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− | <li><a href="# | + | <li><a href="#lensmodel">Lens Cataract Model</a></li> |
<ul> | <ul> | ||
− | <li> <a href="# | + | <li> <a href="#LensPrevention">Prevention</a></li> |
− | <li> <a href="# | + | <li> <a href="#LensTreatment">Treatment</a></li> |
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− | <li><a href="# | + | <li><a href="#construct">Construct</a></li> |
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− | <li> <a href="# | + | <li> <a href="#ConstructPrevention">Prevention</a></li> |
− | <li> <a href="# | + | <li> <a href="#ConstructTreatment">Treatment</a></li> |
+ | </ul> | ||
+ | <li><a href="#prototype">Delivery Prototype</a></li> | ||
+ | <ul> | ||
+ | <li> <a href="#step1">Purification</a></li> | ||
+ | <li> <a href="#step2">Nanoparticle</a></li> | ||
+ | <li> <a href="#step2i">Encapsulation</a></li> | ||
+ | <li> <a href="#step2ii">Release</a></li> | ||
+ | <li> <a href="#step3">Application</a></li> | ||
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<div class="col-sm-12"> | <div class="col-sm-12"> | ||
− | + | <p>A main obstacle for protein delivery into the eye is that the cornea acts as a barrier and blocks materials from entering the eye. To increase the amount of proteins that reach the lens, we made biodegradable chitosan nanoparticles that can package and deliver proteins. According to literature research, chitosan nanoparticles can embed in the cornea, where the encapsulated proteins can be released as the particles degrade. This is a better solution than commercially available eye drops (since more proteins can be delivered through the cornea) and surgery (because it is non-invasive). In addition, the nanoparticles do not affect vision or the normal protective functions of the cornea. We show that our nanoparticles successfully encapsulated proteins. Proteins remain inside nanoparticles at 4℃, which allows for storage, but can be released at body temperature. Finally, we envision using these nanoparticles in eye drops or contact lenses.</p> | |
+ | <h3><u>Packaging in Nanoparticles</u></h3> | ||
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<p> | <p> | ||
− | + | The cornea is the outermost layer of the eye and protects the eye from foreign materials, but also prevents drugs from reaching the lens (Gaudana et al., 2010). Scientists have developed several methods to penetrate the cornea and deliver drugs to the lens, but many are invasive, such as implants (Patel et al., 2013). The most promising method is using nanoparticles as drug carriers (Cholkar et al., 2013). so we chose to use nanoparticles to deliver our proteins to the lens. | |
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− | + | Nanoparticles can be made from a variety of materials, but we selected chitosan for several reasons. Researchers have used chitosan nanoparticles in the eye; its low toxicity to somatic cells makes it safe and it does not affect the anatomy of the eye (Enriquez de Salamanca et al., 2006). We also learned that chitosan nanoparticles can embed in the cornea, and its biodegradability allows the drug to be released continuously into the eye (figure 3.3) (Enriquez de Salamanca et al., 2006; Campos et al., 2005). Therefore, we want to load our purified proteins into chitosan nanoparticles (figure 3.4). | |
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− | + | <figcaption class='darkblue'><b>Figure 3.3: </b>Nanoparticles containing our proteins embed into the cornea and degrade. The released proteins are then delivered within the eye.</figcaption> | |
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− | <img src="https://static.igem.org/mediawiki/2016/ | + | <img src="https://static.igem.org/mediawiki/2016/4/41/T--TAS_Taipei--PurificationAnimation.gif"> |
− | <figcaption class='darkblue'><b> | + | <figcaption class='darkblue'><b>Figure 3.4: </b>Purified proteins can be encapsulated in chitosan nanoparticles.</figcaption> |
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− | + | Below is a video of our nanoparticle synthesis procedure. | |
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− | + | <img src="https://static.igem.org/mediawiki/2016/4/4e/T--TAS_Taipei--NPAnimation.gif"> | |
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<p> | <p> | ||
