Design and control of system for elbow rehabilitation: Preliminary findings

Mikołajczyk, Tadeusz; Kłodowski, Adam; Mikołajewska, Emilia; Walkowiak, Paweł; Berjano, Pedro; Villafañe, Jorge Hugo; Aggogeri, Francesco; Borboni, Alberto; Fausti, Davide; Petrogalli, Gianluigi

doi:10.17219/acem/74556

Cited by 15 publications

(9 citation statements)

References 29 publications

(31 reference statements)

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“…(1) Lack high-h-quality evidence to assess its effectiveness [50]. (2) The advantages and disadvantages of technology are unknown [51].…”

Section: Disadvantagesmentioning

confidence: 99%

“…Wearable-assistive devices have been used in the rehabilitation of neurological disorder such as traumatic brain injury widely. According to the report [ 50 ], Mikołajczyk et al carried out the research and design of the system for elbow rehabilitation which consists of a single-degree-of-freedom (SDOF) solution and a single-axis stepper motor with a controller. They designed an exoskeleton, a wearable, external structure which can support or even replace the muscle actuation in the patient, and the system promotes the rehabilitation of upper limb function after TBI.…”

Section: Wearable-assisted Devicesmentioning

confidence: 99%

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Development and Application of Medicine-Engineering Integration in the Rehabilitation of Traumatic Brain Injury

Wang

Sun

et al. 2021

BioMed Research International

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The rapid progress of the combination of medicine and engineering provides better chances for the clinical treatment and healthcare engineering. Traumatic brain injury (TBI) and its related symptoms have become a major global health problem. At present, these techniques has been widely used in the rehabilitation of TBI. In this review article, we summarizes the progress of the combination of medicine and industry in the rehabilitation of traumatic brain injury in recent years, mainly from the following aspects: artificial intelligence (AI), brain-computer interfaces (BCI), noninvasive brain stimulation (NIBS), and wearable-assisted devices. We believe the summary of this article can improve insight into the combination of medicine and industry in the rehabilitation of traumatic brain injury.

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“…(1) Lack high-h-quality evidence to assess its effectiveness [50]. (2) The advantages and disadvantages of technology are unknown [51].…”

Section: Disadvantagesmentioning

confidence: 99%

Section: Wearable-assisted Devicesmentioning

confidence: 99%

Development and Application of Medicine-Engineering Integration in the Rehabilitation of Traumatic Brain Injury

Wang

Sun

et al. 2021

BioMed Research International

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“…Notably, the resulting parts often have rough and grainy surfaces, which may need coating at the end to be smoothened [91]. According to the manufacturers [92][93][94], it is not preferable to reuse the unfused powder due to degradation by exposure to high temperature. SLS 3D printers use sintering to build up samples, whereas SLM printers use melting of powder beds [95].…”

Section: Selective Laser Sintering (Sls)/ Selective Laser Melting (Slm)mentioning

confidence: 99%

A Review on New 3-D Printed Materials’ Geometries for Catalysis and Adsorption: Paradigms from Reforming Reactions and CO2 Capture

et al. 2020

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“Bottom-up” additive manufacturing (AM) is the technology whereby a digitally designed structure is built layer-by-layer, i.e., differently than by traditional manufacturing techniques based on subtractive manufacturing. AM, as exemplified by 3D printing, has gained significant importance for scientists, among others, in the fields of catalysis and separation. Undoubtedly, it constitutes an enabling pathway by which new complex, promising and innovative structures can be built. According to recent studies, 3D printing technologies have been utilized in enhancing the heat, mass transfer, adsorption capacity and surface area in CO2 adsorption and separation applications and catalytic reactions. However, intense work is needed in the field to address further challenges in dealing with the materials and metrological features of the structures involved. Although few studies have been performed, the promise is there for future research to decrease carbon emissions and footprint. This review provides an overview on how AM is linked to the chemistry of catalysis and separation with particular emphasis on reforming reactions and carbon adsorption and how efficient it could be in enhancing their performance.

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“…Similar solutions have been developed in several countries (e.g., in the USA, and in Singapore [ 3 ]) as prototypes, but to our knowledge, they have not entered into mass production. A prototype of a stationary elbow exoskeleton has been developed by a Polish–Italian team with the participation of the Collegium Medicum Nicolaus Copernicus University (CM UMK) and University of Science and Technology (UTP) [ 4 ], but despite its technical sophistication, it can serve as a stationary elbow joint rehabilitation tool on the rehabilitation center’s equipment, but it cannot serve as a wearable individual elbow joint support that is fully mobile with the patient. For the aforementioned reasons, this solution is technically and purposefully very different from the 3D-printed mobile elbow exoskeleton solution proposed in this paper.…”

Section: Introductionmentioning

confidence: 99%

Reducing Waste in 3D Printing Using a Neural Network Based on an Own Elbow Exoskeleton

et al. 2021

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Traditional rehabilitation systems are evolving into advanced systems that enhance and improve rehabilitation techniques and physical exercise. The reliable assessment and robotic support of the upper limb joints provided by the presented elbow exoskeleton are important clinical goals in early rehabilitation after stroke and other neurological disorders. This allows for not only the support of activities of daily living, but also prevention of the progression neuromuscular pathology through proactive physiotherapy toward functional recovery. The prices of plastics are rising very quickly, as is their consumption, so it makes sense to optimize three dimensional (3D) printing procedures through, for example, improved artificial intelligence-based (AI-based) design or injection simulation, which reduces the use of filament, saves material, reduces waste, and reduces environmental impact. The time and cost savings will not reduce the high quality of the products and can provide a competitive advantage, especially in the case of thinly designed mass products. AI-based optimization allows for one free print after every 6.67 prints (i.e., from materials that were previously wasted).

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Design and control of system for elbow rehabilitation: Preliminary findings

Cited by 15 publications

References 29 publications

Development and Application of Medicine-Engineering Integration in the Rehabilitation of Traumatic Brain Injury

Development and Application of Medicine-Engineering Integration in the Rehabilitation of Traumatic Brain Injury

A Review on New 3-D Printed Materials’ Geometries for Catalysis and Adsorption: Paradigms from Reforming Reactions and CO2 Capture

Reducing Waste in 3D Printing Using a Neural Network Based on an Own Elbow Exoskeleton

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