Difference between revisions of "Team:Pasteur Paris/Device"

 
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<p><a href="#Implant" class="link">Implanting Functional Stem</a></p>
 
<p><a href="#Implant" class="link">Implanting Functional Stem</a></p>
 
<p><a href="#Connect" class="link">Connection to Stump</a></p>
 
<p><a href="#Connect" class="link">Connection to Stump</a></p>
<p><a href="#Recharge" class="link">Recharging Station</a></p>
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<p><a href="#Recharge" class="link">Charging Station</a></p>
 
<p><a href="#Smartphone" class="link">Smartphone & Web App</a></p>
 
<p><a href="#Smartphone" class="link">Smartphone & Web App</a></p>
 
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<i><p>We designed a global proposition, thinking of dimensions, materials, fabrication processes, always taking into consideration the industrial and medical feasibility and the user’s comfort. Our system includes an implantation stem featuring our engineered biofilm, an interface device to collect and process the signal from nerves, and also connect the future prosthesis. A charging station and an app are also part of our setup.</p></i>
+
<i><p>We designed a global proposal, thinking of dimensions, materials, fabrication processes, always taking into consideration the industrial and medical feasibility and the user’s comfort. Our system includes an implantation stem featuring our engineered biofilm, an interface device to collect and process the signal from nerves, and also connect the future prosthesis. A charging station and an app are also part of our setup.</p></i>
 
</div>
 
</div>
 
<div class="block title" id="Implant"><h3 style="text-align: left;">Implanting a functional stem</h3></div>
 
<div class="block title" id="Implant"><h3 style="text-align: left;">Implanting a functional stem</h3></div>
 
<div class="block full">
 
<div class="block full">
<p>To connect our device to the user’s stump, we designed a technical piece, a fully functional stem, that is osseointegrated.
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<p>To connect our device to the user’s stump, we designed a fully functional osseointegrated stem.
 
</p>
 
</p>
<p>This internal device needs an extremely high precision for machining parts. Indeed, the biofilm and the membrane’s nanometric scales and necessity to extend a member leads to constraining strength and precision’s placement. Directly in contact with bone, the sintered ceramic part links the bone and the titanium stem together (Figure1). Where the stem emerges from the bone, its diameter expands, increasing from 6 mm to 10 mm. The biofilm occupies the space in the few centimeters available between the bone and skin. It is contained by a semi-permeable membrane. The latter, in PEDOT: PSS, is the surface upon which the nerves will come to fixate. This also allows the electric nerve current to transmit to an electrical current on the membrane. This membrane is placed around the tube and will conduct the signal to the outside (Figure 2).</p>
+
<p>This internal device needs an extremely high precision for machining parts. Indeed, the biofilm and the membrane’s nanometric scales, coupled with the necessity to extend a member, lead to constraining strength and precision’s placement. Directly in contact with bone, the sintered ceramic part links the bone and the titanium stem together (Figure1). Where the stem emerges from the bone, its diameter expands, increasing from 6 mm to 10 mm. The biofilm occupies the space in the few centimeters available between the bone and the skin. It is contained by a nanoporous membrane. The latter, made of PEDOT: PSS, is the surface upon which the nerves will come to fixate. This also allows the electric nerve current to be transformed into an electrical current on the membrane. This membrane is placed around the tube and will conduct the signal to the outside(Figure 2).</p>
 
<p>The titanium implanted tube, which is biocompatible, has a resistance as measured by it Young’s modulo of 193 GPa, and a low density of 4510 Kg/M<sup>3</sup> compared to biocompatible stainless steel with  114 GPa and 800 Kg/M<sup>3</sup>. </p>
 
<p>The titanium implanted tube, which is biocompatible, has a resistance as measured by it Young’s modulo of 193 GPa, and a low density of 4510 Kg/M<sup>3</sup> compared to biocompatible stainless steel with  114 GPa and 800 Kg/M<sup>3</sup>. </p>
 
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<p>Once the nerves signal is conducted by the electrical wires, it has to be treated and amplified. This is done into an interface device placed between the stump and the bionic prosthesis. </p>
 