− | + | Following the procedure of Quan and Wang (2007), we made nanoparticles and imaged them using scanning electron microscopy and atomic force microscopy (figure 3.5). This revealed our nanoparticles to be spherical and at the optimal size of 200-600 nm (figure 3.6 and 3.7). | |
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− | + | <img src="https://static.igem.org/mediawiki/2016/7/7f/T--TAS_Taipei--MakingNP.png"> | |
− | + | <figcaption class='darkblue'><b>Figure 3.5: </b> Team members imaging nanoparticles on the scanning electron microscope and atomic force microscope. </figcaption> | |
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− | <figcaption class='darkblue'><b>Figure | + | |
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− | <img src="https://static.igem.org/mediawiki/2016/ | + | <img src="https://static.igem.org/mediawiki/2016/3/30/T--TAS_Taipei--SEMChitosan%28C%29.png"> |
− | <figcaption class='darkblue'><b>Figure | + | <figcaption class='darkblue'><b>Figure 3.6: </b>Scanning electron microscope image of chitosan nanoparticles</figcaption> |
</figure> | </figure> | ||
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− | <img src="https://static.igem.org/mediawiki/2016/ | + | <img src="https://static.igem.org/mediawiki/2016/2/27/T--TAS_Taipei--AtomicForceMicroscopeImage%28D%29.png"> |
− | <figcaption class='darkblue'><b>Figure | + | <figcaption class='darkblue'><b>Figure 3.7: </b>We imaged chitosan nanoparticles using atomic force microscopy. On the left is the empty silica plate. On the right is an image of the chitosan nanoparticles, which were placed on the silica plate</figcaption> |
</figure> | </figure> | ||
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− | + | <h3 id="step2i"></h3> | |
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− | + | <h3 style="text-transform: none"><i>Protein Encapsulation</i></h3> | |
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+ | <p>Next, we wanted to load our purified proteins into the nanoparticles. We first used colored proteins to qualitatively test whether proteins could be successfully encapsulated. To do so, we lysed bacteria expressing green fluorescent protein (GFP), red fluorescent protein (RFP), and green pigment (from pGRN, Bba_K274003). We then add the proteins to the chitosan solution. After nanoparticles were made, our results showed that we successfully encapsulated the colored proteins. When we further viewed the nanoparticles under blue light, the GFP- and RFP-containing pellets glowed (figure 3.8), suggesting that the proteins remain functional. Thus, our nanoparticles can serve as protein carriers to enhance drug delivery. </p> | ||
+ | </div> | ||
+ | <figure class = "col-sm-6"> | ||
+ | <img src="https://static.igem.org/mediawiki/2016/2/21/T--TAS_Taipei--ProteinPellets.png" style="width:100%"> | ||
+ | <figcaption class='darkblue'><b>Figure 3.8: </b> Proteins were successfully encapsulated into nanoparticles. Figure shows nanoparticle pellets containing no protein, GFP, RFP, and pGRN (left to right) under white light (top) and blue light (bottom). Fluorescence of GFP and RFP-containing pellets shows that proteins are still functional. </figcaption> | ||
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− | + | <p>In order to quantitatively determine encapsulation efficiency, we measured protein concentration in the supernatant before and after nanoparticle formation. We started with 1 mg/mL of bovine serum albumin (BSA). After nanoparticle formation, we performed a Bradford assay and found that the concentration decreased to 0.28 mg/mL. As shown in figure 3.9, the encapsulation efficiency was 72%.</p> | |
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− | + | <img src="https://static.igem.org/mediawiki/2016/a/ad/T--TAS_Taipei--EncapEfficiency.png" style="width:100%"> | |
− | + | <figcaption class='darkblue'><b>Figure 3.9: </b>The encapsulation efficiency is 72%. Using a Bradford assay, we created a standard curve of known BSA protein concentrations by measuring absorbance at 595 nm. <b>Top</b>: graph shows absorbance values of the supernatant after nanoparticle formation. <b>Bottom</b>: cuvettes containing standard solutions (left) and the sample solution (right). </figcaption> | |
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+ | </div> | ||
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− | <img src="https://static.igem.org/mediawiki/2016/ | + | <img src="https://static.igem.org/mediawiki/2016/1/17/T--TAS_Taipei--BSATempComp.png" style="width:100%"> |
