Difference between revisions of "Team:UESTC-China/Hardware1"

 
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   <ul class="f_mh mya"  style="display: none;margin-left:5px">
<li><a>Overview</a></li>
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<li><a href="#title_1">Overview</a></li>
 
 
<li><a class="ajs">Device design<b class="caret"></b></a></li>
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<li><a class="ajs" href="#title_2">Device design<b class="caret"></b></a></li>
 
<ul class="secondli">
 
<ul class="secondli">
 
<li style="padding-top:10px;"><a href="#stitle_1">Crushing module</a></li>
 
<li style="padding-top:10px;"><a href="#stitle_1">Crushing module</a></li>
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<li><a href="#stitle_4">Water tank module</a></li>
 
<li><a href="#stitle_4">Water tank module</a></li>
 
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</ul>
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<li><a href="#title_3">Safety</a></li>
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                <li><a href="#title_4">Result</a></li>
 
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   <a href="#"> <img  class="up" src="https://static.igem.org/mediawiki/2019/7/7d/T--UESTC-China--up.png" alt="logo" width="100%" > </a> </div>
 
   <a href="#"> <img  class="up" src="https://static.igem.org/mediawiki/2019/7/7d/T--UESTC-China--up.png" alt="logo" width="100%" > </a> </div>
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<div class="bigtitle xlj" id="title_1">
 
<p>Overview</p>
 
<p>Overview</p>
 
</div>  
 
</div>  
 
 
 
<div class="mainbody">
 
<div class="mainbody">
In order to utilize our engineered bacteria to degrade ciprofloxacin in expired drugs, we designed a community drug recycling treatment tank in combination with the third generation fluorescence detection module.<br><br>
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In order to utilize our engineered bacteria to degrade ciprofloxacin in expired drugs, we designed a expired drugs recycling and degrading device in combination with the third generation fluorescence detection module.<br><br>
In order to make it better adapt to more application scenarios and easy to maintain, we adopt a fully modular design, which is mainly divided into two large modules: water tank module and function module. The function module can be further divided into four small modules: a frame module, a pulverizing module, a detection module, and a degradation module.<br><br>
+
In order to make it better adapt to more application scenarios and easy to maintain, we adopt a fully modular design, which is mainly divided into two large modules: water tank module and function module. The function module can be further divided into four small modules: a frame module, a crushing module, a detection module, and a degradation module.<br><br>
We also designed two biosafety lines to ensure the safety of our equipment.
+
We also designed double safety sterilization system to ensure the safety of our equipment.
  
 
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  <div class="words">
 
  <div class="words">
  Fig1. Community drug recycling bin
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  Fig. 1.  Expired drugs recycling and degrading device named Drug Avenger
 
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  </div>
 
</div>
 
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<div class="part">
 
<div class="part">
<div class="bigtitle xxlj">
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<div class="bigtitle xxlj" id="title_2">
 
<p>Device design</p>
 
<p>Device design</p>
 
</div>
 
</div>
 
 
<h2 id="stitle_1">Pulverizing module</h2>
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<h2 id="stitle_1">crushing module</h2>
 
 
 
<div class="mainbody">
 
<div class="mainbody">
We designed the pulverizing module with reference to the principle of the shredder. It is mainly composed of a combination of a cover, a pulverizing wheel, a water pump, a filter membrane and so on.  
+
We designed the crushing module with reference to the principle of the shredder. It is mainly composed of a cover, two crushing wheels, a water pump, a filter membrane and so on.  
Our community drug recovery and treatment tanks have the highest priority in the treatment capacity of the device.
+
Our Drug Avenger takes the degradation ability as the highest priority.
The treatment capacity of the device is the highest priority in our community drug recovery and treatment tanks.
+
The PH of the mobile phase in the whole device is the best working PH of the CrpP, which may result in low solubility of CIP in the drug. This in turn Reduce the efficiency of the device, and our crushing module buffers and solves this problem. After entering the crushing module, the pills or capsules are first crushed into powder by the crushing wheel, and then the pump continues to flush the powder with water to dissolve it. The undissolved powder will be left by the filter membrane until it is dissolved, and the dissolved CIP will flow in the next module.
The ph condition of the mobile phase in the whole device is the best working ph of the crpp enzyme, which may result in low dissolution efficiency of ciprofloxacin in the drug. This in turn affects the work of the device, and our shredding module buffers and solves this problem. After entering the pulverizing module, the tablets or capsules are first pulverized into powder by the pulverizing wheel, and then the pump continues to flush the water to dissolve the powder. The undissolved powder will be left by the filter until it is dissolved, and the dissolved ciprofloxacin will flow in the next module.
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</div>
 
</div>
  
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  <div class="words">
 
  <div class="words">
  Fig2.Pulverizing module
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  Fig. 2. crushing module
 
