Algorithm for optical characterization of dielectric gradient index nanofilm by surface plasmon resonance spectroscopy

A numerical algorithm for determining the refractive index profiles of gradient nanofilms is proposed. A physical justification for the necessity of using spectroscopic measurements in surface plasmon resonance sensing in addition to angular measurements for the unambiguous reconstruction of the shape of the gradient refractive index profile is given. The proposed approach can be effective for nanofilms made of dielectric materials transparent in the IR and THz range.

Investigations of Surface Interactions between PEGDA-Polymer and Drug using Surface Plasmon Resonance

For the development of combination products, the determination of the release kinetics of polymer-based drug delivery systems (DDS) is a central and often timeconsuming investigation. Classical methods are often unsuitable for large-scale screening of potential polymers for combination products. We present a rapid method based on surface plasmon resonance spectroscopy (SPR), using PEGDA700 (Poly(ethylene glycol) diacrylate, average molecular weight (Mn) 700) as an example. This method is capable of determinating the kinetics of drug association and subsequent release within minutes. The proportion of desorption and diffusion can be determined separately. Surface plasmon resonance spectroscopy (SPR) is a label-free and very sensitive optical technique, which allows for real-time observation of surface interactions. The prepared SPR chips were spin-coated with PEGDA700 and crosslinked via photoinduced polymerization. The association and dissociation kinetics of dexamethasone phosphate in swollen PEGDA700 have been studied at different concentrations. The maximum loading of the surface was also obtained by this method. The study of PEGDA presented here identified the wellestablished SPR-based spectroscopy as a potential tool in the development of combination products.

Disrupting the CD177:proteinase 3 membrane complex reduces anti-PR3 antibody-induced neutrophil activation

CD177 is a neutrophil-specific receptor presenting proteinase 3 (PR3) autoantigen on the neutrophil surface. CD177 expression is restricted to a neutrophil subset resulting in CD177pos/mPR3high and CD177neg/mPR3low populations. The size of the CD177pos/mPR3high subset has implications for anti-neutrophil cytoplasmic autoantibody (ANCA)-associated autoimmune vasculitis (AAV) where patients harbor PR3-specific ANCA that activate neutrophils for degranulation. We generated high affinity anti-CD177 monoclonal antibodies, some of which interfered with PR3 binding to CD177 (PR3 "blockers") as determined by surface plasmon resonance spectroscopy, and used them to test the effect of competing PR3 from the surface of CD177pos neutrophils. Because intact anti-CD177 antibodies also caused neutrophil activation, we prepared non-activating Fab fragments of a PR3 blocker and non-blocker that bound specifically to CD177pos neutrophils by flow cytometry. We observed that Fab blocker clone 40, but not non-blocker clone 80, dosedependently reduced anti-PR3 antibody binding to CD177pos neutrophils. Importantly, preincubation with clone 40 significantly reduced respiratory burst in primed neutrophils challenged either with monoclonal antibodies to PR3 or PR3- ANCA IgG from AAV patients. After separating the two CD177/mPR3 neutrophil subsets from individual donors by magnetic sorting, we found that PR3-ANCA provoked significantly more superoxide production in CD177pos/mPR3high than in CD177neg/mPR3low neutrophils, and that anti- CD177 Fab clone 40 reduced the superoxide production of CD177pos cells to the level of the CD177neg cells. Our data demonstrate the importance of the CD177:PR3 membrane complex in maintaining a high ANCA epitope density and thereby underscore the contribution of CD177 to the severity of PR3-ANCA diseases.