Difference between revisions of "Team:XJTU-China/Drylab-Models"

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             <li class="nav-item"><a href="#section4">Microfluidics Model</a></li>
 
             <li class="nav-item"><a href="#section4">Microfluidics Model</a></li>
 
             <li class="nav-item"><a href="#section5">Market Prediction</a></li>
 
             <li class="nav-item"><a href="#section5">Market Prediction</a></li>
 +
            <li class="nav-item"><a href="#section6">Results and Discussion</a></li>
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           </ul>
 
           </ul>
 
         </nav>
 
         </nav>
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<p>In order to predict the concentration of different substance in E.coli, we set the kinetic model according to the reaction rate theory and enzymatic reaction kinetics as our first model in our project. And the production and conversion rate model is included to simulate the directed evolution model and the natural evolution model, and then we can get the time we need in our directed evolution method of DTE. The third model we set up is the microfluidics model to predict and simulate the situation in the microfluidics chip, which is our hardware for the gradient concentration of the psicose and antibiotic to let us have a high throughput experiment. The fourth model we set is the market model to predict the future market and the coefficient between different age groups and the tendency to adopt psicose.</p>
+
       <p>In order to predict the concentration of different substance in E.coli, we set the kinetic model according to the reaction rate theory and enzymatic reaction kinetics as our first model in our project.  
 +
And the production and conversion rate model is included to simulate the directed evolution model and the natural evolution model, and then we can get the time we need in our directed evolution method of DTE.  
 +
The third model we set up is the microfluidics model to predict and simulate the situation in the microfluidics chip, which is our hardware for the gradient concentration of the psicose and antibiotic to let us have a high throughput experiment.  
 +
The fourth model we set is the market model to predict the future market and the coefficient between different age groups and the tendency to adopt psicose.</p>
  
  
  
 
<ol>
 
<ol>
<li>Psicose Synthesis Kinetic Model</li>
+
  <li>Psicose Synthesis Kinetic Model</li>
<li>Production Simulink Model</li>
+
  <li>Production Simulink Model</li>
<li>Market Model</li>
+
  <li>Market Model</li>
<li>Microfluidics Model</li>
+
  <li>Microfluidics Model</li>
  
 
</ol>
 
</ol>
  
 +
   </div>
 +
 +
 +
            <div id="section2">
 +
              <div class="page-header">
 +
                <h2>Psicose Synthesis Kinetic Model</h2>
 +
              </div>
 +
<div align="center"><h3>The Establishment of Psicose Synthesis Kinetic Model</h3></div>
 +
 +
<!--div class="page-header" id="section2">
 
</div>
 
</div>
<div class="page-header" id="section2">
+
<h2>Psicose synthesis kinetic model</h2-->
</div>
+
<h2>Psicose synthesis kinetic model</h2>
+
  
  
 
<p>In our design, the DTE process is one of the most significant part in manufacturing psicose. The main process of psicose manufacture is catalyzed by D-psicose 3-epimerase. The models of device A, B, C and D are as follows.</p>
 
<p>In our design, the DTE process is one of the most significant part in manufacturing psicose. The main process of psicose manufacture is catalyzed by D-psicose 3-epimerase. The models of device A, B, C and D are as follows.</p>
  
<img src=""/>
+
<div align="center"><img src="https://static.igem.org/mediawiki/2018/d/d7/T--XJTU-China--181016d02.png"width="400"/></div>
  
 
<p>In device A, extracellular concentration of $psicose$ is higher than the intracellular concentration, so it can enter the cells by diffusion. As a small molecular, the $psicose$ inside the cell can be combined with $pPsiR$ to generate $CCI$. $pPsiR$ is a repressor, which can bind to promoters on DNA and block gene expression. After binding with $psicode$,$pPsiR$ falls off from the promoter and the gene starts expressing, And eventually produce the produce $EGFP$.</p>
 
<p>In device A, extracellular concentration of $psicose$ is higher than the intracellular concentration, so it can enter the cells by diffusion. As a small molecular, the $psicose$ inside the cell can be combined with $pPsiR$ to generate $CCI$. $pPsiR$ is a repressor, which can bind to promoters on DNA and block gene expression. After binding with $psicode$,$pPsiR$ falls off from the promoter and the gene starts expressing, And eventually produce the produce $EGFP$.</p>
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<p>Where $n$ is hill coefficient, $K$ is the ligand concentration producing half occupation, $\beta_{EGFP}$ is maximal transcription rate of gene $EGFP$, and $H$ is a constant used to indicate the deviation between the theoretical and actual values.</p>
 
<p>Where $n$ is hill coefficient, $K$ is the ligand concentration producing half occupation, $\beta_{EGFP}$ is maximal transcription rate of gene $EGFP$, and $H$ is a constant used to indicate the deviation between the theoretical and actual values.</p>
  
