Hydrogels loaded with cell-derived nanovesicles for skin repair
With the increasing ubiquity of chronic diseases, there is motivation to discover novel bioactive therapy to alleviate debilitating complications experienced by patients with chronic wounds. Various pathophysiological factors can cause anomalies that constantly disrupt the natural reparative heal...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2021
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| Online Access: | https://hdl.handle.net/10356/147917 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | With the increasing ubiquity of chronic diseases, there is motivation to discover novel bioactive
therapy to alleviate debilitating complications experienced by patients with chronic wounds.
Various pathophysiological factors can cause anomalies that constantly disrupt the natural
reparative healing process lowers the patient’s life quality substantially, both physically and
emotionally.
Over the past decade, stem cells are widely considered to be promising candidates for therapeutic
agents due to their properties. While they have excellent self-renewal and replicating properties,
the sophisticated and low yield procedure limit the ability to extract a sizeable amount to be used
in a controlled drug delivery application. Cell-derived nanovesicles (CDNs) were discovered and
developed as a solution that mimics the paracrine signaling function in their counterpart while
attaining exceptional potential to be mass-produced.
This project aims to explore and evaluate the interaction and release effects of CDNs from
chitosan-based hydrogel and the efficacies of its applications in bioactive therapy.
Biocompatibility and bioactivity response of the epithelial cells from CDN release and its
interactions with the chitosan hydrogel was examined by employing various cell studying
techniques.
CDNs of various cell lines, such as U937, HUVEC, OLG, and ADSC, were fabricated and
individually loaded homogeneously in synthesized chitosan hydrogel through a physical crosslinking
mechanism using Chitosan and gelling agents of β -Glycerophosphate(βGP) and
Sodium Hydrogen Carbonate (SHC). We concluded that the CH hydrogel does not slow down or
prevent cell viability and proliferation when applied on endothelial cells, while the free Cy5
attached to the U937 CDN does not have any observable effects on the proliferation of the
endothelial cells. This implied that the CH hydrogel does not have any detrimental/toxic effects
when utilized, making it an ideal Drug Delivery System (DDS).
We expanded the study to further understand the effects of the introduction of CDNs from different
system and origin source. U937, HUVEC, ADSC and OLG -CDNs showed very promising
potential and capabilities to be used as CDN candidates with ADSC and OLG -CDNs OLG show
promises of being a better candidate due to the similar effectiveness albeit at a lower concentration
used. Additionally, this opens the opportunity for further research regarding the use of cross-tissue
or -species CDNs, which allows the possibility of an abundance of inexpensive variety of products
catering for wound care under diabetes.
Fluorescence was observed across all the skin-cartilage interfaces of the pig ear tissues treated
with Cy5 labelled U937 CDNs across different optical magnifications. This is indicative of the
presence of the cellular uptake mechanism as well as tissue retention of CDNs taking place.
A continuation of the current studies will help to further understand various potential CDN
candidates, paving the development of a translational product to enhance wound healing. A better
understanding of the scalability and regenerative capabilities of CDN based technologies is also
instrumental in discovering a safer and more effective therapeutic alternative that can potentially
revolutionize wound care management. |
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