Characterization of human vocal fold fibroblasts derived from chronic scar
ME Jetté, SD Hayer, SL Thibeault - The Laryngoscope, 2013 - Wiley Online Library
ME Jetté, SD Hayer, SL Thibeault
The Laryngoscope, 2013•Wiley Online LibraryAbstract Objectives/Hypothesis: In vitro modeling of cell‐matrix interactions that occur during
human vocal fold scarring is uncommon, as primary human vocal fold scar fibroblast cell
lines are difficult to acquire. The purpose of this study was to characterize morphologic
features, growth kinetics, contractile properties, α‐smooth muscle actin (α‐SMA) protein
expression and gene expression profile of human vocal fold fibroblasts derived from scar
(sVFF) relative to normal vocal fold fibroblasts (nVFF). Study Design: In vitro. Methods: We …
human vocal fold scarring is uncommon, as primary human vocal fold scar fibroblast cell
lines are difficult to acquire. The purpose of this study was to characterize morphologic
features, growth kinetics, contractile properties, α‐smooth muscle actin (α‐SMA) protein
expression and gene expression profile of human vocal fold fibroblasts derived from scar
(sVFF) relative to normal vocal fold fibroblasts (nVFF). Study Design: In vitro. Methods: We …
Objectives/Hypothesis
In vitro modeling of cell‐matrix interactions that occur during human vocal fold scarring is uncommon, as primary human vocal fold scar fibroblast cell lines are difficult to acquire. The purpose of this study was to characterize morphologic features, growth kinetics, contractile properties, α‐smooth muscle actin (α‐SMA) protein expression and gene expression profile of human vocal fold fibroblasts derived from scar (sVFF) relative to normal vocal fold fibroblasts (nVFF).
Study Design
In vitro.
Methods
We successfully cultured human vocal fold fibroblasts from tissue explants of scarred vocal folds from a 56‐year‐old female and compared these to normal fibroblasts from a 59‐year‐old female. Growth and proliferation were assessed by daily cell counts, and morphology was compared at 60% confluence for 5 days. Gel contraction assays were evaluated after seeding cells within a collagen matrix. α‐SMA was measured using western blotting and immunocytochemistry (ICC). Quantitative reverse‐transcriptase polymerase chain reaction (qRT‐PCR) was used to assess differential extracellular matrix gene expression between the two cell types.
Results
sVFF were morphologically indistinguishable from nVFF. sVFF maintained significantly lower proliferation rates relative to nVFF on days 3 to 6 (day 3: P = .0138; days 4, 5, and 6: P < .0001). There were no significant differences in contractile properties between the two cell types at any time point (0 hours: P = .70, 24 hours: P = .79, 48 hours: P = .58). ICC and western blot analyses revealed increased expression of α‐SMA in sVFF as compared with nVFF at passages 4 and 5, but not at passage 6 (passage 4: P = .006, passage 5: P = .0015, passage 6: P = .8860). Analysis of 84 extracellular matrix genes using qRT‐PCR revealed differential expression of 15 genes (P < .01).
Conclusions
nVFF and sVFF displayed differences in proliferation rates, α‐SMA expression, and gene expression, whereas no differences were observed in contractile properties or morphology. Further investigation with a larger sample size is necessary to confirm these findings. Laryngoscope, 2013
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