Aligned microcontact printing of micrometer-scale poly-L-lysine structures for controlled growth of cultured neurons on planar microelectrode arrays

Microcontact printing: a versatile technique for the study of synaptogenic molecules

During synaptogenesis information exchanged locally between synaptic partners results in precise alignment of morphological and molecular specializations. For example, agrin derived from motoneurons induces localized postsynaptic differentiation at the neuromuscular synapse. Similar information molecules are thought to act at other synapses; however, techniques for directly evaluating synaptogenic activities of such molecules are lacking. Here we use agrin-induced differentiation as a model system to validate a novel approach for characterizing synaptogenic molecules. Proteins are patterned with micron scale resolution on glass coverslips by covalent microcontact printing and these substrates are used for cell culture. Postsynaptic molecules accumulate specifically at sites of contact between muscle cells and patterned agrin: a response which is quantifiable. Our results demonstrate that microcontact printing is applicable to the analysis of cellular response to locally immobilized information molecules.

Micropatterned Schwann cell-seeded biodegradable polymer substrates significantly enhance neurite alignment and outgrowth

Biomimetic strategies were employed to promote directional outgrowth of neurites in vitro by using a synergistic combination of physical, chemical, and cellular cues. Compression molded and solvent cast biodegradable polymer substrates made of poly(D,L-lactic acid) were micropatterned to form grooves on the substrate surfaces. Laminin was localized in the grooves, and rat sciatic Schwann cells were seeded on the substrates. Whole as well as dissociated rat dorsal root ganglia were seeded on the substrates along with Schwann cells, and neurite outgrowth and alignment were measured. The micropatterns provide physical guidance, laminin provides chemical cues, and the Schwann cells provide biological cues to the axons. The presence of Schwann cells in the grooves was found to promote neurite alignment as well as outgrowth and help the neurites orient even on shallower grooves and exhibit continued alignment even as the grooves degrade. The synergistic combination of physical, chemical, and cellular guidance enabled greater than 98% alignment of neurites and accelerated outgrowth of neurites in the direction of the microgrooves.

Promotion of neural cell adhesion by electrochemically generated and functionalized polymer films

New strategies for spatially controllable cell adhesion have been developed for brain cells from embryonic chicken. They are based on electrochemically active phenol and pyrrole derivatives, and can be used for the selective coverage of electroconductive substrates. Besides mimicking standard laminin-related adhesion promoting mechanisms by means of an electroactive monomer-linked 18-peptide segment from laminin (SRARKQAASIKVAVSADR), electrochemically generated thin (6-30 nm) polymer films of 3-hydroxybenzyl-hydrazine (3HBH) and 2-(3-hydroxyphenyl)-ethanol (2(3HP)E) with and without mechanically entrapped or covalently linked D-lysine have proved to promote cell adhesion in serum-free medium on indium-doped tin oxide (ITO) substrates during the first 6 culturing days in vitro. The effectiveness of the peptide was strongly density-dependent. Unexpectedly, laminin itself or a combination of laminin and poly-D-lysine (PDL) did not promote cell adhesion and neuron differentiation in serum-free cultures on ITO. However, they worked perfectly well on regular polystyrene substrates in serum-free medium or on ITO when medium with serum was used. This finding might suggest that the adhesion efficiency of laminin does not depend only on the kind of medium supplement but also on the type of substrate. In contrast, the adhesion-promoting properties of "artificial" polymeric films seemed to be based on a more direct cell-film interaction, with the film masking the substrate properties.

Aligned microcontact printing of biomolecules on microelectronic device surfaces

Microcontact printing (muCP) of extracellular matrix proteins is a fascinating approach to control cell positioning and outgrowth, which is essential in the development of applications ranging from cellular biosensors to tissue engineering. Microelectronic devices can be used to detect the activity from a large number of recording sites over the long term. However, signals from cells can only be recorded at small sensitive spots. In this paper, we present an innovative setup to perform aligned muCP of extracellular matrix proteins on microelectronic devices in order to guide the growth of electrogenic cells specifically to these sensitive spots. Our system is based on the combination of a fine-placer with redesigned micro stamps having a rigid glass cylinder as backbone for attachment in the alignment tool. Alignment is performed moving the device with an optical table under microscopic control of the superimposed images from stamp and device surface. After successful alignment, the stamp is brought into contact with the device surface by means of a high-precision lever. With our setup, we were able to pattern up to 40 devices per hour. A lateral alignment accuracy of < 2microm has been achieved. Aligned neuronal growth on patterned devices was demonstrated with dissociated hippocampal neurons.

