Electrochemical biosensors have revolutionized glucose monitoring but have not yet fulfilled their promise of a low cost, direct detection replacement for genetic amplification tests such as PCR [K. Kerman, M. Kobayashi, E. Tamiya, Recent trends in electrochemical DNA biosensor technology, Meas. Sci. Technol. 15 (2004) R1-R11; A. Chaubey, B.D. Malhotra, Mediated biosensors. Biosens. Bioelectron. 17 (6-7) (2002) 441-456]. It has been anticipated that the integration of nanoscale chemical structures such as self-assembled monolayers with electrochemical biosensors would increase sensitivity by decreasing inherent system noise. We have designed a novel biosensing approach incorporating such integration and achieved rapid, ultra-low concentration sensitivities without target amplification. Raw samples are mixed with lysis buffer to allow hybridization of nucleic acid targets with anchor and signal probes before immobilizing a signaling enzyme proximate to the biosensor surface. A bias potential is subsequently applied and the secondary byproduct of a cyclic peroxidase reaction measured. Further studies have demonstrated the application of our approach in protein, clinical chemistry, and ionic assays.
To meet increasing demands for efficient and streamlined production processes of therapeutic antibodies, improved methods of screening clones are required. In this article, we examined the potential of using antibody transcript levels as criteria for clone screening. We evaluated the QuantiGene Plex, a commercially available, high-throughput assay for simultaneously measuring multiple transcripts from cell lysate. Using the development of stable Chinese hamster ovary cell lines as examples, we investigated the relationship between transcript and antibody levels through several rounds of screening. First, we observed that measured heavy chain transcript levels are generally correlated with specific productivity, enabling the identification of high-producing clones from mRNA. Second, we observed that low ratios (< 1.5) of light to heavy chain transcript levels may be indicative of high antibody aggregation levels, allowing for the rapid identification and elimination of clones of questionable product quality. Therefore, an efficient process of identifying high-producing clones of desirable product quality is possible by using QuantiGene Plex assay to measure antibody transcript levels.
Background: Radical reactions result in breakage of the heavy-light chain linkage and hinge cleavage of an IgG1. Results: The degraded products are generated by different reaction pathways and mechanisms. Conclusion: A His 229 /Tyr substitution improves stability and effector function of an IgG1. Significance: A mechanism based strategy to engineer the upper hinge to improve multiple properties of an IgG1 is feasible.
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