− | <figcaption class='darkblue'><b>Figure | + | <figcaption class='darkblue'><b>Figure 3.10: </b>BSA proteins are released from chitosan nanoparticles at 37℃, but almost no change occurred at 4℃. </figcaption> |
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<p> | <p> | ||
− | + | After proteins are encapsulated, nanoparticles should embed in the cornea and release proteins as they degrade over time. To test whether nanoparticles degrade, we measured the release of proteins. After BSA-containing nanoparticles were made, they were spun down and the solution was replaced with phosphate buffered saline (PBS) (Wilson, 2014). Using a Bradford assay, we could then measure protein concentration in the PBS over a 72-hour period. | |
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− | + | Trials were performed at two different temperatures: 4°C and 37°C. Our results show that proteins are released from nanoparticles at 37°C , but almost no change could be detected at 4°C (figure 3.10). This finding suggests that we can store a final functional product (e.g., eye drop) at 4°C without nanoparticle degradation, while the proteins can be released from nanoparticles when the eye drop is applied at body temperature. | |
</p> | </p> | ||
</div> | </div> | ||
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− | </div> | + | <br><br> |
+ | |||
+ | <h3 id="step3"></h3> | ||
+ | <br> | ||
+ | <h3><u>Application (EYE DROP OR CONTACT LENSES)</h3> | ||
<div class="row"> | <div class="row"> | ||
− | + | <div class="col-sm-1"></div> | |
− | + | <div class="col-sm-10"> | |
− | < | + | <p>Our goal is to package GSR and CH25H in nanoparticles to deliver these proteins to the lens using a safe and non-invasive method. We have considered two drug delivery mechanisms to administer the nanoparticles: eye drops and contact lenses. </p> |
− | + | <br> | |
− | + | <b>Eye drops</b> | |
− | + | <p>After packaging our proteins in nanoparticles, the nanoparticles can be spun down and resuspended in saline, since it is commonly used in eye drops (Falsini, 2016). </p> | |
+ | <br> | ||
+ | <b>Contact Lenses</b> | ||
+ | <p>We found a method to make chitosan nanoparticle-embedded hydrogel contact lenses (Behl, 2016). Following their protocol, we created a polymer solution containing all the necessary components, and then transferred this solution into a 3D-printed mold (figure 3.11, left). After exposure to UV for 40 minutes, we successfully made hydrogel contact lenses (figure 3.11, right). </p> | ||
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− | <figure class = "col-sm- | + | <img src="https://static.igem.org/mediawiki/2016/9/9b/T--TAS_Taipei--ContactLensMold.png" style="width:100%"> |
− | <img src="https://static.igem.org/mediawiki/2016/ | + | <figcaption class='darkblue'><b>Figure 3.11: </b>A 3D printed mold (left) used to make hydrogel lenses (right). </figcaption> |
− | <figcaption class='darkblue'><b>Figure | + | |
</figure> | </figure> | ||
− | <figure class = "col-sm- | + | </div> |
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− | <img src="https://static.igem.org/mediawiki/2016/ | + | <figure class = "col-sm-12"> |
− | <figcaption class='darkblue'><b>Figure | + | <img src="https://static.igem.org/mediawiki/2016/7/79/T--TAS_Taipei--Figure3.12a.jpeg " style="width:100%"> |
+ | <figcaption class='darkblue'><b>Figure 3.12: </b>Huiru you type the caption in. </figcaption> | ||
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Revision as of 16:31, 17 October 2016
Applied Design
A main obstacle for protein delivery into the eye is that the cornea acts as a barrier and blocks materials from entering the eye. To increase the amount of proteins that reach the lens, we made biodegradable chitosan nanoparticles that can package and deliver proteins. According to literature research, chitosan nanoparticles can embed in the cornea, where the encapsulated proteins can be released as the particles degrade. This is a better solution than commercially available eye drops (since more proteins can be delivered through the cornea) and surgery (because it is non-invasive). In addition, the nanoparticles do not affect vision or the normal protective functions of the cornea. We show that our nanoparticles successfully encapsulated proteins. Proteins remain inside nanoparticles at 4℃, which allows for storage, but can be released at body temperature. Finally, we envision using these nanoparticles in eye drops or contact lenses.