<p><br>Calculating Results</p>
 
  
<img src="">
+
<div align="center"><img src="https://static.igem.org/mediawiki/2018/d/d0/T--XJTU-China--181016d03.png"width="400"/></div>
  
 
<p>In device B, extracellular concentration of $IPTG$ is higher than which is intracellular, so it can enter the cells by diffusion. As a small molecular, the $IPTG$ inside the cell can be combined with $pLacR$ to generate $CC$. $pLacR$ is a repressor, which can bind to promoters on DNA and block gene expression. After binding with $IPTG$, $pLacR$ falls off from the promoter and the gene starts expressing, And eventually produce the produce $EGFP$. Since the gene of $ABR$ and the gene of $EGFP$ are connected in series, they are expressed together.</p>
 
<p>In device B, extracellular concentration of $IPTG$ is higher than which is intracellular, so it can enter the cells by diffusion. As a small molecular, the $IPTG$ inside the cell can be combined with $pLacR$ to generate $CC$. $pLacR$ is a repressor, which can bind to promoters on DNA and block gene expression. After binding with $IPTG$, $pLacR$ falls off from the promoter and the gene starts expressing, And eventually produce the produce $EGFP$. Since the gene of $ABR$ and the gene of $EGFP$ are connected in series, they are expressed together.</p>
  
<p><br>Similarly, we can get the function of device B by using the reaction rate equation and the diffusion function. First,</p>
+
<p>Similarly, we can get the function of device B by using the reaction rate equation and the diffusion function. First,</p>
 
<p>$$\frac{\text{d}[IPTGO]}{\text{d}t}=0$$</p>
 
<p>$$\frac{\text{d}[IPTGO]}{\text{d}t}=0$$</p>
  
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<p>$$\frac{\text{d}[CC]}{\text{d}t}=-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{CC}[CC]$$</p>
 
<p>$$\frac{\text{d}[CC]}{\text{d}t}=-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{CC}[CC]$$</p>
 
<p>And $pLac$ is a transcription activator of gene $EGFP$, according to hill equation, the concentration of $EGFP$ is </p>
 
<p>And $pLac$ is a transcription activator of gene $EGFP$, according to hill equation, the concentration of $EGFP$ is </p>
<p>$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pLacR]^n} -\delta_{EGFP}[EGFP]$$</p>
+
<p>$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pLacR]^n} -\delta_{EGFP} [EGFP] $$</p>
 
<p>The concentration of $EGFP$ is the same as the concentration of antibiotics resistance due to the transcription and translation of antibiotic resistance gene combined with the gene of $EGFP$.</p>
 
<p>The concentration of $EGFP$ is the same as the concentration of antibiotics resistance due to the transcription and translation of antibiotic resistance gene combined with the gene of $EGFP$.</p>
 
<p>$$\frac{\text{d}[EGFP]}{\text{d}t}=\frac{\text{d}[ABR]}{\text{d}t}$$</p>
 
<p>$$\frac{\text{d}[EGFP]}{\text{d}t}=\frac{\text{d}[ABR]}{\text{d}t}$$</p>
 
<p>Where $[EGFP]$ is the concentration of $EGFP$ and $[ABR]$ is the concentration of antibiotic resistance protein expression.</p>
 
<p>Where $[EGFP]$ is the concentration of $EGFP$ and $[ABR]$ is the concentration of antibiotic resistance protein expression.</p>
<img src="">
 
  
 +
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/5/59/T--XJTU-China--181016d04.png"width="400"/></div>
  
 
<p>Device C is the same with device B. The only difference is the hairpin between gene of $EGFP$ and gene of $RFP$. Similarly, we can get the function of hairpin and its coefficient.</p>
 
<p>Device C is the same with device B. The only difference is the hairpin between gene of $EGFP$ and gene of $RFP$. Similarly, we can get the function of hairpin and its coefficient.</p>
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<p>$$\frac{\text{d}[pLacR]}{\text{d}t}=\alpha_{pLacR}-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{pLacR}[pLacR]$$</p>
 
<p>$$\frac{\text{d}[pLacR]}{\text{d}t}=\alpha_{pLacR}-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{pLacR}[pLacR]$$</p>
 
<p>$$\frac{\text{d}[CC]}{\text{d}t}=m_{IPTG,pLacR}[IPTGI][pLacR]-m_{CC}[CC]-\delta_{CC}[CC]$$</p>
 
<p>$$\frac{\text{d}[CC]}{\text{d}t}=m_{IPTG,pLacR}[IPTGI][pLacR]-m_{CC}[CC]-\delta_{CC}[CC]$$</p>
<p><br>$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pLacR]^n} -\delta_{EGFP}[EGFP]$$</p>
+
<p><br>$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pLacR]^n} -\delta_{EGFP} [EGFP]$$</p>
 
<p>The presence of the hairpin leads to a decrease in $RFP$ expression efficiency, so we have</p>
 
