RESUMEN
BACKGROUND: Hearing rehabilitation of patients with severe hearing loss by cochlear implant (CI) enhances their opportunities for communication immensely with regard to their normal-hearing social environment. The degree of participation depends decisively on speech discrimination. This study examines whether speech discrimination can be improved by equipping patients with next-generation speech processors (SP). METHODS: The changes in speech discrimination of 420 CI patients upon receiving a newer SP from 2003-2012 were retrospectively analyzed. Audiometry comprised the Freiburg number and monosyllable tests and the Oldenburg sentence test in quiet and noise, with a presentation volume of 70â¯dB. RESULTS: In all audiometric tests, the newer SP showed a significant improvement compared to the preceding SP. This improvement was attainable for the majority of patients and was independent of age. CONCLUSION: Upgrade of the SP results in improved speech discrimination. This holds true for several test settings. We therefore recommend earlier upgrades and that the costs for new SP be met.
Asunto(s)
Implantación Coclear , Implantes Cocleares , Sordera , Percepción del Habla , Comprensión , Sordera/rehabilitación , Humanos , Estudios Retrospectivos , HablaRESUMEN
The present work reports on the development of a new generation of Lab-on-a-chip (LOC) to perform in-situ and real-time potentiometric measurements in flowing water. The device consisted of two differentiated parts: a poly (dimethylsiloxane) (PDMS) microfluidic structure obtained by soft lithography and a fully integrated chemical sensing platform including four working microelectrodes, two reference microelectrodes and one counter microelectrode for detecting ammonium in a continuous mode. The performance of the device was evaluated following its potentiometric response when analyzing ammonium containing samples. As a key parameter, its time of response was compared to that of a commercially available electrical conductivity sensor used as reference sensor during tests in laboratory using flowing tap water and technical scale using flowing wastewater. As a result, the LOC showed a slope of 55â¯mV/decade, a limit of detection of 4·10-5â¯M and a time of full response between 10 and 12â¯s. It was demonstrated that the device can provide fast and reliable data at real time when immersed in a laminar flow of water. Moreover, the test of robustness showed that it was still functional after immersion in sewage for at least 15â¯min. Besides, the LOC reported here can be helpful for a wide variety of flowing-water applications such as aqua culture outlets control, in-situ and continuous analysis of rivers effluents and sea waters monitoring among others.