Open Access
Increased Retention of Cardiac Cells to a Glass Substrate through Streptavidin–Biotin Affinity
Author(s) -
Kara A. Davis,
Jensen Goh,
Andrea Sebastian,
Brooke M. Ahern,
Christine A. Trinkle,
Jonathan Satin,
Ahmed AbdelLatif,
Brad J. Berron
Publication year - 2021
Publication title -
acs omega
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.779
H-Index - 40
ISSN - 2470-1343
DOI - 10.1021/acsomega.1c02003
Subject(s) - streptavidin , pipette , myocyte , substrate (aquarium) , cardiac myocyte , adhesion , biophysics , biomedical engineering , cell adhesion , chemistry , surface modification , materials science , fluorescence microscope , nanotechnology , biotin , biochemistry , microbiology and biotechnology , fluorescence , composite material , biology , medicine , ecology , physics , quantum mechanics
In vitro analysis of primary isolated adult cardiomyocyte physiological processes often involves optical imaging of dye-loaded cells on a glass substrate. However, when exposed to rapid solution changes, primary cardiomyocytes often move to compromise quantitative measures. Improved immobilization of cells to glass would permit higher throughput assays. Here, we engineer the peripheral membrane of cardiomyocytes with biotin to anchor cardiomyocytes to borosilicate glass coverslips functionalized with streptavidin. We use a rat cardiac myoblast cell line to determine general relationships between processing conditions, ligand density on the cell and the glass substrate, cellular function, and cell retention under shear flow. Use of the streptavidin-biotin system allows for more than 80% retention of cardiac myoblasts under conventional rinsing procedures, while unmodified cells are largely rinsed away. The adhesion system enables the in-field retention of cardiac cells during rapid fluid changes using traditional pipetting or a modern microfluidic system at a flow rate of 160 mL/min. Under fluid flow, the surface-engineered primary adult cardiomyocytes are retained in the field of view of the microscope, while unmodified cells are rinsed away. Importantly, the engineered cardiomyocytes are functional following adhesion to the glass substrate, where contractions are readily observed. When applying this adhesion system to cardiomyocyte functional analysis, we measure calcium release transients by caffeine induction at an 80% success rate compared to 20% without surface engineering.