Positively charged coating materials such as polylysine improve neuronal attachment in vitro. Due to the structural complexity of these charged molecules, it is unclear whether neuronal effects are due to charge or to physicochemical effects, or both. Polymeric materials with charge storage capabilities and defined surface properties may provide a model in which electrical charge and surface property effects can be separated. Fluorinated ethylenepropylene (FEP) films can store negative or positive charges injected through a corona charging process, thus generating a negative or positive external electrostatic field. In the present study, mouse neuroblastoma (Nb2a) cells were cultured on positive, negative, and uncharged FEP substrates, in both serum-containing and serum-free media. Cell attachment, differentiation, and neurite outgrowth were assessed 24, 48, 72 and 96 h after plating. Electron spectroscopy for chemical analysis (ESCA), contact angle analysis, and scanning electron microscopy (SEM) revealed no differences in surface chemistry and topography between positive, negative, and uncharged FEP. No significant differences in the levels of cell attachment on positive, negative, and uncharged substrates were observed. Significantly higher levels of neurite outgrowth, however, were observed with positive substrates as compared to negative and uncharged substrates, in both media conditions. Substrates charged to +1000 V showed greater levels of outgrowth compared to +500 and +3000 V, suggesting the presence of an optimal range of charge for neurite outgrowth. These results show that cell/charge interactions mediate cell effects on electrically charged substrates with identical surface chemistry, topography and adhesivity.
The lack of sample pre-treatment concepts that are easily automatable, miniaturized and highly efficient for both small volumes and low target concentrations, is one of the key issues that block the road towards effective miniaturized diagnostic instruments. This paper presents a novel, highly efficient and simple method for low-molecular weight RNA extraction using electricity only. Cells are lysed by thermo-electric lysis and RNA is purified using a gel-electrophoretic purification step. The combination of the two steps in one integrated cartridge reduces the time frame between the two steps, thus protecting RNA from enzymatic degradation. A disposable chip solution is proposed using a novel dry film resist laminate technology that allows cheap, large-scale fabrication. The chip contains crucial microfluidic innovations that allow for a simple user interface, reproducible functioning and precise quantification. Phaseguides are invented that allow controlled spatial injection of gel, injection of sample and recovery of extracted RNA. A precise sample volume can be defined by integrating electrophoretic actuation electrodes in the microfluidic chamber. Electrolytic gas bubbles that are the result of constant-current actuation are driven out from the chip by the novel introduction of capillary bubble-expulsion techniques. The extraction approach and the functionality of the chip are demonstrated for Escherichia coli and Streptococcus thermophilus bacteria. Linear extraction behavior is obtained for transfer-messenger RNA down to one colony-forming unit per microlitre, or five colony-forming units per chip. The latter is an increase in extraction efficiency of a factor of 1000 with respect to the commercial extraction kit Ambion Ribopure. The chip shows particularly good performance for extraction of low-molecular weight RNA, thereby eliminating the need for large ribosomal RNA and DNA removal. RNA can be extracted in less than 11 min, being a speed-up of more than a factor of 20 with respect to commercial extraction kits. The presented solution may find broad acceptance and application in drug discovery and clinical diagnostics.
Microarray technology is a powerful tool that provides a high throughput of bioanalytical information within a single experiment. These miniaturized and parallelized binding assays are highly sensitive and have found widespread popularity especially during the genomic era. However, as drug diagnostics studies are often targeted at membrane proteins, the current arraying technologies are ill-equipped to handle the fragile nature of the protein molecules. In addition, to understand the complex structure and functions of proteins, different strategies to immobilize the probe molecules selectively onto a platform for protein microarray are required. We propose a novel approach to create a (membrane) protein microarray by using an indium tin oxide (ITO) microelectrode array with an electronic multiplexing capability. A polycationic, protein- and vesicle-resistant copolymer, poly(l-lysine)-grafted-poly(ethylene glycol) (PLL-g-PEG), is exposed to and adsorbed uniformly onto the microelectrode array, as a passivating adlayer. An electronic stimulation is then applied onto the individual ITO microelectrodes resulting in the localized release of the polymer thus revealing a bare ITO surface. Different polymer and biological moieties are specifically immobilized onto the activated ITO microelectrodes while the other regions remain protein-resistant as they are unaffected by the induced electrical potential. The desorption process of the PLL-g-PEG is observed to be highly selective, rapid, and reversible without compromising on the integrity and performance of the conductive ITO microelectrodes. As such, we have successfully created a stable and heterogeneous microarray of biomolecules by using selective electronic addressing on ITO microelectrodes. Both pharmaceutical diagnostics and biomedical technology are expected to benefit directly from this unique method.
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