Your search keyword '"Christoforou, Nicolas"' showing total 8 results

1. In-depth evaluation of commercially available human vascular smooth muscle cells phenotype: Implications for vascular tissue engineering.

Author

Timraz SBH, Farhat IAH, Alhussein G, Christoforou N, and Teo JCM

Subjects

Biomarkers metabolism, Cell Count, Cell Movement, Cell Proliferation, Cell Shape, Cells, Cultured, Humans, Myocytes, Smooth Muscle cytology, Phenotype, Muscle, Smooth, Vascular cytology, Tissue Engineering methods

Abstract

In vitro research on vascular tissue engineering has extensively used isolated primary human or animal smooth muscle cells (SMC). Research programs that lack such facilities tend towards commercially available primary cells sources. Here, we aim to evaluate the capacity of commercially available human SMC to maintain their contractile phenotype, and determine if dedifferentiation towards the synthetic phenotype occurs in response to conventional cell culture and passaging without any external biochemical or mechanical stimuli. Lower passage SMC adopted a contractile phenotype marked by a relatively slower proliferation rate, higher expression of proteins of the contractile apparatus and smoothelin, elongated morphology, and reduced deposition of collagen types I and III. As the passage number increased, migratory capacity was enhanced, average cell speed, total distance and net distance travelled increased up to passage 8. Through the various assays, corroborative evidence pinpoints SMC at passage 7 as the transition point between the contractile and synthetic phenotypes, while passage 8 distinctly and consistently exhibited characteristics of synthetic phenotype. This knowledge is particularly useful in selecting SMC of appropriate passage number for the target vascular tissue engineering application, for example, a homeostatic vascular graft for blood vessel replacement versus recreating atherosclerotic blood vessel model in vitro., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

2. Comparison of mixed and lamellar coculture spatial arrangements for tissue engineering capillary networks in vitro.

Author

Peters EB, Christoforou N, Leong KW, and Truskey GA

Subjects

Anastomosis, Surgical, Cell Aggregation, Cell Movement, Endothelial Cells cytology, Fetal Blood cytology, Humans, Myocytes, Smooth Muscle cytology, Transduction, Genetic, Capillaries physiology, Coculture Techniques methods, Neovascularization, Physiologic, Tissue Engineering methods

Abstract

Coculture of endothelial cells (ECs) and smooth muscle cells (SMCs) in vitro can yield confluent monolayers or EC networks. Factors influencing this transition are not known. In this study, we examined whether the spatial arrangement of EC-SMC cocultures affected EC migration, network morphology, and angiogenic protein secretion. Human umbilical cord blood-derived ECs (hCB-ECs) were grown in coculture with human aortic SMCs in either a mixed or lamellar spatial geometry and analyzed over a culture period of 12 days. The hCB-ECs cultured on SMCs in a mixed system had higher cell speeds, shorter persistence times, and lower random motility coefficients than ECs in a lamellar system. By day 12 of coculture, mixed systems demonstrated greater anastomoses and capillary loop formation than lamellar systems as evidenced by a higher number of branch points, angle of curvature between branch points, and percentage of imaged area covered by networks. The network morphology was more uniform in the mixed systems than the lamellar systems with fewer EC clusters present after several days in culture. Proliferation of hCB-ECs was higher for mixed cocultures during the first 24 h of coculture, and then declined dramatically suggesting that proliferation only contributed to network formation during the early stages of coculture. Proteome assay results show reduced solution levels, but no change in intracellular levels of angiogenic proteins in lamellar systems compared to mixed systems. These data suggest that mixing ECs and SMCs together favors the formation of EC networks to a greater extent than a lamellar arrangement in which ECs form a cell layer above a confluent, quiescent layer of SMCs.

