A major bottleneck is the identification of relevant product assays

that can be performed in a highly automated fashion and that are resilient to the diverse conditions typically found in developmental studies. Assays to support purification process development have contrasting demands compared to those for release testing. In purification development, feedstocks are usually in short supply so volume requirements for the assays must be Sorafenib mw minimal. Second, the assay should ideally be microplate-based so as to facilitate parallel processing. The assays should be simple, straightforward and rapid as multiple assays may be performed to support a single screen. Integration with robotic liquid handling systems and the typical room temperature environment of the robots is also desired. Another significant issue is assay interference because in-process samples typically have high levels of impurities that can interfere with assays. When combined with lower polysaccharide titres than are found in pure drug substance, this puts stringent demands on assay robustness. Fortunately,

the requirements for accuracy are less stringent than for a release assay. Moreover, as purification HTPD favours the screening of purification conditions in a 96-well microplate, the precision of an assay is often more important than the accuracy. The results from a single screen are compared only within the screen, and the best conditions are subsequently verified with a scaled up process. Most vaccine release assays are specified by the World Health Organization Selleckchem CT99021 (WHO) or Pharmacopoeia organizations and have not changed much in decades.

The relevant established assays and key drawbacks are highlighted in Table 1. While these assays are suitable and highly accurate for the release testing of highly concentrated, relatively pure formulations, Dipeptidyl peptidase they are poorly suited for integration in a high throughput purification context. Typical vaccine release specifications and in-process concentrations provide insight into analytical requirements. The European Pharmacopeia and WHO release specifications for protein and DNA levels in polysaccharide-containing vaccines do not require exhaustively sensitive analytics. With release specifications generally ≤1–3% (w/w CPS) protein or DNA and ≤100 IU/mg polysaccharide for endotoxin, detecting minute quantities of impurities is not necessary [8], [9], [10], [11], [12], [13], [14] and [15]. The conclusion is similar for titre measurements, where in-process polysaccharide concentrations typically range from 0.1 to 10 mg/mL. In this context, quantifying much less than 0.01 mg/mL holds diminishing value. This latter point is driven in part by the modest equilibrium purification factors that can be expected from a single stage purification experiment performed in a microwell.