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ABSTRACT: We introduce a method to electrically stimulate individual neurons at single-cell resolution in arbitrary spatiotemporal patterns with precise control over stimulation thresholds. By exploiting a custom microelectronic chip, up to 65,000 non-Faradaic electrodes can be uniquely addressed with electrode density exceeding 6500 electrodes mm(-2). We demonstrate extracellular stimulation of dispersed primary hippocampal neuronal cultures using the chip at single-cell resolution.
Journal of Neural Engineering 07/2011; 8(4):044003. · 3.84 Impact Factor
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ABSTRACT: The fluidity of cellular membranes imparts lateral mobility of proteins across the cell surface. To understand the impact of lateral mobility on cell-cell communication, a protein consisting of the extracellular recognition domains of E-cadherin was associated with the surface of silica beads by either tethering to a bead-supported lipid bilayer or direct adsorption, resulting in laterally mobile and immobile presentations of this protein. These beads were then seeded onto the upper surface of MDCK cells. Functional engagement of these beads was compared by measurement of Rac1 recruitment around the bead. Lateral mobility enhanced recognition of E-cadherin, promoting cell response to the beads at lower per-area concentrations than their immobilized counterparts. A more complete understanding of how lateral mobility of membrane-associated proteins influences molecular recognition, and potentially other downstream responses, could provide new strategies for the design of materials and devices intended to capture the architecture of natural tissues.
Cellular and Molecular Bioengineering 03/2010; 3(1):84-90. · 1.95 Impact Factor
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ABSTRACT: Mechanical cues may have important roles in tissue morphogenesis; progression through complex functions like differentiation may be associated with changes in cellular force generation and mechanosensing. To explore this concept, we use elastomer pillar arrays to map forces generated by neural stem cells in vitro, and identify two distinct dynamics of force generation. First, cell generated forces decrease as cells transition from a proliferative mode to differentiation, a process covering several days. This change in force generation correlated with a loss of sensitivity to substrate rigidity over a series of polydimethylsiloxane substrates. Second, neural stem cells exhibit a faster pattern of localized contractions at the cell body and outlying processes; each lasts on the order of minutes, and is not synchronized across the cell. This faster process is reminiscent of migratory behavior observed in vivo, and may be involved in controlling the motion of internal structures such as the cell nucleus. These results together provide new clues into the role of forces during development, and may lead to design principles for materials targeted for use in the central nervous system.
Cellular and Molecular Bioengineering 12/2009; 2(4):464-474. · 1.95 Impact Factor
