Achieving Mild Therapeutic Hypothermia in the Human Cochlea

Noninvasive Targeted Temperature Management of the Inner Ear: Numerical Simulations and Experimental Measurements in a Human Cadaver Model

HYPOTHESIS

Mild therapeutic hypothermia (MTH) could be delivered to the human inner ear using a localized, noninvasive approach to achieve protective temperature reductions without systemic side effects.

BACKGROUND

MTH has demonstrated protective effects in the cochlea following injuries such as device implantation, ototoxicity, and noise overexposure. It targets key cellular mechanisms, including proinflammatory pathways, oxidative stress, pyroptosis, and apoptosis. However, systemic and invasive methods for MTH carry risks and are less practical for broader clinical applications. Developing a localized, noninvasive approach could offer a safer, more accessible solution for hearing preservation after cochlear injury.

METHODS

Cadaveric middle and inner ear structures, maintained near physiological conditions, were used to test a custom-designed cooling gel pack (ReBound) placed externally on the temporal bone. Temperature changes were recorded over 60 or 30 minutes. To complement experimental findings, three-dimensional geometrical models were created from imaging data, and finite element heat transfer analysis simulated temperature changes across inner ear structures.

RESULTS

With external gel pack application, inner ear temperatures dropped by 2.9°C within 30 minutes and 4.6°C within 60 minutes. Cooling persisted for 10 minutes post-device removal. Numerical modeling corroborated these findings, indicating average temperature reductions of 2°C to 4°C. Biological sex differences were observed in cooling efficiency and overall temperature drop.

CONCLUSION

This study demonstrates that localized, noninvasive MTH can effectively reduce inner ear temperatures to therapeutically relevant levels. These findings support a promising, clinically translatable approach for protecting cochlear structure and function after injury, with minimal systemic risks.

Targeted therapeutic hypothermia protects against noise induced hearing loss

Introduction

Exposure to occupational or recreational loud noise activates multiple biological regulatory circuits and damages the cochlea, causing permanent changes in hearing sensitivity. Currently, no effective clinical therapy is available for the treatment or mitigation of noise-induced hearing loss (NIHL). Here, we describe an application of localized and non-invasive therapeutic hypothermia and targeted temperature management of the inner ear to prevent NIHL.

Methods

We developed a custom-designed cooling neck collar to reduce the temperature of the inner ear by 3-4°C post-injury to deliver mild therapeutic hypothermia.

Results

This localized and non-invasive therapeutic hypothermia successfully mitigated NIHL in rats. Our results show that mild hypothermia can be applied quickly and safely to the inner ear following noise exposure. We show that localized hypothermia after NIHL preserves residual hearing and rescues noise-induced synaptopathy over a period of months.

Discussion

This study establishes a minimally-invasive therapeutic paradigm with a high potential for rapid translation to the clinic for long-term preservation of hearing health.