Cochlear Implant Used in Gene Therapy to Regrow Auditory Nerves
Researchers at the University of New South Wales (UNSW) in Australia have reportedly for the first time used electrical pulses delivered from a cochlear implant to deliver gene therapy—thereby successfully regrowing auditory nerves.
The research is published in the April 24 edition of Science Translational Medicine.
“People with cochlear implants do well with understanding speech, but their perception of pitch can be poor, so they often miss out on the joy of music,” says UNSW Professor Gary Housley, who is the senior author of the research paper.
“Ultimately, we hope that after further research, people who depend on cochlear implant devices will be able to enjoy a broader dynamic and tonal range of sound, which is particularly important for our sense of the auditory world around us and for music appreciation,” says Dr Housley, who is also the director of the Translational Neuroscience Facility at UNSW Medicine.
The research, which has the support of Australia-based Cochlear Limited through an Australian Research Council Linkage Project grant, has been 5 years in development. It focuses on regenerating surviving nerves after age-related or environmental hearing loss, using existing cochlear technology. The cochlear implants are “surprisingly efficient” at localized gene therapy in the animal model, when a few electric pulses are administered during the implant procedure, says the researchers.
“This research breakthrough is important because while we have had very good outcomes with our cochlear implants so far, if we can get the nerves to grow close to the electrodes and improve the connections between them, then we’ll be able to have even better outcomes in the future,” says Jim Patrick, chief scientist and senior vice-president at Cochlear Limited.
It has long been established that the auditory nerve endings regenerate if neurotrophins—a naturally occurring family of proteins crucial for the development, function, and survival of neurons—are delivered to the cochlea. But, until now, research has stalled because safe localized delivery of the neurotrophins can’t be achieved using drug delivery, nor by viral-based gene therapy.
Dr Housley and his team at UNSW developed a way of using electrical pulses delivered from the cochlear implant to deliver the DNA to the cells close to the array of implanted electrodes. These cells then produce neurotrophins.
“No-one had tried to use the cochlear implant itself for gene therapy,” says Housley. “With our technique, the cochlear implant can be very effective for this.”
While the neurotrophin production dropped away after a couple of months, Housley says ultimately the changes in the hearing nerve may be maintained by the ongoing neural activity generated by the cochlear implant.
“We think it’s possible that in the future this gene delivery would only add a few minutes to the implant procedure,” says the paper’s first author, Jeremy Pinyon, whose PhD is based on this work. “The surgeon who installs the device would inject the DNA solution into the cochlea and then fire electrical impulses to trigger the DNA transfer once the implant is inserted.”
Integration of this technology into other “bionic” devices such as electrode arrays used in deep brain stimulation (for the treatment of Parkinson’s disease and depression, for example) could also afford opportunities for safe, directed gene therapy of complex neurological disorders.
“Our work has implications far beyond hearing disorders,” says coauthor and UNSW associate professor Matthias Klugmann from the university’s Translational Neuroscience Facility research team. “Gene therapy has been suggested as a treatment concept even for devastating neurological conditions and our technology provides a novel platform for safe and efficient gene transfer into tissues as delicate as the brain.
Source: University of New South Wales