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- Part I. General subjects
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1. Need for drug delivery systems 1
- Prof. Ana Catarina Silva
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2. Need for drug delivery systems 2
- Prof. João Nuno Moreira
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3. Routes of drug delivery
- Prof. Dr. Sven Stegemann
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4. Transporters in drug delivery
- Dr. Pravin Shende
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5. The theory and applications of controlled release principles
- Dr. Michael J. Rathbone
- Part II. Routes for drug delivery
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6. Oral drug delivery
- Dr. Vineet Kumar Rai
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7. Transdermal drug delivery
- Prof. Sabine Szunerits
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8. Pulmonary drug delivery
- Prof. Anthony J. Hickey
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9. Gastrointestinal drug delivery
- Prof. Susan Hua
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10. Mucoadhesive drug delivery systems
- Dr. Panoraia I. Siafaka
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11. Ocular drug delivery
- Prof. Emily Dosmar
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12. Vaginal and uterine drug delivery
- Prof. José Luis Arias Mediano
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13. Drug-eluting implants
- Dr. Aliasger K. Salem
- Part III. Materials for drug delivery
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14. Polymers as nanocarriers for controlled drug delivery
- Prof. Dr. Marcelo Calderón
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15. Polymeric gels for drug delivery
- Dr. G. Roshan Deen
- Ms. Dora Safar
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16. Liposomes as a drug delivery system
- Dr. G. Roshan Deen
- Ms. Bushra Hasan
- Ms. Renad AlAnsari
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17. Solid lipid nanoparticles (SLN) and nanostructured lipid carriers (NLC)
- Prof. Ana Catarina Silva
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18. Micellar drug delivery
- Prof. Francesco Cellesi
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19. Nanocrystals in drug delivery
- Prof. Eliana Souto
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20. Layer-by-layer assemblies for drug delivery
- Prof. Szczepan Zapotoczny
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21. Inorganic nanostructured interfaces for therapeutic delivery
- Prof. Tejal Desai
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22. Inorganic porous drug delivery carriers
- Prof. Jessica Rosenholm
- Part IV. Specifics of drug delivery
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23. Delivery of genes and nucleotides
- Prof. Esam Yahya
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24. Vaccine delivery
- Prof. Sevda Şenel
- Part V. Drug delivery in various diseases
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25. Drug delivery for cancer therapeutics
- Prof. Tejraj Aminabhavi
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26. Nanomedicines for brain diseases
- Prof. Giovanni Tosi
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27. Drug delivery to the colon
- Prof. Susan Hua
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28. Role of the lymphatic system in drug absorption
- Dr. Kishor M. Wasan
Printable Handouts
Navigable Slide Index
- Introduction
- Definition (1)
- Definition (2)
- Skin
- Drug delivery via skin
- Transdermal drug absorption routs
- Fundamentals of skin permeation (1)
- Fundamentals of skin permeation (2)
- Parameters effecting drug permeability (1)
- Parameters effecting drug permeability (2)
- Examples of FDA transdermal drugs
- Skin permeation enhancement (1)
- Chemical permeation enhancers
- Skin permeation enhancers
- Skin permeation enhancement (21)
- Microporation
- Mechanical approaches
- Microneedles
- Other microporation techniques
- Electrical techniques (1)
- Electrical techniques (2)
- Ultrasound based delivery
- Thermal approaches
- Laser thermal ablation (1)
- Laser thermal ablation (2)
- Photo-thermal skin ablation (1)
- Photo-thermal skin ablation (2)
- Photo-thermal transdermal drug delivery
- Photo-thermal drug delivery
- Conclusion
- Acknowledgments
- References
Topics Covered
- Transdermal drug delivery and its hurdles to overcome
- State of the art of current transdermal skin patches to deliver therapeutics of different sizes
- Examples of active modes of overcoming the skin barrier
- Focus on thermal based modes to increase skin permeability
- Perspectives and the future of the field
Talk Citation
Szunerits, S. (2019, December 31). Transdermal drug delivery [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 26, 2024, from https://doi.org/10.69645/LBHH6355.Export Citation (RIS)
Publication History
Financial Disclosures
- Funding received from Actions d’initiatives regionales pour la recherche (AIRR), the Université de Lille: I-SITE, FLAG-ERA JTC 2015-GRAPHITIVITY, H2020-MSCA-RISE-2015-PANG. This project has received funding from the European Union's Horizon 2020 Research and Innovation Staff Exchange (RISE).
A selection of talks on Dermatology
Transcript
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0:00
My name is Sabine Szunerits.
I'm a professor at the University of Lille,
attached to the Institute of Electronic,
Microelectronic, and Nanotechnology Department.
Today, I'm going to talk about transdermal drug delivery.
0:14
Transdermal drug delivery is hardly old technology.
The concept that certain drugs can cross the skin might be tracked back to Ibn Sina,
a Persian physician who proposed that dermally applied drugs can have a local effect,
but can also affect tissue immediately beneath the skin, as well as more remote areas.
It was observed that next to the primary role of the skin
serving as an efficient barrier against the invasion of organisms by viruses,
bacteria, dust, toxic chemicals,
as well as UV radiation,
some molecules can penetrate more deeply into the skin structure.
Whereas, dermatologically, topical formulations,
such as foam, creams, and gels, target skin diseases,
topical transdermal delivery systems are designed
to treat systemic medical conditions or localized joint or muscle conditions.
Using the skin as the route of drug delivery,
transdermal drug delivery systems are, thus, defined as systems that utilize the skin
as a site for continuous drug administration into the systemic circulation.
Transdermal drug delivery is part of the family
of drug delivery approaches, as exemplified here for insulin,
with oral, subcutaneous, inhaling,
nasal, and buccal approaches,
to mention some, are being proposed.
Transdermal drug delivery systems are mainly patch-based.
Transdermal patches are, thus, defined as medical adhesives placed on the skin
to deliver a dose of medication through the skin into the bloodstream.