Difference between revisions of "Team:Pasteur Paris/Technicals"
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<p>To jump from the first ideas to tangible solutions, we designed a complete system (hardware and software solutions) including:<br> | <p>To jump from the first ideas to tangible solutions, we designed a complete system (hardware and software solutions) including:<br> | ||
| − | - an implantation stem featuring our engineered biofilm | + | - an implantation stem featuring our engineered biofilm<br> |
| − | - a device making the bridge between the stump and a bionic prosthesis, to collect and process the signal from nerves | + | - a device making the bridge between the stump and a bionic prosthesis, to collect and process the signal from nerves<br> |
| − | - a charging station, to recharge the device and synchronize data with a distant server | + | - a charging station, to recharge the device and synchronize data with a distant server<br> |
| − | - an app / website, to monitor | + | - an app / website, to monitor information, such as device’s battery level, health status, etc. |
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<p>In order to design these solutions in a relevant, feasible and comfortable way, we payed strong attention to the device dimensions, ergonomics, assemblies, materials, colors, look and feel, electronic parts, production process and cost. The following device have been conceived and developed thanks to design and engineering knowledge, skills and tools (McNeel Rhino 3D (<b>Figure 1</b>) as 3D modeling tool, Luxion Keyshot as 3D rendering tool), as well as scientific and industrial advice from experts. Colors, materials and finishes have been chosen regarding our device constraints and thanks to material databases and color charts (<b>Figure 2 and 3</b>). </p> | <p>In order to design these solutions in a relevant, feasible and comfortable way, we payed strong attention to the device dimensions, ergonomics, assemblies, materials, colors, look and feel, electronic parts, production process and cost. The following device have been conceived and developed thanks to design and engineering knowledge, skills and tools (McNeel Rhino 3D (<b>Figure 1</b>) as 3D modeling tool, Luxion Keyshot as 3D rendering tool), as well as scientific and industrial advice from experts. Colors, materials and finishes have been chosen regarding our device constraints and thanks to material databases and color charts (<b>Figure 2 and 3</b>). </p> | ||
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<p>We designed a fully functional stem (<b>Figure 4 and 5</b>) composed of:<br> | <p>We designed a fully functional stem (<b>Figure 4 and 5</b>) composed of:<br> | ||
| − | - a biocompatible tube made of titanium, to mechanically assemble the device to the user’s stump (1.). This material have been chosen instead of stainless steel 316L thanks to the mechanical modeling of the 3D representation of a humerus bone with a prosthesis <a href="">(Download the mechanical modeling here)</a> | + | - a biocompatible tube made of titanium, to mechanically assemble the device to the user’s stump (1.). This material have been chosen instead of stainless steel 316L thanks to the mechanical modeling of the 3D representation of a humerus bone with a prosthesis <a href="">(Download the mechanical modeling here)</a><br> |
| − | - a porous ceramic part (2.), surrounding the metallic tube inside the amputee’s bone (3.) to durably and safely link the tube to the bone | + | - a porous ceramic part (2.), surrounding the metallic tube inside the amputee’s bone (3.) to durably and safely link the tube to the bone<br> |
| − | - our engineered biofilm (4.), surrounding the metallic tube inside the amputee’s stump flesh | + | - our engineered biofilm (4.), surrounding the metallic tube inside the amputee’s stump flesh<br> |
| − | - a nanoporous membrane made of PEDOT: PSS (5.), to confine the biofilm within our system, to fixate nerves on it, and to allow the ionic current from nerves to be transformed into an electrical current, that would be processed and used to actuate a bionic prosthesis | + | - a nanoporous membrane made of PEDOT: PSS (5.), to confine the biofilm within our system, to fixate nerves on it, and to allow the ionic current from nerves to be transformed into an electrical current, that would be processed and used to actuate a bionic prosthesis<br> |
- a thin structure (6.) that supports the nanoporous membrane and transmits electric current from nerves to the stem (7., 8.). | - a thin structure (6.) that supports the nanoporous membrane and transmits electric current from nerves to the stem (7., 8.). | ||
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<p>We designed an ergonomic and functional device (<b>Figure 6</b>) to link the stump to a bionic prosthesis, composed of:<br> | <p>We designed an ergonomic and functional device (<b>Figure 6</b>) to link the stump to a bionic prosthesis, composed of:<br> | ||
