Your search keyword '"Three dimensional"' showing total 5 results

1. 3D heterogeneous islet organoid generation from human embryonic stem cells using a novel engineered hydrogel platform.

Author

Candiello, Joseph, Grandhi, Taraka Sai Pavan, Goh, Saik Kia, Vaidya, Vimal, Lemmon-Kishi, Maya, Eliato, Kiarash Rahmani, Ros, Robert, Kumta, Prashant N., Rege, Kaushal, and Banerjee, Ipsita

Subjects

*ORGANOIDS, *EMBRYONIC stem cells, *HYDROGELS, *PROGENITOR cells, *CELL populations

Abstract

Organoids, which exhibit spontaneous organ specific organization, function, and multi-cellular complexity, are in essence the in vitro reproduction of specific in vivo organ systems. Recent work has demonstrated human pluripotent stem cells (hPSCs) as a viable regenerative cell source for tissue-specific organoid engineering. This is especially relevant for engineering islet organoids, due to the recent advances in generating functional beta-like cells from human pluripotent stem cells. In this study, we report specific engineering of regenerative islet organoids of precise size and cellular heterogeneity, using a novel hydrogel system, Amikagel. Amikagel facilitated controlled and spontaneous aggregation of human embryonic stem cell derived pancreatic progenitor cells (hESC-PP) into robust homogeneous spheroids. This platform further allowed fine control over the integration of multiple cell populations to produce heterogeneous spheroids, which is a necessity for complex organoid engineering. Amikagel induced hESC-PP spheroid formation enhanced pancreatic islet-specific Pdx-1 and NKX6.1 gene and protein expression, while also increasing the percentage of committed population. hESC-PP spheroids were further induced towards mature beta-like cells which demonstrated increased Beta-cell specific INS1 gene and C-peptide protein expression along with functional insulin production in response to in vitro glucose challenge. Further integration of hESC-PP with biologically relevant supporting endothelial cells resulted in multicellular organoids which demonstrated spontaneous maturation towards islet-specific INS1 gene and C-peptide protein expression along with a significantly developed extracellular matrix support system. These findings establish Amikagel –facilitated platform ideal for islet organoid engineering. [ABSTRACT FROM AUTHOR]

Published

2018

2. A microwell pattern for C17.2 cell aggregate formation with concave cylindrical surface induced cell peeling.

Author

Zhang, Li-Guang, Zhong, Dong-Huo, Zhang, Yiguo, Li, Chen-Zhong, Kisaalita, William S., and Wu, Ze-Zhi

Subjects

*CELL aggregation, *POLYDIMETHYLSILOXANE, *MULTICELLULAR organisms, *NEURAL stem cells, *FINITE element method, *CELL growth

Abstract

We have developed a polydimethylsiloxane (PDMS) pattern with arrays of microwells for the formation of multicellular aggregates by C17.2 neural stem cells. Upon interfacing with the patterns, the neural stem cells would firstly attach to the microwell sidewalls, forming cellular strips on day 1 after plating. For channel connected microwells, cellular strips on the concave semi-cylindrical sidewall surfaces continued among wells and through channels, followed by strip peeling due to prestress arising from actin filaments and assembly of suspending cellular aggregates within the microwells in the following 1–2 days. Our results also suggested that a small microwell diameter of 80 and 100 μm and a narrow channel width of 20 μm would facilitate the aggregate formation among the structural dimensions tested. Finite element method (FEM) simulation revealed that cellular strips on the semi-cylindrical sidewall surfaces peeled under significantly smaller prestresses (critical peeling prestress, CPP), than cells on flat substrates. However, the CPP by itself failed to fully account for the difference in aggregate inducing capability among the patterns addressed, suggesting cell growth behaviors might play a role. This study thus justified the current patterning method as a unique and practical approach for establishing 3D neural stem cell-based assay platforms. [ABSTRACT FROM AUTHOR]

Published

2014

3. Transcatheter based electromechanical mapping guided intramyocardial transplantation and in vivo tracking of human stem cell based three dimensional microtissues in the porcine heart

Author

Emmert, Maximilian Y., Wolint, Petra, Winklhofer, Sebastian, Stolzmann, Paul, Cesarovic, Nikola, Fleischmann, Thea, Nguyen, Thi D.L., Frauenfelder, Thomas, Böni, Roland, Scherman, Jacques, Bettex, Dominique, Grünenfelder, Jürg, Schwartlander, Ruth, Vogel, Viola, Gyöngyösi, Mariann, Alkadhi, Hatem, Falk, Volkmar, and Hoerstrup, Simon P.

