Shape-specific microfabricated particles for biomedical applications: a review

The storied history of controlled the release systems has evolved over time; from degradable drug-loaded sutures to monolithic zero-ordered release devices and nano-sized drug delivery formulations. Scientists have tuned the physico-chemical properties of these drug carriers to optimize their perfor...

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Published inDrug delivery and translational research Vol. 12; no. 8; pp. 2019 - 2037
Main Authors Moore, Thomas L., Cook, Alexander B., Bellotti, Elena, Palomba, Roberto, Manghnani, Purnima, Spanò, Raffaele, Brahmachari, Sayanti, Di Francesco, Martina, Palange, Anna Lisa, Di Mascolo, Daniele, Decuzzi, Paolo
Format Journal Article
LanguageEnglish
Published New York Springer US 01.08.2022
Subjects
Biomedical and Life Sciences
Biomedicine
Drug Carriers - chemistry
Drug Compounding
Drug Delivery Systems - methods
Original
Original Article
Particle Size
Pharmaceutical Sciences/Technology
Polymers - chemistry
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Summary:The storied history of controlled the release systems has evolved over time; from degradable drug-loaded sutures to monolithic zero-ordered release devices and nano-sized drug delivery formulations. Scientists have tuned the physico-chemical properties of these drug carriers to optimize their performance in biomedical/pharmaceutical applications. In particular, particle drug delivery systems at the micron size regime have been used since the 1980s. Recent advances in micro and nanofabrication techniques have enabled precise control of particle size and geometry–here we review the utility of microplates and discoidal polymeric particles for a range of pharmaceutical applications. Microplates are defined as micrometer scale polymeric local depot devices in cuboid form, while discoidal polymeric nanoconstructs are disk-shaped polymeric particles having a cross-sectional diameter in the micrometer range and a thickness in the hundreds of nanometer range. These versatile particles can be used to treat several pathologies such as cancer, inflammatory diseases and vascular diseases, by leveraging their size, shape, physical properties (e.g., stiffness), and component materials, to tune their functionality. This review highlights design and fabrication strategies for these particles, discusses their applications, and elaborates on emerging trends for their use in formulations. Graphical abstract
ISSN:2190-393X
2190-3948
DOI:10.1007/s13346-022-01143-4