<p>Once the nerves signal is conducted by the electrical wires, it has to be treated and amplified. This is done into an interface device placed between the stump and the bionic prosthesis. </p>
<p>As for the NeuronArch interface device, we chose ABS (Acrylonitrile-Butadiene-Styrene) as the main material. We wanted an injection moldable plastic to reduce the cost of machining as well as it offered the most interesting properties for our project, among all the available materials.</p>
+
<p>As for the NeuronArch interface device, we chose ABS (Acrylonitrile-Butadiene-Styrene) as the main material. We wanted to use an injection moldable plastic to reduce the cost of machining as well as for providing interesting properties for our project such as weight reduction, heat and shock resistance..</p>
 
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<div class="block title" id="Recharge"><h3 style="text-align: left;">Charging and synchronizing the interface device</h3></div>
 
<div class="block title" id="Recharge"><h3 style="text-align: left;">Charging and synchronizing the interface device</h3></div>
 
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<div class="block one-third">
<p>In order to recharge the NeuronArch device, we designed an induction charging box, that includes a power outlet connectable USB-C plug. The compatible loading station is made of ABS and is used for patient data synchronization. It also features a small elevation on the housing that allows the NeuronArch interface device to be perfectly engaged and stable while charging and synchronizing. For storing cables during transportation we anticipated an elastic strip on the back of the station.</p>
+
<p>In order to recharge the NeuronArch device, we designed an induction charging station, that includes a power outlet connectable by a USB-C plug. The compatible loading station is made of ABS and is used for patient data synchronization. It also features a small elevation on the housing that allows the NeuronArchinterface device to be perfectly engaged and stable while charging and synchronizing. For storing cables during transportation we anticipated an elastic strip on the back of the station. </p>
 
</div>
 
</div>
 
<div class="block two-third">
 
<div class="block two-third">

Latest revision as of 11:58, 14 October 2018

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We designed a global proposal, thinking of dimensions, materials, fabrication processes, always taking into consideration the industrial and medical feasibility and the user’s comfort. Our system includes an implantation stem featuring our engineered biofilm, an interface device to collect and process the signal from nerves, and also connect the future prosthesis. A charging station and an app are also part of our setup.

Implanting a functional stem

To connect our device to the user’s stump, we designed a fully functional osseointegrated stem.

This internal device needs an extremely high precision for machining parts. Indeed, the biofilm and the membrane’s nanometric scales, coupled with the necessity to extend a member, lead to constraining strength and precision’s placement. Directly in contact with bone, the sintered ceramic part links the bone and the titanium stem together (Figure1). Where the stem emerges from the bone, its diameter expands, increasing from 6 mm to 10 mm. The biofilm occupies the space in the few centimeters available between the bone and the skin. It is contained by a nanoporous membrane. The latter, made of PEDOT: PSS, is the surface upon which the nerves will come to fixate. This also allows the electric nerve current to be transformed into an electrical current on the membrane. This membrane is placed around the tube and will conduct the signal to the outside(Figure 2).

The titanium implanted tube, which is biocompatible, has a resistance as measured by it Young’s modulo of 193 GPa, and a low density of 4510 Kg/M3 compared to biocompatible stainless steel with 114 GPa and 800 Kg/M3.

Figure 1: diagram of the implantation’s system parts
Figure 2: Implantation’s sectional view

Connecting the device to the stump

Once the nerves signal is conducted by the electrical wires, it has to be treated and amplified. This is done into an interface device placed between the stump and the bionic prosthesis.

As for the NeuronArch interface device, we chose ABS (Acrylonitrile-Butadiene-Styrene) as the main material. We wanted to use an injection moldable plastic to reduce the cost of machining as well as for providing interesting properties for our project such as weight reduction, heat and shock resistance..

Figure 3: Exploded drawing of NeuronArch’s interface device

Charging and synchronizing the interface device

In order to recharge the NeuronArch device, we designed an induction charging station, that includes a power outlet connectable by a USB-C plug. The compatible loading station is made of ABS and is used for patient data synchronization. It also features a small elevation on the housing that allows the NeuronArchinterface device to be perfectly engaged and stable while charging and synchronizing. For storing cables during transportation we anticipated an elastic strip on the back of the station.

Figure 4: Exploded drawing of NeuronArch charging station

Consulting and monitoring data

Figure 5: App’s connection diagram