Hearing Loss, Cochlear Clinical Trial
Official title:
Expanded Indications in the MED-EL Pediatric Cochlear Implant Population
Sixty (60) subjects between the ages of 7 months and 5 years, 11 months will be implanted with the MED-EL SYNCHRONY/SYNCHRONY 2 Cochlear Implant System. All subjects will demonstrate a severe to profound sensorineural hearing loss (SNHL) in the high frequencies (2000 Hz and above) and insufficient functional access to sound with appropriately fit amplification and aural habilitation. Additionally, subjects implanted under 12 months of age will demonstrate a severe to profound sensorineural hearing loss, defined by a 3-frequency Pure Tone Average (PTA) of ≥ 70 dB HL at 500, 1000 and 2000 Hz, while subjects 12 months to 5 years, 11 months of age will demonstrate a mild to profound sensorineural hearing loss in the low frequencies, defined by a 3-frequency PTA of ≥ 25 dB HL at 500, 1000 and 2000 Hz. For the purposes of this study, insufficient functional access to sound for children who lack the requisite language to complete open-set word recognition testing will be based on the LittlEARS Auditory Questionnaire (LEAQ) and defined as a Total Score below the expected value for normal hearing (NH) children of the same chronological age1. For children with the requisite language to complete MLNT/LNT testing, insufficient functional access to sound will be defined by word recognition scores of ≤ 60% on the MLNT/LNT. Subjects will be followed for twelve (12) months following initial activation of the audio processor, with post-operative evaluations occurring at device.
First enacted in 2000, the federal Early Hearing Detection and Intervention (EHDI) Act aims
to identify hearing loss and provide early intervention at an early age for children in all
50 states. According to the CDC, untreated hearing loss not only delays a child's speech and
language development, but also his or her thinking, learning and social skills. The first
three goals of the EHDI program are often referred to as the 1-3-6 plan, meaning that all
newborns will be screened for hearing loss before one month of age and, if needed, undergo a
diagnostic audiological evaluation before 3 months of age and receive appropriate early
intervention services before six months of age.
With the current FDA-approved indications for cochlear implantation limited to children 12
months of age and older, this creates a significant gap between identification and
appropriate intervention for children with hearing loss that cannot be optimally fit with
conventional amplification. This has created a large population of children who are fit with
hearing aids by 6 months of age and must wait an additional 6 months without sufficient
access to spoken language before receiving a cochlear implant. For children with congenital
hearing loss, this results in greater developmental delays and additional hardships in
closing that gap. The current study aims to evaluate the safety and effectiveness of
implantation in children below the age of 12 months and, thus, reduce the gap between
identification of hearing loss and appropriate intervention.
A number of studies have published data on the safety and effectiveness of cochlear
implantation in children below 12 months of age. Several studies have demonstrated that
cochlear implantation can be performed safely in children 6-12 months of age, with no greater
surgical or anesthetic complications than those expected in older children and adults.
Furthermore, a number of studies report substantial benefit in children implanted between 6
and 12 months of age, compared to those implanted after 12 months of age. In 2000, Waltzman
and Roland concluded that "it is possible that severely to profoundly deaf children can avoid
the gaps in auditory perception that require learning at a faster-than-normal rate to enable
them to reach the age-appropriate levels." In 2004, Lesinski-Schiedat et al. reported that
children implanted before the age of 1 year show a superior rate of progress and greatly
superior speech understanding at 2.5 years of age, compared to children implanted between the
ages of 1 and 2 years. A 2005 publication by Colletti et al. found that children implanted
prior to 12 months of age show a more rapid increase in Categories of Auditory Performance
test (CAP) scores than those implanted after 12 months. In some cases, early implantation led
to speech and language development similar to that of normal hearing children. Schauwers et
al. reported that "children implanted in their first year of life showed a normal CAP
development as early as 3 months after implantation."
While early studies indicate that the sensitive period for word identification extends to
approximately three years of age, more recent studies demonstrate that speech production and
language development have much earlier sensitive periods. Leigh and colleagues suggest "that
the critical period for speech perception extends beyond the first year of life, whereas the
critical period for language development is within the first year of life." This, in part,
may explain contradictory findings within and across studies showing a limited or modest
advantage for speech perception and auditory skill development,versus more significant
benefits for speech production, language development, and developmental trajectories, in
children implanted by 12 months of age, compared to those implanted after 12 months of age.
