Microfluidic Formation of Hydrogel Microcapsules with a Single Aqueous Core by Spontaneous Cross-Linking in Aqueous Two-Phase System Droplets

Watanabe, Takeru; Motohiro, Ibuki; Ono, Tsutomu

doi:10.1021/acs.langmuir.8b04169

Cited by 56 publications

(54 citation statements)

References 52 publications

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“…the aqueous two-phase emulsion system, when the two aqueous phases used are meticulously selected [ 41 , 42 ]. As such, it has been demonstrated that it was possible to directly write [ 43 ] or print [ 44 ] an aqueous pattern within another aqueous bath, or produce droplets using microfluidic devices [ [45] , [46] , [47] , [48] , [49] ]. The unique advantage of biocompatibility of the aqueous two-phase emulsion system allows it to be used in the presence of cells without exerting any toxicity otherwise imposed by the organic solvents in conventional emulsions.…”

Section: Resultsmentioning

confidence: 99%

An open-source handheld extruder loaded with pore-forming bioink for in situ wound dressing

Ying

Manríquez

et al. 2020

Materials Today Bio

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The increasing demand in rapid wound dressing and healing has promoted the development of intraoperative strategies, such as intraoperative bioprinting, which allows deposition of bioinks directly at the injury sites to conform to their specific shapes and structures. Although successes have been achieved to varying degrees, either the instrumentation remains complex and high-cost or the bioink is insufficient for desired cellular activities. Here, we report the development of a cost-effective, open-source handheld bioprinter featuring an ergonomic design, which was entirely portable powered by a battery pack. We further integrated an aqueous two-phase emulsion bioink based on gelatin methacryloyl with the handheld system, enabling convenient shape-controlled in situ bioprinting. The unique pore-forming property of the emulsion bioink facilitated liquid and oxygen transport as well as cellular proliferation and spreading, with an additional ability of good elasticity to withstand repeated mechanical compressions. These advantages of our pore-forming bioink-loaded handheld bioprinter are believed to pave a new avenue for effective wound dressing potentially in a personalized manner down the future.

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Section: Resultsmentioning

confidence: 99%

An open-source handheld extruder loaded with pore-forming bioink for in situ wound dressing

Ying

Manríquez

et al. 2020

Materials Today Bio

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“…After mixing, the gels can be shaped during polymerization in molds or allowed to gel in situ at injection sites for in vivo applications. Recently, microfluidic devices have been used to produce tetra‐PEG gels as MSs 11 …”

Section: Introductionmentioning

confidence: 99%

High‐throughput, aseptic production of injectable Tetra‐PEG hydrogel microspheres for delivery of releasable covalently bound drugs

Henise

Yao

Hearn

et al. 2020

Engineering Reports

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The purpose of this work was to develop equipment and procedures for large‐scale aseptic production of injectable microsphere (MS) drug conjugates. The two major challenges were (a) to prepare sufficient amounts of MSs for clinical trials, and (b) to prepare the MS‐drug product under aseptic conditions. The approach was to prepare the MS‐drug conjugate in two stages. Stage 1 was the preparation of monodisperse tetra‐PEG amine derivatized MSs (amino‐MS) from two soluble PEG prepolymers under low to no bioburden conditions. To accomplish this, custom‐engineered equipment compatible with both aqueous and organic solvents was fabricated for parallel microfluidic preparation of amino‐MS. The system was capable of preparing up to ∼2 L of high quality 50 μm diameter amino‐MS per day. Stage 2 was the sterilization of the starting amino‐MS and aseptic production of the MS‐drug conjugate. The amino‐MS were first sterilized by autoclaving then transferred to a custom‐engineered autoclave‐sterilized washer‐reactor. This apparatus allowed for activation of the amino‐MS and attachment of a linker‐drug under aseptic conditions to give the sterile MS‐drug conjugate drug substance. The final drug product was produced by addition of excipients to form a homogeneous suspension. The entire process is exemplified by an engineering production run of a sterile MS‐peptide drug product.

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“…Microfluidic techniques have a number of appealing features, since it allows a high control over the diameter and morphology of the cell encapsulation matrix. However, it requires a high gelation capacity of the encapsulation matrix solution, which limits the list of available biomaterials [13, 14]. Moreover, oil is often used as a continuous phase to aid forming droplets, which is not a suitable choice for biomedical applications [12].…”

Section: Introductionmentioning

confidence: 99%

Cell encapsulation in liquified compartments: Protocol optimization and challenges

Correia

Ghasemzadeh-Hasankolaei

Mano

2019

PLoS ONE

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Cell encapsulation is a widely used technique in the field of Tissue Engineering and Regenerative Medicine (TERM). However, for the particular case of liquefied compartmentalised systems, only a limited number of studies have been reported in the literature. We have been exploring a unique cell encapsulation system composed by liquefied and multilayered capsules. This system transfigured the concept of 3D scaffolds for TERM, and was already successfully applied for bone and cartilage regeneration. Due to a number of appealing features, we envisage that it can be applied in many other fields, including in advanced therapies or as disease models for drug discovery. In this review, we intend to highlight the advantages of this new system, while discussing the methodology, and sharing the protocol optimization and results. The different liquefied systems for cell encapsulation reported in the literature will be also discussed, considering the different encapsulation matrixes as core templates, the types of membranes, and the core liquefaction treatments.

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Microfluidic Formation of Hydrogel Microcapsules with a Single Aqueous Core by Spontaneous Cross-Linking in Aqueous Two-Phase System Droplets

Cited by 56 publications

References 52 publications

An open-source handheld extruder loaded with pore-forming bioink for in situ wound dressing

An open-source handheld extruder loaded with pore-forming bioink for in situ wound dressing

High‐throughput, aseptic production of injectable Tetra‐PEG hydrogel microspheres for delivery of releasable covalently bound drugs

Cell encapsulation in liquified compartments: Protocol optimization and challenges

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