Bio-electrospraying and aerodynamically assisted bio-jetting the model eukaryotic
            <i>Dictyostelium discoideum</i>
            : assessing stress and developmental competency post treatment

Pakes, Nicholl K.; Jayasinghe, Suwan N.; Williams, Robin S.B.

doi:10.1098/rsif.2010.0696

Cited by 20 publications

(10 citation statements)

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“…In AABJ the cell suspension is drawn into a jet through an exit orifice by means of a pressure gradient subjected by way of a pressurized chamber over the exit orifice 11. This technology could be argued as being a softer approach for jetting cells for deposition, and indeed has been used for handling embryos 12, 13…”

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confidence: 99%

In Vitro and In Vivo Interrogation of Bio‐sprayed Cells

Andreu

Thomas

Saraiva

et al. 2012

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Bio-sprays can directly form pre-organized cell-bearing structures for applications ranging from engineering functional tissues to the forming of cultures, most useful for modeling disease, to the discovery and development of drugs. Bio-electrosprays and aerodynamically assisted bio-jets, are leading approaches that have been demonstrated as having far-reaching ramifications for regenerative biology and medicine.

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confidence: 99%

In Vitro and In Vivo Interrogation of Bio‐sprayed Cells

Andreu

Thomas

Saraiva

et al. 2012

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“…From the demonstration of using this technology for both the processing of a wide range of advanced materials, spanning the structural and functional classes of materials, subsequent investigations established the ability for aerodynamically assisted jets to directly handle a wide range of cells and whole fertilized embryos. [33,34] The processed cells through this technology have undergone rigorous studies for assessing their viability and functionality from a molecular level upward, thus characterized via well-established biological protocols such as gene microarrays to those karyotypic studies. [34,35] Continued investigations have shown these post processed cells have been transplanted into mouse models, which have engrafted without rejection and thus have been comparable to those controls.…”

Section: Nonchannel/capillary Based Flow Cellsmentioning

confidence: 99%

“…[ 33,34 ] The processed cells through this technology have undergone rigorous studies for assessing their viability and functionality from a molecular level upward, thus characterized via well‐established biological protocols such as gene microarrays to those karyotypic studies. [ 34,35 ] Continued investigations have shown these post processed cells have been transplanted into mouse models, which have engrafted without rejection and thus have been comparable to those controls. [ 36 ] These studies together with our other investigations demonstrated AABJ’s capability to directly handle highly concentrated cellular suspensions.…”

Section: Flow Cell Technologymentioning

confidence: 99%

Reimagining Flow Cytometric Cell Sorting

Jayasinghe

2020

Adv. Biosys.

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through computer control, via both software and hardware. Each aspect plays its crucial role for successfully and accurately assessing the dynamics of single cells within a heterogeneous cell population. The reader should note that the author has chosen to describe flow cytometry first and later FACS. The author's reason for explaining the techniques this way round is primarily as this review is designed for lay readers, thus understanding the simplified equipment arrangement, prior to considering the more complex operation that takes place in the cell purification process. Briefly, the cells and/or particles start their journey in flow cytometry as suspensions. Essentially, the fluidics (flow cell) component sees the technology take a near homogenously suspended cellular population, aspirating it in laminar flow conditions, for forming a liquid jet having a near single cell diameter. This is created by the suspension fed into a flow cell accommodating a needle, centrally placed in a cylindrical chamber, having a converging base, and exit, which is coupled with a short jet stabilizing nozzle. This chamber has another input, namely, the sheath flow. With the sheath and sample flowing, the exiting sample is squeezed by the sheath flow, for it to eventually pass through both the converging architecture at the base of the chamber and subsequently flowing past the jet stabilizing exit nozzle. [2] The sheath squeezing effect, both focuses and narrows the ensuing composite jet to nearly the diameter of the cells in suspension. This process is referred to as hydrodynamic focusing. [3] This exiting fine composite jet breaking into droplets subsequently passes the point referred to as the interrogation point, where it is exposed to the laser. There are two angles in which the laser assesses these cells while they are in the jet, namely, through forward and side scatter. The forward scatter assessment process identifies the cells by way of their size. Simply put, if one was to take two objects of different shapes and sizes and place in front of a source of light, their shapes and sizes would scatter different amounts of light. This would be evident by the reflective image of the shapes created of themselves seen on some collector, placed opposite to the light source. Forward scatter works on this principle and has a detector placed on the opposite side of the laser. Similar in some respects, side scatter works with a fluorophore which is tagged using some antibody on one side while the opposite end of the antibody is attached to the molecule of interest. Note that many years of research into molecular and cell biology has given rise to the development of advanced antibodies and fluorophores which enable many cellular components to be assessed in real In this review, a brief history of this unrivaled technology, flow cytometry, is provided, highlighting its past and present advances, with particular focus on "flow cell" technologies. Flow cytometry has truly revolutionized highthroughput single cell analysis, which has treme...

