imple-revise

wiki/pages/implementation.html

@@ -49,8 +49,8 @@
     </ul>
     <h3 id='weakness'><strong>Weakness</strong></h3>
     <ul>
-        <li>Our genetic circuit could be more manageable and more streamlined due to the combinations of various logic
-            gates;</li>
+        <li>Our genetic circuit is not streamlined enough and there may be difficulties in transferring the complete
+            circuit into an E. coli;</li>
         <li>The efficiency, stability, and orthogonality of genetic circuits remained to be enhanced to avoid unwanted
             crosstalk;</li>
         <li>Lack of practical application implementation though with rich application prospectives.</li>
@@ -87,7 +87,8 @@
     <h3 id='pay-attention-to-other-biological-gates'>Pay attention to other biological gates</h3>
     <ul>
         <li><strong>Diverse Gate Types</strong>: Incorporate a variety of logic gates (AND, OR, NOR, NOT, XOR, etc.)
-            into the system to ensure that the genetic circuits can accomplish larger systems.</li>
+            into the system to ensure that our project can perform any logical functions and support the integration of
+            diverse gate functions, such as cell memory.</li>
         <li><strong>Cross-compatibility with Host Systems</strong>: Design similar programmable components across
             various host biological systems to enhance the component&#39;s versatility, laying the foundation for
             building biological logic circuits.</li>
@@ -107,9 +108,9 @@
     </ul>
     <h2 id='reference'><strong>Reference</strong></h2>
     <p>[1] Singh V. (2014). Recent advances and opportunities in synthetic logic gates engineering in living
-        cells. <em>Systems and synthetic biology</em>, <em>8</em>(4), 271–282.</p>
-    <p> [2] Wang, B., Kitney, R., Joly, N. <em>et al.</em> Engineering modular and orthogonal genetic logic gates for
-        robust digital-like synthetic biology. <em>Nat Commun</em> <strong>2</strong>, 508 (2011).</p>
+        cells. <em>Systems and synthetic biology</em>, <em>8</em>(4), 271-282.</p>
+    <p> [2] Wang, B., Kitney, R., Joly, N. <em>et al.</em> Engineering modular and orthogonal genetic logic gates for
+        robust digital-like synthetic biology. <em>Nat Commun</em> <strong>2</strong>, 508 (2011).</p>
     <p> [3] Xia, P., Ling, H., Foo, J. L., &amp; Chang, M. W. (2019). Synthetic genetic circuits for programmable
         biological functionalities. <em>Biotechnology Advances</em>, <em>37</em>(6), 107393.</p>
 </div>