Tag Archives: carbon fibre

Prosthesis of the future, the first in the world with magnetic control

The headline for a September 12, 2024 Sant’Anna School of Advanced Studies (Scuola Superiore Sant’Anna) press release (also on EurekAlert but published September 11, 2024) says it all but first, here’s an image showing off the prosthesis,

Caption: C055800371.png: Experimental tests on robotic prosthesis: clothespin. Credit: © 2024 Scuola Superiore Sant’Anna

Here’s the press release, Note: Links have been removed,

“It feels like I’m moving my own hand”. A research team from the Scuola Superiore Sant’Anna in Pisa has developed the prosthesis of the future, the first in the world with magnetic control

It is a completely new way of controlling the movements of a robotic hand. “The trial on the first patient was successful. We are ready to extend these results to a broader range of amputations” says Prof. Christian Cipriani

It is the first magnetically controlled prosthetic hand, that allows amputees to reproduce all movements simply by thinking and to control the force applied when grasping fragile objects. No wires, no electrical connection, only magnets and muscles to control the movements of the fingers and enable everyday activities such as opening a jar, using a screwdriver, picking up a coin.
A research team from the BioRobotics Institute of the Scuola Superiore Sant’Anna in Pisa, coordinated by Prof. Christian Cipriani, has developed a radically new interface between the residual arm of the amputee and the robotic hand to decode motor intentions. The system involves implanting small magnets into the muscles of the forearm. The implant, integrated with the Mia-Hand robotic hand developed by the spin-off Prensilia, was successfully tested on the first patient, a 34-year-old Italian named Daniel, who used the prosthesis for six weeks. The results of the trial were presented in the scientific journal Science Robotics and represent a significant step forward for the future of prostheses.

“This result rewards a decades-long research path. We have finally developed a functional prosthesis that meets the needs of a person who has lost a hand” says Christian Cipriani, professor at the BioRobotics Institute of the Scuola Superiore Sant’Anna.

Myokinetic control for the development of a natural prosthesis

Myokinetic control: the decoding of motor intentions by means of implantable magnets in the muscles. This is the frontier explored by the research team of the Scuola Superiore Sant’Anna to revolutionise the future of prostheses. The idea behind the new interface, developed as part of the MYKI project, funded by the European Commission through an ERC [European Research Council] Starting Grant, is to use small magnets, a few millimetres in size, to be implanted in the residual muscles of the amputated arm and use the movement resulting from contraction to open and close the fingers.

“There are 20 muscles in the forearm and many of them control the hand movements. Many people who have lost a hand keep on feeling it as if it is still in place and the residual muscles move in response to the commands from the brain” Cipriani explains.

The research team mapped the movements and translated them into signals to guide the fingers of the robotic hand. The magnets have a natural magnetic field that can be easily localized in space. When the muscle contracts, the magnet moves and a special algorithm translates this change into a specific command for the robotic hand.

Daniel, the first patient to test the new prosthesis

Daniel lost his left hand in September 2022. “I suddenly found myself without a hand: one moment I had it and the next moment it was gone”. He was selected as a volunteer for the study because he still felt the presence of his hand and the residual muscles in his arm responded to his movement intentions.

In April 2023, Daniel underwent surgery to implant magnets in his arm. The surgery was carried out at the Azienda Ospedaliero-Universitaria Pisana (AOUP), thanks to the collaboration of a team coordinated by Dr Lorenzo Andreani of the Orthopaedics and Traumatology 2 Operative Unit, Dr Manuela Nicastro of the Anaesthesia and Reanimation Orthopaedics and Burns Centre unit, and Dr Carmelo Chisari of the Neurorehabilitation unit.

“This is a significant advancement in the field of advanced prosthetic medicine – says Dr. Lorenzo Andreani – The surgery was successful thanks to a careful patient selection process based on strict criteria. One of the most complex challenges was identifying the residual muscles in the amputation area, which were precisely selected using preoperative MRI imaging and electromyography. However, the actual condition of the tissue, due to scarring and fibrosis, required intraoperative adaptation”.