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<div class="mainbody">
 
<div class="mainbody">
The detection module will act as a sensor for the entire community drug recovery and treatment tank to control the operation of equipment such as pumps in the tank. By placing the Detection of bacteria we produced in the pulverizing module in the detection module, we can detect the ciprofloxacin from the crushing module, and release AHL to the downstream degradation module to open the expression of CrpP. By detecting fluorescence, the detection module can determine whether ciprofloxacin is contained in the water from the crushing module to control the opening and closing of pumps and other equipment. The whole functional module is divided into three layers. In addition to loading the detection module, the second layer reserves a lot of space. In the future, according to the actual situation, the layer can also be equipped with a small water tank to hold the detection bacteria to provide more AHL.
+
The detection module will act as a sensor for the entire Drug Avenger to control the operation of equipment such as pumps in the device. By placing the detection bacteria we produced in the detection module, we can detect the CIP from the crushing module, and release AHL to the degradation module to open the expression of CrpP. By detecting fluorescence, the detection module can judge whether CIP is contained in the water from the crushing module to control the pumps and other equipment running and stop. The whole function module is divided into three layers. In addition to loading the detection module, the second layer reserves a lot of space. In the future, according to the actual situation, the layer can also be equipped with a small water tank to hold the detection bacteria to provide more AHL.
 
</div>
 
</div>
 
 
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  <div class="words">
 
  <div class="words">
  Fig3. Detection module
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  Fig. 3. Detection module
 
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  </div>
 
 
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  <div class="words">
 
  <div class="words">
  Fig4. Detection module placement diagram
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  Fig. 4. Detection module placement diagram
 
  </div>
 
  </div>
 
 
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<div class="mainbody">
 
<div class="mainbody">
The degradation module is mainly composed of a water tank and a pipeline. The water tank is filled with LB to supply degrading bacteria in the pipeline. The pipeline is composed of a bracket and a dialysis bag, and the inside of the pipeline is filled with degrading bacterias embedded by sodium alginate.The water containing ciprofloxacin and AHL from the upper layer will pass through the pipeline, and AHL will induce the degrading bacteria to express CrpP to degrade ciprofloxacin. Finally, the treated water in the pipeline will be transported to the lower layer of the water tank by the pump under the frame module.  
+
The degradation module is mainly composed of a water tank and a pipeline. The water tank is filled with LB to supply degrading bacteria in the pipeline. The pipeline is composed of a keel and a dialysis bag, and the inside of the pipeline is filled with degrading bacterias embedded by sodium alginate.The water containing CIP and AHL from the upper layer will pass through the pipeline, and AHL will induce the degrading bacteria to express CrpP to degrade CIP. Finally, the treated water in the pipeline will be transported to the lower layer of the water tank module by the pump which is under the frame module.  
 
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</div>
 
 
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  <div class="words">
 
  <div class="words">
  Fig5 Degradation module
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  Fig. 5. Degradation module
 
  </div>
 
  </div>
 
 
 
<div class="mainbody">
 
<div class="mainbody">
In the frame module where place degradation module, two bright blue light tubes are installed to keep them alive by using the suicide gene in the degrading bacteria. Once the degrading bacteria in the pipeline leaves, they will die because they cannot receive blue light.
+
In the frame module where place degradation module, two bright blue light tubes are installed to keep the degrading bacteria alive by using the suicide gene in them. Once the degrading bacteria in the pipeline leaves, they will suicide because they cannot receive blue light.
 
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  Fig6. Blu-ray device
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  Fig.6. Blu-ray device
 
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>
 
>
The water tank module is used to supply water to the functional module and to dilute, process and discharge the waste water from the functional module. The water tank module is divided into two layers. The upper layer is used to supply water to the functional module, and the lower layer is provided with a dark room to make the degrading bacteria suicide and a UV lamp can be installed for secondary sterilization to ensure the safety of the device.
+
The water tank module is used to supply water to the function module and to dilute, process and discharge the treated water from the function module. The water tank module is divided into two layers. The upper layer is used to supply water to the function module, and the lower layer is provided with a dark room to make the degrading bacteria suicide and a UV-sterilized lamp can be installed for secondary sterilization to ensure the safety of the device.
 
