Single cell analysis of Chinese hamster ovary cells during a bioprocess using a novel dynamic imaging system.

Reliable monitoring of mammalian cells in bioreactors is essential to biopharmaceutical production. Trypan blue exclusion is a method of determining cell density and viability that has been used for over one hundred years to monitor cells in culture and is the current standard method in biomanufacturing. This method has many disadvantages however and there is a growing demand for more detailed and in-line measurements of cell growth in bioreactors. This article assesses a novel dynamic imaging system for single cell analysis. This data shows that comparable total cell density, viable cell density and percentage viability data shown here, generated by the imaging system, aligned well with conventional trypan blue counting methods for an industrially relevant Chinese Hamster Ovary (CHO) cell line. Furthermore, detailed statistical analysis shows that the classification system used by the PharmaFlow system can reveal trends of interest in monitoring the health of mammalian cells over a 6-day bioreactor culture. The system is also capable of sampling at-line, removing the necessity for taking samples off-line and enabling real time monitoring of cells in a bioreactor culture.

Synthesis and Pro-Apoptotic Effects of Nitrovinylanthracenes and Related Compounds in Chronic Lymphocytic Leukaemia (CLL) and Burkitt's Lymphoma (BL).

Chronic lymphocytic leukaemia (CLL) is a malignancy of the immune B lymphocyte cells and is the most common leukaemia diagnosed in developed countries. In this paper, we report the synthesis and antiproliferative effects of a series of (E)-9-(2-nitrovinyl)anthracenes and related nitrostyrene compounds in CLL cell lines and also in Burkitt's lymphoma (BL) cell lines, a rare form of non-Hodgkin's immune B-cell lymphoma. The nitrostyrene scaffold was identified as a lead structure for the development of effective compounds targeting BL and CLL. The series of structurally diverse nitrostyrenes was synthesised via Henry-Knoevenagel condensation reactions. Single-crystal X-ray analysis confirmed the structure of (E)-9-chloro-10-(2-nitrobut-1-en-1-yl)anthracene (19f) and the related 4-(anthracen-9-yl)-1H-1,2,3-triazole (30a). The (E)-9-(2-nitrovinyl)anthracenes 19a, 19g and 19i-19m were found to elicit potent antiproliferative effects in both BL cell lines EBV-MUTU-1 (chemosensitive) and EBV+ DG-75 (chemoresistant) with >90% inhibition at 10 µM. Selected (E)-9-(2-nitrovinyl)anthracenes demonstrated potent antiproliferative activity in CLL cell lines, with IC50 values of 0.17 µM (HG-3) and 1.3 µM (PGA-1) for compound 19g. The pro-apoptotic effects of the most potent compounds 19a, 19g, 19i, 19l and 19m were demonstrated in both CLL cell lines HG-3 and PGA-1. The (E)-nitrostyrene and (E)-9-(2-nitrovinyl)anthracene series of compounds offer potential for further development as novel chemotherapeutics for CLL.

Applications of bio-capacitance to cell culture manufacturing.

This review focuses on why bio-capacitance has developed to become the standard online method to estimate biomass in cell-based bio-manufacturing processes. There is now a good understanding behind the apparent divergence seen between bio-capacitance and trypan blue based cell counts in the later stage of culture through recent works in the field of process monitoring. Methods for how various authors have been able to correct the bio-capacitance signal when required are discussed in this work. There is also a focus on the diversification and development of the probes for single use and smaller bioreactors. The review then describes the wide range of applications where bio-capacitance probes have been able to improve productivity. It includes on-line process control of perfusion-based processes, predictive feeding control of bioreactors, applications with attached cells and viral production. The work discusses the importance of scalability and the ability to validate the probes prior to manufacture and also reveals the additional process information that can be gleamed from the technology.

High-throughput and high-sensitivity N-Glycan profiling: A platform for biopharmaceutical development and disease biomarker discovery.

Protein glycosylation contributes to critical biological function of glycoproteins. Glycan analysis is essential for the production of biopharmaceuticals as well as for the identification of disease biomarkers. However, glycans are highly heterogeneous, which has considerably hampered the progress of glycomics. Here, we present an improved 96-well plate format platform for streamlined glycan profiling that takes advantage of rapid glycoprotein denaturation, deglycosylation, fluorescent derivatization, and on-matrix glycan clean-up. This approach offers high sensitivity with consistent identification and quantification of diverse N-glycans across multiple samples on a high-throughput scale. We demonstrate its capability for N-glycan profiling of glycoproteins from various sources, including two recombinant monoclonal antibodies produced from Chinese Hamster Ovary cells, EG2-hFc and rituximab, polyclonal antibodies purified from human serum, and total glycoproteins from human serum. Combined with the complementary information obtained by sequential digestion from exoglycosidase arrays, this approach allows the detection and identification of multiple N-glycans in these complex biological samples. The reagents, workflow, and Hydrophilic interaction liquid chromatography with fluorescence detection (HILIC-FLD), are simple enough to be implemented into a straightforward user-friendly setup. This improved technology provides a powerful tool in support of rapid advancement of glycan analysis for biopharmaceutical development and biomarker discovery for clinical disease diagnosis.

Mammalian cell culture for production of recombinant proteins: A review of the critical steps in their biomanufacturing.

The manufacturing of recombinant protein is traditionally undertaken in mammalian cell culture. Today, speed, cost and safety are the primary considerations for process improvements in both upstream and downstream manufacturing. Leaders in the biopharmaceutical industry are striving for continuous improvements to increase throughput, lower costs and produce safer more efficacious drugs. This can be achieved through advances in cell line engineering, process development of cell culture, development of chemically defined media and increased emphasis on product characterization. In the first part, this review provides a historical perspective on approved biotherapeutics by regulatory bodies which pave the way for next-generation products (including gene therapy). In the second part, it focuses on the application of in vitro and in vivo cell line engineering approaches, modern process development improvements including continuous manufacturing, recent developments in media formulation, and improvements in critical quality attribute determinations for products produced predominantly in mammalian cells.