<p>The presence of the hairpin leads to a decrease in $RFP$ expression efficiency, so we have</p>
 
<p>$$\frac{\text{d}[EGFP]}{\text{d}t}=k\frac{\text{d}[RFP]}{\text{d}t}$$</p>
 
<p>$$\frac{\text{d}[EGFP]}{\text{d}t}=k\frac{\text{d}[RFP]}{\text{d}t}$$</p>
 
<p>Where $[RFP]$ is the concentration of red fluorescence protein, $k$ is the coefficient of hairpin.</p>
 
<p>Where $[RFP]$ is the concentration of red fluorescence protein, $k$ is the coefficient of hairpin.</p>
<img src="">
+
 
 +
 
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/c/cc/T--XJTU-China--181016d05.png"width="500"/></div>
  
  
 
<p>In device D, $IPTG$ gets in cells and bind with $pLacR$, which is a repressor for gene $DTE$. After $IPTG$ binding with $pLacR$, $DTE$ starts to express, and as an enzyme, to catalysis $fructose$ to turn into $psicose$. As more and more $psicose$ are produced, more and more the repressor of gene $EGFP$, $pLacR$ are inactivated, so expression of $EGPF$ increase. At the same time, expression of $ABR$ also increase since the gene of $ABR$ and the gene of $EGFP$ are connected in series by a hairpin.</p>
 
<p>In device D, $IPTG$ gets in cells and bind with $pLacR$, which is a repressor for gene $DTE$. After $IPTG$ binding with $pLacR$, $DTE$ starts to express, and as an enzyme, to catalysis $fructose$ to turn into $psicose$. As more and more $psicose$ are produced, more and more the repressor of gene $EGFP$, $pLacR$ are inactivated, so expression of $EGPF$ increase. At the same time, expression of $ABR$ also increase since the gene of $ABR$ and the gene of $EGFP$ are connected in series by a hairpin.</p>
 
<p>For device D, $psicose$ and $fuctose$ get in cells by diffusion:</p>
 
<p>For device D, $psicose$ and $fuctose$ get in cells by diffusion:</p>
<p>$$\frac{\text{d}[PsiO]}{\text{d}t}=\frac{-\gamma_{F}([PsiO]-[PsiI])}{V_{outside}}=0$$</p>
+
<p>$$\frac{\text{d}[PsiO]}{\text{d}t}=\frac{-\gamma_{F}([PsiO]-[PsiI])}{V_{outside}}=0 $$</p>
 
<p>$$\frac{\text{d}[FO]}{\text{d}t}=\frac{-\gamma_{F}([FO]-[FI])}{V_{outside}}=0$$</p>
 
<p>$$\frac{\text{d}[FO]}{\text{d}t}=\frac{-\gamma_{F}([FO]-[FI])}{V_{outside}}=0$$</p>
 
<p>$$\frac{\text{d}[IPTGO]}{\text{d}t}=\frac{-\gamma_{F}([IPTGO]-[IPTGI])}{V_{outside}}=0$$</p>
 
<p>$$\frac{\text{d}[IPTGO]}{\text{d}t}=\frac{-\gamma_{F}([IPTGO]-[IPTGI])}{V_{outside}}=0$$</p>
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<p>$$\frac{\text{d}[pPsiR]}{\text{d}t}=\alpha_{pPsiR}-m_{pPsiR,PsiI}[pPsiR][PsiI]+m_{CCI}[CCI]-\delta_{pLacR}[pLacR]$$</p>
 
<p>$$\frac{\text{d}[pPsiR]}{\text{d}t}=\alpha_{pPsiR}-m_{pPsiR,PsiI}[pPsiR][PsiI]+m_{CCI}[CCI]-\delta_{pLacR}[pLacR]$$</p>
 
<p>$$\frac{\text{d}[pPsiR]}{\text{d}t}=\alpha_{pPsiR}-m_{pPsiR,Psi}[PsiI][pPsiR]+m_{CCI}[CCI]-\delta_{pPsiR}[pPsiR]$$</p>
 
<p>$$\frac{\text{d}[pPsiR]}{\text{d}t}=\alpha_{pPsiR}-m_{pPsiR,Psi}[PsiI][pPsiR]+m_{CCI}[CCI]-\delta_{pPsiR}[pPsiR]$$</p>
<p>$$\frac{\text{d}[pPsiR]}{\text{d}}CC}t}=m_{IPTG,pLacR}[PsiI][pPsiR]-m_{CC}[CC]-\delta_{CC}[CC]$$</p>
+
 