Packaging in Nanoparticles
The cornea is the outermost layer of the eye and protects the eye from foreign materials, but also prevents drugs from reaching the lens (Gaudana et al., 2010). Scientists have developed several methods to penetrate the cornea and deliver drugs to the lens, but many are invasive, such as implants (Patel et al., 2013). The most promising method is using nanoparticles as drug carriers (Cholkar et al., 2013). so we chose to use nanoparticles to deliver our proteins to the lens.
Nanoparticles can be made from a variety of materials, but we selected chitosan for several reasons. Researchers have used chitosan nanoparticles in the eye; its low toxicity to somatic cells makes it safe and it does not affect the anatomy of the eye (Enriquez de Salamanca et al., 2006). We also learned that chitosan nanoparticles can embed in the cornea, and its biodegradability allows the drug to be released continuously into the eye (figure 3.3) (Enriquez de Salamanca et al., 2006; Campos et al., 2005). Therefore, we want to load our purified proteins into chitosan nanoparticles (figure 3.4).
Below is a video of our nanoparticle synthesis procedure.
Following the procedure of Quan and Wang (2007), we made nanoparticles and imaged them using scanning electron microscopy and atomic force microscopy (figure 3.5). This revealed our nanoparticles to be spherical and at the optimal size of 200-600 nm (figure 3.6 and 3.7).
Protein Encapsulation
Next, we wanted to load our purified proteins into the nanoparticles. We first used colored proteins to qualitatively test whether proteins could be successfully encapsulated. To do so, we lysed bacteria expressing green fluorescent protein (GFP), red fluorescent protein (RFP), and green pigment (from pGRN, Bba_K274003). We then add the proteins to the chitosan solution. After nanoparticles were made, our results showed that we successfully encapsulated the colored proteins. When we further viewed the nanoparticles under blue light, the GFP- and RFP-containing pellets glowed (figure 3.8), suggesting that the proteins remain functional. Thus, our nanoparticles can serve as protein carriers to enhance drug delivery.
In order to quantitatively determine encapsulation efficiency, we measured protein concentration in the supernatant before and after nanoparticle formation. We started with 1 mg/mL of bovine serum albumin (BSA). After nanoparticle formation, we performed a Bradford assay and found that the concentration decreased to 0.28 mg/mL. As shown in figure 3.9, the encapsulation efficiency was 72%.
Protein Release
After proteins are encapsulated, nanoparticles should embed in the cornea and release proteins as they degrade over time. To test whether nanoparticles degrade, we measured the release of proteins. After BSA-containing nanoparticles were made, they were spun down and the solution was replaced with phosphate buffered saline (PBS) (Wilson, 2014). Using a Bradford assay, we could then measure protein concentration in the PBS over a 72-hour period.
Trials were performed at two different temperatures: 4°C and 37°C. Our results show that proteins are released from nanoparticles at 37°C , but almost no change could be detected at 4°C (figure 3.10). This finding suggests that we can store a final functional product (e.g., eye drop) at 4°C without nanoparticle degradation, while the proteins can be released from nanoparticles when the eye drop is applied at body temperature.
Application (EYE DROP OR CONTACT LENSES)
Our goal is to package GSR and CH25H in nanoparticles to deliver these proteins to the lens using a safe and non-invasive method. We have considered two drug delivery mechanisms to administer the nanoparticles: eye drops and contact lenses.
Eye drops
After packaging our proteins in nanoparticles, the nanoparticles can be spun down and resuspended in saline, since it is commonly used in eye drops (Falsini, 2016).
Contact Lenses
We found a method to make chitosan nanoparticle-embedded hydrogel contact lenses (Behl, 2016). Following their protocol, we created a polymer solution containing all the necessary components, and then transferred this solution into a 3D-printed mold (figure 3.11, left). After exposure to UV for 40 minutes, we successfully made hydrogel contact lenses (figure 3.11, right).
Citations
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