Heterogeneity in cell populations poses a major obstacle to understanding complex biological processes. Here we present a microfluidic platform containing thousands of nanoliter-scale chambers suitable for live-cell imaging studies of clonal cultures of nonadherent cells with precise control of the conditions, capabilities for in situ immunostaining and recovery of viable cells. We show that this platform mimics conventional cultures in reproducing the responses of various types of primitive mouse hematopoietic cells with retention of their functional properties, as demonstrated by subsequent in vitro and in vivo (transplantation) assays of recovered cells. The automated medium exchange of this system made it possible to define when Steel factor stimulation is first required by adult hematopoietic stem cells in vitro as the point of exit from quiescence. This technology will offer many new avenues to interrogate otherwise inaccessible mechanisms governing mammalian cell growth and fate decisions.
Chemical patterns have attracted substantial interest for applications in the field of biosensors, fundamental cell–surface interaction studies, tissue engineering, and biomaterials. A novel micropatterning technique is proposed here that combines a top–down approach based on photolithography and a bottom–up strategy through self‐organization of multifunctional molecules. The development of the molecular‐assembly patterning by lift‐off (MAPL) has been driven by the need to economically produce patches incorporating a controlled surface density of bioligands while inhibiting non‐specific adsorption. In the MAPL process, a photoresist pattern is transferred into the desired biochemical pattern by means of spontaneous adsorption of biologically relevant species and photoresist lift‐off. The surface between the interactive patches is subsequently rendered non‐fouling through immobilization of a polycationic poly(ethylene glycol) (PEG)‐graft polymer. We demonstrate that surface density of biotin molecules inside adhesive islands can be tailored quantitatively and that cells grow selectively on cell‐adhesive peptide patterns. MAPL is considered to be a valuable addition to the toolbox of soft‐lithography techniques for life‐science applications combining simplicity (no clean‐room equipment needed), cost‐effectiveness, reproducibility on the scale of whole wafer surfaces, and flexibility in terms of pattern geometry, chemistry, and substrate choice.
We describe a novel parallel method for the patterning of proteins with nanoscale resolution. Combining nanoimprint lithography (NIL) and molecular assembly patterning by lift-off (MAPL), we produced streptavidin patterns with feature sizes in the order of 100 nm. A stamp is imprinted into a heated PMMA film followed by a dry etching step that converts the topography into a PMMA/Nb 2 O 5 contrast. A biotin functionalized copolymer, poly(L-lysine)-graft-poly(ethylene glycol)-biotin (PLL-g-PEG/PEG-biotin), spontaneously adsorbs on the oxide surfaces. After PMMA lift-off, the background is backfilled with protein-resistant PLL-g-PEG. We show that streptavidin selectively adsorbs on the biotin areas and thus can be used as a universal platform for immobilization of biotin-tagged molecules. This novel process is a parallel patterning method that is fast, reproducible, and economic. The PEG-copolymer can be functionalized with a variety of bioactive groups and thus allows a great flexibility in terms of surface chemistry.
We present a novel concept for the creation of lipid vesicle microarrays based on a patterning approach termed Molecular Assembly Patterning by Lift-off (MAPL). A homogeneous MAPL-based single-stranded DNA microarray was converted into a vesicle array by the use of vesicles tagged with complementary DNAs, permitting sequence-specific coupling of vesicles to predefined surface regions through complementary DNA hybridization. In the multistep process utilized to fulfill this achievement, active spots consisting of PLL-g-PEGbiotin with a resistant PLL-g-PEG background, as provided by the MAPL process, was converted into a DNA array by addition of complexes of biotin-terminated DNA and NeutrAvidin. This was then followed by addition of POPC vesicles tagged with complementary cholesterol-terminated DNA, thus providing specific coupling of vesicles to the surface through complementary DNA hybridization. Quartz crystal microbalance with dissipation (QCM-D) and optical waveguide lightmode spectroscopy monitoring were used to optimize the multistep surface modification process. It was found that the amount of adsorbed biotinDNA-NeutrAvidin complexes decreases with increasing molar ratio of biotinDNA to NeutrAvidin and decreasing ionic strength of the buffer solution. Modeling of the QCM-D data showed that the shape of the immobilized vesicles depends on the amount of available anchoring groups between the vesicles and the surface. Fluorescent microscopy images confirmed the possibility to create well-defined patterns of DNA-tagged, fluorescently labeled vesicles in the micrometer range.
Summary
Time-lapse live cell imaging is a powerful tool for studying signaling network dynamics and complexity and is uniquely suited to single cell studies of response dynamics, noise, and heritable differences. Although conventional imaging formats have the temporal and spatial resolution needed for such studies, they do not provide the simultaneous advantages of cell tracking, experimental throughput, and precise chemical control. This is particularly problematic for systems-level studies using non-adherent model organisms such as yeast, where the motion of cells complicates tracking and where large-scale analysis under a variety of genetic and chemical perturbations is desired. We present here a high-throughput microfluidic imaging system capable of tracking single cells over multiple generations in 128 simultaneous experiments with programmable and precise chemical control. High-resolution imaging and robust cell tracking is achieved through immobilization of yeast cells using a combination of mechanical clamping and polymerization in an agarose gel. The channel and valve architecture of our device allows for the formation of a matrix of 128 integrated agarose gel pads, each allowing for an independent imaging experiment with fully programmable medium exchange via diffusion. We demonstrate our system in the combinatorial and quantitative analysis of the yeast pheromone signaling response across 8 genotypes and 16 conditions, and show that lineage-dependent effects contribute to observed variability at stimulation conditions near the critical threshold for cellular decision making.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.