“Despite these difficulties – Andreani continues – we were able to complete the implant and establish the connections—a success that would have been impossible without the collaboration of an exceptional team, whom I would like to thank. Starting with Dr. Manuela Nicastro, head of anaesthesia, to the nurses who worked with dedication and professionalism, contributing decisively to the positive outcome of the operation, which represents an important step forward in medical research”.

Six magnets were implanted in Daniel’s arm. For each one, the team of surgeons and doctors located and isolated the muscle, positioned the magnet and checked that the magnetic field was oriented in the same way.

“To make the connection between the residual arm where the magnets were implanted and the robotic hand easier, we made a carbon fibre prosthetic socket containing the electronic system capable of localising the movement of the magnets” Cipriani explains.

The results of the experiment went far beyond the most optimistic expectations. Daniel was able to control the movements of his fingers, picked up and moved objects of different shapes, performed classic everyday actions such as opening a jar, using a screwdriver, cutting with a knife, closing a zip; he was able to control the force when he had to grasp fragile objects.

“This system allowed me to recover lost sensations and emotions: it feels like I’m moving my own hand” says Daniel.

“To see the work of years of research realised in this study was a great emotion. Working together with Daniel has given us the awareness that we can do a lot to improve his life and the lives of many other people. This is the greatest motivation that drives us to continue our work and to always do better,” explains Marta Gherardini, assistant professor at the Scuola Superiore Sant’Anna and first author of the study.

Next steps

“We are ready to extend these results to a broader range of amputations – Cipriani concludes – In fact, our work on this new implant is going ahead thanks to European and national funding. Among these, I would like to mention the MYTI [MYKI?} project, financed by the European Research Council, which aims at the clinical translation of the interface we have developed; the Fit For Medical Robotics project, financed by the Ministry of University and Research, and all the collaborations we have had for years with INAIL Centro Protesi”.

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The Sant’Anna School of Advanced Studies (Pisa, Italy) is a public university working in the field of applied sciences: Economics and Management, Law, Political Sciences, Agricultural Sciences and Plant Biotechnology, Medicine, and Industrial and Information Engineering.  It is first in the list of Italian Universities, and consistently in the top 2% globally in the Times Higher Education Young University Rankings. https://www.santannapisa.it/en

If you have Italian language skills or like to listen to Italian, there’s an embedded video in the September 12, 2024 Sant’Anna School of Advanced Studies press release.

Here’s a link to and a citation for the paper,

Restoration of grasping in an upper limb amputee using the myokinetic prosthesis with implanted magnets by Marta Gherardini, Valerio Ianniciello, Federico Masiero, Flavia Paggetti, Daniele D’Accolti, Eliana La Frazia, Olimpia Mani, Stefania Dalise, Katarina Dejanovic, Noemi Fragapane, Luca Maggiani, Edoardo Ipponi, Marco Controzzi, Manuela Nicastro, Carmelo Chisari, Lorenzo Andreani, and Christian Cipriani. Science Robotics 11 Sep 2024 Vol 9, Issue 94 DOI: 10.1126/scirobotics.adp3260

This paper is behind a paywall.

A Victoria & Albert Museum installation integrates of biomimicry, robotic fabrication and new materials research in architecture

The Victoria & Albert Museum (V&A) in London, UK, opened its Engineering Season show on May 18, 2016 (it runs until Nov. 6, 2016) featuring a robot installation and an exhibition putting the spotlight on Ove Arup, “the most significant engineer of the 20th century” according to the V&A’s May ??, 2016 press release,

The first major retrospective of the most influential engineer of the 20th century and a site specific installation inspired by nature and fabricated by robots will be the highlights of the V&A’s first ever Engineering Season, complemented by displays, events and digital initiatives dedicated to global engineering design. The V&A Engineering Season will highlight the importance of engineering in our daily lives and consider engineers as the ‘unsung heroes’ of design, who play a vital and creative role in the creation of our built environment.