<p>$$\frac{\text{d}[CCI]}{\text{d}}CC}t}=m_{pSiR}[PsiI][pPsiR]-m_{CCI}[CCI]-\delta_{CCI}[CCI]$$</p>
+
<p>$$\frac{\text{d}[CC]}{\text{d} t}=m_{IPTG,pLacR}[PsiI][pPsiR]-m_{CC}[CC]-\delta_{CC}[CC]$$</p>
 +
<p>$$\frac{\text{d}[CCI]}{\text{d} t}=m_{pSiR}[PsiI][pPsiR]-m_{CCI}[CCI]-\delta_{CCI}[CCI]$$</p>
 +
 
 
<p>$$\frac{\text{d}[DTE]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pLacR]^n}-\delta_{DTE}[DTE]$$</p>
 
<p>$$\frac{\text{d}[DTE]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pLacR]^n}-\delta_{DTE}[DTE]$$</p>
 
<p>$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pPsiR]^n}-\delta_{EGFP}[EGFP]$$</p>
 
<p>$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pPsiR]^n}-\delta_{EGFP}[EGFP]$$</p>
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</div>
 
</div>
 +
<div class="page-header" id="section3">
  
  
</div>
 
<div class="page-header" id="section3">
 
</div>
 
 
<h2>Production and Conversion Rate Simulink Model</h2>
 
<h2>Production and Conversion Rate Simulink Model</h2>
 
+
<div align="center"><h3>The Establishment of Production and Conversion Rate Simulink Model</h3></div>
 
+
 
+
 
+
  
  
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<p>$$grsRate~N(0,errRate)$$</p>
 
<p>$$grsRate~N(0,errRate)$$</p>
 
<p>If we set X as production growth rate,$\sigma^2$ as error rate, then we will get</p>
 
<p>If we set X as production growth rate,$\sigma^2$ as error rate, then we will get</p>
<p>$X\~{}N(0,\sigma^2)$ </p>
+
 
 +
<p>$X ~{}N(0,\sigma^2)$ </p>
 +
 
 
<p>And the probability density function is </p>
 
<p>And the probability density function is </p>
 
<p>$$f(x\mid 0,\sigma^2)=\frac{1}{\sqrt{2\pi\sigma^2}}e^{-\frac{x^2}{2\sigma^2}}$$</p>
 
<p>$$f(x\mid 0,\sigma^2)=\frac{1}{\sqrt{2\pi\sigma^2}}e^{-\frac{x^2}{2\sigma^2}}$$</p>
 
<p>The probability of production growth rate is </p>
 
<p>The probability of production growth rate is </p>
<p>$$P(x_1 \textless grsRat \textless x_2)=F(x_2)-F(x_1)=\int_{x_1}^{x_2}f(x)dx$$</p>
+
 
 +
<p>$$P(x_1 < grsRat < x_2)=F(x_2)-F(x_1)=\int_{x_1}^{x_2}f(x)dx$$</p>
 
<p>The original production is also vital when we simulate the production of our system by reason that the larger our system is, the more psicose we will get in our manufacturing and it makes no sense to compare a certain system with another in a totally different scale. So the standardization and the estimation of original production for psicose is necessary.</p>
 
<p>The original production is also vital when we simulate the production of our system by reason that the larger our system is, the more psicose we will get in our manufacturing and it makes no sense to compare a certain system with another in a totally different scale. So the standardization and the estimation of original production for psicose is necessary.</p>
 
<p>There are many variables which have impacts on the original production, such as the quantity of E.coli, the growth rate of E.coli, the conversion rate of psicose and the total amount of substrate which determines the scale of the production system. The original production rate is as follows </p>
 
<p>There are many variables which have impacts on the original production, such as the quantity of E.coli, the growth rate of E.coli, the conversion rate of psicose and the total amount of substrate which determines the scale of the production system. The original production rate is as follows </p>
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</div>
 
 
</div>
 
</div>
 
<div class="page-header" id="section4">
 
<div class="page-header" id="section4">
 
<h2>Microfludics Model</h2>
 
<h2>Microfludics Model</h2>
 
+
<div align="center"><h3>The Establishment of Microfludics Model</h3></div>
  
  
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<p>In our Lab tour, we find that it is extremely complicated to use pipette to prepare and transfer solutions, especially gradient concentration solutions. High throughput methods to get the gradient concentration of solutions are well needed. In this case, we made a hardware by using the principle of microfluidics and then we simulate it whether it can give us different concentration by using the microfluidics device before the microfluidics chip is finally made. To get the downstream concentration of high concentration and low concentration, particle collision is used to demonstrate the downstream concentration.</p>
 
<p>In our Lab tour, we find that it is extremely complicated to use pipette to prepare and transfer solutions, especially gradient concentration solutions. High throughput methods to get the gradient concentration of solutions are well needed. In this case, we made a hardware by using the principle of microfluidics and then we simulate it whether it can give us different concentration by using the microfluidics device before the microfluidics chip is finally made. To get the downstream concentration of high concentration and low concentration, particle collision is used to demonstrate the downstream concentration.</p>
  