In general, however, many studies agree that language delay is positively correlated with age
at implantation.
There is also a growing body of evidence that cochlear implants can provide significant
improvements for children with residual hearing, compared to traditional hearing aids. Recent
studies have shown that pediatric cochlear implant candidates with pre-operative thresholds
and speech perception scores outside of the current FDA-approved criteria continue to
struggle with conventional amplification. Authors suggest that traditional hearing aids
provide inadequate high-frequency amplification, particularly for patients with steeply
sloping hearing losses (the amount of loss changes dramatically from the low to
high-frequency area), resulting in poorer speech understanding in noise and at presentation
levels below 70 dB SPL. Wilson and colleagues also suggest that "the use of frequency
transposition aids will show good detection, but the more important discrimination resolution
will be compromised." Furthermore, the amount of gain required with conventional
amplification for severe losses can result in distortions of the speech signal.
A number of studies in both children and adults with severe hearing loss or a ski-slope
configuration demonstrate significant benefit with cochlear implants and combined
electric-acoustic stimulation, compared to acoustic amplification. In 2016, Wilson et al.
reported that "all children in the investigator's group have preserved hearing and perform
better with their CI than with their hearing aids, regardless of the level of preservation."
Gratacap and colleagues also demonstrated post-operative improvement in word scores for
children with varying degrees and configurations of residual hearing, stratified into five
groups. Group 1, for example, included five children with low-frequency residual hearing and
average open-set word scores of 79 percent, pre-operatively, and 86 percent post-operatively.
Overall, pre-operative open-set word scores were greater than 50 percent in 22 of 53
children, with a group mean for all subjects of 48 percent. The group mean, open-set word
scores improved to 74 percent at 12 months and 81 percent at 24 months post-operatively. All
five groups showed statistically significant improvement on the open-set word list (OSW) at
24 months post-operatively, and the authors concluded that "CIs provide better results
compared with hearing aids in children with residual hearing".
Preliminary studies on the use of electric-acoustic stimulation (EAS) in children demonstrate
hearing preservation, improved speech perception in quiet and noise, subjective benefit, and
improved classroom listening skills. Kuthubutheen et al. demonstrated significant improvement
in both monosyllabic word scores and sentence scores in children with normal or aidable
residual hearing in the low frequencies. Pre-operative word scores on the NU-CHIP were
between 50 and 72 percent, for an average of 57 percent. Subjects showed improved speech
perception scores on monosyllabic word and sentences in quiet and in noise at three, six,
twelve, and 18 months post-activation, compared to pre-operative performance with hearing
aids. Monosyllabic word scores on the NU-CHIP (test for young children includes pictures) at
18 months post-activation ranged from 72 to 98 percent, for an average of 86 percent and a
group mean improvement of 29 percentage points.
Multi-center clinical trials in adults with the MED-EL Electric-Acoustic Stimulation (EAS)
System and Nucleus Hybrid show significant improvement with combined electric and acoustic
stimulation for patients with normal or aidable residual hearing in the low frequencies.
FDA-approved indications for this population include adults with pre-operative monosyllabic
word scores of up to 60% in the ear to be implanted. Clinical trials with the MED-EL EAS
System showed significant improvement post-operatively in both the EAS and CI-alone
conditions, compared to pre-operative performance with hearing aids. This demonstrates that
patients with residual hearing and pre-operative performance of 60% can benefit from cochlear
implantation, even without acoustic amplification.
Recent publications argue that candidacy criteria in the pediatric cochlear implant
population should be at least equal to that in the adult population. Gifford contends that
"given the critical importance of hearing for various aspects of a child's neurodevelopmental
abilities, having such stringent criteria for pediatric implant candidacy holds considerable
potential to negatively impact a child's neural development, academic success, psychosocial
skills, and overall quality of life." Similarly, Carlson et al. state that "ironically,
audiometric criteria for cochlear implantation are significantly more restrictive for
pediatric patients compared to adults, yet it is the early formative years of life that are
most critical to speech and language development." Thus, many authors advocate for a
large-scale reassessment of pediatric cochlear implant candidacy.
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