Milan Mrksich scite author profile

Human and bovine capillary endothelial cells were switched from growth to apoptosis by using micropatterned substrates that contained extracellular matrix-coated adhesive islands of decreasing size to progressively restrict cell extension. Cell spreading also was varied while maintaining the total cell-matrix contact area constant by changing the spacing between multiple focal adhesion-sized islands. Cell shape was found to govern whether individual cells grow or die, regardless of the type of matrix protein or antibody to integrin used to mediate adhesion. Local geometric control of cell growth and viability may therefore represent a fundamental mechanism for developmental regulation within the tissue microenvironment.

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Geometric cues for directing the differentiation of mesenchymal stem cells

Kilian

Bugarija

Lahn

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

1,650

1,559

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Significant efforts have been directed to understanding the factors that influence the lineage commitment of stem cells. This paper demonstrates that cell shape, independent of soluble factors, has a strong influence on the differentiation of human mesenchymal stem cells (MSCs) from bone marrow. When exposed to competing soluble differentiation signals, cells cultured in rectangles with increasing aspect ratio and in shapes with pentagonal symmetry but with different subcellular curvature-and with each occupying the same area-display different adipogenesis and osteogenesis profiles. The results reveal that geometric features that increase actomyosin contractility promote osteogenesis and are consistent with in vivo characteristics of the microenvironment of the differentiated cells. Cytoskeletal-disrupting pharmacological agents modulate shape-based trends in lineage commitment verifying the critical role of focal adhesion and myosin-generated contractility during differentiation. Microarray analysis and pathway inhibition studies suggest that contractile cells promote osteogenesis by enhancing c-Jun N-terminal kinase (JNK) and extracellular related kinase (ERK1/2) activation in conjunction with elevated winglesstype (Wnt) signaling. Taken together, this work points to the role that geometric shape cues can play in orchestrating the mechanochemical signals and paracrine/autocrine factors that can direct MSCs to appropriate fates. were initially isolated from bone marrow and noted for their ability to differentiate into bone cells (osteoblasts), cartilage cells (chondrocytes), and fat cells (adipocytes) (1, 2). As an autologous source of stem cells, MSCs are under considerable scrutiny for regenerative therapies (3). A combination of physical, chemical, and biological cues present in the stem cell microenvironment have been implicated as directors of stem cell fate in vivo (4). This concept of a stem cell "niche" has motivated empirical studies to identify optimal combinations of extracellular matrix, culture conditions, and temporally administered growth factors to direct stem cell fate in the laboratory (5-7). However, the physical forces and geometry of the MSC microenvironment remain poorly defined and have begun to emerge as critical parameters for regulating cell fate (8, 9).Physical cues, which were postulated as important factors in tissue development over a century ago (10), have also been recognized as important factors in controlling cell function. Research along these lines has been driven in the past decades with the maturation of microengineering techniques (11-13). Ingber, Whitesides, and colleagues demonstrated the use of substrates that were geometrically patterned to control the microenvironment of individual cells and in turn the decision of cells to initiate apoptosis (14). Patterned substrates have also been used to study cytoskeletal dynamics (15-18) and motility (19-22) with singlecell resolution. Chen and coworkers recently demonstrated the important role that cell shape and size can play ...

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Protein Nanoarrays Generated By Dip-Pen Nanolithography

Lee

Park

Mirkin

et al. 2002

Science

1,166

852

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Dip-pen nanolithography was used to construct arrays of proteins with 100- to 350-nanometer features. These nanoarrays exhibit almost no detectable nonspecific binding of proteins to their passivated portions even in complex mixtures of proteins, and therefore provide the opportunity to study a variety of surface-mediated biological recognition processes. For example, reactions involving the protein features and antigens in complex solutions can be screened easily by atomic force microscopy. As further proof-of-concept, these arrays were used to study cellular adhesion at the submicrometer scale.

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Milan Mrksich

Geometric Control of Cell Life and Death

Geometric cues for directing the differentiation of mesenchymal stem cells

Protein Nanoarrays Generated By Dip-Pen Nanolithography

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