Application of NiTi in Assistive and Rehabilitation Devices: A Review

Nematollahi, Mohammadreza; Baghbaderani, Keyvan Safaei; Amerinatanzi, Amirhesam; Zamanian, Hashem; Elahinia, Mohammad

doi:10.3390/bioengineering6020037

Cited by 72 publications

(35 citation statements)

References 47 publications

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“…The additive metal production facilitates the opportunity to fabricate complex components from costly materials such as titanium alloys, which is significant to the biomedical and aerospace industries [173,174]. AM of metals develops rapidly, and new methods, alloys, and applications are achieved with significant quality improvements and reduced production times.…”

Section: Future Of Am In Materialsmentioning

confidence: 99%

The Potential of Additive Manufacturing in the Smart Factory Industrial 4.0: A Review

et al. 2019

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Additive manufacturing (AM) or three-dimensional (3D) printing has introduced a novel production method in design, manufacturing, and distribution to end-users. This technology has provided great freedom in design for creating complex components, highly customizable products, and efficient waste minimization. The last industrial revolution, namely industry 4.0, employs the integration of smart manufacturing systems and developed information technologies. Accordingly, AM plays a principal role in industry 4.0 thanks to numerous benefits, such as time and material saving, rapid prototyping, high efficiency, and decentralized production methods. This review paper is to organize a comprehensive study on AM technology and present the latest achievements and industrial applications. Besides that, this paper investigates the sustainability dimensions of the AM process and the added values in economic, social, and environment sections. Finally, the paper concludes by pointing out the future trend of AM in technology, applications, and materials aspects that have the potential to come up with new ideas for the future of AM explorations.

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Section: Future Of Am In Materialsmentioning

confidence: 99%

The Potential of Additive Manufacturing in the Smart Factory Industrial 4.0: A Review

et al. 2019

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“…Nitinol (NiTi), is a biocompatible, low stiffness, shape memory alloy, which benefits from interesting features such as superelasticity and shape memory. Nitinol has been already used in many industrial applications as well as biomedical applications [8][9][10][11][12][13][14]. In addition to the inherent low stiffness, NiTi superelastic behavior can be made to be very similar to bone tissue.…”

Section: Introductionmentioning

confidence: 99%

Design, Modeling, Additive Manufacturing, and Polishing of Stiffness-Modulated Porous Nitinol Bone Fixation Plates Followed by Thermomechanical and Composition Analysis

Jahadakbar

Nematollahi

Safaei

et al. 2020

Metals

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The use of titanium bone fixation plates is considered the standard of care for skeletal reconstructive surgery. Highly stiff titanium bone fixation plates provide immobilization immediately after the surgery. However, after the bone healing stage, they may cause stress shielding and lead to bone resorption and failure of the surgery. Stiffness-modulated or stiffness-matched Nitinol bone fixation plates that are fabricated via additive manufacturing (AM) have been recently introduced by our group as a long-lasting solution for minimizing the stress shielding and the follow-on bone resorption. Up to this point, we have modeled the performance of Nitinol bone fixation plates in mandibular reconstruction surgery and investigated the possibility of fabricating these implants. In this study, for the first time the realistic design of stiffness-modulated Nitinol bone fixation plates is presented. Plates with different levels of stiffness were fabricated, mechanically tested, and used for verifying the design approach. Followed by the design verification, to achieve superelastic bone fixation plates we proposed the use of Ni-rich Nitinol powder for the AM process and updated the models based on that. Superelastic Nitinol bone fixation plates with the extreme level of porosity were fabricated, and a chemical polishing procedure used to remove the un-melted powder was developed using SEM analysis. Thermomechanical evaluation of the polished bone fixation plates verified the desired superelasticity based on finite element (FE) simulations, and the chemical analysis showed good agreement with the ASTM standard.

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“…Rehabilitation engineering is multidisciplinary in bringing together professionals such as doctors, nurses, physiotherapists, occupational therapists, biologists, engineers, physicists and chemists. Indeed, the rehabilitation devices are developed by a group of specialized professionals with interdisciplinary training, such is the case of bioengineering that is the application of the knowledge gathered in a fertile balance between engineering and medical science [3].…”

Section: Introductionmentioning

confidence: 99%

Design Methodology for Rehabilitation Robots: Application in an Exoskeleton for Upper Limb Rehabilitation

Cruz-Martínez

Avilés

2020

Applied Sciences

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This article presents a methodology for the design of rehabilitation devices that considers factors involved in a clinical environment. This methodology integrates different disciplines that work together. The methodology is composed by three phases and 13 stages with specific tasks, the first phase includes the clinical context considering the requirements of the patient and therapist during the rehabilitation, the second phase is focused in engineering based on the philosophy of digital twin, and in the third phase is evaluated the device. This article explains the characteristics of the methodology and how it was applied in the design of an exoskeleton for passive rehabilitation of upper limb.

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Application of NiTi in Assistive and Rehabilitation Devices: A Review

Cited by 72 publications

References 47 publications

The Potential of Additive Manufacturing in the Smart Factory Industrial 4.0: A Review

The Potential of Additive Manufacturing in the Smart Factory Industrial 4.0: A Review

Design, Modeling, Additive Manufacturing, and Polishing of Stiffness-Modulated Porous Nitinol Bone Fixation Plates Followed by Thermomechanical and Composition Analysis

Design Methodology for Rehabilitation Robots: Application in an Exoskeleton for Upper Limb Rehabilitation

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