Justification of rapid prototyping in the development cycle of thermoplastic-based lab-on-a-chip.

During the developmental cycle of lab-on-a-chip devices, various microstructuring techniques are required. While in the designing and assay implementation phase direct structuring or so-called rapid-prototyping methods such as milling or laser ablation are applied, replication methods like hot embossing or injection moulding are favourable for large quantity manufacturing. This work investigated the applicability of rapid-prototyping techniques for thermoplastic chip development in general, and the reproducibility of performances in dependency of the structuring technique. A previously published chip for prenatal diagnosis that preconcentrates DNA via electrokinetic trapping and field-amplified-sample-stacking and afterwards separates it in CGE was chosen as a model. The impact of structuring, sealing, and the integration of membranes on the mobility of the EOF, DNA preconcentration, and DNA separation was studied. Structuring methods were found to significantly change the location where preconcentration of DNA occurs. However, effects on the mobility of the EOF and the separation quality of DNA were not observed. Exchange of the membrane has no effect on the chip performance, whereas the sealing method impairs the separation of DNA within the chip. The overall assay performance is not significantly influenced by different structuring methods; thus, the application of rapid-prototyping methods during a chip development cycle is well justified.

Identification of the molecular composition of the 20S proteasome of mouse intestine by high-resolution mass spectrometric proteome analysis.

In the last years, intracellular protein degradation by the proteasome has become a focus area of scientific interest. Here, we describe a proteomics approach for the molecular mapping of the constituents of the proteolytically active core particle, the constitutive 20S proteasome from mouse intestine. In addition to the proteomics workflow widely used for protein isolation, gel electrophoretic separation, in-gel digestion, and UV-MALDI mass spectrometry, high-resolution Fourier transform ion cyclotron resonance mass spectrometry using infrared-MALDI ionisation (IR-MALDI FTICR-MS) has been employed as an efficient method for protein identification by peptide mass fingerprint. The 20S proteasome subunits alpha1-alpha7 and beta1-beta7 were completely and unambiguously identified. In addition to subunits beta1 and beta2, the corresponding inducible subunits being part of the immuno-proteasome were identified. The subunit beta5i was found to completely replace the corresponding constitutive subunit, suggesting a high proteolytic activity of the intestinal proteasome leading to increased production of antigenic peptides. The high mass accuracy in the low ppm range and resolution of FTICR-MS provide direct identifications of individual proteins as mixtures such as components resulting from incomplete electrophoretic separation. In addition, the comparison of UV- and IR-MALDI FTICR-MS may provide details of fragmentation and rearrangement reactions that may occur under UV-MALDI ionisation conditions.