106 research outputs found
Microprinted feeder cells guide embryonic stem cell fate
We introduce a non‐contact approach to microprint multiple types of feeder cells in a microarray format using immiscible aqueous solutions of two biopolymers. Droplets of cell suspension in the denser aqueous phase are printed on a substrate residing within a bath of the immersion aqueous phase. Due to their affinity to the denser phase, cells remain localized within the drops and adhere to regions of the substrate underneath the drops. We show the utility of this technology for creating duplex heterocellular stem cell niches by printing two different support cell types on a gel surface and overlaying them with mouse embryonic stem cells (mESCs). As desired, the type of printed support cell spatially direct the fate of overlaid mESCs. Interestingly, we found that interspaced mESCs colonies on differentiation‐inducing feeder cells show enhanced neuronal differentiation and give rise to dense networks of neurons. This cell printing technology provides unprecedented capabilities to efficiently identify the role of various feeder cells in guiding the fate of stem cells. Biotechnol. Bioeng. 2011;108: 2509–2516. © 2011 Wiley Periodicals, Inc.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/86949/1/23190_ftp.pd
Genetic system for project support with the sequencing problem
One of the main problems faced by manufacturing companies in the production sequencing, also called scheduling, which consists of identifying the best way to order the production program on the machines for improving efficiency. This paper presents the integration of a simulation model with an optimization method to solve the problem of dynamic programming with stochastic demand
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Direct 3D printing of a two-part silicone resin to fabricate highly stretchable structures
The direct ink writing (DIW) method of 3D-printing liquid resins has shown promising results in various applications such as flexible electronics, medical devices, and soft robots. A cost-effective extrusion system for a two-part high-viscous resin is developed in this article to fabricate soft and immensely stretchable structures. A static mixer capable of evenly mixing two viscous resins in an extremely low flow regime is designed based on the required mixing performance through a series of biphasic computational fluid dynamics analyses. The printing parameters of the extrusion system are determined empirically, and the mechanical properties of the printed samples are compared to their molded counterparts. Furthermore, some potential applications of the system in soft robotics and medical training are demonstrated. This research provides a clear guide for utilizing DIW to 3D print highly stretchable structures
Metabolic response of lung cancer cells to radiation in a paper-based 3D cell culture system
This work demonstrates the application of a 3D culture system - Cells-in-Gels-in-Paper (CiGiP) - in evaluating the metabolic response of lung cancer cells to ionizing radiation. The 3D tissue-like construct - prepared by stacking multiple sheets of paper containing cell-embedded hydrogels - generates a gradient of oxygen and nutrients that decreases monotonically in the stack. Separating the layers of the stack after exposure enabled analysis of the cellular response to radiation as a function of oxygen and nutrient availability; this availability is dictated by the distance between the cells and the source of oxygenated medium. As the distance between the cells and source of oxygenated media increased, cells show increased levels of hypoxia-inducible factor 1-alpha, decreased proliferation, and reduced sensitivity to ionizing radiation. Each of these cellular responses are characteristic of cancer cells observed in solid tumors. With this setup we were able to differentiate three isogenic variants of A549 cells based on their metabolic radiosensitivity; these three variants have known differences in their metastatic behavior in vivo. This system can, therefore, capture some aspects of radiosensitivity of populations of cancer cells related to mass-transport phenomenon, carry out systematic studies of radiation response in vitro that decouple effects from migration and proliferation of cells, and regulate the exposure of oxygen to subpopulations of cells in a tissue-like construct either before or after irradiation.Chemistry and Chemical Biolog
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A Paper-Based Invasion Assay: Assessing Chemotaxis of Cancer Cells in Gradients of Oxygen
This work describes a 3D, paper-based assay that can isolate subpopulations of cells based on their invasiveness (i.e., distance migrated in a hydrogel) in a gradient of concentration of oxygen (O2). Layers of paper impregnated with a cell-compatible hydrogel are stacked and placed in a plastic holder to form the invasion assay. Stacking the layers of paper assembles them into 3D tissue-like constructs of defined thickness and composition. The plastic holder ensures the layers of paper are in conformal contact; this geometry allows the cells to migrate between adjacent layers through the embedded hydrogel. In most assays, the stack comprises a single layer of paper containing mammalian cells suspended in a hydrogel, sandwiched between multiple layers of paper containing only hydrogel (into which the cells migrate). Cells in the stack consume and produce small molecules; these molecules diffuse throughout the stack to generate gradients both in the stack, and between the stack and the bulk culture medium. Placing the cell-containing layer in different positions of the stack, or modifying the permeability of the holder to oxygen or proteins, alters the profile of the gradients within the stack. Physically separating the layers after culture isolates subpopulations of cells that migrated different distances, and enables their subsequent analysis or culture. Using this system, three independent cell lines derived from A549 cancer cells are shown to produce distinguishable migration behavior in a gradient of oxygen. This result is the first experimental demonstration that oxygen acts as a chemoattractant for cancer cells.Chemistry and Chemical Biolog
