Twisting microfluidics in a planetary centrifuge

Yasuda, Shoya; Hayakawa, Masayuki; Onoe, Hiroaki; Takinoue, Masahiro

doi:10.1039/c6sm02695h

Cited by 13 publications

(5 citation statements)

References 34 publications

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“…Since the publication of Haeberle et al, research has been carried out to optimize the centrifugal encapsulation device and to enhance its performances, notably by the teams of Takeuchi and Zhao. − In a recent publication by the authors of the present study, a dimensionless phase diagram of the centrifugal encapsulation system was established for the prediction of capsule sizes and shapes Figure a shows a schematic representation of the device.…”

Section: Introductionmentioning

confidence: 97%

Physical Analysis of the Centrifugal Microencapsulation Process

Badalan

Ghigliotti

Achard

et al. 2022

Ind. Eng. Chem. Res.

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Centrifugal microcapsule synthesis has been shown to be a promising technique for microencapsulation, satisfying at the same time many requirements needed for biomedical applications (controlled monodisperse size, spherical shape, sterile production environment) and allowing a high capsule production rate, using only conventional lab material. Although efforts have been made over the past decade to optimize centrifugal devices, so far only one stage of the capsule synthesis process has been accurately characterized from a physical and mechanical point of view. In this work we provide the first complete description and modeling of the entire centrifugal encapsulation process, by carefully analyzing all its stages using a combined experimental and analytical approach. This results in defining novel global models and a flow diagram of the process. The analysis and models introduced here are expected to contribute to the understanding, design, improvement, and optimal operation of current and future centrifugal microencapsulation devices. Results obtained for void capsules (beads) are confirmed by experiments on capsules with cargo.

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Section: Introductionmentioning

confidence: 97%

Physical Analysis of the Centrifugal Microencapsulation Process

Badalan

Ghigliotti

Achard

et al. 2022

Ind. Eng. Chem. Res.

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“…Microfluidic technology represents a powerful tool for the fabrication of particle-based drug delivery systems. Notably, batch processes, used for producing microencapsulated drugs, require large volumes of solvent and result in significant batch-to-batch variations in physical characteristics and drug-release profiles. − In contrast, microfluidic approaches enable precise control over fluid flow and mixing at the nanoliter scale within microchannels to produce uniform droplets that can be further solidified to form well-defined, drug-carrying particles. − Further, centrifugal and capillary-based microfluidics can generate sophisticated and versatile microcarriers that are impractical to produce with common microfluidic methods. − Thus, microfluidic approaches can minimize the batch-to-batch variation of the drug carriers, leading to better reproducibility and control over particle characteristics. , …”

Section: Introductionmentioning

confidence: 99%

Microfluidic Systems For Manufacturing of Microparticle-Based Drug-Delivery Systems: Design, Construction, and Operation

Yönet-Tanyeri

Amer

Balmert

et al. 2022

ACS Biomater. Sci. Eng.

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Particles synthesized from biodegradable polymers hold great potential as controlled drug delivery systems. Continuous flow platforms based on microfluidics offer attractive advantages over conventional batch-emulsification techniques for the scalable fabrication of drug-loaded particles with controlled physicochemical properties. However, widespread utilization of microfluidic technologies for the manufacturing of drug-loaded particles has been hindered largely by the lack of practical guidelines toward costeffective development and reliable operation of microfluidic systems. Here, we present a framework for rational design and construction of microfluidic systems using commercially available components for high-throughput production of uniform biodegradable particles encapsulating drugs. We also demonstrate successful implementation of this framework to devise a robust microfluidic system that is capable of producing drug-carrying particles with desired characteristics. The guidelines provided in this study will likely help broaden the applicability of microfluidic technologies for the synthesis of high-quality, drug-loaded biodegradable particles.

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“…Moreover, the simplicity and accessibility of mini-rTDP make it appealing to researchers and engineers. With minimal hardware requirements, it opens doors to novel material synthesis applications, such as the creation of internally twisted structures 32 . It also presents an innovative solution for lab-on-chip devices, enhancing point-of-care diagnostics 33 .…”

Section: Discussionmentioning

confidence: 99%

Twisted fiber microfluidics: a cutting-edge approach to 3D spiral devices

Kato,

Carlson,

Shen

et al. 2024

Microsyst Nanoeng

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The development of 3D spiral microfluidics has opened new avenues for leveraging inertial focusing to analyze small fluid volumes, thereby advancing research across chemical, physical, and biological disciplines. While traditional straight microchannels rely solely on inertial lift forces, the novel spiral geometry generates Dean drag forces, eliminating the necessity for external fields in fluid manipulation. Nevertheless, fabricating 3D spiral microfluidics remains a labor-intensive and costly endeavor, hindering its widespread adoption. Moreover, conventional lithographic methods primarily yield 2D planar devices, thereby limiting the selection of materials and geometrical configurations. To address these challenges, this work introduces a streamlined fabrication method for 3D spiral microfluidic devices, employing rotational force within a miniaturized thermal drawing process, termed as mini-rTDP. This innovation allows for rapid prototyping of twisted fiber-based microfluidics featuring versatility in material selection and heightened geometric intricacy. To validate the performance of these devices, we combined computational modeling with microtomographic particle image velocimetry (μTPIV) to comprehensively characterize the 3D flow dynamics. Our results corroborate the presence of a steady secondary flow, underscoring the effectiveness of our approach. Our 3D spiral microfluidics platform paves the way for exploring intricate microflow dynamics, with promising applications in areas such as drug delivery, diagnostics, and lab-on-a-chip systems.

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Twisting microfluidics in a planetary centrifuge

Cited by 13 publications

References 34 publications

Physical Analysis of the Centrifugal Microencapsulation Process

Physical Analysis of the Centrifugal Microencapsulation Process

Microfluidic Systems For Manufacturing of Microparticle-Based Drug-Delivery Systems: Design, Construction, and Operation

Twisted fiber microfluidics: a cutting-edge approach to 3D spiral devices

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