Patterning of Endothelial Cells and Mesenchymal Stem Cells by Laser-Assisted Bioprinting to Study Cell Migration

Bourget, Jean-Michel; Kérourédan, Olivia; Medina, M.; Rémy, Murielle; Thebaud, Noëlie; Bareille, Reine; Chassande, Olivier; Amédée, Joëlle; Catros, Sylvain; Devillard, Raphaël

doi:10.1155/2016/3569843

Cited by 59 publications

(39 citation statements)

References 33 publications

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“…4a ). During this time period, cells were proliferating (1 doubling per 2 days) and a progressive disorganization of patterns was observed similar to that in monoculture 32 . The MR images acquired with a short scan time (only 4 min) were nevertheless able to show the spread of the cells within the petri dish.…”

Section: Resultssupporting

confidence: 59%

Magnetic Resonance Imaging for tracking cellular patterns obtained by Laser-Assisted Bioprinting

Kérourédan

Ribot

Fricain

et al. 2018

Sci Rep

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Recent advances in the field of Tissue Engineering allowed to control the three-dimensional organization of engineered constructs. Cell pattern imaging and in vivo follow-up remain a major hurdle in in situ bioprinting onto deep tissues. Magnetic Resonance Imaging (MRI) associated with Micron-sized superParamagnetic Iron Oxide (MPIO) particles constitutes a non-invasive method for tracking cells in vivo. To date, no studies have utilized Cellular MRI as a tool to follow cell patterns obtained via bioprinting technologies. Laser-Assisted Bioprinting (LAB) has been increasingly recognized as a new and exciting addition to the bioprinting’s arsenal, due to its rapidity, precision and ability to print viable cells. This non-contact technology has been successfully used in recent in vivo applications. The aim of this study was to assess the methodology of tracking MPIO-labeled stem cells using MRI after organizing them by Laser-Assisted Bioprinting. Optimal MPIO concentrations for tracking bioprinted cells were determined. Accuracy of printed patterns was compared using MRI and confocal microscopy. Cell densities within the patterns and MRI signals were correlated. MRI enabled to detect cell patterns after in situ bioprinting onto a mouse calvarial defect. Results demonstrate that MRI combined with MPIO cell labeling is a valuable technique to track bioprinted cells in vitro and in animal models.

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Section: Resultssupporting

confidence: 59%

Magnetic Resonance Imaging for tracking cellular patterns obtained by Laser-Assisted Bioprinting

Kérourédan

Ribot

Fricain

et al. 2018

Sci Rep

Self Cite

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“…This study indicated that EB diameter was affected by printing density, while there was no such a relevance between the diameter of printed colony and EB size (20). A similar study, in order to figure out the effect of MSCs and endothelial cells (ECs) co-culture on the migration potential, used a LBB system and showed that coprinting can reduce the ECs migration and results in initial pattern conservation (21).…”

Section: Inkjet Bioprintingmentioning

confidence: 87%

Untitled

2018

Mod Med Lab J

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Regenerative medicine, deals with functional reconstruction of damaged tissues or organs after severe injuries chronic diseases, while body's natural responses are not sufficient. In this field, stem cells due to their exclusive potential in self-renewal and differentiation into other cell types, are the main sources of functional cells in regenerative medicine. However, challenges in stem cell culturing highlighted the need for new methods, which in addition to maintaining cell viability and functionality, can control the precise microarchitecture for cells in a three dimensional structure. In this review we focus on the application of different types of bioprinting technology in regenerative medicine and we overview how this method has been able to make progress in 3D-cell culturing and tissue engineering protocols.

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“…In addition, the crosstalk between human osseous cell sheets and HUVECs in the presence of laser assisted bioprinting biopapers leads to the formation of human prevascularized cell‐based osseous constructs that can be applied for autologous bone repair applications . However, when they were printed with MSCs, they remained in the printed lines, which again indicates the importance of coculture of the two cell types . In other attempts to enhance tissue survival and integration, vascularized heterogeneous tissue was developed by using ECs and fibroblasts ( Figure ).…”

Section: Bioprinted Bone Constructsmentioning

confidence: 99%

Advancing Frontiers in Bone Bioprinting

Ashammakhi

Hasan

Kaarela

et al. 2019

Adv Healthcare Materials

183

182

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Three‐dimensional (3D) bioprinting of cell‐laden biomaterials is used to fabricate constructs that can mimic the structure of native tissues. The main techniques used for 3D bioprinting include microextrusion, inkjet, and laser‐assisted bioprinting. Bioinks used for bone bioprinting include hydrogels loaded with bioactive ceramics, cells, and growth factors. In this review, a critical overview of the recent literature on various types of bioinks used for bone bioprinting is presented. Major challenges, such as the vascularity, clinically relevant size, and mechanical properties of 3D printed structures, that need to be addressed to successfully use the technology in clinical settings, are discussed. Emerging approaches to solve these problems are reviewed, and future strategies to design customized 3D printed structures are proposed.

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Patterning of Endothelial Cells and Mesenchymal Stem Cells by Laser-Assisted Bioprinting to Study Cell Migration

Cited by 59 publications

References 33 publications

Magnetic Resonance Imaging for tracking cellular patterns obtained by Laser-Assisted Bioprinting

Magnetic Resonance Imaging for tracking cellular patterns obtained by Laser-Assisted Bioprinting

Untitled

Advancing Frontiers in Bone Bioprinting

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