<img src="">
+
<div align="center"><img src="https://static.igem.org/mediawiki/2018/b/b5/T--XJTU-China--181016d06.png"width="500"/></div>
  
  
 
<p>When the fluid flows into the vertical channel of the microfluidics chip, the number of the solute is equal and both are half of the original quantity. In this case, the concentration of the both sides or both directions are the same with the half original concentration.</p>
 
<p>When the fluid flows into the vertical channel of the microfluidics chip, the number of the solute is equal and both are half of the original quantity. In this case, the concentration of the both sides or both directions are the same with the half original concentration.</p>
<p>$$m_3=m_4=\fac{1}{2}m_1\qquad m_5=m_6=\frac{1}{2}m_2$$</p>
+
<p>$$m_3=m_4=\frac{1}{2}m_1\qquad m_5=m_6=\frac{1}{2}m_2$$</p>
<p>$$n_3=n_4=\fac{1}{2}n_1\qquad n_5=n_6=\frac{1}{2}n_2$$</p>
+
<p>$$n_3=n_4=\frac{1}{2}n_1\qquad n_5=n_6=\frac{1}{2}n_2$$</p>
 
<p>$$c_3=c_4=c_1\qquad c_5=c_6=c_2$$</p>
 
<p>$$c_3=c_4=c_1\qquad c_5=c_6=c_2$$</p>
 
<p>When the liquid flows to the corner of the channels, the momentum is considered as a constant due to the orthogonal relation between the vertical channel and the horizontal channel. According to the momentum conservation theorem, we can get</p>
 
<p>When the liquid flows to the corner of the channels, the momentum is considered as a constant due to the orthogonal relation between the vertical channel and the horizontal channel. According to the momentum conservation theorem, we can get</p>
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<p>$$m_4\overrightarrow{v_1}+ m_5\overrightarrow{v_2}=kn_7c_7\overrightarrow{v_3}+\int{f(n{4,5},ll)dt}$$</p>
 
<p>$$m_4\overrightarrow{v_1}+ m_5\overrightarrow{v_2}=kn_7c_7\overrightarrow{v_3}+\int{f(n{4,5},ll)dt}$$</p>
 
<p>Therefore,</p>
 
<p>Therefore,</p>
<p>$$n_7=\frac{m_4 \overrightarrow{v_1} +m_5 \overrightarrow{v_2} - \int{f(n,l)} dt}{kc_7 \overrightarrow{v_3}$$</p>
+
<p>$$n_7=\frac{m_4 \overrightarrow{v_1} +m_5 \overrightarrow{v_2} - \int{f(n,l)} dt}{kc_7 \overrightarrow{v_3}}$$</p>
 
<p>$$m_7 = kn_7 c_7$$</p>
 
<p>$$m_7 = kn_7 c_7$$</p>
 
<p>And $(m,n,c)$ at the convergence point can be fully determined.</p>
 
<p>And $(m,n,c)$ at the convergence point can be fully determined.</p>
<p>To simplify the calculation, consider the resistance $\int{f(n,l)dt$ as a constant, and the speed inside the channel keeps constant either.</p>
+
<p>To simplify the calculation, consider the resistance $\int f(n,l)dt$ as a constant, and the speed inside the channel keeps constant either.</p>
 
<p>For the channel at the first column at each row,</p>
 
<p>For the channel at the first column at each row,</p>
 
<p>$$ c(i, 1)=c(1,1)$$</p>
 
<p>$$ c(i, 1)=c(1,1)$$</p>
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<p>$$n(i,j)=\frac{m(i-1,j-1)\times \vec{v}+m(i-1,j)\times \vec{v}-\int f(n,l)dt}{kc(i,j)\vec{v}}$$</p>
 
<p>$$n(i,j)=\frac{m(i-1,j-1)\times \vec{v}+m(i-1,j)\times \vec{v}-\int f(n,l)dt}{kc(i,j)\vec{v}}$$</p>
 
<p>To solve our model ,the Navier-Stokes Equations are adopted with the assumption of momentum conservation and mass conservation.</p>
 
<p>To solve our model ,the Navier-Stokes Equations are adopted with the assumption of momentum conservation and mass conservation.</p>
<img src="">
+
 
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/f/f2/T--XJTU-China--181016d07.png"width="550"/></div>
 +
 
 
<p>The results are based on the assumptions as follows:</p>
 
<p>The results are based on the assumptions as follows:</p>
 
<p>Assumptions:</p>
 
<p>Assumptions:</p>
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<p>Where $D$ is the diffusion coefficient of the liquid and $c$ is the concentration of the solution.</p>
 
<p>Where $D$ is the diffusion coefficient of the liquid and $c$ is the concentration of the solution.</p>
 
<p>Taking $m,n,c$ we have mentioned, we can get the concentration distribution as follows: </p>
 
<p>Taking $m,n,c$ we have mentioned, we can get the concentration distribution as follows: </p>
<img src="">
 
