the years to come.…”

Section: Construction Industrymentioning

confidence: 99%

Natural Fiber Composite Filaments for Additive Manufacturing: A Comprehensive Review

Khilji,

Chilakamarry,

Surendran

et al. 2023

Sustainability

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This research explores the potential and significance of 3D printing natural fiber composite (NFC) materials. The primary objective is to investigate the mechanical, thermal, and environmental properties of NFC filaments, mainly focusing on biodegradable, renewable fibers such as jute, hemp, flax, and kenaf. In addition to studying the properties of NFCs, our research delves into the challenges associated with processing, including moisture absorption and fiber-matrix interfacial bonding. The novelty of this work lies in the convergence of traditional composite materials with the versatility of 3D printing technology. NFC filaments offer unique advantages in terms of sustainability, and we examine their potential contributions to the circular economy. By using eco-friendly NFC materials in 3D printing, we aim to present a viable, environmentally responsible alternative to conventional synthetic composites. The importance of 3D printing NFCs stems from the ways their use can align with sustainability goals. These materials provide the advantages of renewability, reduced carbon impact, and in some cases, biodegradability. Their applications extend to various industries, such as automotive, construction, and packaging, where eco-friendly materials are increasingly sought. Such applications showcase the ways in which NFC-based 3D printing can contribute to a more environmentally responsible and sustainable future. This research explores the mechanical, thermal, and environmental properties of NFC materials, highlighting their unique advantages for 3D printing and the potential to have eco-friendly applications in diverse industries.

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Polymer-Based Additive Manufacturing for Orthotic and Prosthetic Devices: Industry Outlook in Canada

Cited by 12 publications

References 51 publications

Three-Dimensional-Printed Polymeric Cores for Methane Hydrate Enhanced Growth

Three-Dimensional-Printed Polymeric Cores for Methane Hydrate Enhanced Growth

Recent Advances in Biomimetics for the Development of Bio-Inspired Prosthetic Limbs

Natural Fiber Composite Filaments for Additive Manufacturing: A Comprehensive Review

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