Bio-electrospraying of human mesenchymal stem cells: An alternative for tissue engineering

Braghirolli, Daikelly Iglesias; Zamboni, Fernanda; Chagastelles, Pedro César; Moura, Dinara Jaqueline; Saffi, Jenifer; Henriques, João Antônio Pêgas; Pilger, Diogo André; Pranke, Patrícia

doi:10.1063/1.4819747

Cited by 36 publications

(42 citation statements)

References 30 publications

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“…The electrostatic repulsion between the positive charges present in the needles used in polymer electrospinning and the cell electrospraying syringes was probably the cause of the displacement of the bioelectrospraying jet away from the Petri dish. This observation is corroborated by the fact that when just the bioelectrospraying was conducted in a previous study, 14 cell recovery was about 83%. The effect was also observed by Stankus et al 10 In their work, the repulsion from Coulombic forces caused a small area of electrospinning and electrospraying convergence.…”

supporting

confidence: 67%

“…In a previous study, 14 the concentration of 3×10 6 cells/mL was used to conduct the standardization of bioelectrospraying parameters. However, when the bioelectrospraying was associated with electrospinning, suspensions with low cell concentrations yielded SCCs with poor cellular densities.…”

Section: Discussionmentioning

confidence: 99%

“…10,11 Mesenchymal stem cells (MSCs) are multipotent stem cells with great plasticity, which secrete different bioactive factors that can assist in the regeneration process at the tissue injury site. 12,13 In a previous study, 14 our group demonstrated that MSCs can be safely electrosprayed, subject to compliance of the applied voltage and time of electrospraying processing.…”

mentioning

confidence: 99%

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Association of electrospinning with electrospraying: a strategy to produce 3D scaffolds with incorporated stem cells for use in tissue engineering

Braghirolli¹,

Zamboni²,

Acasigua³

et al. 2015

IJN

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In tissue engineering, a uniform cell occupation of scaffolds is crucial to ensure the success of tissue regeneration. However, this point remains an unsolved problem in 3D scaffolds. In this study, a direct method to integrate cells into fiber scaffolds was investigated by combining the methods of electrospinning of fibers and bioelectrospraying of cells. With the associating of these methods, the cells were incorporated into the 3D scaffolds while the fibers were being produced. The scaffolds containing cells (SCCs) were produced using 20% poly(lactide- co -glycolide) solution for electrospinning and mesenchymal stem cells from deciduous teeth as a suspension for bioelectrospraying. After their production, the SCCs were cultivated for 15 days at 37°C with an atmosphere of 5% CO 2 . The 3-(4,5-dimethylthiazol- 2-yl)-2,5-diphenyltetrazolium bromide test demonstrated that the cells remained viable and were able to grow between the fibers. Scanning electron microscopy showed the presence of a high number of cells in the structure of the scaffolds and confocal images demonstrated that the cells were able to adapt and spread between the fibers. Histological analysis of the SCCs after 1 day of cultivation showed that the cells were uniformly distributed throughout the thickness of the scaffolds. Some physicochemical properties of the scaffolds were also investigated. SCCs exhibited good mechanical properties, compatible with their handling and further implantation. The results obtained in the present study suggest that the association of electrospinning and bioelectrospraying provides an interesting tool for forming 3D cell-integrated scaffolds, making it a viable alternative for use in tissue engineering.

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supporting

confidence: 67%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Association of electrospinning with electrospraying: a strategy to produce 3D scaffolds with incorporated stem cells for use in tissue engineering

Braghirolli¹,

Zamboni²,

Acasigua³

et al. 2015

IJN

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“…Sahoo et al demonstrated bone marrow stem cells (BMSCs) electrosprayed at 7.5kV retain their multipotency and differentiate into adipogenic, chondrogenic, and osteogenic lineages although cell viability decreased with increasing applied voltages [16] . Furthermore, other studies focusing on applied voltage, needle diameter, polymer concentration and cell density effects confirm that the EHD processing technique does not impose detrimental effects on cell viability [13b, 16] , and that applied voltages between 0kV and 20kV as well as flow rate had no obvious effect on human stem cell survival [17] . To this end, fabricated functional living constructs may be explored for repair and replacement of damaged or degenerating tissues or organs, and/or for delivery of personalised medicines in a controlled and localised manner.…”

Section: Ehd Spraying Technologymentioning

confidence: 61%

Living Cell Factories ‐ Electrosprayed Microcapsules and Microcarriers for Minimally Invasive Delivery

et al. 2015

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Minimally invasive delivery of "living cell factories" consisting of cells and therapeutic agents has gained wide attention for next generation biomaterial device systems for multiple applications including musculoskeletal tissue regeneration, diabetes and cancer. Cellularbased microcapsules and microcarrier systems offer several attractive features for this particular purpose. One such technology capable of generating these types of systems is electrohydrodynamic (EHD) spraying. Depending on various parameters including applied voltage, biomaterial properties (viscosity, conductivity) and needle geometry, complex structures and arrangements can be fabricated for therapeutic strategies. In this paper, we outline the advances in the use of EHD technology specifically in the manipulation of bioactive and dynamic material systems to control size, composition and configuration in the development of minimally invasive micro-scaled biopolymeric systems. The exciting therapeutic applications of this technology, future perspectives and associated challenges are also presented.

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“…In other studies, BES was used to process mesenchymal stem cells and human adipose-derived stem cells. 170,171 In both cases, the viability and proliferative capacity of electrosprayed cells remained intact compared to that of the controls (without undergoing electrical stress) as no changes in cellular metabolism, plasticity, or immunophenotypic profile were observed, although a breakdown of cellular DNA was detected in case of mesenchymal stem cells. However, the exact reason for the damage is still not clear, although genotoxic effects of electromagnetic fields could be a possible cause.…”

Section: Bioelectrospraying and Cell Electrospinningmentioning

confidence: 71%

Pharmaceutical Applications of Electrospraying

Nguyen

Clasen

Mooter

2016

Journal of Pharmaceutical Sciences

153

128

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The electrohydrodynamic atomization technique, or simply called electrospraying, has been extensively studied for biomedical as well as for pharmaceutical applications over the past years. The simplicity, flexibility, and efficiency of producing particles at the microscale or nanoscale, with tailored size, shape, morphology, and microstructure, make electrospraying to become one of the most promising and well-practiced approaches to be applied in many biomedical and pharmaceutical fields, from improving the bioavailability of poorly aqueous soluble drugs, preparing targeted drug delivery systems, and controllable drug release systems to delivering sensitive therapeutic agents such as protein-based drugs or even living cells. Nevertheless, some issues still remain with respect to low throughput as well as the complex interplay between a great number of processing and formulation factors. A comprehensive understanding of these fundamental aspects is essential for the successful application of electrospraying for the production of particulate formulations with desired properties.

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Bio-electrospraying of human mesenchymal stem cells: An alternative for tissue engineering

Cited by 36 publications

References 30 publications

Association of electrospinning with electrospraying: a strategy to produce 3D scaffolds with incorporated stem cells for use in tissue engineering

Association of electrospinning with electrospraying: a strategy to produce 3D scaffolds with incorporated stem cells for use in tissue engineering

Living Cell Factories ‐ Electrosprayed Microcapsules and Microcarriers for Minimally Invasive Delivery

Pharmaceutical Applications of Electrospraying

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