Cell adhesion to protein-micropatterned-supported lipid bilayer membranes

A new method for constructing controlled interfaces between cells and synthetic supported lipid bilayer membranes is reported. Microcontact printing is used to define squares and grid lines of fibronectin onto glass, which subsequently direct the self-assembly of fluid lipid bilayers onto the complementary, uncoated regions of the surface. Features of fibronectin as small as 5 microm effectively control the lateral organization of the lipid bilayers. These fibronectin barriers also facilitate the adhesion of endothelial cells, which exhibit minimal adhesion to fluid supported lipid bilayers alone. Cells selectively adhere to the features of fibronectin, spanning over and exposing the cells to the intervening regions of supported lipid bilayer. Cell spreading is correlated with both the geometry and dimensions of the fibronectin barriers. Importantly, lipids underlying adherent cells are laterally mobile, suggesting that, in contrast to the regions of fibronectin, cells were not in direct contact with the supported membrane. Protein micropatterning thus provides a valuable tool for controlling supported membranes and for juxtaposing anchorage-dependent cells with lipid bilayers. These systems should be generally useful for studying specific interactions between cells and biomolecules incorporated into supported membranes, and as an approach for integrating living cells with synthetic, laterally complex surfaces.

Schwann cell response to micropatterned laminin surfaces

In the peripheral nervous system, Schwann cells are closely associated with, and play key roles in, the development, maintenance, and regeneration of peripheral neurons. Following injury, Schwann cell orientation may also play a role in guiding regenerating axons. To aid in the investigation of these interactions between Schwann cells and growing neurites, we have developed a method of controlling Schwann cell placement and orientation in vitro by using microlithographically patterned laminin substrates, alternating 20-microm regions of laminin with bovine serum albumin (BSA) stripes. The Schwann cells predominantly attached and elongated on the laminin stripes and organized into multicellular aggregates that were oriented with the micropattern. A detailed analysis of Schwann cell aggregate orientation and shape demonstrated a strong dependence on time. At 1 h after seeding the cells, 70% of the aggregates were oriented with respect to the micropattern; 94% were oriented at 24 h. Variations in laminin concentration and seeding density were also investigated. The only significant differences in Schwann cell response occurred 1 h after seeding (the earliest time point the cultures were observed), and the main factor controlling the cellular orientation appeared to be the presence of the laminin-BSA interface. This ability to control cell orientation and placement provides a tool for future investigations of Schwann cell-neuronal interactions in vitro.

Axonal outgrowth of hippocampal neurons on micro-scale networks of polylysine-conjugated laminin

Microcontact printing was used to define an interconnected lattice network of polylysine-conjugated laminin, a protein-polypeptide ligate that is an effective promoter of neuron outgrowth on material surfaces. In the presence of serum proteins, rat hippocampal neurons selectively adhered to features of polylysine-conjugated laminin as narrow as 2.6 microm in width. Adhering neurons extended long axonal processes, which precisely followed and did not deviate from the prescribed patterns, demonstrating that neurons respond to this protein with high selectivity and that these techniques effectively provide long-range guidance of axonal outgrowth. Further examination of neuron response under serum-free cell culture conditions demonstrated that the outgrowth-promoting activity of polylysine-conjugated laminin was attributed to biologically active laminin. Together, these results demonstrate that polylysine-conjugated laminin provides for high-precision guidance of neuron attachment and axon outgrowth on material surfaces in a serum-independent manner. This ability to guide hippocampal neuron response in low-density, serum-free culture with high precision is valuable for the development of advanced, neuron-based devices.