Journal Article10.1517/14712598.4.1.35
Microspheres for controlled release drug delivery
Neelesh K. Varde,Daniel W. Pack +1 more
431
TL;DR: Methods of microparticle fabrication and the major factors controlling the release rates of encapsulated drugs are described, as well as recent advances in the use of polymer microsphere-based systems for delivery of single-shot vaccines, plasmid DNA and therapeutic proteins are discussed.
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Abstract: Controlled release drug delivery employs drug-encapsulating devices from which therapeutic agents may be released at controlled rates for long periods of time, ranging from days to months. Such systems offer numerous advantages over traditional methods of drug delivery, including tailoring of drug release rates, protection of fragile drugs and increased patient comfort and compliance. Polymeric microspheres are ideal vehicles for many controlled delivery applications due to their ability to encapsulate a variety of drugs, biocompatibility, high bioavailability and sustained drug release characteristics. Research discussed in this review is focused on improving large-scale manufacturing, maintaining drug stability and enhancing control of drug release rates. This paper describes methods of microparticle fabrication and the major factors controlling the release rates of encapsulated drugs. Furthermore, recent advances in the use of polymer microsphere-based systems for delivery of single-shot vaccines, plasmid DNA and therapeutic proteins are discussed, as well as some future directions of microsphere research.
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Citations
k-Casein upregulates osteogenic differentiation on bone marrow mesenchymal stem cells cultured on agarose microcarriers
Hammed Tanimowo Aiyelabegan,Malihe T. K. Ebadi,Gholam Ali Kardar,Nasrin Lotfibakhshaiesh,Farid Abedin Dorkoosh,Somayeh Ebrahimi Barough,Esmaeil Sadroddiny +6 more
TL;DR: A novel agarose-κ-casein microsphere was fabricated and upregulated the expression of osteogenic differentiation markers on bone marrow mesenchymal stem cells cultured on the carrier systems to assess its compatibility towards stem cells attachment, proliferation, survival, differentiation and osteogenic expression.
WITHDRAWN: Application of poly(Clove Oil)-Based Organo-Hydrogels for Drug Delivery Systems
Tuba Erşen Dudu,Duygu Alpaslan,Abdullah Turan,Nahit Aktaş +3 more
- 20 Nov 2024
TL;DR: This preprint on poly(Clove Oil)-based organo-hydrogels for drug delivery systems has been withdrawn due to an error in submission, and authors request no citation, directing inquiries to the corresponding author.
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Juliane Fjelrad Christfort,Antonio José Guillot,Ana Melero,Lasse Højlund Thamdrup,Teresa María Garrigues,Anja Boisen,Kinga Zor,Line Hagner Nielsen +7 more
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