AB Cochlear Implants deliver the proven benefits of clearer speech and a broader range of sound.
AB recipients are able to hear the softest to the very loudest sounds without having to change any settings. This means that, as an AB recipient, you have access to all of the changes in loudness with music while also being able to hear the soft whispers of children.
From the graphs below, Advanced Bionics surpasses the competition in all areas due to the superior temporal (time) and spectral resolution (frequency) and input dynamic (loudness) range1,2,3,4.
The HiRes technology in the AB device allows for access to finer qualities of speech like frequency (pitch) and time, enabling better speech understanding and music enjoyment5,6,7. As an adult AB CI recipient you will have the best opportunity to reconnect with the hearing world; your child, as an AB CI recipient, can have access to the best speech and language development possible with the added benefit of technology that will meet the growing needs of your child8,9,10.
When choosing a device, you should consider that the implantable technology can be with you for a lifetime. So, the device you choose should be capable of delivering all of the details (loudness, pitch, and time) you need to enjoy a world of sound.
The AB cochlear implant from Advanced Bionics was designed to capture the details of sound. It automatically encodes an incredibly wide range of intensities (up to 80 decibels). It is capable of delivering frequency information to 120 cochlear places using a patented delivery method. It also provides up to 83,000 pulses per second1. That is far more detail than any other system can deliver.
We pushed the limits of technology to provide the most detailed representation of sound because we want you to get the most out of every listening experience.
HiRes™ Ultra Cochlear Implant
Designed for a gentle cochlear insertion,11,12,13 the electrodes deliver 120 spectral bands of sound to help you understand speech and enjoy music.14
Advanced technology designed to support current and future generations of sound processors and features.
This sophisticated communication link receives digital representations of sound from the external sound processor and sends information about the status of the implant system and your hearing nerve back to the processor.
Provides a reliable connection to the externa headpiece. It is safe for standard MRI scans and can easily be removed and replaced if more powerful scans are necessary.
Two implant types, HiRes Ultra Cochlear Implant and HiRes 90K family Cochlear Implants are available with Advanced Bionics. Each implant type offers electrode choices to accommodate for anatomical differences, and your surgeon's practice preference.
AB Cochlear Implants utilize forward-thinking technologies, designed to accommodate signal processing improvements for decades to come, ideal for the demanding needs of adults and the ever-changing needs of children as they grow.
Upgrade your sound processor and enjoy new listening features and expanded capabilities without changing your implant.
AB Cochlear Implants are designed to exceed industry standards for impact resistance,15 allowing you or your child to enjoy life’s adventures without concern.
AB offers an implant option designed to be thin, small, and discreet, making them suitable for adults and children.
MRI is a common imaging technique used in hospitals. This diagnostic equipment generates powerful magnetic fields, and not all medical devices are compatible with this technology.
With an AB Cochlear Implant, a conventional MRI can be performed easily16 and a more powerful clinical MRI can be performed with a minor modification.
With two unique options to choose from in the HiFocus family of electrodes, surgeons can choose the most appropriate type of electrode to suit individual recipient needs and provide the best possible hearing.
The HiFocus SlimJ electrode features a thin, straight design while still offering full spectrum coverage with a key goal of protecting the delicate structures of the cochlea during insertion.
The HiFocus MidScala electrode features have been developed to insert easily and gently for offering full spectrum coverage with a key goal of protecting the delicate structures of the cochlea during insertion.
Ruckenstein M (2012) Cochlear Implants and Other Implantable Hearing Devices
Koch D. B., Downing M., Osberger M. J., and Litvak L. (2007). “ Using current steering to increase spectral resolution in CII and HiRes 90K users,” Ear Hear. 28(2)
Chang YT, Yang HM, Lin YH, Liu SH, Wu JL. Tone discrimination and speech perception benefit in Mandarin speaking children fit with HiRes fidelity 120 sound processing. Otol Neurotol. 2009 Sep;30(6):750-7. doi: 10.1097/MAO.0b013e3181b286b2.
Adams D, Ajimsha KM, Barberá MT, Gazibegovic D, Gisbert J, Gómez J, Raveh E, Rocca C, Romanet P, Seebens Y, Zarowski A., Multicentre evaluation of music perception in adult users of Advanced Bionics cochlear implants Cochlear Implants Int. 2014 Jan;15(1):20-6. doi: 10.1179/1754762813Y.0000000032. Epub 2013 Nov 25.
Firszt JB, Koch DB, Downing M, Litvak L. (2007) Current steering creates additional pitch percepts in adult cochlear implant recipients. Otology and Neurotology, 28(5):629-636.
Koch DB, Osberger MJ, Segel P, Kessler DK. (2004) HiResolution and conventional sound processing in the HiResolution Bionic Ear: using appropriate outcome measures to assess speech-recognition ability. Audiology and Neurotology, 9:214-223.
Spahr A, Dorman MF, Loiselle LH. 2007. Performance of Patients Using Different Cochlear Implant Systems: Effects of Input Dynamic Range. Ear and Hearing. 28:260-275.
Levitin D (2007) - This is your brain on music, the science of a human obsession
Moira Y (2002). Tone. (Cambridge Textbooks in Linguistics), Cambridge: Cambridge University Press.
Hirst D, Di Cristo A (1998). A survey of intonation systems. In: D. Hirst, A. Di Cristo (Eds.). Intonation Systems, a Survey of Twenty Languages. Cambridge University Press Cambridge (1998)
Hassepass F. Bulla S. Maier W. Laszig R. Arndt S. Beck R. Traser L., Aschendorff A. (2014) The New Mid-Scala Electrode Array: A Radiologic, and Histologic Study in Human Temporal Bones. Otology and Neurotology. 35:1415-1420.
Lenarz T, Prenzler N, Salcher R, Andreas Buechner A (2017) First experience with a new thin lateral electrode array. American Cochlear Implant Alliance, San Francisco, July 26–29, 2017.
Rivas A, Isaacson B, Kim A, Driscoll C, Cullen R, Rebscher S, (2017) New Lateral Wall Electrode, Evaluation of Surgical Handling, Radiological Placement, and Histological Appraisal of Insertion Trauma , San Francisco, July 26 -29, 2017.
Osberger MJ, Quick A, Arnold L, Boyle P. (2010) Music benefits with HiRes Fidelity 120 sound processing.Cochlear Implants Intl 11 Suppl 1:351-354.
EN 45502-2-3:2010. Active Implantable Medical Devices. Particular Requirements for Cochlear and Auditory Brainstem Implant Systems.
The procedure requires the use of the Antenna Coil Cover and following the head-bandage procedure as outlined in the Instructions for Use.
Frijns JHM, Kalkman RK, Vanpoucke FJ, Bongers JS, Briaire JJ. Simultaneous and non-simultaneous dual electrode stimulation in cochlear implants: evidence for two neural response modalities. Acta Otolaryngol. 2009 Apr; 129(4):433-9.
Stakhovskaya O, Sridhar D, Bonham BH, et al. Frequency map for the human cochlear spiral ganglion: Implications for cochlear implants. J Assoc Res Otolaryngol. 2007 8: 220-233.
Holden LK, Finley CC, Firszt JB, Holden TA, Brenner C, Potts LG, Gotter BD, Vanderhoof SS, Mispagel K, Heyebrand G, Skinner MW. Factors affecting open-set word recognition in adults with cochlear implants. Ear and Hearing. 2013 Jan 23; Epub.