| − | - a three parts plastic case made of light-weight, heat and shock resistant injection moldable plastic (ABS - Acrylonitrile-Butadiene-Styrene), to safely enclose technical parts. Injection molding is a reliable process that permits a low cost mass production. Two removable shells (1.) surround the main structure (2.) to facilitate maintenance. An elastomer seal (3.) is placed between these parts and make the device waterproof. Moreover, plastic have been textured to make user’s daily interactions with his device easier | + | - a three parts plastic case made of light-weight, heat and shock resistant injection moldable plastic (ABS - Acrylonitrile-Butadiene-Styrene), to safely enclose technical parts. Injection molding is a reliable process that permits a low cost mass production. Two removable shells (1.) surround the main structure (2.) to facilitate maintenance. An elastomer seal (3.) is placed between these parts and make the device waterproof. Moreover, plastic have been textured to make user’s daily interactions with his device easier<br> |
| − | - a antibacterial ceramic shell (4.), placed between the stump and the device, to improve hygiene and to protect the user from friction | + | - a antibacterial ceramic shell (4.), placed between the stump and the device, to improve hygiene and to protect the user from friction <br> |
- electronic parts, to amplify and process the signal (5.), to charge the device (6., 7., 8.), to store (9.) and to send data (10.). | - electronic parts, to amplify and process the signal (5.), to charge the device (6., 7., 8.), to store (9.) and to send data (10.). | ||
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<p>Finally, we designed an app / website to create a user friendly interface. This app / website allows every NeuronArch user to store, monitor, understand, and share with a doctor his personal data. To do so, our app / website (<b>Figure 9</b>) is composed of:<br> | <p>Finally, we designed an app / website to create a user friendly interface. This app / website allows every NeuronArch user to store, monitor, understand, and share with a doctor his personal data. To do so, our app / website (<b>Figure 9</b>) is composed of:<br> | ||
| − | - a personal home page (1.), to have a general overview regarding health data, charging level, and general notifications | + | - a personal home page (1.), to have a general overview regarding health data, charging level, and general notifications<br> |
| − | - a personal dashboard (2.), to monitor recorded health data such as glycemia, blood pressure, etc. | + | - a personal dashboard (2.), to monitor recorded health data such as glycemia, blood pressure, etc.<br> |
| − | - a medical appointment booking platform (3.), including registered primary doctor availabilities, prosthetists locations, etc. | + | - a medical appointment booking platform (3.), including registered primary doctor availabilities, prosthetists locations, etc.<br> |
- a unique QR code (4.), to securely share recorded personal data with the user’s doctors during appointments. </p> | - a unique QR code (4.), to securely share recorded personal data with the user’s doctors during appointments. </p> | ||
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Revision as of 00:43, 17 October 2018
There are many kinds of design approaches : « space designers » create new places to live in, « sound designers » create new experiences to hear, « food designers » create new tastes, « graphic designers » create new signs and symbols to see, and « digital designers » create new interfaces to navigate into the digital world.
iGEM Pasteur Paris team integrates industrial designers from ENSCI-les Ateliers. Industrial design is a creative discipline that aims to produce innovative solutions in order to solve contemporary issues in various fields : health, well-being, energy, mobility, habitat, food, etc. When designing new products or services, designers apply a user centric approach that integrates several notions such as usages, ergonomics, industrial processes, technologies, social, cultural, environmental and economical aspects. Taking into account all these parameters allows designers to conceive solutions that address the targeted issues in a relevant way, and that benefit to the user.
Nowadays, industrial design is evolving. To address problems in a more and more complex and accurate way, industrial designers are getting closer to science by working with scientists and by settling in the labs. Our team is a good example of these new ways to co-create tomorrow’s innovations.
Despite promising opportunities offered by these new cooperations, designers and scientists do not have the same cultures, languages, tools, etc., that prevents these collaborations from reaching their full potential. To overcome these issues, we shared and thought design tools and methodologies with our team mates in order to build a common ground for understanding and co-creation. Once done, we followed the subsequent process :
