Lousineh Arakélian scite author profile

In recent years, 3D cell culture models such as spheroid or organoid technologies have known important developments. Many studies have shown that 3D cultures exhibit better biomimetic properties compared to 2D cultures. These properties are important for in-vitro modeling systems, as well as for in-vivo cell therapies and tissue engineering approaches. A reliable use of 3D cellular models still requires standardized protocols with well-controlled and reproducible parameters. To address this challenge, a robust and scaffold-free approach is proposed, which relies on multi-trap acoustic levitation. This technology is successfully applied to Mesenchymal Stem Cells (MSCs) maintained in acoustic levitation over a 24-h period. During the culture, MSCs spontaneously self-organized from cell sheets to cell spheroids with a characteristic time of about 10 h. Each acoustofluidic chip could contain up to 30 spheroids in acoustic levitation and four chips could be ran in parallel, leading to the production of 120 spheroids per experiment. Various biological characterizations showed that the cells inside the spheroids were viable, maintained the expression of their cell surface markers and had a higher differentiation capacity compared to standard 2D culture conditions. These results open the path to long-time cell culture in acoustic levitation of cell sheets or spheroids for any type of cells.

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Circumferential Esophageal Replacement by a Tissue-engineered Substitute Using Mesenchymal Stem Cells

Catry

Luong-Nguyen

Arakélian

et al. 2017

Cell Transplant

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Tissue engineering appears promising as an alternative technique for esophageal replacement. Mesenchymal stem cells (MSCs) could be of interest for esophageal regeneration. Evaluation of the ability of an acellular matrix seeded with autologous MSCs to promote tissue remodeling toward an esophageal phenotype after circumferential replacement of the esophagus in a mini pig model. A 3 cm long circumferential replacement of the abdominal esophagus was performed with an MSC-seeded matrix (MSC group, n = 10) versus a matrix alone (control group, n = 10), which has previously been matured into the great omentum. The graft area was covered with an esophageal removable stent. A comparative histological analysis of the graft area after animals were euthanized sequentially is the primary outcome of the study. Histological findings after maturation, overall animal survival, and postoperative morbidity were also compared between groups. At postoperative day 45 (POD 45), a mature squamous epithelium covering the entire surface of the graft area was observed in all the MSC group specimens but in none of the control group before POD 95. Starting at POD 45, desmin positive cells were seen in the graft area in the MSC group but never in the control group. There were no differences between groups in the incidence of surgical complications and postoperative death. In this model, MSCs accelerate the mature re-epitheliazation and early initiation of muscle cell colonization. Further studies will focus on the use of cell tracking tools in order to analyze the becoming of these cells and the mechanisms involved in this tissue regeneration.

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Esophageal tissue engineering: Current status and perspectives

Poghosyan

Catry

Luong-Nguyen

et al. 2016

Journal of Visceral Surgery

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Tissue engineering, which consists of the combination and in vivo implantation of elements required for tissue remodeling toward a specific organ phenotype, could be an alternative for classical techniques of esophageal replacement. The current hybrid approach entails creation of an esophageal substitute composed of an acellular matrix and autologous epithelial and muscle cells provides the most successful results. Current research is based on the use of mesenchymal stem cells, whose potential for differentiation and proangioogenic, immune-modulator and anti-inflammatory properties are important assets. In the near future, esophageal substitutes could be constructed from acellular "intelligent matrices" that contain the molecules necessary for tissue regeneration; this should allow circumvention of the implantation step and still obtain standardized in vivo biological responses. At present, tissue engineering applications to esophageal replacement are limited to enlargement plasties with absorbable, non-cellular matrices. Nevertheless, the application of existing clinical techniques for replacement of other organs by tissue engineering in combination with a multiplication of translational research protocols for esophageal replacement in large animals should soon pave the way for health agencies to authorize clinical trials.

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Esophageal tissue engineering: from bench to bedside

Arakélian

Kanai

Dua

et al. 2018

Annals of the New York Academy of Sciences

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For various esophageal diseases, the search for alternative techniques for tissue repair has led to significant developments in basic and translational research in the field of tissue engineering. Applied to the esophagus, this concept is based on the in vitro combination of elements judged necessary for in vivo implantation to promote esophageal tissue remodeling. Different methods are currently being explored to develop substitutes using cells, scaffolds, or a combination of both, according to the severity of lesions to be treated. In this review, we discuss recent advances in (1) cell sheet technology for preventing stricture after extended esophageal mucosectomy and (2) full‐thickness circumferential esophageal replacement using tissue‐engineered substitutes.

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Trends in 3D bioprinting for esophageal tissue repair and reconstruction

et al. 2021

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A clinical‐grade acellular matrix for esophageal replacement

Arakélian

Caille

Faivre

et al. 2019

J Tissue Eng Regen Med

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Biofabrication of an Esophageal Tissue Construct from a Polymer Blend Using 3D Extrusion‐Based Printing

et al. 2022

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Many tissue engineering approaches are being explored to offer solutions for diseased esophageal tissue and its repair. However, classical techniques in tissue engineering are not capable of recapitulating the structural and functional parameters of native esophagi. Esophageal 3D bioprinting is yet an emerging field but holds great promise in meeting this challenge. Herein, the use of extrusion‐based 3D printing is examined to generate esophageal substitutes from a polymer blend‐based formulation. The fabricated 3D esophageal structures are printed at a very high speed without collapse and without the use of supporting material. In vitro analysis reveals that the printed material enables cell adhesion, proliferation, and migration into the deeper zones. Moreover, the designed construct is suturable to the native esophagus and exhibits no leakage while offering mechanical properties similar to that of the native tissue. Overall, these biochemical and biomechanical features make the reported artificial esophagus a promising solution for the repair of damaged esophagi.

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