posted on 2023-01-19, 16:05authored byZiyi Cao, Dustin M. Harmon, Ruochen Yang, Aleksandr Razumtcev, Minghe Li, Mark S. Carlsen, Andreas C. Geiger, Dmitry Zemlyanov, Alex M. Sherman, Nita Takanti, Jiayue Rong, Yechan Hwang, Lynne S. Taylor, Garth J. Simpson
The use of periodically structured illumination coupled
with spatial
Fourier-transform fluorescence recovery after photobleaching (FT-FRAP)
was shown to support diffusivity mapping within segmented domains
of arbitrary shape. Periodic “comb-bleach” patterning
of the excitation beam during photobleaching encoded spatial maps
of diffusion onto harmonic peaks in the spatial Fourier transform.
Diffusion manifests as a simple exponential decay of a given harmonic,
improving the signal to noise ratio and simplifying mathematical analysis.
Image segmentation prior to Fourier transformation was shown to support
pooling for signal to noise enhancement for regions of arbitrary shape
expected to exhibit similar diffusivity within a domain. Following
proof-of-concept analyses based on simulations with known ground-truth
maps, diffusion imaging by FT-FRAP was used to map spatially-resolved
diffusion differences within phase-separated domains of model amorphous
solid dispersion spin-cast thin films. Notably, multi-harmonic analysis
by FT-FRAP was able to definitively discriminate and quantify the
roles of internal diffusion and exchange to higher mobility interfacial
layers in modeling the recovery kinetics within thin amorphous/amorphous
phase-separated domains, with interfacial diffusion playing a critical
role in recovery. These results have direct implications for the design
of amorphous systems for stable storage and efficacious delivery of
therapeutic molecules.