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Printable Handouts
Navigable Slide Index
- Introduction
- Lecture outline
- Definition of a micelle
- Micelle formation
- Critical micelle concentration
- Key micelle characteristics
- 1. Size
- 2. Shape
- 3. Drug encapsulation
- Methods of drug encapsulation
- Drug encapsulation parameters
- Nanocarriers and nanomedicine
- Administration routes
- Major nanocarrier entry routes
- Biological barriers
- Passive targeting
- Active targeting
- Opsonization
- The mononuclear phagocyte system
- Stealth characteristics
- Biodistribution
- Micelle design for drug delivery
- Typical micelle polymers in nanomedicine
- Ligand conjugation
- Drawbacks of the CMC
- Unimolecular micelles (1)
- Unimolecular micelles (2)
- Polymer architecture
- Multifunctional micelles
- Stimuli responsive micelles
- Labile chemical bonds
- Advanced encapsulation strategies
- Targeted delivery of paclitaxel via π–π stacking
- pH sensitive micellar pro-drug system
- Cisplatin loaded micelles
- Clinical tested polymer micelles
- Conclusions and future directions
- References
Topics Covered
- The definition of micelles
- Micelles formation
- Critical micelles concentration
- Micelles characteristic: size shape and drug encapsulation
- Methods of drug encapsulation
- Micelles as nanocarriers
- Micelle design for drug delivery
- Advanced drug delivery strategies: multifunctional micelles, stimuli responsive micelles, pH sensitive micellular pro-drug system, cisplatin loaded micelles
Talk Citation
Cellesi, F. (2020, February 27). Micellar drug delivery [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 23, 2024, from https://doi.org/10.69645/RRRA7694.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. Francesco Cellesi has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Other Talks in the Series: Drug Delivery
Transcript
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0:00
Hello, I'm Francesco Cellesi,
Associate Professor at the Department of Chemistry,
Materials and Chemical Engineering,
"Giulio Natta", Politecnico di Milano in Italy.
The title of this presentation is Micellar Drug Delivery,
a topic which is gaining particular attention in the field of nanomedicine.
0:23
Firstly, I will give you a definition of micelles and
then I will introduce the basic physico-chemical aspects,
which are essential to understand the mechanism of micelle formation.
Afterwards, we'll discuss about the key mechanism
of drug encapsulation in this micellar systems,
and a brief overview on how micelles can act as a nanocarriers will be provided.
Finally, I will show you which tools are
typically used in micelles design for drug delivery,
and some examples of advanced drug delivery strategies will also be provided.
1:06
According to IUPAC definition,
a micelle is a particle of a colloidal dimension that exist in
equilibrium with the molecules or ions in solutions from which it is formed.
In other words, micelles are formed by self-assembling amphiphilic molecules.
This amphiphilic molecules contain hydrophilic polar region,
so we call it head and hydrophobic non-polar region, the tail.
Micelles are formed in aqueous solution,
whereby the polar region phases the outside surface of
the micelle and the non-polar region forms the core.