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  Fig7. Water tank module
 
  Fig7. Water tank module
 
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  </div>
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<div class="part">
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<div class="bigtitle xxlj" id="title_3">Safety</div>
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<div class="mainbody">
 +
In order to achieve the goal of double sterilization system as much as possible to ensure the most effective biosafety, we designed two blue light tubes to ensure the smooth work of the engineering bacteria, and designed a black box to implement the first safety mechanism to prevent engineering <i>E.coli</i> leaks. In addition, we designed to install a UV-sterilized lamp to ensure that all harmful bacteria are killed, and no other super bacteria are produced.
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</div>
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<div class="picture">
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<img src="https://static.igem.org/mediawiki/2019/a/ae/T--UESTC-China--hardware_1_n.png" alt="last" width="80%">
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</div>
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<div class="words">Fig. 8. Safety measures</div>
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</div>
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 +
<div class="part">
 +
<div class="bigtitle xxlj" id="title_4">Result</div>
 +
<div class="mainbody">
 +
We managed to make the degradation module. We first used the sodium alginate to embed the degrading bacteria into small balls, then poured the small balls into the pipes made of dialysis bag , and then loaded the pipes into the water tank filled with PBS buffer (In the future we will add LB to the water tank).We use pumps driven by mobile power supply to run the device and display a fast-forward video.
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</div>
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<div class="picture">
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<img src="https://static.igem.org/mediawiki/2019/6/68/T--UESTC-China--Hardware_1_9.png" alt="9" width="80%">
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</div>
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<div class="words">Fig. 9. Degradation module</div>
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<div style="text-align:center">
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<video  controls preload width="70%" id="video" >
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<source src="https://static.igem.org/mediawiki/2019/5/52/T--UESTC-China--Hardware_1_mp4.mp4" type="video/mp4">
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    </video>
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Latest revision as of 02:01, 22 October 2019

description

0% 完成
logo
logo

Overview

In order to utilize our engineered bacteria to degrade ciprofloxacin in expired drugs, we designed a expired drugs recycling and degrading device in combination with the third generation fluorescence detection module.

In order to make it better adapt to more application scenarios and easy to maintain, we adopt a fully modular design, which is mainly divided into two large modules: water tank module and function module. The function module can be further divided into four small modules: a frame module, a crushing module, a detection module, and a degradation module.

We also designed double safety sterilization system to ensure the safety of our equipment.
logo
Fig. 1. Expired drugs recycling and degrading device named Drug Avenger

Device design

crushing module

We designed the crushing module with reference to the principle of the shredder. It is mainly composed of a cover, two crushing wheels, a water pump, a filter membrane and so on. Our Drug Avenger takes the degradation ability as the highest priority. The PH of the mobile phase in the whole device is the best working PH of the CrpP, which may result in low solubility of CIP in the drug. This in turn Reduce the efficiency of the device, and our crushing module buffers and solves this problem. After entering the crushing module, the pills or capsules are first crushed into powder by the crushing wheel, and then the pump continues to flush the powder with water to dissolve it. The undissolved powder will be left by the filter membrane until it is dissolved, and the dissolved CIP will flow in the next module.
logo
Fig. 2. crushing module

Detection module

The detection module will act as a sensor for the entire Drug Avenger to control the operation of equipment such as pumps in the device. By placing the detection bacteria we produced in the detection module, we can detect the CIP from the crushing module, and release AHL to the degradation module to open the expression of CrpP. By detecting fluorescence, the detection module can judge whether CIP is contained in the water from the crushing module to control the pumps and other equipment running and stop. The whole function module is divided into three layers. In addition to loading the detection module, the second layer reserves a lot of space. In the future, according to the actual situation, the layer can also be equipped with a small water tank to hold the detection bacteria to provide more AHL.
logo
Fig. 3. Detection module
logo
Fig. 4. Detection module placement diagram

Degradation module

The degradation module is mainly composed of a water tank and a pipeline. The water tank is filled with LB to supply degrading bacteria in the pipeline. The pipeline is composed of a keel and a dialysis bag, and the inside of the pipeline is filled with degrading bacterias embedded by sodium alginate.The water containing CIP and AHL from the upper layer will pass through the pipeline, and AHL will induce the degrading bacteria to express CrpP to degrade CIP. Finally, the treated water in the pipeline will be transported to the lower layer of the water tank module by the pump which is under the frame module.
logo
Fig. 5. Degradation module
In the frame module where place degradation module, two bright blue light tubes are installed to keep the degrading bacteria alive by using the suicide gene in them. Once the degrading bacteria in the pipeline leaves, they will suicide because they cannot receive blue light.
logo
Fig.6. Blu-ray device

Water tank module

The water tank module is used to supply water to the function module and to dilute, process and discharge the treated water from the function module. The water tank module is divided into two layers. The upper layer is used to supply water to the function module, and the lower layer is provided with a dark room to make the degrading bacteria suicide and a UV-sterilized lamp can be installed for secondary sterilization to ensure the safety of the device.
logo
Fig7. Water tank module
Safety
In order to achieve the goal of double sterilization system as much as possible to ensure the most effective biosafety, we designed two blue light tubes to ensure the smooth work of the engineering bacteria, and designed a black box to implement the first safety mechanism to prevent engineering E.coli leaks. In addition, we designed to install a UV-sterilized lamp to ensure that all harmful bacteria are killed, and no other super bacteria are produced.
last
Fig. 8. Safety measures
Result
We managed to make the degradation module. We first used the sodium alginate to embed the degrading bacteria into small balls, then poured the small balls into the pipes made of dialysis bag , and then loaded the pipes into the water tank filled with PBS buffer (In the future we will add LB to the water tank).We use pumps driven by mobile power supply to run the device and display a fast-forward video.
9
Fig. 9. Degradation module
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