Abstract
Agent based models (ABM) were developed to numerically simulate the biological response to surgical vocal fold injury and repair at the physiological level. This study aimed to improve the representation of existing ABM through a combination of empirical and computational experiments. Empirical data of vocal fold cell populations including neutrophils, macrophages and fibroblasts were obtained using flow cytometry up to four weeks following surgical injury. Random Forests were used as a sensitivity analysis method to identify model parameters that were most influential to ABM outputs. Statistical Parameter Optimization Tool for Python was used to calibrate those parameter values to match the ABM-simulation data with the corresponding empirical data from Day 1 to Day 5 following surgery. Model performance was evaluated by verifying if the empirical data fell within the 95% confidence intervals of ABM outputs of cell quantities at Day 7, Week 2 and Week 4. For Day 7, all empirical data were within the ABM output ranges. The trends of ABM-simulated cell populations were also qualitatively comparable to those of the empirical data beyond Day 7. Exact values, however, fell outside of the 95% statistical confidence intervals. Parameters related to fibroblast proliferation were indicative to the ABM-simulation of fibroblast dynamics in final stages of wound healing.
Highlights
Voice disorders involve impairments with varying pitch, quality and loudness in daily conversation as well as in occupational voice use such as during voice performance and teaching
Parameters related to fibroblast proliferation were indicative to the Agent based models (ABM)-simulation of fibroblast dynamics in final stages of wound healing
The primary goal of this study was to improve the accuracy of existing vocal fold agent-based models (VF-ABM) in simulating cellular and molecular activities associated with surgical vocal fold injury and repair
Summary
Voice disorders involve impairments with varying pitch, quality and loudness in daily conversation as well as in occupational voice use such as during voice performance and teaching. Vocal fold scarring is considered as one of the most perplexing clinical problems [1,2,3]. Current treatment options to fully repair the fibrotic tissue are deemed to be limited [2,3,4]. Vocal fold scars can develop within the lamina propria after surgical removal of benign or malignant vocal fold lesions. The scarred tissue alters the microarchitecture and vibratory functions of the vocal folds, resulting in a debilitating condition of the human voice, namely, dysphonia [2,3,4,5,6,7,8]. Iatrogenic vocal fold scarring triggers a cascade of cellular and molecular events associated with inflammation and
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