Microfluidic fabrication of bioactive microgels for rapid formation and enhanced differentiation of stem cell spheroids

Siltanen, Christian; Yaghoobi, Maliheh; Haque, Amranul; You, Jungmok; Lowen, Jeremy; Soleimani, Masoud; Revzin, Alexander

doi:10.1016/j.actbio.2016.01.012

Cited by 101 publications

(92 citation statements)

References 33 publications

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“…The polydispersity of microgel particle size distributions was calculated as the standard deviation of the diameter of particles divided by the mean diameter for both microfluidic and vortex fabrication methods. The microfluidic technique generated microgels with a 6.22% polydispersity while vortexing produced particle samples with an average polydispersity of 23.62%, Monodispersity of microgels generated by microfluidics has been shown to be increased by further reducing channel and particle size 26 . Well-controlled size distributions holds enabling consequences for precision cell encapsulation 61 and high throughput cell screening 37 .…”

Section: Resultsmentioning

confidence: 99%

“…Miniaturizing PEG hydrogels through microfabrication or microfluidics has emerged as a promising and versatile platform for biosensing 23 , tissue engineering 24 , drug delivery 25,26 , and high throughput screening 27 . The generation of structured hydrogels through bioprinting 28 , photolithography 29 , and liquid bridging 30 have been demonstrated to effectively generate functional platforms for cell studies.…”

Section: Introductionmentioning

confidence: 99%

“…However, the throughput of SFL is ultimately limited by exposure area and polymerization kinetics 33,34 . Microfluidic emulsification, a two-phase microfluidic technique capable of generating monodisperse aqueous droplets in continuous oil phase has improved microgel fabrication frequency to kHz 26 , thus providing a potential tool for high throughput single cell encapsulation or screening 35-37 . Sustained cell viability following photoencapsulation is a critical parameter for therapeutic cell delivery applications.…”

Section: Introductionmentioning

confidence: 99%

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A microfluidic-based cell encapsulation platform to achieve high long-term cell viability in photopolymerized PEGNB hydrogel microspheres

et al. 2017

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Cell encapsulation within photopolymerized polyethylene glycol (PEG)-based hydrogel scaffolds has been demonstrated as a robust strategy for cell delivery, tissue engineering, regenerative medicine, and developing in vitro platforms to study cellular behavior and fate. Strategies to achieve spatial and temporal control over PEG hydrogel mechanical properties, chemical functionalization, and cytocompatibility have advanced considerably in recent years. Recent microfluidic technologies have enabled the miniaturization of PEG hydrogels, thus enabling the fabrication of miniaturized cell-laden vehicles. However, rapid oxygen diffusive transport times on the microscale dramatically inhibit chain growth photopolymerization of polyethylene glycol diacrylate (PEGDA), thus decreasing the viability of cells encapsulated within these microstructures. Another promising PEG-based scaffold material, PEG norbornene (PEGNB), is formed by a step-growth photopolymerization and is not inhibited by oxygen. PEGNB has also been shown to be more cytocompatible than PEGDA and allows for orthogonal addition reactions. The step-growth kinetics, however, are slow and therefore challenging to fully polymerize within droplets flowing through microfluidic devices. Here, we describe a microfluidic-based droplet fabrication platform that generates consistently monodisperse cell-laden water-in-oil emulsions. Microfluidically generated PEGNB droplets are collected and photopolymerized under UV exposure in bulk emulsions. In this work, we compare this microfluidic-based cell encapsulation platform with a vortex-based method on the basis of microgel size, uniformity, post-encapsulation cell viability and long-term cell viability. Several factors that influence post-encapsulation cell viability were identified. Finally, long-term cell viability achieved by this platform was compared to a similar cell encapsulation platform using PEGDA. We show that this PEGNB microencapsulation platform is capable of generating cell-laden hydrogel microspheres at high rates with well-controlled size distributions and high long-term cell viability.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A microfluidic-based cell encapsulation platform to achieve high long-term cell viability in photopolymerized PEGNB hydrogel microspheres

et al. 2017

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“…Crosslinking PEG-4MAL macromers can be accomplished with dithiol molecules and does not require free radical initiators, which are detrimental to encapsulated cell health 13 . Similar microfluidic schemes for producing microgels [14][15][16] and encapsulating cells [17][18][19] have recently been reported for widely varying applications, including wound healing, stem cell culture and fundamental studies of cell biology. The versatility of microfluidic cell encapsulation extends to other polymers, including Matrigel 20 , agarose 21 and even multilayer core-shell composites such as collagen cores with alginate shells 22 .…”

Section: Introductionmentioning

confidence: 99%

Parallel droplet microfluidics for high throughput cell encapsulation and synthetic microgel generation

