Michael W. Toepke

PDMS absorption of small molecules and consequences in microfluidic applications.

Microfluidic devices made out of polydimethylsiloxane (PDMS) have many physical properties that are useful for cell culture applications, such as transparency and gas permeability. Another distinct characteristic of PDMS is its ability to absorb hydrophobic small molecules. Partitioning of molecules into PDMS can significantly change solution concentrations and could potentially alter experimental outcomes. Herein we discuss PDMS absorption and its potential impact on microfluidic experiments.

A platform for assessing chemotactic migration within a spatiotemporally defined 3D microenvironment

While the quantification of cell movement within defined biochemical gradients is now possible with microfluidic approaches, translating this capability to biologically relevant three-dimensional microenvironments remains a challenge. We introduce an accessible platform, requiring only standard tools (e.g. pipettes), that provides robust soluble factor control within a three-dimensional biological matrix. We demonstrate long-lasting linear and non-linear concentration profiles that were maintained for up to ten days using 34.5 muL solute volume. We also demonstrate the ability to superimpose local soluble factor pulses onto existing gradients via defined dosing windows. The combination of long-term and transient gradient characteristics within a three-dimensional environment opens the door for signaling studies that investigate the migratory behavior of cells within a biologically representative matrix. To this end, we apply temporally evolving and long-lasting gradients to study the chemotactic responses of human neutrophils and the invasion of metastatic rat mammary adenocarcinoma cells (MtLN3) within three-dimensional collagen matrices.

Specific VEGF sequestering and release using peptide-functionalized hydrogel microspheres

Growth factor signaling plays an essential role in regulating processes such as tissue development, maintenance, and repair. Gene expression levels, diffusion, degradation, and sequestration by extracellular matrix components all play a role in regulating the concentration of growth factors within the cellular microenvironment. Herein, we describe the synthesis and characterization of hydrogel microspheres that mimic the ability of the native extracellular matrix to reversibly bind vascular endothelial growth factor (VEGF) out of solution. A peptide ligand derived from the VEGF receptor 2 (VEGFR2) was covalently incorporated into the hydrogel microspheres in order to achieve binding affinity and specificity. In addition to being able to both bind and release VEGF in a controllable manner, the microspheres were also shown to affect human umbilical vein endothelial cell (HUVEC) proliferation. The resulting microspheres may enable new strategies to specifically upregulate or downregulate growth factor signaling in the cellular microenvironment.

Microfluidic logic gates and timers

We use surface tension-based passive pumping and fluidic resistance to create a number of microfluidic analogs to electronic circuit components. Three classes of components are demonstrated: (1) OR/AND, NOR/NAND, and XNOR digital microfluidic logic gates; (2) programmable, autonomous timers; and (3) slow, perfusive flow rheostats. The components can be implemented with standard pipettes and provide a means of non-electronic and autonomous preprogrammed control with potential utility in cell studies and high throughput screening applications.

Micropatterning of 3D Microenvironments for Living Biosensor Applications.

Micro-scale printing and patterning of living cells has multiple applications including tissue engineering, cell signaling assays, and the fabrication of cell-based biosensors. In this work, a molecular printing instrument, the Bioforce Nano eNabler, was modified to enable micron-scale “quill-pen” based printing of mammalian cells in a 3D hyaluronan/gelatin based hydrogel. Specifically, photo-initiated “thiol-ene” click chemistry was used to couple the thiol groups of thiolated hyaluronan/thiolated gelatin to the alkene groups of 4-arm polyethylene glycol (PEG)-norbornene molecules. Rapid photopolymerization enabled direct printing and controlled curing of living cells within the hydrogel matrix. The resulting hydrogels were biocompatible with human adipose-derived stem cells, NIH-3T3 cells, and mouse embryonic stem cells. The utility of this printing approach was also explored for cell-based biosensors. Micro-printed cells expressing a redox sensitive variant of the green fluorescent protein (roGFP-R12) showed a measurable fluorescent response to addition of oxidizing and then reducing agents. This work represents a novel approach to micron-scale cell patterning, and its potential for living, cell-based biosensors.

Regulating Specific Growth Factor Signaling Using Immobilized Branched Ligands

VEGF-binding peptide ligands are incorporated into hydrogel microspheres and reduce the amount of growth factor in solution. VEGF binding affinity is enhanced by creating ligands with a dimer structure. The spheres are able to knock down VEGF-mediated HUVEC growth and reduce calcium signaling. The binding interaction is reversible, allowing the spheres to be used as a VEGF delivery vehicle.