Heat Shock Therapy to Improve Mitochondrial Function in Neuropathy

Summary

Sensory dysfunction as a result of peripheral nerve damage is a significant problem that leads to reduced quality of life for patients. The prevalence of sensory dysfunction in peripheral neuropathy associates with epidemic increases in prediabetes and diabetes, but also is relevant to chemotherapy treatments and genetic disorders. Clinical approaches to treat peripheral neuropathy and to stimulate axon growth in settings of peripheral axon loss are limited. Although new drugs will hopefully be forthcoming, the most promising approaches likely involve behavioral and lifestyle interventions. Mitochondrial dysfunction is emerging as a key cellular contribution to peripheral axon health and peripheral neuropathy. Mitochondrial deficiencies contribute to neuropathy and include impaired mitochondrial problems with trafficking, mitophagy, fission, and biogenesis. All of these are thought to lead to a bioenergetic crisis, ending in distal axonal degeneration, sensory dysfunction and pain. Heat shock proteins play a critically important role in cellular homeostasis and increasing heat shock protein functions within cells leads to a range of positive improvements, particularly in mitochondria. In addition, new evidence suggests that increasing heat shock protein responses in peripheral nerves has powerful, positive impacts on sensory function and neuropathy.

Our interdisciplinary team will investigate the role of mitochondrial dysfunction in peripheral neuropathy and translate these approaches to improve treatment for patients with peripheral neuropathy. The investigators hypothesize that novel heat treatment interventions that improve mitochondrial function will improve metabolic symptoms and peripheral nerve mitochondria, leading to improvements in sensory function, via heat shock protein induction. The investigators will employ immersion heat treatment to elevate heat shock protein responses that induce positive changes in peripheral nerve mitochondria. One aspect is to confirm the efficacy, safety, and potential for heat treatment to improve sensory dysfunction in human patients with prediabetes. The goal of this proposal is 1) to test the breadth of heat treatment on various forms of neuropathy, 2) identify mechanisms in which heat treatment improves mitochondrial function, and 3) test the efficacy, safety, and potential for heat treatment to improve sensory dysfunction in human patients with prediabetes.

Conditions

• PreDiabetes
• Neuropathy

Interventions

BEHAVIORAL

Heat Therapy

Subjects will undergo 12 hot water immersions of 40.5 degrees Celsius for approximately 45 minutes per session over 4 weeks. Subjects will be immersed up to the shoulder in a 40°C hot tub until rectal temperature (Tre) increases by 1°C (\~20 minutes). Subjects will then remain in the water bath submerged to waist level to maintain Tre between 38.5 and 39.0°C for another 30 minutes (approx. total time submerged \~50 minutes). Following hot water immersion, subjects will be monitored for another 10 min, or until Tre falls below 38.5°C. Core temperature will be monitored using either 1) a rectal probe with sterile disposable sheaths or 2) a sterile disposable rectal thermistor probe (401 A/C, Advanced Industrial Systems, Inc., Harrods Creek, KY) to be inserted \~1 inch past the anal sphincter (inserted by participant). Heart rate and blood pressure will be monitored throughout the treatment. Subjects will be continually monitored and removed from the hot bath if Tre exceeds 39.5°C.

Sponsors & Collaborators

• University of Kansas Medical Center

  lead OTHER

Principal Investigators

• Paige Geiger, PhD · University of Kansas Medical Center

Study Design

Allocation

NA

Purpose

TREATMENT

Masking

NONE

Model

SINGLE_GROUP

Eligibility

Min Age

45 Years

Max Age

75 Years

Sex

ALL

Healthy Volunteers

No

Timeline & Regulatory

Start

2020-07-27

Primary Completion

2022-07-11

Completion

2022-07-11

Countries

• United States

Study Locations