Abstract
Hearing loss, often caused by prolonged exposure to loud noises, is a critical public health issue,
with the basilar membrane in the cochlea playing a central role in this process. The basilar membrane's ability
to di
erentiate sound frequencies is vital for auditory perception, yet its response to noise exposure and the
subsequent damage to cochlear hair cells are not fully understood. This gap provides a platform to propose
a dynamic-cum-statistical modelling approach to understand the basilar membrane's response to various sound
frequencies and the impact of noise-induced disturbances on hearing. The model incorporates a position-dependent
sensitivity function along the basilar membrane and accounts for both normal and toxic frequencies. By integrating
sensitivity and damage functions, the model demonstrates how di
erent frequencies are processed along the basilar
membrane and evaluates the potential for hair cell damage. We establish the log-normal nature of accumulated
damage, and exploit this feature to develop quanti
able measurables that can be subjected to statistical analysis of
probability, mean, variance, and standard deviation. Theoretical results indicate mechanisms for probability risk
assessment, measuring membrane vulnerability through spatial mapping, and sensitivity dynamics to exposure to
toxic frequencies. The results emphasize the importance of considering cumulative damage and spatial variability
in sensitivity when assessing the risk of hearing loss due to sound exposure. Further re
nement of the model to
account for individual variations in basilar membrane structure and noise exposure patterns is recommended.