Imaging of Fluorophores in Chromatographic Beads, Reconstruction of Radial Density Distributions and Characterisation of Protein Uptaking Processes

Stanislawski, Bernd; Schmit, Elodie; Ohser, Joachim

doi:10.5566/ias.v29.p181-189

Cited by 5 publications

(1 citation statement)

References 21 publications

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“…When Raman spectroscopy is applied to study distribution of unlabeled protein in the chromatographic particles, it provides additional benefits as an excellent tool to characterize protein secondary structure (Figure ). In addition, spectral normalization based on characteristic Raman bands of the particle (Figures and ) provides a nondestructive experimental avenue to correct the light attenuation effect caused by RI mismatching in the particle, unlike cross-sectioning of the particle and mathematical modeling ,, used during CLSM studies. With this new approach, quantitative comparison of protein in the chromatographic particles can be possible for the two ionic strength conditions investigated in this report.…”

Section: Discussionmentioning

confidence: 99%

Confocal Raman Microscopy of Protein Adsorbed in Chromatographic Particles

Xiao¹,

Stone²,

Bell³

et al. 2012

Anal. Chem.

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Confocal Raman microscopy is a nondestructive analytical technique that combines the chemical information from vibrational spectroscopy with the spatial resolution of confocal microscopy. It was applied, for the first time, to measure conformation and distribution of protein adsorbed in wetted chromatographic particles. Monoclonal antibody was loaded into the Fractogel EMD SO(3) (M) cation exchanger at 2 mS/cm or 10 mS/cm. Amide I and III frequencies in the Raman spectrum of the adsorbed protein suggest that there are no detectable changes of the original β-sheet conformation in the chromatographic particles. Protein depth profile measurements indicate that, when the conductivity is increased from 2 mS/cm to 10 mS/cm, there is a change in mass transport mechanism for protein adsorption, from the shrinking-core model to the homogeneous-diffusion model. In this study, the use of confocal Raman microscopy to measure protein distribution in chromatographic particles fundamentally agrees with previous confocal laser scanning microscopic investigations, but confocal Raman spectroscopy enjoys additional advantages: use of unlabeled protein to eliminate fluorescent labeling, ability for characterization of protein secondary structure, and ability for spectral normalization to provide a nondestructive experimental approach to correct light attenuation effects caused by refractive index (RI) mismatching in semiopaque chromatographic particles.

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