  
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/1/1b/T--XJTU-China--181016d08.png"width="400"/></div>
  
  
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<div class="page-header" id="section5">
 
<div class="page-header" id="section5">
 
<h2>Potential Market Model</h2>
 
<h2>Potential Market Model</h2>
 +
<div align="center"><h3>The Establishment of Potential Market Model</h3></div>
  
  
  
 +
<p>In our market model, we’d like to analyze the relationship between the choice of psicose and the market scale. Then, the market od psicose is predicted.</p>
  
<p>In our market model, we’d like to</p>
+
 
 +
 
 +
</div>
 +
<div class="page-header" id="section6">
 
<h2>Results and Discussion </h2>
 
<h2>Results and Discussion </h2>
 
</div>
 
</div>
  
<img src="">
 
<img src="">
 
<img src="">
 
<img src="">
 
<img src="">
 
  
 +
 +
<p>Basing our model, we can calculate and simulate our system as follows:</p>
 +
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/2/2c/T--XJTU-China--181016d09.png"width="400"/></div>
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/3/3e/T--XJTU-China--181016d10.pngg"width="400"/></div>
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/f/f8/T--XJTU-China--181016d11.png"width="400"/></div>
 +
<p>From the picture below, it is evident that with time going by, the concentration of IPTG outside the cell will decrease due to the diffusion process, while the RFP expression level is increasing stably.</p>
 +
 +
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/e/e0/T--XJTU-China--18101d12.png"width="400"/></div>
 +
<div align="center"><img src="https://static.igem.org/mediawiki/2018/9/98/T--XJTU-China--181016d13.png"width="400"/></div>
 +
<p>If we do more experiments shown below, we can find that the expression level of RFP is increasing with the increase of the concentration of IPTG, which proves that we can get a linear range of IPTG to get the RFP expression level. According to device A, B, C, D, this conclusion can also be made, which proves the validation of our kinetic model</p>
  
 
<h2>Reference</h2>
 
<h2>Reference</h2>

Latest revision as of 02:49, 16 October 2018

Modelling

       

In order to predict the concentration of different substance in E.coli, we set the kinetic model according to the reaction rate theory and enzymatic reaction kinetics as our first model in our project. And the production and conversion rate model is included to simulate the directed evolution model and the natural evolution model, and then we can get the time we need in our directed evolution method of DTE. The third model we set up is the microfluidics model to predict and simulate the situation in the microfluidics chip, which is our hardware for the gradient concentration of the psicose and antibiotic to let us have a high throughput experiment. The fourth model we set is the market model to predict the future market and the coefficient between different age groups and the tendency to adopt psicose.

      
  1. Psicose Synthesis Kinetic Model
  2.   
  3. Production Simulink Model
  4.   
  5. Market Model
  6.   
  7. Microfluidics Model
   

The Establishment of Psicose Synthesis Kinetic Model

In our design, the DTE process is one of the most significant part in manufacturing psicose. The main process of psicose manufacture is catalyzed by D-psicose 3-epimerase. The models of device A, B, C and D are as follows.

In device A, extracellular concentration of $psicose$ is higher than the intracellular concentration, so it can enter the cells by diffusion. As a small molecular, the $psicose$ inside the cell can be combined with $pPsiR$ to generate $CCI$. $pPsiR$ is a repressor, which can bind to promoters on DNA and block gene expression. After binding with $psicode$,$pPsiR$ falls off from the promoter and the gene starts expressing, And eventually produce the produce $EGFP$.


For device A, the dynamic equation can be listed as follows:

Concentrations of A and B are different inside and outside the cell, so the diffusion rate of $psicose$ is proportional to the concentration difference between inside and outside of the cells.

$$\frac{\text{d}[PsiO]}{ \text{d}t}V_{outside}=-\gamma_F([PsiO]-[PsiI])$$

Where $\gamma_F$ is the diffusion coefficient.

Consider the external solution as an infinitely solution, which means $V_{outside}\rightarrow\infty$ , so

$$\frac{\text{d}[PsiO]}{ \text{d}t}=0$$

When reducer psicose combines with repressor, the process is

$$PsiI+pPsiR\rightarrow CCI$$

Where $PsiI$ is the intracellular $psicose$, $pPsiR$ is $psicose$ dependent repressor and $CCI$ is $psicose$-repressor complex. The change in concentration of $PsiI$,$pPsiR$ and $CCI$ contains three influencing factors: the binding reaction of $pPsiR$ and $psicose$, and the degradation reaction of themselves and the reverse reaction. Here we consider the binding reaction as a second order reaction and the degradation reaction and reverse reaction as first order reactions. According to law of mass action, reaction rate is proportional to the product of the reactant concentration, so we have

$$\frac{\text{d}[PsiI]}{\text{d}t}=\frac{-\gamma_F([PsiI]-[PsiO])}{V_{cell}}-m_{pPsiR,Psi}[PsiI][pPsiR]+m_{CCI}[CCI]-\delta_{PsiI}[PsiI]$$

