Evaluation of a robotic system for the recovery of peripheral blood mononuclear cells.

Investigations into immune responses are often based upon recovery of peripheral blood mononuclear cells (PBMC). To this purpose, the recovery of PBMC by gradient centrifugation is labour-intensive and requires a reasonable level of skill by the laboratory technician. Thus, we set out to determine whether laboratory automation equipment could be used for the recovery of PBMC from blood samples of horses, pigs and cattle, based on the Ficoll-Paque gradient centrifugation technique. Mixing of blood samples with PBS, layering of diluted blood onto Ficoll-Paque gradients, recovery of separated PBMC in RPMI 1640 medium were performed using an automated robotic system, the SBF200 (AM Robotic Systems, Warrington, UK) under laminar air flow conditions. Tubes were tagged with bar codes and manually placed after gradient centrifugation into a tube reader to measure the volume and position of the PBMC layer. The results of the automated procedure compared very well to those of the manual one in terms of percent cell recovery, sterility and cell viability. Also, a high throughput of samples could be implemented: with the integration of cell counting it should be possible for 96 blood samples to be processed, including the production of aliquots, by one person in a day.

Designing an automated blood fractionation system.

BACKGROUND: UK Biobank will be collecting blood samples from a cohort of 500 000 volunteers and it is expected that the rate of collection will peak at approximately 3000 blood collection tubes per day. These samples need to be prepared for long-term storage. It is not considered practical to manually process this quantity of samples so an automated blood fractionation system is required. METHODS: Principles of industrial automation were applied to the blood fractionation process leading to the requirement of developing a vision system to identify the blood fractions within the blood collection tube so that the fractions can be accurately aspirated and dispensed into micro-tubes. A prototype was manufactured and tested on a range of human blood samples collected in different tube types. RESULTS: A specially designed vision system was capable of accurately measuring the position of the plasma meniscus, plasma/buffy coat interface and the red cells/buffy coat interface within a vacutainer. A rack of 24 vacutainers could be processed in <5 min. CONCLUSION: An automated, high throughput blood fractionation system offers a solution to the problem of processing human blood samples collected in vacutainers in a consistent manner and provides a means of ensuring data and sample integrity.