Published

2013

3. Cartilage tissue engineering using differentiated and purified induced pluripotent stem cells.

Author

Diekman BO, Christoforou N, Willard VP, Sun H, Sanchez-Adams J, Leong KW, and Guilak F

Subjects

Animals, Cell Separation, Cellular Reprogramming genetics, Chondrogenesis genetics, Collagen Type II metabolism, Elastic Modulus, Flow Cytometry, Gene Expression Regulation, Glycosaminoglycans metabolism, Green Fluorescent Proteins metabolism, Mice, Microscopy, Atomic Force, Organ Specificity, Sepharose, Wound Healing, Cartilage physiology, Cell Differentiation genetics, Induced Pluripotent Stem Cells cytology, Induced Pluripotent Stem Cells metabolism, Tissue Engineering methods

Abstract

The development of regenerative therapies for cartilage injury has been greatly aided by recent advances in stem cell biology. Induced pluripotent stem cells (iPSCs) have the potential to provide an abundant cell source for tissue engineering, as well as generating patient-matched in vitro models to study genetic and environmental factors in cartilage repair and osteoarthritis. However, both cell therapy and modeling approaches require a purified and uniformly differentiated cell population to predictably recapitulate the physiological characteristics of cartilage. Here, iPSCs derived from adult mouse fibroblasts were chondrogenically differentiated and purified by type II collagen (Col2)-driven green fluorescent protein (GFP) expression. Col2 and aggrecan gene expression levels were significantly up-regulated in GFP+ cells compared with GFP- cells and decreased with monolayer expansion. An in vitro cartilage defect model was used to demonstrate integrative repair by GFP+ cells seeded in agarose, supporting their potential use in cartilage therapies. In chondrogenic pellet culture, cells synthesized cartilage-specific matrix as indicated by high levels of glycosaminoglycans and type II collagen and low levels of type I and type X collagen. The feasibility of cell expansion after initial differentiation was illustrated by homogenous matrix deposition in pellets from twice-passaged GFP+ cells. Finally, atomic force microscopy analysis showed increased microscale elastic moduli associated with collagen alignment at the periphery of pellets, mimicking zonal variation in native cartilage. This study demonstrates the potential use of iPSCs for cartilage defect repair and for creating tissue models of cartilage that can be matched to specific genetic backgrounds.

Published

2012

4. Pluripotent stem cell-derived cardiac tissue patch with advanced structure and function.

Author

Liau B, Christoforou N, Leong KW, and Bursac N

Subjects

Animals, Cell Line, Coculture Techniques, Electrophysiological Phenomena, Fibroblasts cytology, Fibroblasts metabolism, Mice, Myocardium metabolism, Myocytes, Cardiac cytology, Myocytes, Cardiac metabolism, Pluripotent Stem Cells metabolism, Rats, Myocardium cytology, Pluripotent Stem Cells cytology, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Recent advances in pluripotent stem cell research have provided investigators with potent sources of cardiogenic cells. However, tissue engineering methodologies to assemble cardiac progenitors into aligned, 3-dimensional (3D) myocardial tissues capable of physiologically relevant electrical conduction and force generation are lacking. In this study, we introduced 3D cell alignment cues in a fibrin-based hydrogel matrix to engineer highly functional cardiac tissues from genetically purified mouse embryonic stem cell-derived cardiomyocytes (CMs) and cardiovascular progenitors (CVPs). Procedures for CM and CVP derivation, purification, and functional differentiation in monolayer cultures were first optimized to yield robust intercellular coupling and maximize velocity of action potential propagation. A versatile soft-lithography technique was then applied to reproducibly fabricate engineered cardiac tissues with controllable size and 3D architecture. While purified CMs assembled into a functional 3D syncytium only when supplemented with supporting non-myocytes, purified CVPs differentiated into cardiomyocytes, smooth muscle, and endothelial cells, and autonomously supported the formation of functional cardiac tissues. After a total culture time similar to period of mouse embryonic development (21 days), the engineered cardiac tissues exhibited unprecedented levels of 3D organization and functional differentiation characteristic of native neonatal myocardium, including: 1) dense, uniformly aligned, highly differentiated and electromechanically coupled cardiomyocytes, 2) rapid action potential conduction with velocities between 22 and 25 cm/s, and 3) significant contractile forces of up to 2 mN. These results represent an important advancement in stem cell-based cardiac tissue engineering and provide the foundation for exploiting the exciting progress in pluripotent stem cell research in the future tissue engineering therapies for heart disease., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

5. Low oxygen tension and synthetic nanogratings improve the uniformity and stemness of human mesenchymal stem cell layer.