Before launching into the robot/biomimicry part of this story, here’s a very brief description of why Ove Arup is considered so significant and influential,

Engineering the World: Ove Arup and the Philosophy of Total Design will explore the work and legacy of Ove Arup (1895-1988), … . Ove pioneered a multidisciplinary approach to design that has defined the way engineering is understood and practiced today. Spanning 100 years of engineering and architectural design, the exhibition will be guided by Ove’s writings about design and include his early projects, such as the Penguin Pool at London Zoo, as well as renowned projects by the firm including Sydney Opera House [Australia] and the Centre Pompidou in Paris. Arup’s collaborations with major architects of the 20th century pioneered new approaches to design and construction that remain influential today, with the firm’s legacy visible in many buildings across London and around the world. It will also showcase recent work by Arup, from major infrastructure projects like Crossrail and novel technologies for acoustics and crowd flow analysis, to engineering solutions for open source housing design.

Robots, biomimicry and the Elytra Filament Pavilion

A May 18, 2016 article by Tim Master for BBC (British Broadcasting Corporation) news online describes the pavilion installation,

A robot has taken up residence at the Victoria & Albert Musuem to construct a new installation at its London gardens.

The robot – which resembles something from a car assembly line – will build new sections of the Elytra Filament Pavilion over the coming months.

The futuristic structure will grow and change shape using data based on how visitors interact with it.

Elytra’s canopy is made up of 40 hexagonal cells – made from strips of carbon and glass fibre – which have been tightly wound into shape by the computer-controlled Kuka robot.

Each cell takes about three hours to build. On certain days, visitors to the V&A will be able to watch the robot create new cells that will be added to the canopy.

Here are some images made available by V&A,

Elytra Filament Pavilion arriving at the V&A, 2016. © Victoria and Albert Museum, London

Elytra Filament Pavilion arriving at the V&A, 2016. © Victoria and Albert Museum, London

Kuka robot weaving Elytra Filament Pavilion cell fibres, 2016. © Victoria and Albert Museum, London

Kuka robot weaving Elytra Filament Pavilion cell fibres, 2016. © Victoria and Albert Museum, London

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Elytra Filament Pavilion at the V&A, 2016. © Victoria and Albert Museum, London

Elytra Filament Pavilion at the V&A, 2016. © Victoria and Albert Museum, London

Here’s more detail from the V&A’s Elytra Filament Pavilion installation description,

Elytra Filament Pavilion has been created by experimental German architect Achim Menges with Moritz Dörstelmann, structural engineer Jan Knippers and climate engineer Thomas Auer.

Menges and Knippers are leaders of research institutes at the University of Stuttgart that are pioneering the integration of biomimicry, robotic fabrication and new materials research in architecture. This installation emerges from their ongoing research projects and is their first-ever major commission in the UK.

The pavilion explores the impact of emerging robotic technologies on architectural design, engineering and making.

Its design is inspired by lightweight construction principles found in nature, the filament structures of the forewing shells of flying beetles known as elytra. Made of glass and carbon fibre, each component of the undulating canopy is produced using an innovative robotic winding technique developed by the designers. Like beetle elytra, the pavilion’s filament structure is both very strong and very light – spanning over 200m2 it weighs less than 2,5 tonnes.

Elytra is a responsive shelter that will grow over the course of the V&A Engineering Season. Sensors in the canopy fibres will collect data on how visitors inhabit the pavilion and monitor the structure’s behaviour, ultimately informing how and where the canopy grows. During a series of special events as part of the Engineering Season, visitors will have the opportunity to witness the pavilion’s construction live, as new components are fabricated on-site by a Kuka robot.

Unfortunately, I haven’t been able to find more technical detail, particularly about the materials being used in the construction of the pavilion, on the V&A website.

One observation, I’m a little uncomfortable with how they’re gathering data “Sensors in the canopy fibres will collect data on how visitors inhabit the pavilion … .” It sounds like surveillance to me.

Nonetheless, the Engineering Season offers the promise of a very intriguing approach to fulfilling the V&A’s mandate as a museum dedicated to decorative arts and design.