Droplet encapsulation of particles in different regimes and sorting of particle-encapsulating-droplets from empty droplets

Jayaprakash, Karamil; Sen, A. K.

doi:10.1063/1.5096937

Cited by 15 publications

(5 citation statements)

References 33 publications

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“…Another widely used method is fluid extrusion, in which a solution of cells suspended in a liquid is taken up in glass syringes and pumped into microchannels using syringe pumps to generate droplets. Depending on the number of flow capillaries, droplets can be generated in three regimes: squeezing, dripping, and jetting, using a flow-focusing junction (Jayaprakash and Sen, 2019).…”

Section: Cellular Microencapsulation Techniquesmentioning

confidence: 99%

On the path to a diabetes cure: a critical appraisal of developments in pancreatic beta cell encapsulation and implantation

Díaz

2024

Rev Fac, Farmacia

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Microencapsulation of β-cells is a rapidly growing field that offers broad potential for the therapy and possible cure of diabetes, especially type 1 diabetes, thanks to the immunization of the engrafted tissue that increases its long-term efficacy and decreases the risk of immunogenicity. Despite the promising results obtained in human and animal studies, important challenges need to be addressed. The structure and composition of the microspheres and the site where they are implanted can affect the effectiveness of the treatment, and associated immunogenicity problems have been reported. To improve the safety of the encapsulated islet graft system, new efforts are being made in the bioengineering of the capsules and the production of insulin-producing cells within the capsular membranes. These critical advances in cell encapsulation technology are expected to enable broader and more effective human application of this system. In this review, the great potential of encapsulated pancreatic islet transplantation to provide a cure for type 1 diabetes is highlighted. The advantages and disadvantages of this therapeutic strategy are also outlined, as well as key advances made in cellular microencapsulation research for treating diabetes.

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Section: Cellular Microencapsulation Techniquesmentioning

confidence: 99%

On the path to a diabetes cure: a critical appraisal of developments in pancreatic beta cell encapsulation and implantation

Díaz

2024

Rev Fac, Farmacia

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“…Droplet sorting can not only be achieved based on fluorescent properties but also on droplet size ( Huh et al 2007 ; Tan et al 2008 ; Li et al 2018 ), deformation ( Chang et al 2020 ), density ( Deshpande et al 2017 ) and directly using noninertial lift-induced forces ( Hazra et al 2019 ), sheath fluid properties with acoustics ( Karthick et al 2018 ), and mechanical properties ( Sajeesh et al 2014 ). Fluorescent tags may change the metabolome, and hence sorting by a cell's physiological and mechanical properties is highly efficient, especially for further downstream analysis ( Jayaprakash and Sen 2019 ). As the technology has advanced further, droplets have been sorted using an automated system that performs real-time dual-camera imaging.…”

Section: Single-cell Samplingmentioning

confidence: 99%

Advances in single-cell metabolomics to unravel cellular heterogeneity in plant biology

Pandian,

Matsui,

Hankemeier

et al. 2023

Plant Physiology

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Single-cell metabolomics is a powerful tool that can reveal cellular heterogeneity and can elucidate the mechanisms of biological phenomena in detail. It is a promising approach in studying plants, especially when cellular heterogeneity has an impact on different biological processes. In addition, metabolomics, which can be regarded as a detailed phenotypic analysis, is expected to answer previously unanswered questions which will lead to expansion of crop production, increased understanding of resistance to diseases, and in other applications as well. In this review, we will introduce the flow of sample acquisition, and single-cell metabolomics techniques to facilitate the adoption of single-cell metabolomics. Furthermore, the applications of single cell metabolomics will be summarized and reviewed.

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“…The successful preparation of designer droplets requires consideration of several tradeoffs, the specifics of which depend on the desired performance or applications. While encapsulation and controlled release of active agents comprise a major focus in the field, [ 1–8 ] other complementary objectives are gaining increasing attention. For example, controlling the propensity of droplets to disperse, coalesce, or aggregate without coalescing (i.e., adhere to one another) represents a new, innovative approach to soft materials construction using droplets, and hinges on embedding of stimuli‐responsive functionality into surfactant structures.…”

Section: Introductionmentioning

confidence: 99%

Smart Droplets Stabilized by Designer Surfactants: From Biomimicry to Active Motion to Materials Healing

Yang,

Snyder,

Sathyan

et al. 2023

Adv Funct Materials

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The science and technologies of emulsion droplets have been a long‐term focus of extensive research endeavors for their practical utility across a breadth of industries, including pharmaceutical products, oil recovery processes, and the food sciences. However, with advances in materials chemistry and characterization tools, new emerging areas are arising with a focus on “smart droplets”. The versatility of emulsion droplets across is based on their ability to partition and create isolated systems with properties defined by the liquid–liquid interface, while preparative routes allow manipulation of droplet size, stability, and encapsulated contents. As described in this article, significant efforts are being devoted to creating new types of droplets by “activating” this interface through the incorporation of reactive structures that trigger droplet response to applied or environmental stimuli (e.g., pH, temperature, salt, or external fields). Moreover, parallels between droplets and live cells inspire efforts to conceive systems that resemble biological motifs or that can produce cellular behaviors that imitate biology (e.g., swarming, communication, or motion). The authors highlight recent advances in smart droplets, with emphasis on organic, polymer, and/or particle surfactants that give rise to inter‐droplet communication (via aggregation, fusion, division, or mass transfer), droplet vehicles for controlled delivery, autonomous droplet motion, and tunable emulsion inversion. Especially emphasized is the macromolecular design to produce reactive and functional surfactants, which are crucial to responsive droplet behavior and their underlying mechanisms. More generally, the exquisite interplay between materials science and biology inspires the review of this research area that provides unique opportunities for insight and inspiration into the capabilities of new droplet designs.

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Droplet encapsulation of particles in different regimes and sorting of particle-encapsulating-droplets from empty droplets

Cited by 15 publications

References 33 publications

On the path to a diabetes cure: a critical appraisal of developments in pancreatic beta cell encapsulation and implantation

On the path to a diabetes cure: a critical appraisal of developments in pancreatic beta cell encapsulation and implantation

Advances in single-cell metabolomics to unravel cellular heterogeneity in plant biology

Smart Droplets Stabilized by Designer Surfactants: From Biomimicry to Active Motion to Materials Healing

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