In-flow protein immobilization monitored by magnetic resonance imaging.

Protein immobilization is a key enabling technology for flow biocatalysis. For this purpose, many different immobilization protocols and characterization techniques have been developed in recent decades. However, examples where proteins are directly immobilized on ready-to-use reactors are scarce, likely due to the lack of analytical tools to monitor in-flow protein immobilization in a non-invasive manner. Here, we have for the first time exploited Magnetic Resonance Imaging (MRI) to characterize in-flow protein immobilization on pre-packed bed columns. This concept was demonstrated by in-flow immobilization of a green fluorescence protein. MRI analysis revealed that both the protein concentration of the flushed solution and flow rate play key roles in controlling the spatial organization of the protein across the packed-bed reactor. This analytical tool coupled to in-flow protein immobilization has been expanded to more industrially relevant enzymes, such as the lipase from Thermomyces lanuginosus, achieving a ready-to-use reactor packed with a heterogeneous biocatalyst with high activity (up to 3000 U × g-1) and high stability (75% residual activity after 1 h incubation at 60 °C). Introducing new analytical tools during the fabrication of heterogeneous biocatalysts will contribute to make the process of immobilizing proteins on solid carriers more rational than currently is.

Direct and label-free detection of the human growth hormone in urine by an ultrasensitive bimodal waveguide biosensor.

A label-free interferometric transducer showing a theoretical detection limit for homogeneous sensing of 5 × 10-8 RIU, being equivalent to a protein mass coverage resolution of 2.8 fg mm-2 , is used to develop a high sensitive biosensor for protein detection. The extreme sensitivity of this transducer combined with a selective bioreceptor layer enables the direct evaluation of the human growth hormone (hGH) in undiluted urine matrix in the 10 pg mL-1 range.