And considering $pPsiR$ is constantly expressing, we can get

$$\frac{\text{d}[pPsiR]}{\text{d}t}=\alpha_{pPsiR}-m_{pPsiR,Psi}[PsiI][pPsiR]+m_{CCI}[CCI]-\delta_{pPsiR}[pPsiR]$$

Where $m_{pPsiR,Psi}$ is the coefficient of reaction rate of the binding reaction, $\alpha_{pPsiR}$ is the rate of constant expression of $pPsiR$, $\delta_{pPsiR}$ and $\delta_{PsiI}$ are coefficients of reaction rate of the degradation reaction of $pPsiR$ and $PsicoseI$ respectively.


The concentration of inactivated repressor is

$$\frac{\text{d}[CCI]}{\text{d}t}=m_{pPsiR,Psi}[PsiI][pPsiR]+m_{CCI}[CCI]-\delta_{CCI}[CCI]$$

The change in $EGFP$ concentration depends on the concentration of its repressor, $pPsiR$ which can be described by Hill-equation. Considering $EGFP$ is also degrading, the equation is

$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pPsiR]^n} -\delta_{EGFP}[EGFP]$$

Where $n$ is hill coefficient, $K$ is the ligand concentration producing half occupation, $\beta_{EGFP}$ is maximal transcription rate of gene $EGFP$, and $H$ is a constant used to indicate the deviation between the theoretical and actual values.

In device B, extracellular concentration of $IPTG$ is higher than which is intracellular, so it can enter the cells by diffusion. As a small molecular, the $IPTG$ inside the cell can be combined with $pLacR$ to generate $CC$. $pLacR$ is a repressor, which can bind to promoters on DNA and block gene expression. After binding with $IPTG$, $pLacR$ falls off from the promoter and the gene starts expressing, And eventually produce the produce $EGFP$. Since the gene of $ABR$ and the gene of $EGFP$ are connected in series, they are expressed together.

Similarly, we can get the function of device B by using the reaction rate equation and the diffusion function. First,

$$\frac{\text{d}[IPTGO]}{\text{d}t}=0$$

According to the reaction between $IPTGI$ and $pLacR$ and the reaction rate equation, we can get

$$IPTGI+pLacR\rightarrow CC$$

This reaction is similar with the reaction in device A, so we have

$$\frac{\text{d}[IPTGI]}{\text{d}t}=\frac{-\gamma_{IPTG}([IPTGI]-[IPTGO])}{V_{cell}}-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{IPTG}[IPTGI]$$

Similarly, we can also get

$$\frac{\text{d}[pLacR]}{\text{d}t}=\alpha_{pLacR}-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{pLacR}[pLacR]$$

$$\frac{\text{d}[CC]}{\text{d}t}=-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{CC}[CC]$$

And $pLac$ is a transcription activator of gene $EGFP$, according to hill equation, the concentration of $EGFP$ is

$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pLacR]^n} -\delta_{EGFP} [EGFP] $$

The concentration of $EGFP$ is the same as the concentration of antibiotics resistance due to the transcription and translation of antibiotic resistance gene combined with the gene of $EGFP$.

$$\frac{\text{d}[EGFP]}{\text{d}t}=\frac{\text{d}[ABR]}{\text{d}t}$$

Where $[EGFP]$ is the concentration of $EGFP$ and $[ABR]$ is the concentration of antibiotic resistance protein expression.

Device C is the same with device B. The only difference is the hairpin between gene of $EGFP$ and gene of $RFP$. Similarly, we can get the function of hairpin and its coefficient.

The first few equations are the same as in device B:

$$\frac{\text{d}[IPTGO]}{\text{d}t}=0$$

$$\frac{\text{d}[IPTGI]}{\text{d}t}=\frac{-\gamma_{IPTG}([IPTGI]-[IPTGO])}{V_{cell}}-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{IPTG}[IPTGI]$$

$$\frac{\text{d}[pLacR]}{\text{d}t}=\alpha_{pLacR}-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{pLacR}[pLacR]$$

$$\frac{\text{d}[CC]}{\text{d}t}=m_{IPTG,pLacR}[IPTGI][pLacR]-m_{CC}[CC]-\delta_{CC}[CC]$$


$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pLacR]^n} -\delta_{EGFP} [EGFP]$$

The presence of the hairpin leads to a decrease in $RFP$ expression efficiency, so we have

$$\frac{\text{d}[EGFP]}{\text{d}t}=k\frac{\text{d}[RFP]}{\text{d}t}$$

Where $[RFP]$ is the concentration of red fluorescence protein, $k$ is the coefficient of hairpin.