A variable stiffness soft gripper using granular jamming and biologically inspired pneumatic muscles
As the domains in which robots operate change the objects a robot may be required to grasp and manipulate are likely to vary significantly and often. Furthermore there is increasing likelihood that in the future robots will work collaboratively alongside people. There has therefore been interest in the development of biologically inspired robot designs which take inspiration from nature. This paper presents the design and testing of a variable stiffness, three fingered soft gripper which uses pneumatic muscles to actuate the fingers and granular jamming to vary their stiffness. This gripper is able to adjust its stiffness depending upon how fragile/deformable the object being grasped is. It is also lightweight and low inertia making it better suited to operation near people. Each finger is formed from a cylindrical rubber bladder filled with a granular material. It is shown how decreasing the pressure inside the finger increases the jamming effect and raises finger stiffness. The paper shows experimentally how the finger stiffness can be increased from 21 to 71 N/m. The paper also describes the kinematics of the fingers and demonstrates how they can be position-controlled at a range of different stiffness values
Multizone Paper Platform for 3D Cell Cultures
In vitro 3D culture is an important model for tissues in
vivo. Cells in different locations of 3D tissues are
physiologically different, because they are exposed to different concentrations
of oxygen, nutrients, and signaling molecules, and to other environmental
factors (temperature, mechanical stress, etc). The majority of high-throughput
assays based on 3D cultures, however, can only detect the
average behavior of cells in the whole 3D construct.
Isolation of cells from specific regions of 3D cultures is possible, but relies
on low-throughput techniques such as tissue sectioning and micromanipulation.
Based on a procedure reported previously (“cells-in-gels-in-paper”
or CiGiP), this paper describes a simple method for culture of arrays of thin
planar sections of tissues, either alone or stacked to create more complex 3D
tissue structures. This procedure starts with sheets of paper patterned with
hydrophobic regions that form 96 hydrophilic zones. Serial spotting of cells
suspended in extracellular matrix (ECM) gel onto the patterned paper creates an
array of 200 micron-thick slabs of ECM gel (supported mechanically by cellulose
fibers) containing cells. Stacking the sheets with zones aligned on top of one
another assembles 96 3D multilayer constructs. De-stacking the layers of the 3D
culture, by peeling apart the sheets of paper, “sections” all 96
cultures at once. It is, thus, simple to isolate 200-micron-thick
cell-containing slabs from each 3D culture in the 96-zone array. Because the 3D
cultures are assembled from multiple layers, the number of cells plated
initially in each layer determines the spatial distribution of cells in the
stacked 3D cultures. This capability made it possible to compare the growth of
3D tumor models of different spatial composition, and to examine the migration
of cells in these structures
Chemotaxis of Cell Populations through Confined Spaces at Single-Cell Resolution
Cell migration is crucial for both physiological and pathological processes. Current in vitro cell motility assays suffer from various drawbacks, including insufficient temporal and/or optical resolution, or the failure to include a controlled chemotactic stimulus. Here, we address these limitations with a migration chamber that utilizes a self-sustaining chemotactic gradient to induce locomotion through confined environments that emulate physiological settings. Dynamic real-time analysis of both population-scale and single-cell movement are achieved at high resolution. Interior surfaces can be functionalized through adsorption of extracellular matrix components, and pharmacological agents can be administered to cells directly, or indirectly through the chemotactic reservoir. Direct comparison of multiple cell types can be achieved in a single enclosed system to compare inherent migratory potentials. Our novel microfluidic design is therefore a powerful tool for the study of cellular chemotaxis, and is suitable for a wide range of biological and biomedical applications
Design, fabrication and control of soft robots
Conventionally, engineers have employed rigid materials to fabricate precise, predictable robotic systems, which are easily modelled as rigid members connected at discrete joints. Natural systems, however, often match or exceed the performance of robotic systems with deformable bodies. Cephalopods, for example, achieve amazing feats of manipulation and locomotion without a skeleton; even vertebrates such as humans achieve dynamic gaits by storing elastic energy in their compliant bones and soft tissues. Inspired by nature, engineers have begun to explore the design and control of soft-bodied robots composed of compliant materials. This Review discusses recent developments in the emerging field of soft robotics.National Science Foundation (U.S.) (Grant IIS-1226883
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