Subjects

*CATHETERIZATION, *ELECTROMECHANICAL devices, *HEART transplantation, *MYOCARDIAL infarction treatment, *STEM cell treatment, *LABORATORY swine

Abstract

Abstract: Stem cells have been repeatedly suggested for cardiac regeneration after myocardial infarction (MI). However, the low retention rate of single cell suspensions limits the efficacy of current therapy concepts so far. Taking advantage of three dimensional (3D) cellular self-assembly prior to transplantation may be beneficial to overcome these limitations. In this pilot study we investigate the principal feasibility of intramyocardial delivery of in-vitro generated stem cell-based 3D microtissues (3D-MTs) in a porcine model. 3D-MTs were generated from iron-oxide (MPIO) labeled human adipose-tissue derived mesenchymal stem cells (ATMSCs) using a modified hanging-drop method. Nine pigs (33 ± 2 kg) comprising seven healthy ones and two with chronic MI in the left ventricle (LV) anterior wall were included. The pigs underwent intramyocardial transplantation of 16 × 103 3D-MTs (1250 cells/MT; accounting for 2 × 10 7 single ATMSCs) into the anterior wall of the healthy pigs (n = 7)/the MI border zone of the infarcted (n = 2) of the LV using a 3D NOGA electromechanical mapping guided, transcatheter based approach. Clinical follow-up (FU) was performed for up to five weeks and in-vivo cell-tracking was performed using serial magnet resonance imaging (MRI). Thereafter, the hearts were harvested and assessed by PCR and immunohistochemistry. Intramyocardial transplantation of human ATMSC based 3D-MTs was successful in eight animals (88.8%) while one pig (without MI) died during the electromechanical mapping due to sudden cardiac-arrest. During FU, no arrhythmogenic, embolic or neurological events occurred in the treated pigs. Serial MRI confirmed the intramyocardial presence of the 3D-MTs by detection of the intracellular iron-oxide MPIOs during FU. Intramyocardial retention of 3D-MTs was confirmed by PCR analysis and was further verified on histology and immunohistochemical analysis. The 3D-MTs appeared to be viable, integrated and showed an intact micro architecture. We demonstrate the principal feasibility and safety of intramyocardial transplantation of in-vitro generated stem cell-based 3D-MTs. Multimodal cell-tracking strategies comprising advanced imaging and in-vitro tools allow for in-vivo monitoring and post-mortem analysis of transplanted 3D-MTs. The concept of 3D cellular self-assembly represents a promising application format as a next generation technology for cell-based myocardial regeneration. [Copyright &y& Elsevier]

Published

2013

4. Cell–Cell interactions of human neural progenitor-derived astrocytes within a microstructured 3D-scaffold

Author

Führmann, Tobias, Hillen, Lisa M., Montzka, Katrin, Wöltje, Michael, and Brook, Gary A.

Subjects

*CELL communication, *ASTROCYTES, *MICROSTRUCTURE, *TISSUE scaffolds, *NERVOUS system regeneration, *COLLAGEN, *CELL culture, *CELLULAR mechanics

Abstract

Abstract: In the present in vitro study, the axon growth promoting effects of human neural progenitor-derived astrocytes (hNP-AC) were investigated in simple 2D- as well as in more complex 3D-culture systems. The interactions of the hNP-AC with migrating Schwann cells and fibroblasts were also studied. hNP-AC were found to promote extensive dorsal root ganglion axon regeneration in 2D cultures, being even greater than that observed on the positive control, laminin-coated substrate. Contact-mediated mechanisms and the release of substances into the medium both played a role in supporting axon regeneration. Following seeding onto 3D collagen scaffolds, hNP-AC also promoted significantly greater axon regeneration from DRG explants than was seen on non-seeded scaffolds. The highly orientated, porous microstructure of the scaffold also supported substantial intermixing of hNP-AC and migrating Schwann cells/fibroblasts from the DRG explant, cell populations that are normally mutually repulsive. This suggests that the topography of 3D scaffolds may not only influence cell–substrate interactions but also cell–cell interactions within the scaffold. This opens the possibility that the design of future scaffolds could be optimised to enhance cell integration as well as modulating complex cell–cell interactions. [ABSTRACT FROM AUTHOR]

Published

2010

5. Electrophysiological characterization of embryonic hippocampal neurons cultured in a 3D collagen hydrogel

Author

Xu, Tao, Molnar, Peter, Gregory, Cassie, Das, Mainak, Boland, Thomas, and Hickman, James J.

Subjects

*ELECTROPHYSIOLOGY, *EMBRYOLOGY, *HIPPOCAMPUS (Brain), *NEURONS, *CELL culture, *COLLAGEN, *COLLOIDS in medicine, *LABORATORY rats

Abstract

Abstract: Rat embryonic hippocampal neurons were cultured in (1) 3D collagen hydrogels as ‘entrapped’ evenly distributed cells, (2) at the interface of two collagen layers (sandwich model), and (3) on the surface of collagen coated coverslips (2D model). In the ‘entrapment’ model the neuronal processes grew out of the plane of the cell body and extended into the collagen matrix, in contrast to the sandwich model where the cells and their processes rarely left the plane in which they were seeded. Hippocampal neurons ‘entrapped’ in the 3D collagen gel grew the same number, but shorter, processes and exhibited improved survival compared to neurons cultured in the 2D model. There was no difference in the electrophysiological properties of the neurons cultured in the 3D compared to the 2D model except in the resting membrane potential and in the duration of the after-hyperpolarization. Spontaneous postsynaptic currents were recorded in 14- and 21-day-old 3D cultures evidencing functional synapse formation. Our results indicate that the physiological characteristics of 3D neuronal cultures are similar to traditional 2D cultures. However, functional 3D networks of hippocampal neurons will be necessary for multi-level circuit formation, which could be essential for understanding the basis of physiological learning and memory. [Copyright &y& Elsevier]

Published

2009