The Balanced Electromagnetic Separation Transducer for Bone Conduction Audiometry and Hearing Rehabilitation
Hearing via air conduction (AC) and bone conduction (BC) are attributed to be
the natural ways of conducting sound to the cochlea. With AC hearing, air pressure
variations are transmitted to the cochlea via the ear canal, whereas with BC
hearing, sound vibrations are transmitted through the skull bone to the cochlea.
Patients with a hearing loss in the cochlea or auditory nerve are commonly rehabilitated
with conventional AC hearing aids in the ear canal, but also using cochlear
implants. If the pathway for AC sound to reach the cochlea is obstructed, patients
can often benet from bone conduction devices (BCDs). In order to determine
the type and degree of hearing loss, the BC hearing thresholds are measured using
a bone conduction vibrator, and then analyzed together with the AC hearing
thresholds for the diagnosis and to suggest an appropriate rehabilitation alternative.
The motor unit in conventional BCDs and bone vibrators are known to
generate high amount of distortion at low frequencies where the Balanced Electromagnetic
Separation Transducer (BEST) principle may oer a new era in BC
hearing rehabilitation and audiometry.
This thesis combines two BC hearing related topics, where the rst topic is an
evaluation of a new audiometric bone vibrator, Radioear B81, which is assumed
to oer more accurate BC hearing threshold measurements. The second topic is
related to a new type of active transcutaneous BCD, called the Bone Conduction
Implant (BCI), which leaves the skin intact by using a wireless solution that
does not require a permanent skin penetration. Even though the applications are
dierent, both devices use the BEST principle as motor unit in their design.
The audiometric bone vibrator Radioear B81 was found to have an improved
performance at low frequencies where it can produce higher output levels with less
harmonic distortion than the conventional Radioear B71. In a clinical study of the
rst six patients, the BCI was found as ecient as already commercially available
BCDs, and with the advantage of not needing a skin penetration. In a technical
evaluation of the BCI, it was shown to be a mechanically robust design and to
tolerate magnetic resonance imaging at 1.5 Tesla.
balanced electromagnetic separation transducer
magnetically induced torque
magnetic resonance imaging