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“…Townsend‐Nicholson and Jayasinghe showed that it was possible to directly electrospin living organisms under stable threading conditions by using a coaxial needle arrangement where a concentrated living biosuspension flowed through the inner needle and a medical grade poly(dimethylsiloxane) medium with high viscosity and low electrical conductivity flowed through the outer needle. This technique was employed to electrospin primary cells and whole organisms (e. g. Saccharomyces cerevisiae and Xenopus tropicalis ) that were viable over long periods of time . By employing a rotating mandrel as fibers collector for cell electrospinning, multiple core vessel‐like structures containing multiple cell types from the inner to the outer core were developed .…”

Section: Nano/microfibrous Scaffolds Fabricationmentioning

confidence: 99%

Nano/microfibrous polymeric constructs loaded with bioactive agents and designed for tissue engineering applications: A review

et al. 2014

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Nano/microfibrous polymeric constructs present various inherent advantages, such as highly porous architecture and high surface to volume ratio, making them attractive for tissue engineering purposes. Electrospinning is the most preferred technique for the fabrication of polymeric nanofibrous assemblies that can mimic the physical functions of native extracellular matrix greatly favoring cells attachment and thus influencing their morphology and activities. Different approaches have been developed to apply polymeric microfiber fabrication techniques (e.g. wet-spinning) for the obtainment of scaffolds with a three-dimensional network of micropores suitable for effective cells migration. Progress in additive manufacturing technology has led to the development of complex scaffold's shapes and microfibrous structures with a high degree of automation, good accuracy and reproducibility. Various loading methods, such as direct blending, coaxial electrospinning and microparticles incorporation, are enabling to develop customized strategies for the biofunctionalization of nano/microfibrous scaffolds with a tailored kinetics of release of different bioactive agents, ranging from small molecules, such as antibiotics, to protein drugs, such as growth factors, and even cells. Recent activities on the combination of different processing techniques and loading methods for the obtainment of biofunctionalized polymeric constructs with a complex multiscale structure open new possibilities for the development of biomimetic scaffolds endowed with a hierarchical architecture and a sophisticated release kinetics of different bioactive agents. This review is aimed at summarizing current advances in technologies and methods for manufacturing nano/microfibrous polymeric constructs suitable as tissue engineering scaffolds, and for their combination with different bioactive agents to promote tissue regeneration and therapeutic effects.

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Bio-electrospraying and aerodynamically assisted bio-jetting the model eukaryotic Dictyostelium discoideum : assessing stress and developmental competency post treatment

Cited by 20 publications

References 46 publications

In Vitro and In Vivo Interrogation of Bio‐sprayed Cells

In Vitro and In Vivo Interrogation of Bio‐sprayed Cells

Reimagining Flow Cytometric Cell Sorting

Nano/microfibrous polymeric constructs loaded with bioactive agents and designed for tissue engineering applications: A review

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