Author

Zhao F, Veldhuis JJ, Duan Y, Yang Y, Christoforou N, Ma T, and Leong KW

Subjects

Blotting, Western, Cell Differentiation physiology, Cells, Cultured, Humans, Immunohistochemistry, Reverse Transcriptase Polymerase Chain Reaction, Mesenchymal Stem Cells cytology, Nanostructures chemistry, Oxygen metabolism, Tissue Engineering methods

Abstract

A free-standing, robust cell sheet comprising aligned human mesenchymal stem cells (hMSCs) offers many interesting opportunities for tissue reconstruction. As a first step toward this goal, a confluent, uniform hMSC layer with a high degree of alignment and stemness maintenance needs to be created. Hypothesizing that topographical cue and a physiologically relevant low-oxygen condition could promote the formation of such an hMSC layer, we studied the culture of hMSCs on synthetic nanogratings (350 nm width and 700 nm pitch) and either under 2 or 20% O(2). Culturing hMSCs on the nanogratings highly aligned the cells, but it tended to create patchy layers and accentuate the hMSC differentiation. The 2% O(2) improved the alignment and uniformity of hMSCs, and reduced their differentiation. Over a 14-day culture period, hMSCs in 2% O(2) showed uniform connexon distribution, secreted abundant extracellular matrix (ECM) proteins, and displayed a high progenicity. After 21-day culture on nanogratings, hMSCs exposed to 2% O(2) maintained a higher viability and differentiation capacity. This study established that a 2% O(2) culture condition could restrict the differentiation of hMSCs cultured on nanopatterns, thereby setting the foundation to fabricate a uniformly aligned hMSC sheet for different regenerative medicine applications.

Published

2010

6. Poly(Ethylene Glycol) Hydrogel Scaffolds Containing Cell-Adhesive and Protease-Sensitive Peptides Support Microvessel Formation by Endothelial Progenitor Cells

Author

Peters, Erica B., Christoforou, Nicolas, Leong, Kam W., Truskey, George A., and West, Jennifer L.

Published

2016

7. Umbilical Cord Blood-Derived Mononuclear Cells Exhibit Pericyte-Like Phenotype and Support Network Formation of Endothelial Progenitor Cells In Vitro

Author

Peters, Erica B., Liu, Betty, Christoforou, Nicolas, West, Jennifer L., and Truskey, George A.

Published

2015

8. Induced Pluripotent Stem Cell-Derived Cardiac Progenitors Differentiate to Cardiomyocytes and Form Biosynthetic Tissues.

Author

Christoforou, Nicolas, Liau, Brian, Chakraborty, Syandan, Chellapan, Malathi, Bursac, Nenad, and Leong, Kam W.

Subjects

*PLURIPOTENT stem cells, *PROGENITOR cells, *HEART cells, *BIOSYNTHESIS, *MAMMAL anatomy, *MYOCARDIUM, *ELECTROPHYSIOLOGY, *TISSUE engineering

Abstract

The mammalian heart has little capacity to regenerate, and following injury the myocardium is replaced by non-contractile scar tissue. Consequently, increased wall stress and workload on the remaining myocardium leads to chamber dilation, dysfunction, and heart failure. Cell-based therapy with an autologous, epigenetically reprogrammed, and cardiac-committed progenitor cell source could potentially reverse this process by replacing the damaged myocardium with functional tissue. However, it is unclear whether cardiac progenitor cell-derived cardiomyocytes are capable of attaining levels of structural and functional maturity comparable to that of terminally-fated cardiomyocytes. Here, we first describe the derivation of mouse induced pluripotent stem (iPS) cells, which once differentiated allow for the enrichment of Nkx2-5(+) cardiac progenitors, and the cardiomyocyte-specific expression of the red fluorescent protein. We show that the cardiac progenitors are multipotent and capable of differentiating into endothelial cells, smooth muscle cells and cardiomyocytes. Moreover, cardiac progenitor selection corresponds to cKit(+) cell enrichment, while cardiomyocyte cell-lineage commitment is concomitant with dual expression of either cKit/Flk1 or cKit/Sca-1. We proceed to show that the cardiac progenitor-derived cardiomyocytes are capable of forming electrically and mechanically coupled large-scale 2D cell cultures with mature electrophysiological properties. Finally, we examine the cell progenitors’ ability to form electromechanically coherent macroscopic tissues, using a physiologically relevant 3D culture model and demonstrate that following long-term culture the cardiomyocytes align, and form robust electromechanical connections throughout the volume of the biosynthetic tissue construct. We conclude that the iPS cell-derived cardiac progenitors are a robust cell source for tissue engineering applications and a 3D culture platform for pharmacological screening and drug development studies. [ABSTRACT FROM AUTHOR]

Published

2013