2018

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Cells can be microencapsulated in synthetic hydrogel microspheres (microgels) using droplet microfluidics, but microfluidic devices with a single droplet generating geometry have limited throughput, especially as microgel diameter decreases. Here we demonstrate microencapsulation of human mesenchymal stem cells (hMSCs) in small ( o100 μm diameter) microgels utilizing parallel droplet generators on a two-layer elastomer device, which has 600% increased throughput vs. single-nozzle devices. Distribution of microgel diameters were compared between products of parallel vs. single-nozzle configurations for two square nozzle widths, 35 and 100 μm. Microgels produced on parallel nozzles were equivalent to those produced on single nozzles, with substantially the same polydispersity. Microencapsulation of hMSCs was compared for parallel nozzle devices of each width. Thirty five micrometer wide nozzle devices could be operated at twice the cell concentration of 100 μm wide nozzle devices but produced more empty microgels than predicted by a Poisson distribution. Hundred micrometer wide nozzle devices produced microgels as predicted by a Poisson distribution. Polydispersity of microgels did not increase with the addition of cells for either nozzle width. hMSCs encapsulated on 35 μm wide nozzle devices had reduced viability (~70%) and a corresponding decrease in vascular endothelial growth factor (VEGF) secretion compared to hMSCs cultured on tissue culture (TC) plastic. Encapsulating hMSCs using 100 μm wide nozzle devices mitigated loss of viability and function, as measured by VEGF secretion.

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“…17,18 In contrast to macroscopic hydrogels, microgels exhibit reduced characteristic lengths and increased surface area, which provides potential for manipulation as a delivery platform. These strategies have been used to promote cellular encapsulation, 19,20 control drug release, 21,22 and have formed a platform for responsive materials. [23][24][25][26] Microgel encapsulation may hold advantage for the delivery of lentivectors, [27][28][29] but adapting these microfluidic techniques for producing lentivector-compatible microgels represents an engineering challenge.…”

Section: Introductionmentioning

confidence: 99%

Microfluidic generation of alginate microgels for the controlled delivery of lentivectors

et al. 2016

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Microgels fabricated through distinct microfluidic procedures encapsulate and release functioning lentivectors in a controlled manner.Please check this proof carefully. Our staff will not read it in detail after you have returned it.Translation errors between word-processor files and typesetting systems can occur so the whole proof needs to be read. Please pay particular attention to: tabulated material; equations; numerical data; figures and graphics; and references. If you have not already indicated the corresponding author(s) please mark their name(s) with an asterisk. Please e-mail a list of corrections or the PDF with electronic notes attached -do not change the text within the PDF file or send a revised manuscript. Corrections at this stage should be minor and not involve extensive changes. All corrections must be sent at the same time.Please bear in mind that minor layout improvements, e.g. in line breaking, table widths and graphic placement, are routinely applied to the final version.Please note that, in the typefaces we use, an italic vee looks like this: n, and a Greek nu looks like this: n.We will publish articles on the web as soon as possible after receiving your corrections; no late corrections will be made.Please return your final corrections, where possible within 48 hours of receipt, by e-mail to: materialsB@rsc.orgQueries for the attention of the authors However, achieving safe, localized, and sufficient gene expression remain key challenges for effective lentivectoral therapy. Localized and efficient gene expression can be promoted by developing material systems to deliver lentivectors. Here, we address the utility of microgel encapsulation as a strategy for the controlled release of lentivectors. Three distinct routes for ionotropic gelation of alginate were incorporated into microfluidic templating to create lentivector-loaded microgels. Comparisons of the three microgels revealed marked differences in mechanical properties, crosslinking environment, and ultimately lentivector release and functional gene expression in vitro. Gelation with chelated calcium demonstrated low utility for gene delivery due to a loss of lentivector function with acidic gelation conditions. Both calcium carbonate gelation, and calcium chloride gelation, preserved lentivector function with a more sustained transduction and gene expression over 4 days observed with calcium chloride gelated microgels. The validation of these two strategies for lentivector microencapsulation may provide a platform for controlled gene delivery.

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Microfluidic fabrication of bioactive microgels for rapid formation and enhanced differentiation of stem cell spheroids

Cited by 101 publications

References 33 publications

A microfluidic-based cell encapsulation platform to achieve high long-term cell viability in photopolymerized PEGNB hydrogel microspheres

A microfluidic-based cell encapsulation platform to achieve high long-term cell viability in photopolymerized PEGNB hydrogel microspheres

Parallel droplet microfluidics for high throughput cell encapsulation and synthetic microgel generation

Microfluidic generation of alginate microgels for the controlled delivery of lentivectors

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