In device D, $IPTG$ gets in cells and bind with $pLacR$, which is a repressor for gene $DTE$. After $IPTG$ binding with $pLacR$, $DTE$ starts to express, and as an enzyme, to catalysis $fructose$ to turn into $psicose$. As more and more $psicose$ are produced, more and more the repressor of gene $EGFP$, $pLacR$ are inactivated, so expression of $EGPF$ increase. At the same time, expression of $ABR$ also increase since the gene of $ABR$ and the gene of $EGFP$ are connected in series by a hairpin.

For device D, $psicose$ and $fuctose$ get in cells by diffusion:

$$\frac{\text{d}[PsiO]}{\text{d}t}=\frac{-\gamma_{F}([PsiO]-[PsiI])}{V_{outside}}=0 $$

$$\frac{\text{d}[FO]}{\text{d}t}=\frac{-\gamma_{F}([FO]-[FI])}{V_{outside}}=0$$

$$\frac{\text{d}[IPTGO]}{\text{d}t}=\frac{-\gamma_{F}([IPTGO]-[IPTGI])}{V_{outside}}=0$$

And device D consists of device A and device C connected by an extra step:

$$FI\underrightarrow{DTE}PsiI$$

This reaction is an enzyme catalyzed reaction, which can be described by Michaelis equation, so we can get the following equations:


$$\frac{\text{d}[FI]}{\text{d}t}=\frac{-\gamma_{F}([FI]-[FO])}{V_{cell}}-\frac{k_2[DTE][FI]}{K_M+[FI]}-\delta_{FI}[FI]$$

$$\frac{\text{d}[PsiI]}{\text{d}t}=\frac{-\gamma_{F}([PsiI]-[PsiO])}{V_{cell}}+\frac{k_2[DTE][FI]}{K_M+[FI]}-\delta_{PsiI}[PsiI]$$

$$\frac{\text{d}[IPTGI]}{\text{d}t}=\frac{-\gamma_{IPTG}([IPTGI]-[IPTGO])}{V_{cell}}+m_{IPTG,pLacR}[IPTGI][pLacR]-\delta_{IPTG}[IPTGI]$$


Where $k_2$ is reaction rate coefficient of transition state product’s decomposition reaction, $K_M$ is the Michaelis contant.


The rest of the equations are the same with which in device A and device C:

$$\frac{\text{d}[pLacR]}{\text{d}t}=\alpha_{pLacR}-m_{IPTG,pLacR}[IPTGI][pLacR]+m_{CC}[CC]-\delta_{pLacR}[pLacR]$$

$$\frac{\text{d}[pPsiR]}{\text{d}t}=\alpha_{pPsiR}-m_{pPsiR,PsiI}[pPsiR][PsiI]+m_{CCI}[CCI]-\delta_{pLacR}[pLacR]$$

$$\frac{\text{d}[pPsiR]}{\text{d}t}=\alpha_{pPsiR}-m_{pPsiR,Psi}[PsiI][pPsiR]+m_{CCI}[CCI]-\delta_{pPsiR}[pPsiR]$$

$$\frac{\text{d}[CC]}{\text{d} t}=m_{IPTG,pLacR}[PsiI][pPsiR]-m_{CC}[CC]-\delta_{CC}[CC]$$

$$\frac{\text{d}[CCI]}{\text{d} t}=m_{pSiR}[PsiI][pPsiR]-m_{CCI}[CCI]-\delta_{CCI}[CCI]$$

$$\frac{\text{d}[DTE]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pLacR]^n}-\delta_{DTE}[DTE]$$

$$\frac{\text{d}[EGFP]}{\text{d}t}=H\frac{\beta_{EGFP}K^n}{K^n+[pPsiR]^n}-\delta_{EGFP}[EGFP]$$

$$\frac{\text{d}[ABR]}{\text{d}t}=k\frac{\text{d}[EGFP]}{\text{d}t}$$

Basing our model, we can calculate and simulate our system as follows:

From the picture below, it is evident that with time going by, the concentration of IPTG outside the cell will decrease due to the diffusion process, while the RFP expression level is increasing stably.

If we do more experiments shown below, we can find that the expression level of RFP is increasing with the increase of the concentration of IPTG, which proves that we can get a linear range of IPTG to get the RFP expression level. According to device A, B, C, D, this conclusion can also be made, which proves the validation of our kinetic model

Reference

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Lin P Y, Whang L M, Wu Y R, et al. Biological hydrogen production of the genus Clostridium: Metabolic study and mathematical model simulation[J]. International Journal of Hydrogen Energy, 2007, 32(12):1728-1735.
Whang L M, Hsiao C J, Cheng S S. A dual-substrate steady-state model for biological hydrogen production in an anaerobic hydrogen fermentation process[J]. Biotechnology & Bioengineering, 2010, 95(3):492-500.
Rousu J, Elomaa T, Aarts R. Predicting the speed of beer fermentation in laboratory and industrial scale[J]. 1999, 1607.